CA1203237A - Phosphoramidite compounds and processes - Google Patents
Phosphoramidite compounds and processesInfo
- Publication number
- CA1203237A CA1203237A CA000399518A CA399518A CA1203237A CA 1203237 A CA1203237 A CA 1203237A CA 000399518 A CA000399518 A CA 000399518A CA 399518 A CA399518 A CA 399518A CA 1203237 A CA1203237 A CA 1203237A
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- Prior art keywords
- compound according
- anisylphenylmethyl
- methyl
- carbon atoms
- group
- Prior art date
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- C—CHEMISTRY; METALLURGY
- C07—ORGANIC CHEMISTRY
- C07H—SUGARS; DERIVATIVES THEREOF; NUCLEOSIDES; NUCLEOTIDES; NUCLEIC ACIDS
- C07H21/00—Compounds containing two or more mononucleotide units having separate phosphate or polyphosphate groups linked by saccharide radicals of nucleoside groups, e.g. nucleic acids
Abstract
ABSTRACT OF THE INVENTION
A new class of nucleoside phosphoramidites which are relatively stable to permit isolation thereof and storage at room temperature. The phosphoramidites are derivatives of saturated secondary amines. The nucleoside phosphoramidites are useful in the manufacture of oligo-nucleotides such as, for example, genes.
A new class of nucleoside phosphoramidites which are relatively stable to permit isolation thereof and storage at room temperature. The phosphoramidites are derivatives of saturated secondary amines. The nucleoside phosphoramidites are useful in the manufacture of oligo-nucleotides such as, for example, genes.
Description
~Z~;3 Z37 PHOSPHORAMID~TE COM20UNDS AND PROCESSES
This invention relates to new and useful phosphorus compounds which are particularly useful in the production of oligonucleotides.
The present invention relates to new and useful phosphor~
amidites which are intermediates for polynucleotide synthesis, as well as the improved process for production of oligonucleotides from which polynucleotides are prepared.
Numerous attempts have been made to develop a successful methodology ~or synthesizing sequence defined oligonucleotides.
Howe~er, the stepwise synthesis of polynucleotides, and specifi-cally oligonucleotides still remains a difficult and time consuming task, often with low yields. One prior art technique has included the use of organic polymers as supports during polynucleotide synthesis. Classically the major problems with polymer supported synthesis strategies has been inherent in the nature of the polymer support. ~arious prior art polymers used in such synthesis ha~e proven inadequate for reasons such as: (1) slow diffusion rates o~ activated nucleotides into the support; (2) excessive swelling of various macroporous, low cross-linked support polymers;
and (3) irreversible absorption of reagent onto the polymer. See for example, V. Amarnath and A.D. Broom, Chemical Reviews 77, 183-217 (1977)~
Modified inorganic polymers are known in the prior art, primarily for use as absorption materials, for example, in liquid chromatography. The attachment of nucleosidephosphates to silica gel using a trityl linking group is described in the prior art (H. Koster, Tetrahedron Letters, 1527-1530, 1972) but the method is apparently applicable only to pyrimidine nucleosides. The cleavage of the nucleoside from the silica support can only be accomplished with acid to which the purine n~lcleosides are sensitive.
This specification is related to a copending case assigned to the same assignee and now issued as Canadian Patent No.
1,168,229 on May 29, 1985.
,~,.. "~
~.
)3237 The production of phosphotriester derivatives of oligothymidylates is described in literature (R.L. Letsinger and W.B. Lunsford, Journal of the American Chemical Society, 98:12, 3655-3661) by reaction of a phosphorodichloridite with a 5'-O blocked thymidine and subse~uent reaction of the product with a 3'-O blocked thymidine followed by oxidation of the resulting phosphite to a phosphate and removal of blocking groups to obtain the phosphotriesters; using this procedure, the tetramer and pentamer products, dTpTpTpT and dTpTpTpTpT in which -T is thymidine were prepared. Vnfortunately, the process requires separation and purification of products at each stage to ensure proper sequencing of the added nucleosides. Separation techniques including precipitation and washing of precipitates are necessary to implement each successive stage reaction.
In the aforementioned commonly assigned patent are described methods for forming internucleotide bonds, i.e. bonds linking nucleosides in an oligonucleotide or polynucleotide, by reaction of halophosphoridites with suitably blocked nucleoside or oligonucleo~ide molecules.
The deoxynucleoside-modified silica gel is condensed with a selected nucleotide through formation of a triester phosphite linkage between the 5' -OH of the deoxynucleoside. The phosphite linkage can be produced by first incorporating the phosphite group onto the 5' -OH of the nucleoside on the silica gel followed by condensation with the added nucleoside through the 3' -OH. Alternatively, and preferably, the phosphite group is incorporated into the added nucleoside at the 3' -OH (the 5l -OH
being blocked as by tritylating) and the resulting nucleoside phosphite then reacted with the 5' -OH o the nucleoside of the silica gel.
1 The deoxvnucleoside-modifie~ silica gel can also be condensed with a selected nucleoside through fcrmation of a triester phosphite linkage between the 3' -OH of the deoxy-nucleoside of the silica gel and the 5' -OH of the selected deoxynucleoside. The phosphite li.n]~age can be produced by first incorporating the phosphite group onto the 3' -0~ of the nucleoside on the silica gel followed by condensation with the added nucleoside through the 5' -OH. Alternatively and preferably by this approach, the phosphite group is incor-porated into the added nucleoside at the 5' -OH (3' -OH being hlocked as by tritylating using art form procedures) and the resulting nucleoside phosphite then reacted with the 3' -OH
of the nucleoside on the silica gel.
The general reaction can be represented by the fOllO~ing:
~T ~ B ~ O ~ R
O A O A
t ~ ~ R
~.
o A O
__ p ~ I ~ III
OP~
12~23~7 l The preferred reaction is represented as follows:
HC~B RC ~ ~B
~ A --~A
Ia 1 IIa Rio_p_x RO ~ O- ~ B
--<
O A
) R iO~P _O ~OyB
IIIa ~) 25 wherein ~ is an inorganic polymer linked to the 3' or 5'-0-of the nucleoside through a base hydrolyzable covalent bond:
R iS H or a blocking group; Rl is a hydrocarbyl radical containing up to l0 carbons; each B is a nucleoside or deoxy-nucleoside base; and each A is H, OH or OR4 i.n which R4 is a 30 blocking group; and X is halogen, preferably Cl or Br or a secondary amino group.
1 The compounds of structure II and IIa wherein X
is a 2~ amino group include those in which the amino group is an unsaturated nitrogen heterocycle such as tetrazole, indole, imiclazole, benzimidazole and similar nitrogen 5 heterocycles characterized by at least two ethylenic double bonds, normally conjugated, and which may also include other heteroatoms such as N, S or O. These compounds of structure II and IIa wherein X is such a heterocyclic amine, i.e., one in which the amino nitrogen is a ring heteroatom, 10 are characterized by an extremely high reactivity, and con-sequently relatively low stability, particularly in the indicated preparation of compounds of structure III and IIIa.
These phosphoramidites and the corresponding chloridites from which they are prepared are unstable to water (hydrolysis) 15 and air (oxidation). As a consequence, such compounds can only be maintained under inert atmosphere, usually in sealed containers, at e~tremely low temperatures generally well below 0C. Thus, the use of these compounds in the preparation of compounds of structure III and IIIa requires extreme 20 precautions and careful handling due to the aforesaid high reactivity and low stability.
l'he present new compounds are of structure II and IIa wherein X is a certain type of secondary amlno group.
Specifically, the present new compounds are those in which 25 X is a saturated secondarY amino group, i.e.one in which no double bond is present in the secondary amino radical. ~lore parti-cularly, X is NP'2~3, wherein R'2 and Rl3 taken separately each re-presents alkyl, aralkyl, cycloalkyl and cycloalkylalkyl containing up to 10 carbon atoms, R2 and R3 when taken together form 3oan alkylene chain containing up to 5 carbon atoms in the principal chain and a total of up to 10 carbon atoms with both terminal valence bonds of said chain being attached to the nitrogen atom to which R2 and R3 are attached; and R2 and R3 when taken toaether with the nitrogen atom to 35which they are attached form a saturated nitrogen heterocycle ~V~J
including at least one additional heteroatom from the group con-sisting of nitrogen, oxygen and sulfur.
The present new compounds are not as reactive as those of the a~oresaid patent, and not as unstable. However, the present new compounds do react readily with unblocked 3'-OH or 5'-OH of nucleosides under normal conditions. The present new phosphoramidites are stable under normal laboratory conditions to hydrolysis and air oxidation, and are stored as dry, stable powders. Therefore, the present new phospnoramidites are more lQ efficiently employed in the process of forming internucleotide bonds, particularly in automated processing for formation of oligonucleotides and polynucleotides as described in the afore-said patent.
Amines from which the group NR2R3 can be derived include a wide variety of saturate~ secondary amines such as dimethylamine, diethylamine, diisopl-opylamine, dibutylamine, methylpropylamine, methylhexylamine, methylcyclopropylamine, ethylcyclohexylamine, methylbenzylamine, methylcyclohexylmethyl-amine, butylcyclohexylamine, morpholine, thiomorpholine, pyrrolidine, piperidine, 2,6-dimethylpiperidine, piperazine and similar saturated monocyclic nitrogen heterocycles.
The nucleoside and deoxynucleoside bases represented by B in the above formulae are well known and include purine derivatives, e.g. adenine, hypoxanthine and guanine, and pyri-midine derivatives, e.g. cytosine, uracil and thymine.
The blocking groups represented by R4 in the above formulae include trityl, methoxytrityl, dimethoxytrityl, dialkyl-phosphite, pivalyl, isobutyloxycarbonyl, t-butyl dimethylsilyl, acetyl and similar such blocking groups.
The hydrocarbyl radicals represented by Rl include a wide variety including alkyl, alkenyl, aryl, aralkyl and cyclo-aJ-.yl containing up to about 10 carbon atoms. Representative radicals are methyl, butyl, hexyl, phenethyl, benzyl, cyclohexyl, phenyl, naphthyl, allyl and cyclobutyl. Of these the preferred are lower alkyl, especially methyl and ethyl.
l~V3;23~
Thus in certain embodiments the present invention provides compounds represented by the ~ormula RO ~ ~ B
~.
O A
?_~Ri X
wherein B is a nucleoside or deoxynucleoside base; A is H, OH or OR2 in which R4 is a blocking group, R is a blockin~ group; Ri is a hydrocarbyl radical containing up to about 10 carbon atoms; and X is NR2R3, wherein R2 and R3 taken separately each represent alkyl, aryl, aralkyl, cycloalkyl and cycloalkylalkyl containing up to 10 carbon atoms; R2 and R3 when taken together form an alkylene chain containing up to 5 carbon atoms in the principal chain and a total of up to 10 carbon atoms with both terminal valence bonds of said chain being attached to the nitrogen atom to which R2 and R3 are attached; and R2 and R3 when taken together with the nitrogen atom to which they are attached form a saturated nitrogen heterocycle including at least one addi-tional heteroatom from the group consisting of nitrogen, oxygen and sulfur. In one aspect such a compound is chosen from such compounds wherein:
R is di-p-anisylphenylmethyl, B is l-cytosinyl, Ri is methyl, A is H and X is dimethylamino;
R is di-p-anisylphenylmethyl, B is 9-(N-6-benzoyladeninyl), Ri is methyl, A is H and X is piperidino;
R is di-p-anisylphenylmethyl, B is 9-guaninyl, Ri is methyl, A is H and X is dimethylamino;
R is di-p-anisylphenylmethyl, B is 9-(N-6-benzoyladeninyl), Rl is methyl, A is H and X is morpholino;
R is di-p-anisylphenylmethyl B is thyminyl, Rl is methyl, A is H and X is morpholino;
R is di-p-anisylphenylmethyl, B is l-cytosinyl, Ri is methyl, A is H and X is morpholino;
or R is di-p-anisylphenylmethyl, B is 9-guaninyl, Ri is methyl, A is H and X is morpholino.
In further aspects the in~ention provides such compounds wherein R is di-p-anisylphenylmethyl, B is 9-(N-6-benzoyl-adeninyl), Rl is methyl, A is H and X is dimethylamino; and wherein B is 9-(N-6-acetyladeninyl) or 9-(N-6-isobutyryladeninyl).
,.~, ~
~, .
~2~ 37 -7a-In another aspect the invention provides such compounds wherein R is di-p-anisylphenylmethyll B is 9-(N-6-benzoyl-adeninyl~, Ri is methyl, A is H and X is piperidino;
and wherein B is 9-(N-6-acetyladeninyl) or 9-(N-6-isobutyryladeninyl).
In certain aspects the invention provides compounds having the formulae set out below:
5'-0-di-p-Anisylphenylmethyl-N-isobutyryl-deoxyguanosine 3'-N,N-morpholinomethoxyphosphine.
5'-0-p-Anisyl-l-naphthylphenylmethyldeoxythymi-dine-3'-N,N-morpholinomethoxyphosphine.
5'-0-di-o-Anisyl-l-naphthylmethyl-N-benzoyl-deoxycytidine-3'-N,N-morpholinomethoxyphosphine.
sl-o-p-Tolyldiphenylmethyl-N-benzoyldeoxyaden sine-3'-N,N-morpholinomethoxyphosphine.
5'-0-di-p-Anisylphenylmethyl-N-acetyl-deoxyguanosine-3'-N,N-dimethylaminomethoxyphosphine.
5'-0-di-p-Anisylphenylmethyl-N-benzoyl-deoxyg~anosine-3'-N,N-dimethylamlnomethoxyphosphine.
5'-0-di-o-Anisyl-l-naphthylmethyl-N-acetyl-deoxycytidine-3'-N,N-dimethylaminomethoxyphosphine.
5'-0-di-o-Anisyl-l-naphthylmethyl-N-lsobutyryl-deoxycytidine-3'-N,N-dimethylaminomethoxyphosphine.
5'-0-p-Tolyldiphenylmethyl-N-acetyldeoxyadeno-sine-3'-N,IN-dimethylaminomethoxyphosphine.
5'-0-p-Tolyldiphenylmethyl-N-isobutyryladeno-sine-3'-N,N-dimethylaminomethoxyphosphine.
5'-0-di-p-Anisylphenylmethyl-N-acetyl-deoxyguanosine-3'-N,N-morpholinomethoxyphosphine.
5'-0-di-p-Anisylphenylmethyl-N-benzoyl-deoxyguanosine-3'-N,N-morpholinomethoxyphosphine.
5'-0-di-o-Anisyl-l-naphthylmethyl-N-isobutyryl-deoxycytidine-3'-N,N-morpholinomethoxy?hosphine.
5'-0-di-o-Anisyl-l-napthylmethyl-N-acetyl-deoxycytidine-3'-N,N-morpholinomethoxyDhosphine.
5'-0-p-Tolyldiphenylmethyl-N-acetyldeoxyadeno-sine~3'-N,N-morpholinomethoxyphosine.
5'-0-p-Tolyldiphenylmethyl-N-isobutyryldeoxyadeno-sine-3~-N~N-morpholinomethoxyphosphine.
-7b-In still a further aspect the invention provides such compounds wherein R is di-p-anisylphenylmethyl, B is l-cytosinyl, Ri is methyl, A is H and X is dimethylamino, wherein B is l-(N-4-acetylcytosine), l-(N-~-benzoylcytosine), or l-(N-4-isobutyrylcytosine).
In still a further aspect the in~ention provides such compounds wherein R is di-p-anisylphenylmethyl, B is 9-guaninyl, Ri is methyl, A is H and ~ is dimethylamino, wherein B is 9-(N-6-benzoylguaninyl), 9-(N-6-acetylguaninyl), or 9-(N-6-isobutyrylguaninyl).
Certain preferred new compounds are those of structure IIawherein X is di-lower alkyl amino, pyrrolidino, morpholino or piperidino, particularly preferred being the lower alkyl amino, especially, morpholino, dimethylamino and diethylamino; A is H;
Rl is lower alkyl; R is a trityl group; B is a nucleoside or deoxynucleotide base; and ~ is silica gel.
The new compounds of the present invention can be pre-pared according to art-recognized procedures such as by reaction of the selected secondary amine wit~ the corresponding nucleoside phosphomonochloridite. This reaction is accomplished by dis-solving the said nucleoside in an organic solvent, such as tetrahydrofuran or acetonitrile, and adding the selected secondary amine. After removing unwanted hydrochloride salt, the organic solvent solution of the phosphoramidite may be used as such for polynucleotide synthesis or the product can be isolated from the organic solvent solution and purified before further reaction.
As a further embodiment of the invention, the phosphor-amidites are preferably prepared by forming the desired chloro-(2amino)alkoxyphosphine and thereafter condensing this product with the selected nucleoside. This procedure obviates thedifficulties of handling inherent in the case of the nucleoside phosphomonochlorodite which is susceptible to moisture hydrolysis and air degradation.
The reaction of the chloro-(2amino)alkoxyphosphine is effected in an organic solvent solution of the selected nucleo-side, preferably in the presence of a tertiary amine to take up the hydrogen chloride formed in the condensation reaction~ The reaction proceeds smoothly at room temperature lZ~)3Z3 ~
1 in a dry atmosphere and under an inert gas such as N2 or helium.
