WO1996011683A1 - New cytotoxic agents - Google Patents

Abstract

A method for inhibiting growth of cancer cells comprising contacting said cells with an effective amount of a composition comprising formula (I) wherein R represents Ac or H; R' represents formula (II); or formula (III); or formula (IV); or OH; and R' represents formula (V); or formula (VI).

Description

NEW CYTOTOXIC AGENTS

This application is a continuation-in-part of patent application Serial No. 122,921, filed on September 17, 1993, which is, in turn, a continuation-in-part of patent

application Serial No. 973,076, filed by Murray et al. on November 6, 1992, for "Oxidation of Glycoside Substituted Taxanes to Taxol or Taxol Precursors and New Compounds

Formed as Intermediates." In particular, this application relates to the intermediate compounds described in our original application and their use as cytotoxic agents.

BACKGROUND OF THE INVENTION

This invention relates to taxane derivatives. More particularly, this invention relates to derivatives of naturally occurring xylosyl substituted taxanes. These new compounds demonstrate surprising tubulin binding activity and cytotoxicity. "Although plant extracts have been used as anticancer agents for centuries, only a handful of plant-derived natural products have been found to show clinically useful activity, and taxol is clearly a member of this select group." (Kingston, "The Chemistry of Taxol, Pharmac.

Ther., Vol. 52, pp. 1-34, 1 (1991); "Kingston"). Taxol, shown as composition 1 in Figure 1, is a compound that occurs in the bark of the Pacific yew tree as well as other members of the taxus species. Taxol has been identified as having significant tubulin binding activity (Schiff, P.B. et al.. "Promotion of Microtubule Assembly in vitro by Taxol," Nature, Vol. 277: 655-67 (Feb. 1979)), and when delivered to the cell, it has significant cytotoxicity. Taxol was recently approved for the treatment of refractory ovarian cancer by the United States Food and Drug Administration.

Taxol is unusual among cytotoxic agents in that its method of action is through stabilization of polymerized tubulin, i.e., "tubulin binding." Because this mechanism is different from conventional cytotoxic agents, it is a highly important addition to the arsenal of cancer therapy

"weapons." Taxol is a complex molecule, and the specific attributes of its chemistry responsible for its tubulin binding activity have not been identified. Numerous taxol derivatives, having one or more substituted side groups, have been tested for tubulin binding activity with varying and unpredictable results. It is apparent from those tests that even minor changes in the taxol molecule may result in significantly different tubulin binding and cytotoxicity.

Generally, the cytotoxic activity of most taxol analogs that have been studied parallel their tubulin-assembly

activities. (Kingston, at 30.)

One of the few taxol related compounds that

demonstrates enhanced tubulin binding is the compound known as "Taxotere," i.e., compound 2 shown in Figure 1, which is a semisynthetic derivative of taxol with improved water solubility. "Taxotere" is a registered trademark of Rhone-Poulenc Rorer. Taxotere has been compared with taxol in phase I clinical trials. Although the structural

differences between taxol 1 and Taxotere 2 are minor (see Figure 1), enhanced in vitro tubulin binding activity is observed for Taxotere. Taxotere is slightly more active as a promoter of tubulin polymerization, 1.5 times more potent as an inhibitor of replication in mouse macrophage-like

J774.2 cells and in P388 murine leukemia cells, and at least five-fold more potent in taxol-resistant tumor cells.

(Pazdur, R. et al., "Phase I Trial of Taxotere: Five-Day Schedule", Journal of the National Cancer Institute, 1781, (1992)).

On the other hand, minor variations in the taxol molecule have frequently resulted in compounds that have significantly less tubulin binding activity and

cytotoxicity. (For example, see compounds 10 through 15 in Table 2, p. 28 of Kingston). There are thousands of

potential variations of the taxol molecule. "With few exceptions, changes in the taxane skeleton appear to reduce the activity of taxol." (Kingston, at 31.)

It is difficult to predict the relative potency of a taxol analog for microtubulin polymerization activity based on small changes in the overall structure. An examination of the Kingston review provides an overall view of the complexity of the structure-activity relationship of taxol analogs. It is clear that minor structural changes can cause major changes in tubulin binding activity and

cytotoxicity. These changes can even completely eliminate any activity.

In addition, there are other factors, such as water solubility, toxicity, and pharmacokinetics which must be strongly considered when evaluating the efficacy of

therapeutic agents for cancer treatment in general and the relative desirability of using particular agents in a given cancer treatment regimen. For example, certain recently reported negative side effects of Taxotere deserve further investigation. (Fumoleau, P. et al., "First Line

Chemotherapy with Taxotere In Advanced Breast Cancer:

A Phase II Study of the EORTC Clinical Screening Group,"

Proceedings of the American Society of Clinical Oncologists, Vol. 12, March 1993, p. 59 and Wanders, J. et al. "The EORTC ECTG Experience with Acute Hypersensitivity Reactions (HSR) in Taxotere Studies," Proceedings of the American Society of Clinical Oncologists, Vol. 12, March 1993, p. 73.) Taxol itself is difficult to deliver to the target site in vivo due to its poor solubility in water and the need to use delivery media which themselves have certain deficiencies. The synthetic taxol derivatives described herein have not previously been described, and the literature does not suggest that they would exhibit cytotoxicity and enhanced tubulin assembly. Indeed, changes to taxol at the C-7 site including acylation, attachment of polar groups and

epimerization reduce the activity of the molecule.