Organic solvents useful for this reaction include any solvent which will dissolve the reactants such as diethyl ether, chloroform, methylene chloride, ethylene chloride, ethyl acetate, and the like.
The solution of product is separated from the precipitated hydrochloride salt of the added tertiary amine and can be used as such in forming polynucleotide or alternatively can be separated from the solvent and purified as by crystallization before further use. While the foregoing disclosure has mentioned the use of chloro compounds, it should be understood that bromo compounds can be used as desired with essentially the same results.
When the present new compounds are used in forming internucleotide bonds, they are preferably employed with proton donors. Thus, the phosphoramidites are activated by acidic compounds through protonation which facilitates the desired internucleotide bond formation. The acidic compounds to be employed for the purpose of the said activation are preferably mildly acidic and include, for example, amine hydrohalide salts and nitrogen heterocyclic compounds such as tetrazoles, imidazoles, nitroimidazoles, benzimidazoles and similar nitrogen heterocyclic proton donors. The amine hydrohalide salts to be used for the protonation activation are preferably tertiary amine salts, and, preferably, the hydrochloride salts, although hydrobromide, hydroiodide or hydrofluoride salts can also be used. The aforesaid tertiary amines include, for example, dimethylaniline, diisopropyl-aniline, methylethylaniline, methyldiphenylamine, pyridine and similar tertiary amines.
, , l;Z Q3~37 When the nucleoside is guanosine, i.e. where B is guanine, the use of amine hydrochlorides is not very effective for the purpose of activation, i.e~ by protonation. With those co~pounds in which B is guanine, activation is preferably accomplished with the aforesaid nitrogen heterocyclic hydrogen donors.
Of course, as described in the aforesaid Canadian patent, once the internucleotide bond is formed, the product is then further treated to remove blocking groups, e.g. blocking group R, which permits reaction with a further nucleoside of formula II herein and repeat reaction sives rise to the poly-nucleotide of determined sequence of nucleotides attached to the silica gel through the covalently-bonded linking groups, e.g.
ester linking group.
After each nucleoside is added, the phosphite group preferably should be oxidized to phosphate, usually by reaction with iodine as oxidizing agent, although this can be accomplished by reaction with peroxides such as tertiary butyl peroxide and benzoyl peroxide, as well as hydroperoxides.
The oligonucleotide can then be obtained by hydro-lytic cleavage to separate from the silica gel support, usually after removal of blocking groups such as R blocking groups and blocking groups on the nucleoside base moieties as described in the aforesaid Canadian patent, generally by hydrolysis with ammonia.
., 12V32~7 1 Of particular value as blocking groups definitive of R are arylmethyl groups, including monoaryl dialkymethyl, diaryl monoalkylmethyl and triarylmethyl blocking groups. Of these, the preferred are the triarylmethyl of which the trityl blocking groups are well know. The triarylmethyl blocking groups are generally readily removable but they also afford a method of monitoring the sequencing of oligonucleotides as well as the yield of product obtained. One major criticism of known oligo-nucleotide synthesis is the lack of monitoring of the product produced in successive condensations of nucleotides. Such monitoring would require removal of an aliquot of the reaction system, e.g. the silica gel or other support on which the oligonucleotide is being synthesized, hydrolysis of the product from the support and finally analysis of the product, all of which is time-consuming. Because of this difficulty, oligonucleotides are usually synthesized without appropriate monitoring steps which is most undesirable~ The uise of triarylmethyl blocking groups provides a simple but accurate method of monitoring the sequence of nucleosides in the oligonucleotide product as formed, as well as the yield of product obtained at each stepwise addition of nucleoside.
This method is predicated on color formation by the triarylmethyl cation in the presence of an acid, whether a Lewis acid or a protic acid. By selection of appropriate triarylmethyl blocking groups for the phosphoramidite compound of structures II or IIa herein, which provide distinguishing color in acids, each nucleoside can be labelled with the triarylmethyl group of distinguishing color. As each condensation reaction is completed to form the phosphorus linkage illustrated in compounds of formula III and IIIa herein, the next step in the synthesis is the removal of the blocking group R therefrom. This is conveniently accomplished .i. .
~;~03Z37 with a Lewis acid such as zinc bromide and simultaneously produces a color reaction, e.g. di-p-anisylphenylmethyl group forms an orange color with ZnBr2; when removed from the oligonucleotide.
The color can be used to identify the triarylmethyl blocking group used to identify the initial phosphoramidite employed and also to measure the extent of reaction by measurement of the intensity thereof.
~ ost triarylmethyl groups, in present experience, have shown color production on exposure to acids. In fact, a wide variety of colors has been obtained by varying the make-up of the triarylmethyl group, including as the aryl group not only phenyl and naphthyl but also substituted phenyl and naphthyl, as well as heterocyclic rings such as quinolinyl, furyl, thienyl, and other nitrogen, sulfur and/or oxygen containing heterocyclic rings.
The said aryl groups can include substituents such as halide (F, Cl, Br, I); nitro, alkoxy, alkyl, aryl, aralkyl, cycloalkyl and like hydrocarbyl substituents. In these substituents, the number of carbon atoms should preferably be from l to about 12.
The preferred triarylmethyl groups are represented by the formula:
Rl wherein each of Rl, R2 and R3 is an aryl group such as phenyl, naphthyl, quinolyl, furyl, thienyl, or other nitrogen, sulfur and/or oxygen-containing heterocyclic ring; or such aryl groups with a monosubstituent such as halide (F, Cl, Br or I), nitro, lower alkoxy, lower alkyl, and aryl, aralkyl and cycloalkyl containing up to lO catbon atoms. R2 and R3 each may also be alkyl, cycloalkyl or aralkyl containing up to lO carbon atoms.
Preferable triarylmethyl groups are given in Table I:
~LZ~3Z37 LEGEND ,Rl '~3 ~CH3 ~ OCH3 ~
ta)(b) (c) (d) (e) (f3 (g~ ( ~3~1P2 ~Cl (j)~k) (1) (m) (n) (O) ~ ~ (p) (q) (r) Aryl Functional Groups as Defined in the Legend Color Rl = R2 = c; R3 Orange Rl - c; R2 = b; R3 - a Red Rl = c; R2 = d; R3 = a Orange Rl = c; R2 = q; R3 Colorless Rl = c; R2 = r; R3 = a Colorless Rl = c; R2 = P; R3 = a Red-Orange Rl = R2 = b; R3 = a Black Rl = R2 = q; R3 = a Colorless Rl = R2 = r; R3 = a Colorless Rl = R2 = P; R3 = a Violet-Red Rl = R2 a; R3 Yellow-Orange Rl = R2 = a; R3 Yellow Rl = R2 = a; R3 = d Yellow Rl = R2 = a; R3 q Colorless Rl = R2 = a; R3 Colorless 121~i3237 qABLE I ( CC)ntinued ) Aryl Fun~tional Groups as Def ined in the Legend . Colc r R~ = R2 = c; R3 = n Yiolet R, = R2 = b; R; = n ~lue R, = R2 = p; R3 = n Deep Purple R, = R2 = c; R3 = o Burnt Orange R~ = R2 = c; R3 = p Purple R, = R2 = b; R3 = p Purple R~ = R2 = gi R3 = m ~ellow-Orange R, = R2 = f; R3 = m Colorless R, = R2 = p; R3 = m Peach R, = R2 = e; R3 = m Yellow R, = R2 = d; R3 = m Yellow R~ = R2 = c; R3 = m Yellow Rl = R2 = a; R3 = m Color7ess R~ = R2 = b; R3 = m Lilac Rl = R2 = g; R3 = c - Red-Orange R~ = R2 = f; R3 = c Yellow R, = R2 = p; R3 = c Red Rl = R2 = e; R3 = c Red-Orange R, = R2 = di R3 = c Red Rl = R2 = R = c . Red Rl = g; R2 = a; R3 = i Deep Red R, - f; R2 = a: R3 = i Yellow R. = p; R2 = a; R3 = i Yellow R, = e; R2 = a; R3 = i Red Violet Rl = d; R2 = a; R3 = i Burnt-Orange R, = c; R2 = a; R3 = i Deep Purple 3~ Rl = R~ = a; R~ = i Red-Violet R~ = b; R2 = a; R3 = i Red R, = g; R2 = a; R- = j Yellow Rl = f; R2 = a; R3 = j Yellow ~2~3237 1 TABLE I (continued) Ar~ unctional Groups as Def1ned in the Leqend Color R, = p; R2 = a; R3 = j Colorless Ri = e; R: = a; R~ = j Orange Rl = d; R2 = a; R3 = j Carmine Rl = c; R2 = a; R3 = ~i Deep eurnt Orange Rl = R2 = a; R3 = j Yellow Rl = R2 = 9; R3 - k Yellow Rl = R2 = f; R3 = k Yellow R, = R2 = p; R3 = k Colorless R, = R2 = e; R3 = k Yellow-Orange R, = R2 = d; R3 = k Yellow Rl = R2 = c; R3 = k Orange Rl = R2 ~ a; R3 = k Yellow Rl = g; R2 = R3 = a Yellow Rl = f; R2 = R3 = a Yellow Rl = p; R2 = R3 = a Yellow R, = e; R2 = R3 = a Oranqe R, = R2 = R3 = a Yellow R~ = n; R2 = 1; R3 = a Green Rl = h; R2 = 1; R3 = a Canary Yellow Rl = g; R2 = 1; R3 = a Yellow Rl c; R2 = 1; R3 = a Yellow Orange R~ = n; R2 = 9; R3 = a Green Rl = h R2 = 9; R3 = a Canary Yellow Rl = R2 = g; R3 = a Yellow Rl = ci R~ = g; R3 = a Yellow-Orange Rl = b; R2 = g; R3 = a Yellow 3 Rl = n; R. = R~ = 9 Green lZ~3237 --1 .--1 T~L~ I (continued) Aryl Funstional Groups as Defined in the~ Leqend Colo-Rl = h; R- = R3 = 9 Canary Yello~
Rl = R.- = R~ = g Yello~
R, = b; R2 = R3 = 9 Yellow R, = n; R2 = j; R3 = a Green Rl = h; R2 ~ j; R3 = a Canary Yella~J
Rl = g; R~ = j; R3 - a Yellow Rl = c; R2 = j R3 = a Yello~Y-Orange Rl = n; R2 = R3 = a Green Rl = h; R2 = R3 = a Yellow Rl = a; R2 = e; R3 = n Green Rl = a; R~ = e; R3 = h Yello~
Rl = a; R2 = e; R3 = 9 Yello~
Rl = a; R2 = e; R3 = c Yellow-Orange Rl = a; R2 = c; R3 = n Red 20 All colors were determined by the following procedure:
an aliquot of the hydrolyzed Grignard reaction product (the triarylmethyl alcohol produced by the procedure described in Example V herein) was analyzed by thin layer chromatography. The thin layer plates were then exposed 25 to hydrochloric acid vapor and the color of the trityl cations recorded.
Thus, of the blocking groups de~initive of R, the prererred are the arylmethyl groups, particularly triaryl-methyl groups, and especially those arylmethyl groups which provide a visible color when contacted with acids.
As used herein the symbols for nucleotides and poly-nucleotides and polydeoxynucleotides are according to the IUPAC-IUB Commissioner of Biochemical Nomenclature Recommendations [(1970) Biochemistrv 9, 4022].
The following examples further illustrate the invention.
~Z~3;;:3~7 E Xl\ MP L~
Preparation of phosphoramidites of the formula:
Dl`rTO O
N(CH3)2 represented as compounds I-IV, in which in compound 1, B = l-Thyminyl;
II, B = l-(N-4-benzoylcytosinyl), III, B = 9-(N-6-benzoyladeninyl);
IV, B = 9-(N-2-isobutyrylguaninyl~;
and DMT = di-~-anisylphenylmethyl.
The synthesis of compounds I-IV begins with the preparation of chloro-N, N-dimethylaminomethoxyphosphine ICH30 P(Cl) N(CH3)2] which is used as a monofunctional phos-phitylating agent. A 250 ml addition funnel was charged with 100 ml of precooled anhydrous ether (-78C) and pre-cooled (-78C) anhydrous dimethylamine (45.9 g, 1.02 mol).
The addition funnel was wrapped with aluminum foil containing dry ice in order to avoid evaporation of dimethylamine.
This solution was added dropwise at -15C (ice-acetone bath) over 2 h to a mechanically stirred solution of methoxy-dichlorophosphine (47.7 ml, 67.32 g, 0.51 mol) in 300 ml of anhydrcus ether. The addition funnel was removed and the 1 l.~three-necked round bottom flask was stopPered with serum caps tightened with copper wire. The suspension was mechanically stirred for 2 h at room temperature, then filtered and the amine hydrochloride salt washed with 500 ml anhydrous ether. The combined filtrate and washings were ~;Z03;237 1 distilled at atmospheric pressure and the residue distilled under reduced pressure. The product was distilled at 40-42C 13 mm Hg and was isolated in 71% yield (51.1 g, 0.36 mol). d25 = 1.115 g/ml.
31P-N.M.R., = -179.5 ppm (CDC13) with respect to internal 5% v/v aqueous H3PO4 standard. lH-N.M.~. doublet at 3.8 and 3.6 ppm JP H = 14 ~z (3H, OCH3) and two singlets at 2.8 and 2.6 ppm (6H, N(CH3)2). The mass spectrum showed a parent peak at m/e = 141.
The 4'-O-di-p-anisylphenylmethyl nucleoside (1 mmol) was dissolved in 3 ml of dry, acid free chloroform and diisopropy-lethylamine (4 mmol) in a 10 ml reaction vessel preflushed with dry nitrogen. [CH3OP(Cl)N(CH3)2] (2 mmol) was added dropwise (30-60 sec) by syringe to the solution under nitrogen at room temperature. ~fter 15 min the solution was transferred with 35 ml of ethyl acetate into a 125 ml separatory funnel. The solution was extracted four times with an aqueous, saturated solution of NaCl (80 ml). The organic phase was dried over anhydrous Na2SO4 and evaporated to a foam under reduced pressure. The foam was dissolved with toluene (10 ml) (IV was dissolved with 10 ml of ethyl acetate) and the solution was added dropwise to 50 ml of cold hexanes (-78C) with vigorus stirring. The cold suspension was filtered and the white powder was washed with 75 ml of cold hexanes (-78C). The white powder was dried under reduced pressure and stored under nitrogen. Isolated yields of compounds I-IV were 90-94% (see Table II).
. . .,,~:g ~Z~;~Z3'7 1 ~ ~
1 The purity of the products was checked by 3 P-N.I~i.R.
Additionaily, when analyzed b~ 31P-N.~i.R., these compounds were stable for at least a month wnen stored at room temperature under nitrogen. Furthermore, no si~nificant amount of(3'-3')dinucleoside phosphite was detected by P-N.~ . (less than 4;~). The low content of the~(3'-3'~
dinucleoside phosphite represents a signi~lcant improve-ment over the prior art phosphite couplins procedure where a considerable amount of unwanted (3'-3') dinucleoside phos phite was unavoidable.
The aminophosphoralrlidites I-IV were emplGyed in condensation with 3~-0-blocked nucleosides to form internucleotide bonds. The phosphoramidites were activated by weak acids such as amine hydrochloride salts or tetra-zoles.
A. In the following procedure, the processwas monitored using P-N.M.R. In a 10 mm. N.M.R. tube, 1.2 molar equivalents of 3'-0-levulinylthymidine and collidine were added to a mixture formed by addin~ N,N-dimethylaniline hydrochloride (1 mmol) in 0.5 ml dry CDC13 at room temperature under N2 to amidite compound I (0.5 mmol, -147.7 and -14~.3 ppm) in 2 ml of dry, acid free CDCi3 and an essentially ¢uantitative yield of dinucleoside phosphite Ia (-140.8 and -139.~ ~pm) was obtained.
B. Amidite compound I (0.5 ~mol) and 3'-0-levulinylthyr.idine (0.6 mmol) were placed in a 10 mm N.M.R.
tube and sublimed lH-tetrazole (1.5 mmol) in 2.5 ml of dry acetonitrile d3 was added under nitroqen at~osphere. The 31P-N.~5. R. spectrum was immediately recorded and disp~ayed a 3~ quantitative yield o Ia. Similarly, dinucieosides were obtained when II, III and IV were reacted with 3'-levulinylthymidine to form IIa, IIIa and IVa as shown in Table II. The appropriate chemical shifts of compounds I-IV and Ia-IVa with respect to internal 5% v/v aqueous H3P04 standard are reported in Ta~e I.
w ~ r~
o ~n O ~J1 0 TABLE I T
COMPOU~D ~_ P (ppm) o- P (ppm) ISOLATED YIELD
(Acetone-d6) (CDC13) (%) -146.0, -145.4 -147.7, -146.8 93, 95*
II -146.3, -145.5 -148.0, -147.0 92, 95* ,.
III -146.1 ~ -145.8 -147.4, -147.3 90, 98*
IV -145.9, -145 7 -147.7, -147.2 90, 98* , Ia -139.6, -138.9 -140.8, -139.9 97~*
ILa -139.6, -139.0 -140.6, -140.0 94** r 2 IIIa -139.7, -138.9 -141.0, -139.9 97**
IVa -140.3, -140.2 -143.6, -141.9 93**
*Estimated purity from 31P-N.M.R.
J~*Estimated yield fr(~m 31P-N.M.R.
lZ(~3;~3'~
~Lr IJ
Alternat~ pxocedure for Chloro-N N-disubstituted Aminomethoxyphosphlne A 50 ml droppin~ funnel was char~ed with 31.5~ g of N, N-Dimethylaminotrimethylsilane (42.1 ml, ~.27 mol) which wad a2ded dropwise o~er 1 h under nitrogen atmosphere to 25 ml of cold (-15C) metho~dichlorophosp~llne (35.15 g, 0.27 mol) in a 250 ml round bottom flask. A white unidentified pre-lO cipitate formed during the course of ~he addition. Once the addition was finished, the ice-acetone bath was removed and the suspension was stirred at room temperature for 1 h. The reaction mixture was then slowly vacuum distilled through a one foot long, vacuum jacketed glass helices (3/3 ") column.
15 The product distilled at 40-42C ~l 13 mm Hg and was isolated in 81~ yield (30.77 g, 0.22 mol). d25 = 1.115 g/ml. 31P-N.M.R., = -179.5 ppm (CDC13) with respect to internal 5Qd aqueous H3~o4 standard. 1H-N.M.R. doublet at 3.8 and 3.6 ppm JP-~ =
14 ~lz (3H, OCH3) and two singlets at 2.8 and 2.6 ppm (6H, N(CH3)2, The mass spectrum showed a parent peak at m/e = 141.
Anal. calcd. for C3HgClNOP: C, 24.45; H, 6.42; N, 9.90;
O, 11.30; P, 21.88. Found C, 24.53; H, 6.20; N, 10.04;
O, 11.08; P, 21.44.
The procedure was successfully applied to the pre-paration of chloro-N, N-diethylaminomethoxyphosphine and chloropyrrolidino-metho~.yphosphine.
3o ~Z0323~
The applicability of phosphoramidites I-IV to the synthesis of deoxyoligonucleotides on polymer supports was accomplished by condensing compounds I-IV with N-2-isobutyryl-deoxyguanosine attached covalently to silica gel. Thus, N-2-isobutyryldeoxyguanosine (1 ~mGle) covalently attached to silica gel (20 mg) at the 3'-position, I (10 ~mole), and lH-tetrazole (50 ~mole in 0.1 ml dry acetonitrile) were shaken for 20 min and the reaction was then quenched with aqueous lutidine. The same reaction sequence was effected with II, III and IV. After the usual oxidation and deprotection procedures, d(TpG), d(CpG), d(ApG) and d(GpG) were obtained in 100~, 98~, 94%, and 93% yield respectively (measured spectrometrically from the dimethoxytrityl cation using an extinction of 7 x 104 at 498 nm). These dinucleotides were completely degraded by snake venom phosphodiesterase and the appropriate nucleosides and nucleotides were obtained in the proper ratios (monitored via high pressure liquid chromatography analysis of snake venom phosphodiesterase hydrolysates).
The following deoxynucleotides have been synthesized using this procedure:
d(C-T-C-A-A-A-T-G-G-G-T-C) d(C-C-A-C-A-A-A-C-C~C) d(A-A-A-T-G-C-G-A-C-C-C-A) d(A-G-C-T-A-T-G-G-G-T-T-T) d(T-T-T-G-A-G-C-C-A-A-C-A) d(T-T-A-G-C-T-C-A-C-T-C-A) d(T-C-A-T-C-C T-G-T-T-G-G) d(T-T-A-G-G-C-A-C-C-C) d(G-G-G-C-C-G-A-A-T-T-G-T) d(C-A-G-G-C-T-T-T-A-C-A) d(C-G-G-C-C-C-C-T-T-A-C-T) d(C-T-T-T-A-T-G-C-T-T-C) d(T-C-C-T-C-A-A-G-T-A-A-G) d(C-G-G-C-T-C-G-T-A) d(T-G-A-G-G-A-T-A-A-A-T-T) d(T-G-T-A-C-T-A-A-G~
d (A-T-G-T-G-T-G-A-T-T-T-A) d(G-A-G-G-T-T-G-T-A-T-G) d(G-T-G-G-T-A-A-A-T-C-A~ d(T-A-C-A-T-G-C-A-A) ~ 5 3Z3'~
, , l~;l'L~ I~
5 -~-D~T-~-benzoyldeo~-~yadenosine ~DMTrd(bzl~)]
(.66 g., 1 mmole) in dry T~ (3 ml) is adde~ dropwise un~er 5 an ar~on atmosphere to a stirred solution of the THr (3 containing methvldichlorophosphite (.113 ml, 1.2 m~ole) an~
This invention relates to new and useful phosphorus compounds which are particularly useful in the production of oligonucleotides.
The present invention relates to new and useful phosphor~
amidites which are intermediates for polynucleotide synthesis, as well as the improved process for production of oligonucleotides from which polynucleotides are prepared.
Numerous attempts have been made to develop a successful methodology ~or synthesizing sequence defined oligonucleotides.
Howe~er, the stepwise synthesis of polynucleotides, and specifi-cally oligonucleotides still remains a difficult and time consuming task, often with low yields. One prior art technique has included the use of organic polymers as supports during polynucleotide synthesis. Classically the major problems with polymer supported synthesis strategies has been inherent in the nature of the polymer support. ~arious prior art polymers used in such synthesis ha~e proven inadequate for reasons such as: (1) slow diffusion rates o~ activated nucleotides into the support; (2) excessive swelling of various macroporous, low cross-linked support polymers;
and (3) irreversible absorption of reagent onto the polymer. See for example, V. Amarnath and A.D. Broom, Chemical Reviews 77, 183-217 (1977)~
Modified inorganic polymers are known in the prior art, primarily for use as absorption materials, for example, in liquid chromatography. The attachment of nucleosidephosphates to silica gel using a trityl linking group is described in the prior art (H. Koster, Tetrahedron Letters, 1527-1530, 1972) but the method is apparently applicable only to pyrimidine nucleosides. The cleavage of the nucleoside from the silica support can only be accomplished with acid to which the purine n~lcleosides are sensitive.
This specification is related to a copending case assigned to the same assignee and now issued as Canadian Patent No.
1,168,229 on May 29, 1985.
,~,.. "~
~.
)3237 The production of phosphotriester derivatives of oligothymidylates is described in literature (R.L. Letsinger and W.B. Lunsford, Journal of the American Chemical Society, 98:12, 3655-3661) by reaction of a phosphorodichloridite with a 5'-O blocked thymidine and subse~uent reaction of the product with a 3'-O blocked thymidine followed by oxidation of the resulting phosphite to a phosphate and removal of blocking groups to obtain the phosphotriesters; using this procedure, the tetramer and pentamer products, dTpTpTpT and dTpTpTpTpT in which -T is thymidine were prepared. Vnfortunately, the process requires separation and purification of products at each stage to ensure proper sequencing of the added nucleosides. Separation techniques including precipitation and washing of precipitates are necessary to implement each successive stage reaction.
In the aforementioned commonly assigned patent are described methods for forming internucleotide bonds, i.e. bonds linking nucleosides in an oligonucleotide or polynucleotide, by reaction of halophosphoridites with suitably blocked nucleoside or oligonucleo~ide molecules.
The deoxynucleoside-modified silica gel is condensed with a selected nucleotide through formation of a triester phosphite linkage between the 5' -OH of the deoxynucleoside. The phosphite linkage can be produced by first incorporating the phosphite group onto the 5' -OH of the nucleoside on the silica gel followed by condensation with the added nucleoside through the 3' -OH. Alternatively, and preferably, the phosphite group is incorporated into the added nucleoside at the 3' -OH (the 5l -OH
being blocked as by tritylating) and the resulting nucleoside phosphite then reacted with the 5' -OH o the nucleoside of the silica gel.
1 The deoxvnucleoside-modifie~ silica gel can also be condensed with a selected nucleoside through fcrmation of a triester phosphite linkage between the 3' -OH of the deoxy-nucleoside of the silica gel and the 5' -OH of the selected deoxynucleoside. The phosphite li.n]~age can be produced by first incorporating the phosphite group onto the 3' -0~ of the nucleoside on the silica gel followed by condensation with the added nucleoside through the 5' -OH. Alternatively and preferably by this approach, the phosphite group is incor-porated into the added nucleoside at the 5' -OH (3' -OH being hlocked as by tritylating using art form procedures) and the resulting nucleoside phosphite then reacted with the 3' -OH
of the nucleoside on the silica gel.
The general reaction can be represented by the fOllO~ing:
~T ~ B ~ O ~ R
O A O A
t ~ ~ R
~.
o A O
__ p ~ I ~ III
OP~
12~23~7 l The preferred reaction is represented as follows:
HC~B RC ~ ~B
~ A --~A
Ia 1 IIa Rio_p_x RO ~ O- ~ B
--<
O A
) R iO~P _O ~OyB
IIIa ~) 25 wherein ~ is an inorganic polymer linked to the 3' or 5'-0-of the nucleoside through a base hydrolyzable covalent bond:
R iS H or a blocking group; Rl is a hydrocarbyl radical containing up to l0 carbons; each B is a nucleoside or deoxy-nucleoside base; and each A is H, OH or OR4 i.n which R4 is a 30 blocking group; and X is halogen, preferably Cl or Br or a secondary amino group.
1 The compounds of structure II and IIa wherein X
is a 2~ amino group include those in which the amino group is an unsaturated nitrogen heterocycle such as tetrazole, indole, imiclazole, benzimidazole and similar nitrogen 5 heterocycles characterized by at least two ethylenic double bonds, normally conjugated, and which may also include other heteroatoms such as N, S or O. These compounds of structure II and IIa wherein X is such a heterocyclic amine, i.e., one in which the amino nitrogen is a ring heteroatom, 10 are characterized by an extremely high reactivity, and con-sequently relatively low stability, particularly in the indicated preparation of compounds of structure III and IIIa.
These phosphoramidites and the corresponding chloridites from which they are prepared are unstable to water (hydrolysis) 15 and air (oxidation). As a consequence, such compounds can only be maintained under inert atmosphere, usually in sealed containers, at e~tremely low temperatures generally well below 0C. Thus, the use of these compounds in the preparation of compounds of structure III and IIIa requires extreme 20 precautions and careful handling due to the aforesaid high reactivity and low stability.
l'he present new compounds are of structure II and IIa wherein X is a certain type of secondary amlno group.
Specifically, the present new compounds are those in which 25 X is a saturated secondarY amino group, i.e.one in which no double bond is present in the secondary amino radical. ~lore parti-cularly, X is NP'2~3, wherein R'2 and Rl3 taken separately each re-presents alkyl, aralkyl, cycloalkyl and cycloalkylalkyl containing up to 10 carbon atoms, R2 and R3 when taken together form 3oan alkylene chain containing up to 5 carbon atoms in the principal chain and a total of up to 10 carbon atoms with both terminal valence bonds of said chain being attached to the nitrogen atom to which R2 and R3 are attached; and R2 and R3 when taken toaether with the nitrogen atom to 35which they are attached form a saturated nitrogen heterocycle ~V~J
including at least one additional heteroatom from the group con-sisting of nitrogen, oxygen and sulfur.
The present new compounds are not as reactive as those of the a~oresaid patent, and not as unstable. However, the present new compounds do react readily with unblocked 3'-OH or 5'-OH of nucleosides under normal conditions. The present new phosphoramidites are stable under normal laboratory conditions to hydrolysis and air oxidation, and are stored as dry, stable powders. Therefore, the present new phospnoramidites are more lQ efficiently employed in the process of forming internucleotide bonds, particularly in automated processing for formation of oligonucleotides and polynucleotides as described in the afore-said patent.
Amines from which the group NR2R3 can be derived include a wide variety of saturate~ secondary amines such as dimethylamine, diethylamine, diisopl-opylamine, dibutylamine, methylpropylamine, methylhexylamine, methylcyclopropylamine, ethylcyclohexylamine, methylbenzylamine, methylcyclohexylmethyl-amine, butylcyclohexylamine, morpholine, thiomorpholine, pyrrolidine, piperidine, 2,6-dimethylpiperidine, piperazine and similar saturated monocyclic nitrogen heterocycles.
The nucleoside and deoxynucleoside bases represented by B in the above formulae are well known and include purine derivatives, e.g. adenine, hypoxanthine and guanine, and pyri-midine derivatives, e.g. cytosine, uracil and thymine.
The blocking groups represented by R4 in the above formulae include trityl, methoxytrityl, dimethoxytrityl, dialkyl-phosphite, pivalyl, isobutyloxycarbonyl, t-butyl dimethylsilyl, acetyl and similar such blocking groups.
The hydrocarbyl radicals represented by Rl include a wide variety including alkyl, alkenyl, aryl, aralkyl and cyclo-aJ-.yl containing up to about 10 carbon atoms. Representative radicals are methyl, butyl, hexyl, phenethyl, benzyl, cyclohexyl, phenyl, naphthyl, allyl and cyclobutyl. Of these the preferred are lower alkyl, especially methyl and ethyl.
l~V3;23~
Thus in certain embodiments the present invention provides compounds represented by the ~ormula RO ~ ~ B
~.
O A
?_~Ri X
wherein B is a nucleoside or deoxynucleoside base; A is H, OH or OR2 in which R4 is a blocking group, R is a blockin~ group; Ri is a hydrocarbyl radical containing up to about 10 carbon atoms; and X is NR2R3, wherein R2 and R3 taken separately each represent alkyl, aryl, aralkyl, cycloalkyl and cycloalkylalkyl containing up to 10 carbon atoms; R2 and R3 when taken together form an alkylene chain containing up to 5 carbon atoms in the principal chain and a total of up to 10 carbon atoms with both terminal valence bonds of said chain being attached to the nitrogen atom to which R2 and R3 are attached; and R2 and R3 when taken together with the nitrogen atom to which they are attached form a saturated nitrogen heterocycle including at least one addi-tional heteroatom from the group consisting of nitrogen, oxygen and sulfur. In one aspect such a compound is chosen from such compounds wherein:
R is di-p-anisylphenylmethyl, B is l-cytosinyl, Ri is methyl, A is H and X is dimethylamino;
R is di-p-anisylphenylmethyl, B is 9-(N-6-benzoyladeninyl), Ri is methyl, A is H and X is piperidino;
R is di-p-anisylphenylmethyl, B is 9-guaninyl, Ri is methyl, A is H and X is dimethylamino;
R is di-p-anisylphenylmethyl, B is 9-(N-6-benzoyladeninyl), Rl is methyl, A is H and X is morpholino;
R is di-p-anisylphenylmethyl B is thyminyl, Rl is methyl, A is H and X is morpholino;
R is di-p-anisylphenylmethyl, B is l-cytosinyl, Ri is methyl, A is H and X is morpholino;
or R is di-p-anisylphenylmethyl, B is 9-guaninyl, Ri is methyl, A is H and X is morpholino.
In further aspects the in~ention provides such compounds wherein R is di-p-anisylphenylmethyl, B is 9-(N-6-benzoyl-adeninyl), Rl is methyl, A is H and X is dimethylamino; and wherein B is 9-(N-6-acetyladeninyl) or 9-(N-6-isobutyryladeninyl).
,.~, ~
~, .
~2~ 37 -7a-In another aspect the invention provides such compounds wherein R is di-p-anisylphenylmethyll B is 9-(N-6-benzoyl-adeninyl~, Ri is methyl, A is H and X is piperidino;
and wherein B is 9-(N-6-acetyladeninyl) or 9-(N-6-isobutyryladeninyl).
In certain aspects the invention provides compounds having the formulae set out below:
5'-0-di-p-Anisylphenylmethyl-N-isobutyryl-deoxyguanosine 3'-N,N-morpholinomethoxyphosphine.
5'-0-p-Anisyl-l-naphthylphenylmethyldeoxythymi-dine-3'-N,N-morpholinomethoxyphosphine.
5'-0-di-o-Anisyl-l-naphthylmethyl-N-benzoyl-deoxycytidine-3'-N,N-morpholinomethoxyphosphine.
sl-o-p-Tolyldiphenylmethyl-N-benzoyldeoxyaden sine-3'-N,N-morpholinomethoxyphosphine.
5'-0-di-p-Anisylphenylmethyl-N-acetyl-deoxyguanosine-3'-N,N-dimethylaminomethoxyphosphine.
5'-0-di-p-Anisylphenylmethyl-N-benzoyl-deoxyg~anosine-3'-N,N-dimethylamlnomethoxyphosphine.
5'-0-di-o-Anisyl-l-naphthylmethyl-N-acetyl-deoxycytidine-3'-N,N-dimethylaminomethoxyphosphine.
5'-0-di-o-Anisyl-l-naphthylmethyl-N-lsobutyryl-deoxycytidine-3'-N,N-dimethylaminomethoxyphosphine.
5'-0-p-Tolyldiphenylmethyl-N-acetyldeoxyadeno-sine-3'-N,IN-dimethylaminomethoxyphosphine.
5'-0-p-Tolyldiphenylmethyl-N-isobutyryladeno-sine-3'-N,N-dimethylaminomethoxyphosphine.
5'-0-di-p-Anisylphenylmethyl-N-acetyl-deoxyguanosine-3'-N,N-morpholinomethoxyphosphine.
5'-0-di-p-Anisylphenylmethyl-N-benzoyl-deoxyguanosine-3'-N,N-morpholinomethoxyphosphine.
5'-0-di-o-Anisyl-l-naphthylmethyl-N-isobutyryl-deoxycytidine-3'-N,N-morpholinomethoxy?hosphine.
5'-0-di-o-Anisyl-l-napthylmethyl-N-acetyl-deoxycytidine-3'-N,N-morpholinomethoxyDhosphine.
5'-0-p-Tolyldiphenylmethyl-N-acetyldeoxyadeno-sine~3'-N,N-morpholinomethoxyphosine.
5'-0-p-Tolyldiphenylmethyl-N-isobutyryldeoxyadeno-sine-3~-N~N-morpholinomethoxyphosphine.
-7b-In still a further aspect the invention provides such compounds wherein R is di-p-anisylphenylmethyl, B is l-cytosinyl, Ri is methyl, A is H and X is dimethylamino, wherein B is l-(N-4-acetylcytosine), l-(N-~-benzoylcytosine), or l-(N-4-isobutyrylcytosine).
In still a further aspect the in~ention provides such compounds wherein R is di-p-anisylphenylmethyl, B is 9-guaninyl, Ri is methyl, A is H and ~ is dimethylamino, wherein B is 9-(N-6-benzoylguaninyl), 9-(N-6-acetylguaninyl), or 9-(N-6-isobutyrylguaninyl).
Certain preferred new compounds are those of structure IIawherein X is di-lower alkyl amino, pyrrolidino, morpholino or piperidino, particularly preferred being the lower alkyl amino, especially, morpholino, dimethylamino and diethylamino; A is H;
Rl is lower alkyl; R is a trityl group; B is a nucleoside or deoxynucleotide base; and ~ is silica gel.
The new compounds of the present invention can be pre-pared according to art-recognized procedures such as by reaction of the selected secondary amine wit~ the corresponding nucleoside phosphomonochloridite. This reaction is accomplished by dis-solving the said nucleoside in an organic solvent, such as tetrahydrofuran or acetonitrile, and adding the selected secondary amine. After removing unwanted hydrochloride salt, the organic solvent solution of the phosphoramidite may be used as such for polynucleotide synthesis or the product can be isolated from the organic solvent solution and purified before further reaction.
As a further embodiment of the invention, the phosphor-amidites are preferably prepared by forming the desired chloro-(2amino)alkoxyphosphine and thereafter condensing this product with the selected nucleoside. This procedure obviates thedifficulties of handling inherent in the case of the nucleoside phosphomonochlorodite which is susceptible to moisture hydrolysis and air degradation.
The reaction of the chloro-(2amino)alkoxyphosphine is effected in an organic solvent solution of the selected nucleo-side, preferably in the presence of a tertiary amine to take up the hydrogen chloride formed in the condensation reaction~ The reaction proceeds smoothly at room temperature lZ~)3Z3 ~
1 in a dry atmosphere and under an inert gas such as N2 or helium.
Organic solvents useful for this reaction include any solvent which will dissolve the reactants such as diethyl ether, chloroform, methylene chloride, ethylene chloride, ethyl acetate, and the like.
The solution of product is separated from the precipitated hydrochloride salt of the added tertiary amine and can be used as such in forming polynucleotide or alternatively can be separated from the solvent and purified as by crystallization before further use. While the foregoing disclosure has mentioned the use of chloro compounds, it should be understood that bromo compounds can be used as desired with essentially the same results.
When the present new compounds are used in forming internucleotide bonds, they are preferably employed with proton donors. Thus, the phosphoramidites are activated by acidic compounds through protonation which facilitates the desired internucleotide bond formation. The acidic compounds to be employed for the purpose of the said activation are preferably mildly acidic and include, for example, amine hydrohalide salts and nitrogen heterocyclic compounds such as tetrazoles, imidazoles, nitroimidazoles, benzimidazoles and similar nitrogen heterocyclic proton donors. The amine hydrohalide salts to be used for the protonation activation are preferably tertiary amine salts, and, preferably, the hydrochloride salts, although hydrobromide, hydroiodide or hydrofluoride salts can also be used. The aforesaid tertiary amines include, for example, dimethylaniline, diisopropyl-aniline, methylethylaniline, methyldiphenylamine, pyridine and similar tertiary amines.
, , l;Z Q3~37 When the nucleoside is guanosine, i.e. where B is guanine, the use of amine hydrochlorides is not very effective for the purpose of activation, i.e~ by protonation. With those co~pounds in which B is guanine, activation is preferably accomplished with the aforesaid nitrogen heterocyclic hydrogen donors.
Of course, as described in the aforesaid Canadian patent, once the internucleotide bond is formed, the product is then further treated to remove blocking groups, e.g. blocking group R, which permits reaction with a further nucleoside of formula II herein and repeat reaction sives rise to the poly-nucleotide of determined sequence of nucleotides attached to the silica gel through the covalently-bonded linking groups, e.g.
ester linking group.
After each nucleoside is added, the phosphite group preferably should be oxidized to phosphate, usually by reaction with iodine as oxidizing agent, although this can be accomplished by reaction with peroxides such as tertiary butyl peroxide and benzoyl peroxide, as well as hydroperoxides.
The oligonucleotide can then be obtained by hydro-lytic cleavage to separate from the silica gel support, usually after removal of blocking groups such as R blocking groups and blocking groups on the nucleoside base moieties as described in the aforesaid Canadian patent, generally by hydrolysis with ammonia.
., 12V32~7 1 Of particular value as blocking groups definitive of R are arylmethyl groups, including monoaryl dialkymethyl, diaryl monoalkylmethyl and triarylmethyl blocking groups. Of these, the preferred are the triarylmethyl of which the trityl blocking groups are well know. The triarylmethyl blocking groups are generally readily removable but they also afford a method of monitoring the sequencing of oligonucleotides as well as the yield of product obtained. One major criticism of known oligo-nucleotide synthesis is the lack of monitoring of the product produced in successive condensations of nucleotides. Such monitoring would require removal of an aliquot of the reaction system, e.g. the silica gel or other support on which the oligonucleotide is being synthesized, hydrolysis of the product from the support and finally analysis of the product, all of which is time-consuming. Because of this difficulty, oligonucleotides are usually synthesized without appropriate monitoring steps which is most undesirable~ The uise of triarylmethyl blocking groups provides a simple but accurate method of monitoring the sequence of nucleosides in the oligonucleotide product as formed, as well as the yield of product obtained at each stepwise addition of nucleoside.
This method is predicated on color formation by the triarylmethyl cation in the presence of an acid, whether a Lewis acid or a protic acid. By selection of appropriate triarylmethyl blocking groups for the phosphoramidite compound of structures II or IIa herein, which provide distinguishing color in acids, each nucleoside can be labelled with the triarylmethyl group of distinguishing color. As each condensation reaction is completed to form the phosphorus linkage illustrated in compounds of formula III and IIIa herein, the next step in the synthesis is the removal of the blocking group R therefrom. This is conveniently accomplished .i. .
~;~03Z37 with a Lewis acid such as zinc bromide and simultaneously produces a color reaction, e.g. di-p-anisylphenylmethyl group forms an orange color with ZnBr2; when removed from the oligonucleotide.
The color can be used to identify the triarylmethyl blocking group used to identify the initial phosphoramidite employed and also to measure the extent of reaction by measurement of the intensity thereof.
~ ost triarylmethyl groups, in present experience, have shown color production on exposure to acids. In fact, a wide variety of colors has been obtained by varying the make-up of the triarylmethyl group, including as the aryl group not only phenyl and naphthyl but also substituted phenyl and naphthyl, as well as heterocyclic rings such as quinolinyl, furyl, thienyl, and other nitrogen, sulfur and/or oxygen containing heterocyclic rings.
The said aryl groups can include substituents such as halide (F, Cl, Br, I); nitro, alkoxy, alkyl, aryl, aralkyl, cycloalkyl and like hydrocarbyl substituents. In these substituents, the number of carbon atoms should preferably be from l to about 12.
The preferred triarylmethyl groups are represented by the formula:
Rl wherein each of Rl, R2 and R3 is an aryl group such as phenyl, naphthyl, quinolyl, furyl, thienyl, or other nitrogen, sulfur and/or oxygen-containing heterocyclic ring; or such aryl groups with a monosubstituent such as halide (F, Cl, Br or I), nitro, lower alkoxy, lower alkyl, and aryl, aralkyl and cycloalkyl containing up to lO catbon atoms. R2 and R3 each may also be alkyl, cycloalkyl or aralkyl containing up to lO carbon atoms.
Preferable triarylmethyl groups are given in Table I:
~LZ~3Z37 LEGEND ,Rl '~3 ~CH3 ~ OCH3 ~
ta)(b) (c) (d) (e) (f3 (g~ ( ~3~1P2 ~Cl (j)~k) (1) (m) (n) (O) ~ ~ (p) (q) (r) Aryl Functional Groups as Defined in the Legend Color Rl = R2 = c; R3 Orange Rl - c; R2 = b; R3 - a Red Rl = c; R2 = d; R3 = a Orange Rl = c; R2 = q; R3 Colorless Rl = c; R2 = r; R3 = a Colorless Rl = c; R2 = P; R3 = a Red-Orange Rl = R2 = b; R3 = a Black Rl = R2 = q; R3 = a Colorless Rl = R2 = r; R3 = a Colorless Rl = R2 = P; R3 = a Violet-Red Rl = R2 a; R3 Yellow-Orange Rl = R2 = a; R3 Yellow Rl = R2 = a; R3 = d Yellow Rl = R2 = a; R3 q Colorless Rl = R2 = a; R3 Colorless 121~i3237 qABLE I ( CC)ntinued ) Aryl Fun~tional Groups as Def ined in the Legend . Colc r R~ = R2 = c; R3 = n Yiolet R, = R2 = b; R; = n ~lue R, = R2 = p; R3 = n Deep Purple R, = R2 = c; R3 = o Burnt Orange R~ = R2 = c; R3 = p Purple R, = R2 = b; R3 = p Purple R~ = R2 = gi R3 = m ~ellow-Orange R, = R2 = f; R3 = m Colorless R, = R2 = p; R3 = m Peach R, = R2 = e; R3 = m Yellow R, = R2 = d; R3 = m Yellow R~ = R2 = c; R3 = m Yellow Rl = R2 = a; R3 = m Color7ess R~ = R2 = b; R3 = m Lilac Rl = R2 = g; R3 = c - Red-Orange R~ = R2 = f; R3 = c Yellow R, = R2 = p; R3 = c Red Rl = R2 = e; R3 = c Red-Orange R, = R2 = di R3 = c Red Rl = R2 = R = c . Red Rl = g; R2 = a; R3 = i Deep Red R, - f; R2 = a: R3 = i Yellow R. = p; R2 = a; R3 = i Yellow R, = e; R2 = a; R3 = i Red Violet Rl = d; R2 = a; R3 = i Burnt-Orange R, = c; R2 = a; R3 = i Deep Purple 3~ Rl = R~ = a; R~ = i Red-Violet R~ = b; R2 = a; R3 = i Red R, = g; R2 = a; R- = j Yellow Rl = f; R2 = a; R3 = j Yellow ~2~3237 1 TABLE I (continued) Ar~ unctional Groups as Def1ned in the Leqend Color R, = p; R2 = a; R3 = j Colorless Ri = e; R: = a; R~ = j Orange Rl = d; R2 = a; R3 = j Carmine Rl = c; R2 = a; R3 = ~i Deep eurnt Orange Rl = R2 = a; R3 = j Yellow Rl = R2 = 9; R3 - k Yellow Rl = R2 = f; R3 = k Yellow R, = R2 = p; R3 = k Colorless R, = R2 = e; R3 = k Yellow-Orange R, = R2 = d; R3 = k Yellow Rl = R2 = c; R3 = k Orange Rl = R2 ~ a; R3 = k Yellow Rl = g; R2 = R3 = a Yellow Rl = f; R2 = R3 = a Yellow Rl = p; R2 = R3 = a Yellow R, = e; R2 = R3 = a Oranqe R, = R2 = R3 = a Yellow R~ = n; R2 = 1; R3 = a Green Rl = h; R2 = 1; R3 = a Canary Yellow Rl = g; R2 = 1; R3 = a Yellow Rl c; R2 = 1; R3 = a Yellow Orange R~ = n; R2 = 9; R3 = a Green Rl = h R2 = 9; R3 = a Canary Yellow Rl = R2 = g; R3 = a Yellow Rl = ci R~ = g; R3 = a Yellow-Orange Rl = b; R2 = g; R3 = a Yellow 3 Rl = n; R. = R~ = 9 Green lZ~3237 --1 .--1 T~L~ I (continued) Aryl Funstional Groups as Defined in the~ Leqend Colo-Rl = h; R- = R3 = 9 Canary Yello~
Rl = R.- = R~ = g Yello~
R, = b; R2 = R3 = 9 Yellow R, = n; R2 = j; R3 = a Green Rl = h; R2 ~ j; R3 = a Canary Yella~J
Rl = g; R~ = j; R3 - a Yellow Rl = c; R2 = j R3 = a Yello~Y-Orange Rl = n; R2 = R3 = a Green Rl = h; R2 = R3 = a Yellow Rl = a; R2 = e; R3 = n Green Rl = a; R~ = e; R3 = h Yello~
Rl = a; R2 = e; R3 = 9 Yello~
Rl = a; R2 = e; R3 = c Yellow-Orange Rl = a; R2 = c; R3 = n Red 20 All colors were determined by the following procedure:
an aliquot of the hydrolyzed Grignard reaction product (the triarylmethyl alcohol produced by the procedure described in Example V herein) was analyzed by thin layer chromatography. The thin layer plates were then exposed 25 to hydrochloric acid vapor and the color of the trityl cations recorded.
Thus, of the blocking groups de~initive of R, the prererred are the arylmethyl groups, particularly triaryl-methyl groups, and especially those arylmethyl groups which provide a visible color when contacted with acids.
As used herein the symbols for nucleotides and poly-nucleotides and polydeoxynucleotides are according to the IUPAC-IUB Commissioner of Biochemical Nomenclature Recommendations [(1970) Biochemistrv 9, 4022].
The following examples further illustrate the invention.
~Z~3;;:3~7 E Xl\ MP L~
Preparation of phosphoramidites of the formula:
Dl`rTO O
N(CH3)2 represented as compounds I-IV, in which in compound 1, B = l-Thyminyl;
II, B = l-(N-4-benzoylcytosinyl), III, B = 9-(N-6-benzoyladeninyl);
IV, B = 9-(N-2-isobutyrylguaninyl~;
and DMT = di-~-anisylphenylmethyl.
The synthesis of compounds I-IV begins with the preparation of chloro-N, N-dimethylaminomethoxyphosphine ICH30 P(Cl) N(CH3)2] which is used as a monofunctional phos-phitylating agent. A 250 ml addition funnel was charged with 100 ml of precooled anhydrous ether (-78C) and pre-cooled (-78C) anhydrous dimethylamine (45.9 g, 1.02 mol).
The addition funnel was wrapped with aluminum foil containing dry ice in order to avoid evaporation of dimethylamine.
This solution was added dropwise at -15C (ice-acetone bath) over 2 h to a mechanically stirred solution of methoxy-dichlorophosphine (47.7 ml, 67.32 g, 0.51 mol) in 300 ml of anhydrcus ether. The addition funnel was removed and the 1 l.~three-necked round bottom flask was stopPered with serum caps tightened with copper wire. The suspension was mechanically stirred for 2 h at room temperature, then filtered and the amine hydrochloride salt washed with 500 ml anhydrous ether. The combined filtrate and washings were ~;Z03;237 1 distilled at atmospheric pressure and the residue distilled under reduced pressure. The product was distilled at 40-42C 13 mm Hg and was isolated in 71% yield (51.1 g, 0.36 mol). d25 = 1.115 g/ml.
31P-N.M.R., = -179.5 ppm (CDC13) with respect to internal 5% v/v aqueous H3PO4 standard. lH-N.M.~. doublet at 3.8 and 3.6 ppm JP H = 14 ~z (3H, OCH3) and two singlets at 2.8 and 2.6 ppm (6H, N(CH3)2). The mass spectrum showed a parent peak at m/e = 141.
The 4'-O-di-p-anisylphenylmethyl nucleoside (1 mmol) was dissolved in 3 ml of dry, acid free chloroform and diisopropy-lethylamine (4 mmol) in a 10 ml reaction vessel preflushed with dry nitrogen. [CH3OP(Cl)N(CH3)2] (2 mmol) was added dropwise (30-60 sec) by syringe to the solution under nitrogen at room temperature. ~fter 15 min the solution was transferred with 35 ml of ethyl acetate into a 125 ml separatory funnel. The solution was extracted four times with an aqueous, saturated solution of NaCl (80 ml). The organic phase was dried over anhydrous Na2SO4 and evaporated to a foam under reduced pressure. The foam was dissolved with toluene (10 ml) (IV was dissolved with 10 ml of ethyl acetate) and the solution was added dropwise to 50 ml of cold hexanes (-78C) with vigorus stirring. The cold suspension was filtered and the white powder was washed with 75 ml of cold hexanes (-78C). The white powder was dried under reduced pressure and stored under nitrogen. Isolated yields of compounds I-IV were 90-94% (see Table II).
. . .,,~:g ~Z~;~Z3'7 1 ~ ~
1 The purity of the products was checked by 3 P-N.I~i.R.
Additionaily, when analyzed b~ 31P-N.~i.R., these compounds were stable for at least a month wnen stored at room temperature under nitrogen. Furthermore, no si~nificant amount of(3'-3')dinucleoside phosphite was detected by P-N.~ . (less than 4;~). The low content of the~(3'-3'~
dinucleoside phosphite represents a signi~lcant improve-ment over the prior art phosphite couplins procedure where a considerable amount of unwanted (3'-3') dinucleoside phos phite was unavoidable.
The aminophosphoralrlidites I-IV were emplGyed in condensation with 3~-0-blocked nucleosides to form internucleotide bonds. The phosphoramidites were activated by weak acids such as amine hydrochloride salts or tetra-zoles.
A. In the following procedure, the processwas monitored using P-N.M.R. In a 10 mm. N.M.R. tube, 1.2 molar equivalents of 3'-0-levulinylthymidine and collidine were added to a mixture formed by addin~ N,N-dimethylaniline hydrochloride (1 mmol) in 0.5 ml dry CDC13 at room temperature under N2 to amidite compound I (0.5 mmol, -147.7 and -14~.3 ppm) in 2 ml of dry, acid free CDCi3 and an essentially ¢uantitative yield of dinucleoside phosphite Ia (-140.8 and -139.~ ~pm) was obtained.
B. Amidite compound I (0.5 ~mol) and 3'-0-levulinylthyr.idine (0.6 mmol) were placed in a 10 mm N.M.R.
tube and sublimed lH-tetrazole (1.5 mmol) in 2.5 ml of dry acetonitrile d3 was added under nitroqen at~osphere. The 31P-N.~5. R. spectrum was immediately recorded and disp~ayed a 3~ quantitative yield o Ia. Similarly, dinucieosides were obtained when II, III and IV were reacted with 3'-levulinylthymidine to form IIa, IIIa and IVa as shown in Table II. The appropriate chemical shifts of compounds I-IV and Ia-IVa with respect to internal 5% v/v aqueous H3P04 standard are reported in Ta~e I.
w ~ r~
o ~n O ~J1 0 TABLE I T
COMPOU~D ~_ P (ppm) o- P (ppm) ISOLATED YIELD
(Acetone-d6) (CDC13) (%) -146.0, -145.4 -147.7, -146.8 93, 95*
II -146.3, -145.5 -148.0, -147.0 92, 95* ,.
III -146.1 ~ -145.8 -147.4, -147.3 90, 98*
IV -145.9, -145 7 -147.7, -147.2 90, 98* , Ia -139.6, -138.9 -140.8, -139.9 97~*
ILa -139.6, -139.0 -140.6, -140.0 94** r 2 IIIa -139.7, -138.9 -141.0, -139.9 97**
IVa -140.3, -140.2 -143.6, -141.9 93**
*Estimated purity from 31P-N.M.R.
J~*Estimated yield fr(~m 31P-N.M.R.
lZ(~3;~3'~
~Lr IJ
Alternat~ pxocedure for Chloro-N N-disubstituted Aminomethoxyphosphlne A 50 ml droppin~ funnel was char~ed with 31.5~ g of N, N-Dimethylaminotrimethylsilane (42.1 ml, ~.27 mol) which wad a2ded dropwise o~er 1 h under nitrogen atmosphere to 25 ml of cold (-15C) metho~dichlorophosp~llne (35.15 g, 0.27 mol) in a 250 ml round bottom flask. A white unidentified pre-lO cipitate formed during the course of ~he addition. Once the addition was finished, the ice-acetone bath was removed and the suspension was stirred at room temperature for 1 h. The reaction mixture was then slowly vacuum distilled through a one foot long, vacuum jacketed glass helices (3/3 ") column.
15 The product distilled at 40-42C ~l 13 mm Hg and was isolated in 81~ yield (30.77 g, 0.22 mol). d25 = 1.115 g/ml. 31P-N.M.R., = -179.5 ppm (CDC13) with respect to internal 5Qd aqueous H3~o4 standard. 1H-N.M.R. doublet at 3.8 and 3.6 ppm JP-~ =
14 ~lz (3H, OCH3) and two singlets at 2.8 and 2.6 ppm (6H, N(CH3)2, The mass spectrum showed a parent peak at m/e = 141.
Anal. calcd. for C3HgClNOP: C, 24.45; H, 6.42; N, 9.90;
O, 11.30; P, 21.88. Found C, 24.53; H, 6.20; N, 10.04;
O, 11.08; P, 21.44.
The procedure was successfully applied to the pre-paration of chloro-N, N-diethylaminomethoxyphosphine and chloropyrrolidino-metho~.yphosphine.
3o ~Z0323~
The applicability of phosphoramidites I-IV to the synthesis of deoxyoligonucleotides on polymer supports was accomplished by condensing compounds I-IV with N-2-isobutyryl-deoxyguanosine attached covalently to silica gel. Thus, N-2-isobutyryldeoxyguanosine (1 ~mGle) covalently attached to silica gel (20 mg) at the 3'-position, I (10 ~mole), and lH-tetrazole (50 ~mole in 0.1 ml dry acetonitrile) were shaken for 20 min and the reaction was then quenched with aqueous lutidine. The same reaction sequence was effected with II, III and IV. After the usual oxidation and deprotection procedures, d(TpG), d(CpG), d(ApG) and d(GpG) were obtained in 100~, 98~, 94%, and 93% yield respectively (measured spectrometrically from the dimethoxytrityl cation using an extinction of 7 x 104 at 498 nm). These dinucleotides were completely degraded by snake venom phosphodiesterase and the appropriate nucleosides and nucleotides were obtained in the proper ratios (monitored via high pressure liquid chromatography analysis of snake venom phosphodiesterase hydrolysates).
The following deoxynucleotides have been synthesized using this procedure:
d(C-T-C-A-A-A-T-G-G-G-T-C) d(C-C-A-C-A-A-A-C-C~C) d(A-A-A-T-G-C-G-A-C-C-C-A) d(A-G-C-T-A-T-G-G-G-T-T-T) d(T-T-T-G-A-G-C-C-A-A-C-A) d(T-T-A-G-C-T-C-A-C-T-C-A) d(T-C-A-T-C-C T-G-T-T-G-G) d(T-T-A-G-G-C-A-C-C-C) d(G-G-G-C-C-G-A-A-T-T-G-T) d(C-A-G-G-C-T-T-T-A-C-A) d(C-G-G-C-C-C-C-T-T-A-C-T) d(C-T-T-T-A-T-G-C-T-T-C) d(T-C-C-T-C-A-A-G-T-A-A-G) d(C-G-G-C-T-C-G-T-A) d(T-G-A-G-G-A-T-A-A-A-T-T) d(T-G-T-A-C-T-A-A-G~
d (A-T-G-T-G-T-G-A-T-T-T-A) d(G-A-G-G-T-T-G-T-A-T-G) d(G-T-G-G-T-A-A-A-T-C-A~ d(T-A-C-A-T-G-C-A-A) ~ 5 3Z3'~
, , l~;l'L~ I~
5 -~-D~T-~-benzoyldeo~-~yadenosine ~DMTrd(bzl~)]
(.66 g., 1 mmole) in dry T~ (3 ml) is adde~ dropwise un~er 5 an ar~on atmosphere to a stirred solution of the THr (3 containing methvldichlorophosphite (.113 ml, 1.2 m~ole) an~
2, 4, 6 trimethylpyridine ~.633 ml. 4.8 mmole) at - 78C.
After 10 minutes at -78C., the reaction solution is filtered through a sintered glass funnel and solvent is removed by 10 concentration in vacuo. Excess methyl phosphodichloridite is removed by dissolving the resulting gum in toluene: TH~ (2 ml, 2:1) and re-evaporating _ vacuo to a gum. This procedure is re-peated several times to insured removal of the dichloridite.
The nucleoside phosphomonochloridite is con~erted to the tetra-15 zolide. The gum resulting from the final re-evaporation is dis-solved in THF (2 ml). A solution of the selected secondary amine 0.9 mmole) in THF (2 ml) is then added dropwise with stirring at -78C. to the nucleoside phosphomonochloridite. After 10 minutes at -78C., the solution is transferred to a centrifuge 20 tube, spun at low speed, and the supernatant is removed. Thls solution contains the activated nucleoside phosphora-midite. If not used immediatelv, this phosphoramidite can be placed in long term storage after precipitation by dropwise ad-dition into dry pentane, ~ollowed by collection, drying 1n vacuo, 25 and storing in sealed tubes under argon or other inert gas at room temperature, or lower temperatures, e.g. 0C.
All operations are performed under inert gas to avoid oxidation. At no time is the active agent exposed -to air.
The foregoing procedure is applicable for the pre-
After 10 minutes at -78C., the reaction solution is filtered through a sintered glass funnel and solvent is removed by 10 concentration in vacuo. Excess methyl phosphodichloridite is removed by dissolving the resulting gum in toluene: TH~ (2 ml, 2:1) and re-evaporating _ vacuo to a gum. This procedure is re-peated several times to insured removal of the dichloridite.
The nucleoside phosphomonochloridite is con~erted to the tetra-15 zolide. The gum resulting from the final re-evaporation is dis-solved in THF (2 ml). A solution of the selected secondary amine 0.9 mmole) in THF (2 ml) is then added dropwise with stirring at -78C. to the nucleoside phosphomonochloridite. After 10 minutes at -78C., the solution is transferred to a centrifuge 20 tube, spun at low speed, and the supernatant is removed. Thls solution contains the activated nucleoside phosphora-midite. If not used immediatelv, this phosphoramidite can be placed in long term storage after precipitation by dropwise ad-dition into dry pentane, ~ollowed by collection, drying 1n vacuo, 25 and storing in sealed tubes under argon or other inert gas at room temperature, or lower temperatures, e.g. 0C.
All operations are performed under inert gas to avoid oxidation. At no time is the active agent exposed -to air.
The foregoing procedure is applicable for the pre-
3 paration of activated thymidine, deoxycytidine, and deo~yadeno-sine nucleotides ~or the preparation of the activated deoxy-guanosine nucleotide, the procedure is the same except for the lZ~3;237 ) ~
s~oichiometry. The molar ratio of 5 -O-DMT-N-isobu,yryl-deoxyquanosine ~D~ITrd(ibG)]; methyldichlorophosphite; 2, 4, 6 ~rimethylpyridine and tet~ra7,01e is 1 0.9 : 3.8 : ~.7.
Tne steps necessary for addition of one nucleotide to the moc,ified silica gel polymer support ~ollow. The removal of tne dimethoxytrityl group from ~he nucleotide is accoMplishec' by exposiny the modified silica gel support to 0.1 ~ ZnBr2 in nitromethane for 15 to 3n minutes. The support is then washed 10 initially with butanol: 2, 6 lutidine : THF (4 : 1 : 5 by volume) and finally with THF. The solvent ratio is not im-portant since this step is used to remove potential zinc esters - of nucleosides. This step could be eliminated but lower yields mav result. Other Lewis acids could be substltuted for ZnBr2, 15 such as BF3, AlC13 and TiC14. However ZnBr2 is prefe~re~,-Pro~ic acids can also be used. However approximately 3_5So depurination of each purine by protic acids is observed even when the amount of acid is reduced to the ~inimum amount needed to remove the dimethoxytrityl group. The next step in the process 20 is condensation of the protected and activated nucleotide to the nucleoside or oligonucleotide covalently boun~ to the support.
This is accomplished by using 10-15 e¢uivalents of the activated phosphoramidite and a reaction time of about one hour. The solvent is anhydrous THF. The next step in the process is the 25 blocking of unreacted 5'-hydroxyl groups. This is accomplished using a solution of acetic anhydride, dimethylaminopyridine, pyridine and THF. This may also be accomplished using a 0.33 M
solution of diethylmonotriazolophosphite in 2,6-lutidine/THF
(1:5 by volume). The reaction time is 5 min. and is followed by a ~2~323~7 -~4_ 1 TH~ wash. As a furtner alternative, a solution of pllenyliso-cvanate~lutidine (45 : 55 by volume) and a 90 minute reaction time may be used for this step. This sGlution is then re-moved from the modified silica gel by washing the support 5 with THF and with acetonitrile. The first procedure is preferred. This step can be eliminated or other reagents that react with 5'-hydroxyl groups and are compatible with the overall chemistry can be substituted therefore. However, by including this step, the final purification of the desir-10 able oligonucleotide is rendered much easier. This is be-cause the complexity of the total synthetic material bound to the support is reduced considerably. The final step in each cycle is oxidation of the phosphite to the phosphate.
~ composition of 0.1 rl I 2 in water/2, 6 lutidine/THF (1 :1 : 3) 15 is preferred, although other ratios can be used. Furthermore, other oxidizing agents such as N-chlorosuccinimide or aryl or alkyl peroxides, e.g., t-butyl peroxide, could also be used. After the addition of the appropriate activated nucleotides in any predetermined sequence, the deoxy-20 oligonucleotide is removed from the support by basehydrolysis and blocking groups where present are also removed, either selectively i.e., stepwise, or in an overall hydrolysis treatment such as heating at 50C
in ammon1um hydroxide. When Rl is a methyl group, this is 25 removed by treatment with thiophenol prior to removing the oligonucleotide from the support.
3o ~,r~v V~J ~
1 E~ LE ~
General method for synthesizin chl~rotriar~-lmethanes In the synthesis of this series of compounds there are two types of substrates for the respective Grignard reagents: 1) diaryl ketones, i.e. benzophenones, which require one equivalent of Grignard reagent; 2) esters of aryl carboxylic acids, which require two equivalents. The following will describe the former. Appropriate adjustments should be made for reactions of the latter type.
Table VII A Summary of Reagents Used for Synthesizing Triarylcarbinols Reagent Example mmoles aryl bromide p-bromoanisole 100 magnesium 110 diethyl ether 250 ml iodine 2 crystals 20 diaryl ketone 4-methoxybenzophenone The magnesium,aryl bromide and ether are combined in 1000 ml round bottom flask. The iodine is added. In order to initiate the formation of the aryl magnesium bromide, it is necessary to crush the magnesium with a glass rod.
[Note: grinding the magnesium in a Waring Blender also helps to get the reaction going.] Once the reaction has hegun, it is allowed to reflux, with no external heating, until the ether ceases to boil. An ethereal solution of the diaryl-ketone is added dropwise, with stirring. The reaction isallowed to proceed overnight. At this time the reaction is analyzed by thin layer chromotography (tlc) in 1:1 ether:hexane.
The Rf of the product will be approximately 0.7.
~;~03~3~
-~6-1 If the reaction is satis~actory, it is quencne~
.ith lOgc (w/v) ammonium sulfate. The product is extracted four times with 300 ml of toluene. Th-e extracts are dried over sodium sulfate and evaporated down as far as possible.
The concentrated organic phas~is dried in vacuo overnight.
At this time the product crystallizes out. The product tritanol is collected in a funnel and washed with hexane.
The tritanol is taken up in 100 ml of toluene.
200 mmoles of acetyl chloride is added. 300 ml of hexane is added. The product is allowed to recrystallize overnight at -20C. The crystals are collected, washed with hexane, and dried _ vacuo.
In order to determine the reactivity of the trityl chloride, a small amount is quenched into water and N-butanol 15 with toluene as solvent. The samples are analyzed via tlc using 3:1 hexane:ether. The trityl butyl ether runs at Rf approximately 0.8 while the tritanol runs at Rf approximately 0.4.
Using this procedure, the various alcohols described in Table I were prepared.
Several of the triarylmethylchlorides were con-densed with the 5' hydroxyl of appropriately protected deoxynucleosides. These compounds are listed in Tables IV
and V. The 5'-triarylmethyldeoxynucleosides were treated 25 with protic and Lewis acids using carefully controlled con-ditions. The results of these studies are also recorded in Tables IV and V. These results show that several triaryl-methyl groups forming different colors in acid solutions are hydrolyzed at approximately the same rapid rate in the pre-sence of ZnBr2. The rates are more variable with protic acids.
W W ~ ~ I' i' ~n o ~n o ~n o ~ 1--T~BL~ IV
Table IV The Lewis Acid Hydrolysis Rates of Triarylmethyl Groups Attached to the 5'-HydroYyl of Deoxynucleosidesl t~ (sec) Triarylmethyl Group2 Deoxynucleoside3 in ZnBr2 Color in Acid Rl = n; R2 = c; R3 = a T 60 Green Rl = n; R2 = e; R3 = a T 60 Red Rl = R2 = c; R3 = a T 60 Orange Rl = R2 = b; R3 = n T 30 Blue Rl = R2 = c; R3 = a C 45 Orange C
Rl = R2 = b; R3 = n C 30 Blue ' Rl = R2 = b; R3 = a G 20 Black Rl = R2 = c; R3 = a G 20 Orange '~
Rl = h; R2 = R3 = a A 45 Yellow Rl = R2 = c; R3 = a A 20 Orange IReaction conditions were 0.08 M ZnBr2 in nitromethane. Aliquots were removed from the reaction solution, quenched with ammoniurll acetate and analyzed visually after tlc and expo-sure to HCl vapors. Time points were taken at 10, 20, 30, 45, 60, 90, 120, 1807 and 240 sec.
2The aromatic functional groups are defined in the legend to Table 1.
3The symbols T, C, G and A refer to the nucleosides thymidine, N-benzoyldeoxycytidine, rl-isobutyrldeoxyguanosine, and N-benzoyldeoxyadenosine. The nucleoside 5'-hydroxyl was derivatized to contain the triarylmethyl group.
~Z(~3Z3~
1 For the repetitive addition of mononucleotides to a growing oligonucleotide attached covalently to a polymer support, the various color coded triarylmethyl groups should preferably be hydrolyzed at approximately the same rate. Otherwise, each addition cycle must be individually monitored if completed manually or independently programmed if completed in a machine. Because the hydrolysis rates with ZnBr2 are similar, the results outlined in Table IV suggest that most, if not all, of the triarylmethyl alcohols listed in Table 1 could be incorporated into synthetic procedures as color coded blocking groups.
.~,. ....
W o U- o Ul O ~ 1--T~BLE V
The Protic Acid Hydrolysis Rates of Triarylmethyl Groups Attached to the 5 -Hydroxyl of ~eoxynucleosidesl t'2 (sec) Color in Time (sec) to Triaryllnethyl Group2Deoxynucleoside3 in H+ Acid Complete Hydrolysis Rl = n; R2 = c; R3 = a T 30 Green 45 Rl = n; R2 = e; R3 = a ~ 180 Red >600 Rl = R2 = c; R3 = a T -O- Orange 30 Rl = R2 = b; R3 = n T 45 Blue 90 Rl = R2 = c. R3 = a C -O- Orange 30 R~ = R2 = b; R3 = n C 45 to 60 Blue 120 ~ ~
Rl = R2 = b; R3 = a G 15 Black 45 , ~3 Rl = R2 = c; R3 = a G -O- Orange 30 Rl = h; R2 = R3 = a A 60 Yellow240 Rl = R2 -~c; R3 = a A -O- Orange 30 IReaction conditions were 2~ toluenesulfonic acid in chlorofornn:methanol (7 3). Aliquots were removed from the reaction solution quenched with ammonium acetate and analyzed visually after tlc and exposure to HCl vapors. Time points were taken at 15 30 45 60 90 12G 240 300 and 600 sec.
2The aromatic functional groups are defined in the legend to Ta~le 1.
3The symbols T C G and A refer to the nucleosides thymidine N-benzoyldeoxycytidine N-isobuty!-ldeoxyguanosine arld N-benzoyldeoxyadenosine. The nucleoside 5 -hydroxyl was derivatized to corltain the triarylmethyl group.
W ~ r~
~n o ~ O ~ o T~BLE VI
Table VI provides the spectral characteristics of selecte~ triarylmetlly]
alcohols.
Triarylcarbinoll )~ Maximuln(s)2 Extinction Coefficient (nanonleters) (~lolar~' cm-l) Rl - R2 = b; R, = a 423 9300 503 52~0 585 3900 ~
Rl = R2 = a; R3 = h 452 42000 0 Rl = a; R2 = c; R3 = n 545 25000 ~ 2 455 28000 1 ~a Ri = R2 = b; R3 = 1~ 586 Rl = a; R2 = n; R3 = e 577 9500 421 2~500 lSee the legend to Tablel for d definition of the functiorlal groups Rl R2 and R3.
2All spectra ~ere taken in a saturated ZnBr2 nitromethane solution. All spectra ~lere recorded on a Carey model 21 scanning from 350 nm to 603 nm.
;
w w r~
u- o ~ o ~n o Fo~lr ~?eo~yoligollucleodides were synthesized using color coded deo~y-nucleotide phosphoramidites. The compounds were d(G-T-A~T-A-A-C-A-C), d(C-A-T~ A-A-G-A-A-A-A-A), d(G-T-A-C-A-G-C-T-G-G-C-T~ and d(C-C-C-T-T-T-C-T-T-A-f~-A).
The 5'-hydrox~-1 of eacll deoxynucleotide was protected with a different triaryl~lethyl group. These groups as assigned for the synthesis of deoxyoligonucleotides are listed in l'able VII.
TABLE VII
Triarylmethyl Groupl Deoxynucleoside Color~
R, = R2 = b; R3 = n N-benzoyldeoxycytidine Blue , R, = h; R2 = R3 = a N-benzoyldeoxyadenosine ~ellow ~ t~
Rl = c; R2 = n. R3 = a Deoxythylnidirle Red Rl = R2 = c; R3 = a N-isobutyrldeoxyguanosine Orange 'The aromatic furlctional groups are defined in the legend to Tàble I.
2The color of the triaryllnethyl group is lbserved when the 5 -triarylphenyl deoxynucleo-side is exposed to either protic or Lewis acids.
9 ~f~
1 Thus the 5'-triarylmethyl groups of ~`-benzoyldeoxvadenosine, ~-benzoyldeoxycytidine, M-isobutyrldeoxyguanosine and deoxy-thymidine produced yellow, blue, orange and red colors respectively when exposed to either Lewis or protic acids.
These triarylmethyldeoxynucleosides were synthesized as out-lined in this disclosure. Conversion to the appropriate 5'-0-triarylmethyl and deoxynucleoside N, ~-dimethylamino-methoxyphosphines was completed using the procedure of Example VI.
EXAMPLE VI
General synthesis of 5'-triarylmethyl deoxynucleosides 5 mmoles of N-protected deoxynucleoside or thy-midine is dissolved in 50 ml of dry pyridine. The sample is e~raporated to a gum in vacuo. 25 ml of dry pyridine is added. Six mmoles of triarylmethyl chloride is added. The reaction mixture is shaken overnight. The reaction is moni-tored in methanol:chloroform (1:~). The product has an Rf of 0.5 and the unreacted deoxynucleoside has an Rf of 0.2.
The reaction is quenched with 5 ml of absolute methanol.
After 30 minutes the reaction mixture is concen-trated to a small volume, taken up in ethyl acetate and extracted once with water. The organic phase is dried over sodium sulfate and concentrated to a gum. 10 ml of toluene is added and then evaporated.
The reaction mixture is then taken up in chloro-form and applied to a silica gel column (5 cm ~ 20 cm) that has been equilibrated with 1% pyridine in chloroform. After the compound is loaded on the column, the column is washed 3 with 500 ml of 1% pyridine in chloroform. The compound is eluted from the column with 3 to 6% methanol. The fractions containing the desired product are pocled, concentrated to a foam, taken up in chloroform and precipitated into hexane.
~LZ~323~
.3 The precipit~_e is collected in G Buchner funne~
and dried in vacuo. The average yield by weight is ~5'c.
The 5'-triarylmethyldeo~ynucleosides carrylng functional ~roups as out]ined in Table VII were connected to chloro-N,~-dimethylaminomethoxyphosphine using the pro-cedure of Example I. The 5'-triarylmethyldeoxynucleoside-3'-N,N-dlmethylaminomethoxvphosphines were used as intermediates in deoxyoligonucleotide synthesis using the procedure of Example IV. Thus, the synthesis of d(G-T-A-T-A-A-C-T-A-C-A-C) 10 beains with N-benzoyldeoxycytidine attached covalently to silica gel through the 3'-hydroxyl. The next step was condensation with 5'-0-p-tolyldiphenylmethyl-N-benzoyl-deoxyadenosine 3'~N, N-dimethylaminomethoxyphosphine.
After acylation and oxidation, detritylation was completed l using a saturated solution of 2nBr2 in nitromethane:methanol (19:1). A yellow color indicating the addition of N-benzoyl-deoxyadenosine was observed. The remaining nucleotides were added in a similar manner. During each detritylation step, colors were observed in the following sequential order:
20 blue, yellow, red, blue, yellow, yellow, red, yellow, red, and orange. These were the expected colors and confirm that the correct deoxyoligonucleotide was synthesized. Purifica-tion of the deoxyoligonucleotide was by reverse phase high performance liquid chromatography and polvacrylamide gel 25 ele^trophoresis. Characterization was by two dimension sequence analysis (Sanger, Donelson, Coulson, Kossel, and Fischer, Proc. Natl. Acad. Sci. USA 70, 1209-1213, 1973).
This analysis reconfirmed that the correct deoxyoligonucleo-tide had been synthesized as indlcated by the colorimetric 3 results. The three remaining deoxyoligonucleotides were synthesized and characterized in the same way.
For tne synthesis of the four enumerated oligodeoxy-nucleotides, the quantities of silica gel usea and the choice of nucleoside joined to the silica gel support are 35 summarized in Table VIII.
w w rv ~ I' ~Jl O ~1 0 Ul O 'J
T~sLE VIII
Deoxyoligonllcleotide Nucleoside on Silica ~Imole Nucleoside/ Gram Silica Gel Gram Silica Gel Gel Used d(G-T-A-T-A-r~-c-T-A-c-A-c) N-benzoyldeoxycytidine 45 0.15 d(C-A-T-A-A-A-G-A-A-A-A-A) N-benzoyldeoxyadenosine 40 0.15 d(C-C-C-T-T-T-C-T-T-A-A-A) N-benzoyldeoxyadenosine 40 0.15 d(~-T-A-C-A-G-C-T-G-G-C-T) deoxythymidille 53 0.15 Table IX sll~arizes physical pa~ameters of 5'-0-t~iarylmethylnucleoside-3'-r~,tl-dimethylaminomethoxyphosphines used in the synthesis of the four enurnerated oligo- ~U`
deoxynucleotid~s. o TABLE IX
Nucleotide M. Wt. Phosphorus N~R Chemical - Color~ Shifts (ppm) 5'-0-di-r-anisylphenyll!lethyl- 746 146.3, 146.1 Oranae N-isobutyryldeoxyguanosine-3'-N, N-dimethylaminomethoxyphosphine 5'-0-j~-anisyl-1-naphthylphenyl- 659 146.4, 145.7 Red methyldeoxythy!nidine-3'-N,N-dimethylaminomethoxyphosphine 5'-0-di-o-anisyl-1-na~thylmethyl 790 147.6, 145.4 Blue N-benzoyldeoxycytidine-3'-N, N-dimethylaminomethoxyphosphine 5'-0-~-tolyldiphenylmethyl-~l-berlzoyl- 718 146.4, 146.1 Yello~^~
deoxyadenosine-3'-~l, N-dimethylamino-methoxyphosphine 1Spectra were recorded in CH3CN as solvent and against phosphoric acid as external standard.
~ Color produced in either a Le~is acid or a protic acid.
1 Fcr each condensa~ion step, 120 !~moles of the 5'-0-triaryl-me'.ilylnucleotide, acetonitrile, and 4~0 I)mole tetrazole were used. The next steps were acvlation ~;ith acetic anhyd~ide, oxidation with I2 and detritylation with Zn~r2. ~fter each detritylation step, the expected color corresponding to the required trityl cation was observed.
Once each synthesis was complete, the deoxyoligo-nucleotide was isolated by the following procedure. Each deoxyoligonucleotide covalently bound to silica gel (30 mg) was first treated with thiophenol:triethylamine:dioxane (1:1:2) for 90 minutes, washed four times with methanol and then washed once with diethylether. The silica gel was isolated by centrifugation and air dried. Each sample was next treated with t-butylamine:methanol (1:1) for 18 hours ~5 at 50C. The supernatants obtained after centrifugation were removed and dried in vacuo. The silica gel samples were next treated with concentrated ammonium hydroxide at room temperature for three hours in order to remove the deoxyoligonucleotide from the silica gel. The supernatants 2C were trans~erred to test tubes containing the residues fro~
the t-butylamine procedure and the solutions concentrated in vacuo. ~resh concentrated ammonium hydroxide was added to the dry residues and the solutions were warmed at 50C
for 22 hours in order to remove amino protecting groups from deoxyoligonucleotide bases. The samples were concentrated in vacuo and each sample was next dissolved in 200 ~il water.
Purification was by reverse phase high performance liquid chromatography. The retention times and solvent conditions are outlined in Table X. Each deoxyoligonucleotide was next 3 treated with 80~ acetic acid at room temperature for 1 hour in order to remove the triarylphenylmethyl group. After concentration in vacuo, each sample was purified by polyacrylamide gel electrophoresis and analyzed as to the correct deoxymononucleotide sequence by two dimension sequence analysis.
w w r~
~1 0 Ul O ~Ji O `~1 1' TABLE X
Deoxyol;gonucleotide ~ Acetonitrile1 Retention Time2 d(G-T-A-T-A-A-C-T-A-C-A-C)3 29 2.6 27 3.8 26 6.2 d(C-A-T-A-A-A-G-A-A-A-A-A)4 30 2.9 28 3.0 26 4.5 d(C-C-C-T-T-T-C-T-T-A-A-A) 4 30 2.9 26 4.6 7.2 24 9.8 d(G-T-A-C-A-G-C-T-G-G-C-T)s 29 2.6 27 3.6 t~
6.3 !The aqueous buffer contains 0.1 M triethylammonium acetate.
21.2 min/k at 2.0 ml/lllin.
?Triarylmethyl group was di-p-anisylphenylm~-ttlyl preparative isolation was at 25`~
acetonitrile 4Triarylmethyl ciroup was di-o-anisyl-l-napthylm?thyl preparative isolation ~-as at 25 acetonitrile.
sTriarylmethyl group was di-p-anisylptienylmethyl Preparative isolation was at 24^
acetonitrile.
s~oichiometry. The molar ratio of 5 -O-DMT-N-isobu,yryl-deoxyquanosine ~D~ITrd(ibG)]; methyldichlorophosphite; 2, 4, 6 ~rimethylpyridine and tet~ra7,01e is 1 0.9 : 3.8 : ~.7.
Tne steps necessary for addition of one nucleotide to the moc,ified silica gel polymer support ~ollow. The removal of tne dimethoxytrityl group from ~he nucleotide is accoMplishec' by exposiny the modified silica gel support to 0.1 ~ ZnBr2 in nitromethane for 15 to 3n minutes. The support is then washed 10 initially with butanol: 2, 6 lutidine : THF (4 : 1 : 5 by volume) and finally with THF. The solvent ratio is not im-portant since this step is used to remove potential zinc esters - of nucleosides. This step could be eliminated but lower yields mav result. Other Lewis acids could be substltuted for ZnBr2, 15 such as BF3, AlC13 and TiC14. However ZnBr2 is prefe~re~,-Pro~ic acids can also be used. However approximately 3_5So depurination of each purine by protic acids is observed even when the amount of acid is reduced to the ~inimum amount needed to remove the dimethoxytrityl group. The next step in the process 20 is condensation of the protected and activated nucleotide to the nucleoside or oligonucleotide covalently boun~ to the support.
This is accomplished by using 10-15 e¢uivalents of the activated phosphoramidite and a reaction time of about one hour. The solvent is anhydrous THF. The next step in the process is the 25 blocking of unreacted 5'-hydroxyl groups. This is accomplished using a solution of acetic anhydride, dimethylaminopyridine, pyridine and THF. This may also be accomplished using a 0.33 M
solution of diethylmonotriazolophosphite in 2,6-lutidine/THF
(1:5 by volume). The reaction time is 5 min. and is followed by a ~2~323~7 -~4_ 1 TH~ wash. As a furtner alternative, a solution of pllenyliso-cvanate~lutidine (45 : 55 by volume) and a 90 minute reaction time may be used for this step. This sGlution is then re-moved from the modified silica gel by washing the support 5 with THF and with acetonitrile. The first procedure is preferred. This step can be eliminated or other reagents that react with 5'-hydroxyl groups and are compatible with the overall chemistry can be substituted therefore. However, by including this step, the final purification of the desir-10 able oligonucleotide is rendered much easier. This is be-cause the complexity of the total synthetic material bound to the support is reduced considerably. The final step in each cycle is oxidation of the phosphite to the phosphate.
~ composition of 0.1 rl I 2 in water/2, 6 lutidine/THF (1 :1 : 3) 15 is preferred, although other ratios can be used. Furthermore, other oxidizing agents such as N-chlorosuccinimide or aryl or alkyl peroxides, e.g., t-butyl peroxide, could also be used. After the addition of the appropriate activated nucleotides in any predetermined sequence, the deoxy-20 oligonucleotide is removed from the support by basehydrolysis and blocking groups where present are also removed, either selectively i.e., stepwise, or in an overall hydrolysis treatment such as heating at 50C
in ammon1um hydroxide. When Rl is a methyl group, this is 25 removed by treatment with thiophenol prior to removing the oligonucleotide from the support.
3o ~,r~v V~J ~
1 E~ LE ~
General method for synthesizin chl~rotriar~-lmethanes In the synthesis of this series of compounds there are two types of substrates for the respective Grignard reagents: 1) diaryl ketones, i.e. benzophenones, which require one equivalent of Grignard reagent; 2) esters of aryl carboxylic acids, which require two equivalents. The following will describe the former. Appropriate adjustments should be made for reactions of the latter type.
Table VII A Summary of Reagents Used for Synthesizing Triarylcarbinols Reagent Example mmoles aryl bromide p-bromoanisole 100 magnesium 110 diethyl ether 250 ml iodine 2 crystals 20 diaryl ketone 4-methoxybenzophenone The magnesium,aryl bromide and ether are combined in 1000 ml round bottom flask. The iodine is added. In order to initiate the formation of the aryl magnesium bromide, it is necessary to crush the magnesium with a glass rod.
[Note: grinding the magnesium in a Waring Blender also helps to get the reaction going.] Once the reaction has hegun, it is allowed to reflux, with no external heating, until the ether ceases to boil. An ethereal solution of the diaryl-ketone is added dropwise, with stirring. The reaction isallowed to proceed overnight. At this time the reaction is analyzed by thin layer chromotography (tlc) in 1:1 ether:hexane.
The Rf of the product will be approximately 0.7.
~;~03~3~
-~6-1 If the reaction is satis~actory, it is quencne~
.ith lOgc (w/v) ammonium sulfate. The product is extracted four times with 300 ml of toluene. Th-e extracts are dried over sodium sulfate and evaporated down as far as possible.
The concentrated organic phas~is dried in vacuo overnight.
At this time the product crystallizes out. The product tritanol is collected in a funnel and washed with hexane.
The tritanol is taken up in 100 ml of toluene.
200 mmoles of acetyl chloride is added. 300 ml of hexane is added. The product is allowed to recrystallize overnight at -20C. The crystals are collected, washed with hexane, and dried _ vacuo.
In order to determine the reactivity of the trityl chloride, a small amount is quenched into water and N-butanol 15 with toluene as solvent. The samples are analyzed via tlc using 3:1 hexane:ether. The trityl butyl ether runs at Rf approximately 0.8 while the tritanol runs at Rf approximately 0.4.
Using this procedure, the various alcohols described in Table I were prepared.
Several of the triarylmethylchlorides were con-densed with the 5' hydroxyl of appropriately protected deoxynucleosides. These compounds are listed in Tables IV
and V. The 5'-triarylmethyldeoxynucleosides were treated 25 with protic and Lewis acids using carefully controlled con-ditions. The results of these studies are also recorded in Tables IV and V. These results show that several triaryl-methyl groups forming different colors in acid solutions are hydrolyzed at approximately the same rapid rate in the pre-sence of ZnBr2. The rates are more variable with protic acids.
W W ~ ~ I' i' ~n o ~n o ~n o ~ 1--T~BL~ IV
Table IV The Lewis Acid Hydrolysis Rates of Triarylmethyl Groups Attached to the 5'-HydroYyl of Deoxynucleosidesl t~ (sec) Triarylmethyl Group2 Deoxynucleoside3 in ZnBr2 Color in Acid Rl = n; R2 = c; R3 = a T 60 Green Rl = n; R2 = e; R3 = a T 60 Red Rl = R2 = c; R3 = a T 60 Orange Rl = R2 = b; R3 = n T 30 Blue Rl = R2 = c; R3 = a C 45 Orange C
Rl = R2 = b; R3 = n C 30 Blue ' Rl = R2 = b; R3 = a G 20 Black Rl = R2 = c; R3 = a G 20 Orange '~
Rl = h; R2 = R3 = a A 45 Yellow Rl = R2 = c; R3 = a A 20 Orange IReaction conditions were 0.08 M ZnBr2 in nitromethane. Aliquots were removed from the reaction solution, quenched with ammoniurll acetate and analyzed visually after tlc and expo-sure to HCl vapors. Time points were taken at 10, 20, 30, 45, 60, 90, 120, 1807 and 240 sec.
2The aromatic functional groups are defined in the legend to Table 1.
3The symbols T, C, G and A refer to the nucleosides thymidine, N-benzoyldeoxycytidine, rl-isobutyrldeoxyguanosine, and N-benzoyldeoxyadenosine. The nucleoside 5'-hydroxyl was derivatized to contain the triarylmethyl group.
~Z(~3Z3~
1 For the repetitive addition of mononucleotides to a growing oligonucleotide attached covalently to a polymer support, the various color coded triarylmethyl groups should preferably be hydrolyzed at approximately the same rate. Otherwise, each addition cycle must be individually monitored if completed manually or independently programmed if completed in a machine. Because the hydrolysis rates with ZnBr2 are similar, the results outlined in Table IV suggest that most, if not all, of the triarylmethyl alcohols listed in Table 1 could be incorporated into synthetic procedures as color coded blocking groups.
.~,. ....
W o U- o Ul O ~ 1--T~BLE V
The Protic Acid Hydrolysis Rates of Triarylmethyl Groups Attached to the 5 -Hydroxyl of ~eoxynucleosidesl t'2 (sec) Color in Time (sec) to Triaryllnethyl Group2Deoxynucleoside3 in H+ Acid Complete Hydrolysis Rl = n; R2 = c; R3 = a T 30 Green 45 Rl = n; R2 = e; R3 = a ~ 180 Red >600 Rl = R2 = c; R3 = a T -O- Orange 30 Rl = R2 = b; R3 = n T 45 Blue 90 Rl = R2 = c. R3 = a C -O- Orange 30 R~ = R2 = b; R3 = n C 45 to 60 Blue 120 ~ ~
Rl = R2 = b; R3 = a G 15 Black 45 , ~3 Rl = R2 = c; R3 = a G -O- Orange 30 Rl = h; R2 = R3 = a A 60 Yellow240 Rl = R2 -~c; R3 = a A -O- Orange 30 IReaction conditions were 2~ toluenesulfonic acid in chlorofornn:methanol (7 3). Aliquots were removed from the reaction solution quenched with ammonium acetate and analyzed visually after tlc and exposure to HCl vapors. Time points were taken at 15 30 45 60 90 12G 240 300 and 600 sec.
2The aromatic functional groups are defined in the legend to Ta~le 1.
3The symbols T C G and A refer to the nucleosides thymidine N-benzoyldeoxycytidine N-isobuty!-ldeoxyguanosine arld N-benzoyldeoxyadenosine. The nucleoside 5 -hydroxyl was derivatized to corltain the triarylmethyl group.
W ~ r~
~n o ~ O ~ o T~BLE VI
Table VI provides the spectral characteristics of selecte~ triarylmetlly]
alcohols.
Triarylcarbinoll )~ Maximuln(s)2 Extinction Coefficient (nanonleters) (~lolar~' cm-l) Rl - R2 = b; R, = a 423 9300 503 52~0 585 3900 ~
Rl = R2 = a; R3 = h 452 42000 0 Rl = a; R2 = c; R3 = n 545 25000 ~ 2 455 28000 1 ~a Ri = R2 = b; R3 = 1~ 586 Rl = a; R2 = n; R3 = e 577 9500 421 2~500 lSee the legend to Tablel for d definition of the functiorlal groups Rl R2 and R3.
2All spectra ~ere taken in a saturated ZnBr2 nitromethane solution. All spectra ~lere recorded on a Carey model 21 scanning from 350 nm to 603 nm.
;
w w r~
u- o ~ o ~n o Fo~lr ~?eo~yoligollucleodides were synthesized using color coded deo~y-nucleotide phosphoramidites. The compounds were d(G-T-A~T-A-A-C-A-C), d(C-A-T~ A-A-G-A-A-A-A-A), d(G-T-A-C-A-G-C-T-G-G-C-T~ and d(C-C-C-T-T-T-C-T-T-A-f~-A).
The 5'-hydrox~-1 of eacll deoxynucleotide was protected with a different triaryl~lethyl group. These groups as assigned for the synthesis of deoxyoligonucleotides are listed in l'able VII.
TABLE VII
Triarylmethyl Groupl Deoxynucleoside Color~
R, = R2 = b; R3 = n N-benzoyldeoxycytidine Blue , R, = h; R2 = R3 = a N-benzoyldeoxyadenosine ~ellow ~ t~
Rl = c; R2 = n. R3 = a Deoxythylnidirle Red Rl = R2 = c; R3 = a N-isobutyrldeoxyguanosine Orange 'The aromatic furlctional groups are defined in the legend to Tàble I.
2The color of the triaryllnethyl group is lbserved when the 5 -triarylphenyl deoxynucleo-side is exposed to either protic or Lewis acids.
9 ~f~
1 Thus the 5'-triarylmethyl groups of ~`-benzoyldeoxvadenosine, ~-benzoyldeoxycytidine, M-isobutyrldeoxyguanosine and deoxy-thymidine produced yellow, blue, orange and red colors respectively when exposed to either Lewis or protic acids.
These triarylmethyldeoxynucleosides were synthesized as out-lined in this disclosure. Conversion to the appropriate 5'-0-triarylmethyl and deoxynucleoside N, ~-dimethylamino-methoxyphosphines was completed using the procedure of Example VI.
EXAMPLE VI
General synthesis of 5'-triarylmethyl deoxynucleosides 5 mmoles of N-protected deoxynucleoside or thy-midine is dissolved in 50 ml of dry pyridine. The sample is e~raporated to a gum in vacuo. 25 ml of dry pyridine is added. Six mmoles of triarylmethyl chloride is added. The reaction mixture is shaken overnight. The reaction is moni-tored in methanol:chloroform (1:~). The product has an Rf of 0.5 and the unreacted deoxynucleoside has an Rf of 0.2.
The reaction is quenched with 5 ml of absolute methanol.
After 30 minutes the reaction mixture is concen-trated to a small volume, taken up in ethyl acetate and extracted once with water. The organic phase is dried over sodium sulfate and concentrated to a gum. 10 ml of toluene is added and then evaporated.
The reaction mixture is then taken up in chloro-form and applied to a silica gel column (5 cm ~ 20 cm) that has been equilibrated with 1% pyridine in chloroform. After the compound is loaded on the column, the column is washed 3 with 500 ml of 1% pyridine in chloroform. The compound is eluted from the column with 3 to 6% methanol. The fractions containing the desired product are pocled, concentrated to a foam, taken up in chloroform and precipitated into hexane.
~LZ~323~
.3 The precipit~_e is collected in G Buchner funne~
and dried in vacuo. The average yield by weight is ~5'c.
The 5'-triarylmethyldeo~ynucleosides carrylng functional ~roups as out]ined in Table VII were connected to chloro-N,~-dimethylaminomethoxyphosphine using the pro-cedure of Example I. The 5'-triarylmethyldeoxynucleoside-3'-N,N-dlmethylaminomethoxvphosphines were used as intermediates in deoxyoligonucleotide synthesis using the procedure of Example IV. Thus, the synthesis of d(G-T-A-T-A-A-C-T-A-C-A-C) 10 beains with N-benzoyldeoxycytidine attached covalently to silica gel through the 3'-hydroxyl. The next step was condensation with 5'-0-p-tolyldiphenylmethyl-N-benzoyl-deoxyadenosine 3'~N, N-dimethylaminomethoxyphosphine.
After acylation and oxidation, detritylation was completed l using a saturated solution of 2nBr2 in nitromethane:methanol (19:1). A yellow color indicating the addition of N-benzoyl-deoxyadenosine was observed. The remaining nucleotides were added in a similar manner. During each detritylation step, colors were observed in the following sequential order:
20 blue, yellow, red, blue, yellow, yellow, red, yellow, red, and orange. These were the expected colors and confirm that the correct deoxyoligonucleotide was synthesized. Purifica-tion of the deoxyoligonucleotide was by reverse phase high performance liquid chromatography and polvacrylamide gel 25 ele^trophoresis. Characterization was by two dimension sequence analysis (Sanger, Donelson, Coulson, Kossel, and Fischer, Proc. Natl. Acad. Sci. USA 70, 1209-1213, 1973).
This analysis reconfirmed that the correct deoxyoligonucleo-tide had been synthesized as indlcated by the colorimetric 3 results. The three remaining deoxyoligonucleotides were synthesized and characterized in the same way.
For tne synthesis of the four enumerated oligodeoxy-nucleotides, the quantities of silica gel usea and the choice of nucleoside joined to the silica gel support are 35 summarized in Table VIII.
w w rv ~ I' ~Jl O ~1 0 Ul O 'J
T~sLE VIII
Deoxyoligonllcleotide Nucleoside on Silica ~Imole Nucleoside/ Gram Silica Gel Gram Silica Gel Gel Used d(G-T-A-T-A-r~-c-T-A-c-A-c) N-benzoyldeoxycytidine 45 0.15 d(C-A-T-A-A-A-G-A-A-A-A-A) N-benzoyldeoxyadenosine 40 0.15 d(C-C-C-T-T-T-C-T-T-A-A-A) N-benzoyldeoxyadenosine 40 0.15 d(~-T-A-C-A-G-C-T-G-G-C-T) deoxythymidille 53 0.15 Table IX sll~arizes physical pa~ameters of 5'-0-t~iarylmethylnucleoside-3'-r~,tl-dimethylaminomethoxyphosphines used in the synthesis of the four enurnerated oligo- ~U`
deoxynucleotid~s. o TABLE IX
Nucleotide M. Wt. Phosphorus N~R Chemical - Color~ Shifts (ppm) 5'-0-di-r-anisylphenyll!lethyl- 746 146.3, 146.1 Oranae N-isobutyryldeoxyguanosine-3'-N, N-dimethylaminomethoxyphosphine 5'-0-j~-anisyl-1-naphthylphenyl- 659 146.4, 145.7 Red methyldeoxythy!nidine-3'-N,N-dimethylaminomethoxyphosphine 5'-0-di-o-anisyl-1-na~thylmethyl 790 147.6, 145.4 Blue N-benzoyldeoxycytidine-3'-N, N-dimethylaminomethoxyphosphine 5'-0-~-tolyldiphenylmethyl-~l-berlzoyl- 718 146.4, 146.1 Yello~^~
deoxyadenosine-3'-~l, N-dimethylamino-methoxyphosphine 1Spectra were recorded in CH3CN as solvent and against phosphoric acid as external standard.
~ Color produced in either a Le~is acid or a protic acid.
1 Fcr each condensa~ion step, 120 !~moles of the 5'-0-triaryl-me'.ilylnucleotide, acetonitrile, and 4~0 I)mole tetrazole were used. The next steps were acvlation ~;ith acetic anhyd~ide, oxidation with I2 and detritylation with Zn~r2. ~fter each detritylation step, the expected color corresponding to the required trityl cation was observed.
Once each synthesis was complete, the deoxyoligo-nucleotide was isolated by the following procedure. Each deoxyoligonucleotide covalently bound to silica gel (30 mg) was first treated with thiophenol:triethylamine:dioxane (1:1:2) for 90 minutes, washed four times with methanol and then washed once with diethylether. The silica gel was isolated by centrifugation and air dried. Each sample was next treated with t-butylamine:methanol (1:1) for 18 hours ~5 at 50C. The supernatants obtained after centrifugation were removed and dried in vacuo. The silica gel samples were next treated with concentrated ammonium hydroxide at room temperature for three hours in order to remove the deoxyoligonucleotide from the silica gel. The supernatants 2C were trans~erred to test tubes containing the residues fro~
the t-butylamine procedure and the solutions concentrated in vacuo. ~resh concentrated ammonium hydroxide was added to the dry residues and the solutions were warmed at 50C
for 22 hours in order to remove amino protecting groups from deoxyoligonucleotide bases. The samples were concentrated in vacuo and each sample was next dissolved in 200 ~il water.
Purification was by reverse phase high performance liquid chromatography. The retention times and solvent conditions are outlined in Table X. Each deoxyoligonucleotide was next 3 treated with 80~ acetic acid at room temperature for 1 hour in order to remove the triarylphenylmethyl group. After concentration in vacuo, each sample was purified by polyacrylamide gel electrophoresis and analyzed as to the correct deoxymononucleotide sequence by two dimension sequence analysis.
w w r~
~1 0 Ul O ~Ji O `~1 1' TABLE X
Deoxyol;gonucleotide ~ Acetonitrile1 Retention Time2 d(G-T-A-T-A-A-C-T-A-C-A-C)3 29 2.6 27 3.8 26 6.2 d(C-A-T-A-A-A-G-A-A-A-A-A)4 30 2.9 28 3.0 26 4.5 d(C-C-C-T-T-T-C-T-T-A-A-A) 4 30 2.9 26 4.6 7.2 24 9.8 d(G-T-A-C-A-G-C-T-G-G-C-T)s 29 2.6 27 3.6 t~
6.3 !The aqueous buffer contains 0.1 M triethylammonium acetate.
21.2 min/k at 2.0 ml/lllin.
?Triarylmethyl group was di-p-anisylphenylm~-ttlyl preparative isolation was at 25`~
acetonitrile 4Triarylmethyl ciroup was di-o-anisyl-l-napthylm?thyl preparative isolation ~-as at 25 acetonitrile.
sTriarylmethyl group was di-p-anisylptienylmethyl Preparative isolation was at 24^
acetonitrile.
Claims (70)
1. A compound represented by one of the formulae:
wherein B is a nucleoside or deoxynucleoside base; A is H, OH or OR4 in which R4 is a blocking group; R is a blocking group; R? is a hydrocarbyl radical containing up to about 10 carbon atoms; and X is NR?R?, wherein R? and R? taken separately each represent alkyl, aryl, aralkyl, cycloalkyl and cycloalkylalkyl containing up to 10 carbon atoms; R?
and R? when taken together form an alkylene chain con-taining up to 5 carbon atoms in the principal chain and a total of up to 10 carbon atoms with both terminal valence bonds of said chain being attached to the nitrogen atom to which R? and R? are attached; and R? and R? when taken together with the nitrogen atom to which they are attached form a saturated nitrogen heterocycle including at least one additional heteroatom from the group consisting of nitrogen, oxygen and sulfur.
wherein B is a nucleoside or deoxynucleoside base; A is H, OH or OR4 in which R4 is a blocking group; R is a blocking group; R? is a hydrocarbyl radical containing up to about 10 carbon atoms; and X is NR?R?, wherein R? and R? taken separately each represent alkyl, aryl, aralkyl, cycloalkyl and cycloalkylalkyl containing up to 10 carbon atoms; R?
and R? when taken together form an alkylene chain con-taining up to 5 carbon atoms in the principal chain and a total of up to 10 carbon atoms with both terminal valence bonds of said chain being attached to the nitrogen atom to which R? and R? are attached; and R? and R? when taken together with the nitrogen atom to which they are attached form a saturated nitrogen heterocycle including at least one additional heteroatom from the group consisting of nitrogen, oxygen and sulfur.
2. A compound represented by the formula:
wherein B is a nucleoside or deoxynucleoside base; A is H, OH or OR2 in which R4 is a blocking group; R is a blocking group; R? is a hydrocarbyl radical containing up to about 10 carbon atoms; and X is NR?R?, wherein R? and R? taken separately each represent alkyl, aryl, aralkyl, cycloalkyl and cycloalkylalkyl containing up to 10 carbon atoms; R?
and R? when taken together form an alkylene chain con-taining up to 5 carbon atoms in the principal chain and a total of up to 10 carbon atoms with both terminal valence bonds of said chain being attached to the nitrogen atom to which R? and R? are attached; and R? and R? when taken together with the nitrogen atom to which they are attached form a saturated nitrogen heterocycle including at least one additional heteroatom from the group consisting of nitrogen, oxygen and sulfur.
wherein B is a nucleoside or deoxynucleoside base; A is H, OH or OR2 in which R4 is a blocking group; R is a blocking group; R? is a hydrocarbyl radical containing up to about 10 carbon atoms; and X is NR?R?, wherein R? and R? taken separately each represent alkyl, aryl, aralkyl, cycloalkyl and cycloalkylalkyl containing up to 10 carbon atoms; R?
and R? when taken together form an alkylene chain con-taining up to 5 carbon atoms in the principal chain and a total of up to 10 carbon atoms with both terminal valence bonds of said chain being attached to the nitrogen atom to which R? and R? are attached; and R? and R? when taken together with the nitrogen atom to which they are attached form a saturated nitrogen heterocycle including at least one additional heteroatom from the group consisting of nitrogen, oxygen and sulfur.
3. A compound according to Claim 1 or 2 wherein R is a trityl group.
4. A compound according to Claim 1 or 2 wherein R is a di-p-anisylphenylmethyl group.
5. A compound according to Claim 1 or 2 wherein R is a p-anisyldiphenylmethyl group.
6. A compound according to Claim 1 or 2 wherein R? is lower alkyl.
7. A compound according to Claim 1 wherein X is di-lower alkylamino.
8. A compound according to Claim 7 wherein X
is dimethylamino.
is dimethylamino.
9. A compound according to Claim 1 wherein X is a saturated nitrogen heterocyclic.
10. A compound according to Claim 9 wherein the nitrogen heterocyclic is piperidine, morpholine, or piperazine.
11. A compound according to Claim 1 or 2 wherein B is adenine, guanine, cytosine, uracil and thymine.
12. The compound according to Claim 2 wherein R is di-p-anisylphenylmethyl, B is 9-(N-6-benzoyladeninyl), R? is methyl, A is H and X is dimethylamino.
13. The compound according to Claim 2 wherein R is di-p-anisylphenylmethyl, B is thyminyl, R? is methyl, A is H and X is dimethylamino.
14. The compound according to Claim 2 wherein R is di-p-anisylphenylmethyl, B is l-cytosinyl, R? is methyl, A is H and X is dimethylamino.
15. The compound according to Claim 2 wherein R is di-p-anisylphenylmethyl, B is 9-(N-6-benzoyladeninyl), R? is methyl, A is H and X is piperidino.
16. The compound according to Claim 2 wherein R is di-p-anisylphenylmethyl, B is 9-guaninyl, R? is methyl, A is H
and X is dimethylamino.
and X is dimethylamino.
17. The compound according to Claim 2 wherein R is di-p-anisylphenylmethyl, B is 9-(N-6-benzoyladeninyl), R? is methyl, A is H and X is morpholino.
18. The compound according to Claim 2 wherein R is di-p-anisylphenylmethyl, B is thyminyl, R? is methyl, A is H
and X is morpholino.
and X is morpholino.
19. The compound according to Claim 2 wherein R is di-p-anisylphenylmethyl, B is l-cytosinyl, R? is methyl, A is H
and X is morpholino.
and X is morpholino.
20. The compound according to Claim 2 wherein R is di-p-anisylphenylmethyl, B is 9-guaninyl, R? is methyl, A is H
and X is morpholino.
and X is morpholino.
21. The compound according to Claim 14 wherein B is l-(N-4-acetylcytosine), 1-(N-4-benzoylcytosine), or 1-(N-4-iso-butyrylcytosine).
22. The compound according to Claim 16 wherein B is 9-(N-6-benzoylguaninyl), 9-(N-6-acetylguaninyl), or 9-(N-6-iso-butyrylguaninyl).
23. The compound according to Claim 12 wherein B is 9-(N-6-acetyladeninyl) or 9-(N-6-isobutyryladeninyl).
24. The compound according to Claim 15 wherein B is 9-(N-6-acetyladeninyl) or 9-(N-6-isobutyryladeninyl).
25. In a process of producing oligonucleotides which comprises the step of condensing the 3'-OH or 5'-OH group of a nucleoside or oligonucleotide with a nucleoside phosphite the improvement wherein the nucleoside phosphite is a compound of one of the formulae:
wherein B is a nucleoside or deoxynucleoside base; A is H, OH or OR4 in which R4 is a blocking group; R is a blocking group;
R? is a hydrocarbyl radical containing up to about 10 carbon atoms;
and X is NR?R?, wherein R? and R? taken separately each represent alkyl, aryl, aralkyl, cycloalkyl and cycloalkylalkyl containing up to 10 carbon atoms; R? and R? when taken together form an alkylene chain containing up to 5 carbon atoms in the principal chain and a total of up to 10 carbon atoms with both terminal valence bonds of said chain being attached to the nitrogen atom to which R? and R? are attached; and R? and R? when taken together with the nitrogen atom to which they are attached form a saturated nitrogen heterocycle including at least one additional heteroatom from the group consisting of nitrogen, oxygen and sulfur.
wherein B is a nucleoside or deoxynucleoside base; A is H, OH or OR4 in which R4 is a blocking group; R is a blocking group;
R? is a hydrocarbyl radical containing up to about 10 carbon atoms;
and X is NR?R?, wherein R? and R? taken separately each represent alkyl, aryl, aralkyl, cycloalkyl and cycloalkylalkyl containing up to 10 carbon atoms; R? and R? when taken together form an alkylene chain containing up to 5 carbon atoms in the principal chain and a total of up to 10 carbon atoms with both terminal valence bonds of said chain being attached to the nitrogen atom to which R? and R? are attached; and R? and R? when taken together with the nitrogen atom to which they are attached form a saturated nitrogen heterocycle including at least one additional heteroatom from the group consisting of nitrogen, oxygen and sulfur.
26. The process according to Claim 25 wherein R is a trityl group.
27. The process according to Claim 25 wherein R is a di-p-anisylphenylmethyl.
28. The process according to Claim 25 wherein R is p-anisyldiphenylmethyl.
29. The process according to Claim 25 wherein R? is lower alkyl.
30. The process according to Claim 25 wherein X is di-lower alkylamino.
31. The process according to Claim 25 wherein X is a saturated nitrogen heterocyclic.
32. The process according to Claim 25 wherein B is adenine, guanine, cytosine, uracil and thymine.
33. The process according to Claim 25 wherein R is di-p-anisylphenylmethyl, B is 9-(N-6-benzoyladeninyl), R? is methyl, A is H and X is morpholino.
34. The process according to Claim 25 wherein R is di-p-anisylphenylmethyl, B is thyminyl, R? is methyl, A is H
and X is dimethylamino.
and X is dimethylamino.
35. The process according to Claim 25 wherein R is di-p-anisylphenylmethyl, B is 1-(N-4-benzoylcytosinyl), R? is methyl, A is H and X is dimethylamino.
36. The process according to Claim 25 wherein R is di-p-anisylphenylmethyl, B is 9-(N-6-benzoyladeninyl), R? is methyl, A is H and X is dimethylamino.
37. The process according to Claim 25 wherein R is di-p-anisylphenylmethyl, B is 9-(N-2-isobutyrylguaninyl), R? is methyl, A is H and X is dimethylamino.
38. The process according to Claim 25 wherein said nucleoside or oligonucleotide is covalently bonded to an inorganic polymer.
39. The process according to Claim 38 wherein said nucleoside or oligonucleotide is linked to the inorganic polymer through a base hydrolyzable covalent bond.
40. The process according to Claim 39 wherein the base hydrolyzable covalent bond is an ester linkage.
41. A compound represented by one of the formulae wherein B is a nucleoside or deoxynucleoside base; A is H, OH or OR4 in which R4 is a blocking group; R? is a hydro-carbyl radical containing up to about 10 carbon atoms;X
is NR?R? wherein R? and R? taken separately each represents alkyl, aryl, aralkyl, cycloalkyl and cycloalkylalkyl con-taining up to 10 carbon atoms; R? and R? when taken together form an alkylene chain containing up to 5 carbon atoms in the principal chain and a total of up to 10 carbon atoms with both terminal valence bonds of said chain being attached to the nitrogen atom to which R? and R? are attached; and R? and R? when taken together with the nitrogen atom to which they are attached form a saturated nitrogen heterocycle including at least one additional heteroatom from the group consisting of nitrogen, oxygen and sulfur; and R is a tri-arylmethyl blocking group.
is NR?R? wherein R? and R? taken separately each represents alkyl, aryl, aralkyl, cycloalkyl and cycloalkylalkyl con-taining up to 10 carbon atoms; R? and R? when taken together form an alkylene chain containing up to 5 carbon atoms in the principal chain and a total of up to 10 carbon atoms with both terminal valence bonds of said chain being attached to the nitrogen atom to which R? and R? are attached; and R? and R? when taken together with the nitrogen atom to which they are attached form a saturated nitrogen heterocycle including at least one additional heteroatom from the group consisting of nitrogen, oxygen and sulfur; and R is a tri-arylmethyl blocking group.
42. A compound according to Claim 41 wherein said triarylmethyl blocking group is a trityl group.
43. A compound according to Claim 41 wherein said triarylmethyl blocking group is di-p-anisylphenylmethyl.
44. A compound according to Claim 41 wherein said triarylmethyl blocking group is p-anisyl-l-naphthylphenyl-methyl.
45. A compound according to Claim 41 wherein said triarylmethyl blocking group is di-0-anisyl-l-naphthylmethyl.
46. A compound according to Claim 41 wherein said triarylmethyl blocking group is p-tolyldiphenylmethyl.
47. 5'-O-di-p-Anisylphenylmethyl-N-isobutyryl-deoxyguanosine-3'-N,N-dimethylaminomethoxyphosphine.
48. 5'-O-p-Anisyl-l-naphthylphenylmethyldeoxythymidine-3'-N,N-diemthylaminomethoxyphosphine.
49. 5'-O-di-o-Anisyl-l-naphthylmethyl-N-benzoyl-deoxycytidine-3'-N,N-dimethylaminomethoxyphosphine.
50. 5'-O-p-Tolyldiphenylmethyl-N-benzoyldeoxyadeno-3'-N,N-dimethylaminomethoxyphosphine.
51. 5'-O-di-p-Anisylphenylmethyl-N-isobutyryl-deoxyguanosine-3'-N,N-morpholinomethoxyphosphine.
52. 5'-O-p-Anisyl-l-naphthylphenylmethyldeoxythymidine-3'-N,N-morpholinomethoxyphosphine.
53. 5'-O-di-o-Anisyl-l-naphthylmethyl-N-benzoyl-deoxycytidine-3'-N,N-morpholinomethoxyphosphine.
54. 5'-O-p-Tolyldiphenylmethyl-N-benzoyldeoxyadeno-3'-N,N-morpholinomethoxyphosphine.
55. 5'-O-di-p-Anisylphenylmethyl-N-acetyl-deoxyguanosine-3'-N,N-dimethylaminomethoxyphosphine.
56. 5'-O-di-p-Anisylphenylmethyl-N-benzoyl-deoxyguanosine-3'-N,N-dimethylaminomethoxyphosphine.
57. 5'-O-di-o-Anisyl-l-naphthylmethyl-N-acetyl-deoxycytidine-3'-N,N-dimethylaminomethoxyphosphine.
58. 5'-O-di-o-Anisyl-l-naphthylmethyl-N-isobutyryl-deoxycytidine-3'-N,N-dimethylaminomethoxyphosphine.
59. 5'-O-p-Tolyldiphenylmethyl-N-acetyldeoxyadeno-sine-3'-N,N,-dimethylaminomethoxyphosphine.
60. 5'-O-p-Tolyldiphenylmethyl-N-isobutyryladeno-sine-3'-N,N-dimethylaminomethoxyphosphine.
61. 5'-O-di-p-Anisylphenylmethyl-N-acetyl-deoxyquanosine-3'-N,N-morpholinomethoxyphosphine.
62. 5'-O-di-p-Anisylphenylmethyl-N-benzoyl-deoxyquanosine-3'-N,N-morpholinomethoxyphosphine.
63. 5'-O-di-o-Anisyl-l-naphthylmethyl-N-isobutyryl-deoxycytidine-3'-N,N-morpholinomethoxyphosphine.
64. 5'-O-di-o-Anisyl-l-napthylmethyl-N-acetyl-deoxycytidine-3'-N,N-morpholinomethoxyphosphine.
65. 5'-O-p-Tolyldiphenylmethyl-N-acetyldeoxyadeno-sine-3'-N,N-morpholinomethoxyphosine.
66. 5'-O-p-Tolyldiphenylmethyl-N-isobutyryldeoxyadeno-sine-3'-N,N-morpholinomethoxyphosphine.
67. A compound according to claim 1 wherein X is selected from the class consisting of dimethylamino, diethyl-amino, diisopropylamino, dibutylamino, methylpropylamino, methylhexylamino, methylcyclopropylamino, ethylcyclohexylamino, methylbenzylamino, methylcyclohexylmethylamino, butylcyclo-hexylamino, morpholino, thiomorpholino, pyrrolidino, piperidino, 2,6-dimethylpiperidino and piperazino.
68. A compound according to claim 1 wherein X is diisopropylamino.
69. A compound according to claim 2 wherein X is selected from the class consisting of dimethylamino, diethylamino, diisopropylamino, dibutylamino, methylpropylamino, methyl-hexylamino, methylcyclopropylamino, ethylcyclohexylamino, methylbenzylamino, methylcyclohexylmethylamino, butylcyclo-hexylamino, morpholino, thiomorpholino, pyrrolidino, piperidino, 2,6-dimethylpiperidino and piperazino.
70. A compound according to claim 2 wherein X is diisopropylamino.
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US248,450 | 1981-03-27 | ||
US06/248,450 US4415732A (en) | 1981-03-27 | 1981-03-27 | Phosphoramidite compounds and processes |
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US3534017A (en) * | 1967-03-14 | 1970-10-13 | Kyowa Hakko Kogyo Kk | Process for the preparation of nucleoside-5'-diphosphates and triphosphates and mono- and oligo-nucleotidyl-nucleoside-5'-diphosphates and triphosphates |
EP0173356B1 (en) * | 1980-02-29 | 1990-09-19 | University Patents, Inc. | Process for preparing modified inorganic polymers |
-
1981
- 1981-03-27 US US06/248,450 patent/US4415732A/en not_active Expired - Lifetime
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1982
- 1982-03-26 AT AT82102570T patent/ATE12236T1/en not_active IP Right Cessation
- 1982-03-26 AU AU81997/82A patent/AU551324B2/en not_active Expired
- 1982-03-26 EP EP82102570A patent/EP0061746B1/en not_active Expired
- 1982-03-26 DE DE8282102570T patent/DE3262598D1/en not_active Expired
- 1982-03-26 MX MX192002A patent/MX157501A/en unknown
- 1982-03-26 CA CA000399518A patent/CA1203237A/en not_active Expired
- 1982-03-27 JP JP57049938A patent/JPS57176998A/en active Granted
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1987
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JPS6365677B2 (en) | 1988-12-16 |
JPS6328439B2 (en) | 1988-06-08 |
ATE12236T1 (en) | 1985-04-15 |
EP0061746A1 (en) | 1982-10-06 |
EP0061746B1 (en) | 1985-03-20 |
DE3262598D1 (en) | 1985-04-25 |
AU8199782A (en) | 1982-09-30 |
JPS57176998A (en) | 1982-10-30 |
MX157501A (en) | 1988-11-28 |
AU551324B2 (en) | 1986-04-24 |
JPS63179889A (en) | 1988-07-23 |
US4415732A (en) | 1983-11-15 |
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