Oxidation of taxol at the C-7 site also reduces activity significantly. (Kingston, at 30-31.)

The compounds of this invention have been tested for tubulin binding and cytotoxicity, using B-16 melanoma. In addition, the compounds have been screened by the National Cancer Institute using a number of cancer cell lines with surprisingly good results. The National Cancer Institute has selected these compounds for further testing as

potential cancer-treating drugs.

SUMMARY OF THE INVENTION

We have discovered a modification of the 7-xylosyl substituted taxanes that produces compounds that display in vitro tubulin binding and cytotoxicity which is better than that of the starting materials. Tubulin binding of these compounds is at least as good as taxol. These new compounds have the following general formula:

Wherein R represents Ac or H;

R' represents: ;

OR

;

OR

;

OR OH; and R" represents : ;

OR

These new compounds are produced by selective oxidation of the xylosyl portion of the naturally occurring taxanes.

For lack of a better term, we have chose to designate these compounds as the "oxo" form of the xylosyl compounds from which they are obtained by oxidation. These "oxo" compounds should not be confused with "7-oxo-taxol" described in

Kingston as taxol oxidized at the C-7 site. The process of forming the oxo compounds of this invention and the

nomenclature for the compounds produced is illustrated in the attached drawings. The formation of a new compound from 7-xylosyl taxol (i.e., "XT") (3), is shown in Figure 2. We have chosen to call this compound "oxo-XT" (4).

The formation of the corresponding new compound from 10-deacetyl-7-xylosyl taxol (i.e., "10-DAXT") (5) is shown in Figure 3. We have chosen to call this new compound "oxo-10-DAXT" (6).

The formation of a new compound from 7-xylosyl cephalomannine, or 7-xylosyl taxol B (i.e., "XTB") (7), is shown in Figure 4. We have chosen to call this new compoun "oxo-XTB" (8).

The formation of a new compound from 10-deacetyl-7-xylosyl cephalomannine, or 10-deacetyl-7-xylosyl taxol B (9), is shown in Figure 5. We have chosen to call this new compound "oxo-10-DAXTB" (10).

The formation of a new compound from 7-xylosyl taxol C (11), is shown in Figure 6. We have chosen to call this ne compound "oxo-XTC" (12).

The formation of a new compound from 10-deacetyl-7-xylosyl taxol C (13), is shown in Figure 7. We have chosen to call this new compound "oxo-10-DAXTC" (14).

The "oxo" compounds directly formed from the

xylopyranoside substituted taxanes are hemialdals. The reduced form of the "oxo" materials are referred to as "oxo diols." For example, the formation of "oxo-10-DAXT diol" from oxo-10-DAXT is shown in Figure 8. Unless otherwise indicated herein, "oxo" is intended to include both the hemialdals and the diols.

We have found unexpectedly that the "oxo" compounds have enhanced tubulin binding and cytotoxicity compared to their precursors.

It is an object of this invention to provide new taxol analogs that display both unexpectedly high activity in promoting the assembly of microtubulin j_n vitro, and

unexpected cytotoxicity.

It is another object of this invention to provide a pharmaceutical composition which is effective in inhibiting the growth of tumor cells and a method of employing such compositions for that purpose.

Other objects and advantages of the present invention will be apparent from the following detailed description and the accompanying drawings.

DESCRIPTION OF THE INVENTION AND THE PREFERRED EMBODIMENT

This invention relates to the treatment of certain 7-xylosyl substituted naturally occurring taxanes with an oxidizing agent sufficient to partially oxidize the xylosyl group and to generate in good yield the hemialdal

intermediate that we call the "oxo" compound. The various naturally occurring xylosyl derivatives can be isolated in a conventional manner such as described in a recent

publication. (Rao, Koppaka V., "Taxol and Related Taxanes. I. Taxanes of Taxus brevifolia Bark", Pharmaceutical

Research, Vol. 10, No. 4, 1993).

A. Preparation:

The hemialdal "oxo" compounds of the present invention are obtained by oxidation of naturally occurring xylosyl substituted taxanes. The oxidation reactions of this invention are mild enough that their progress can be

monitored, and they do not continue beyond the desired end-point to produce unwanted products. Generally the reactions can be monitored utilizing high-pressure liquid

chromatography ("HPLC") and thin-layer chromatography

("TLC"). When the presence of glycoside substituted taxane starting material is no longer detected, and the product peak appears homogeneous, the reaction is deemed to be complete.

In addition, the oxidation is quite selective. This is true in two respects. First, the oxidation occurs

selectively on the xylopyranoside at the C-7 site. (For purposes of this specification the terms "xylosyl" and

"xylopyranoside" are intended to mean the same thing and are used interchangeably.) Normally, one should anticipate that the introduction of an oxidizing agent to a xylopyranoside substituted taxane could cause oxidation at sites other than C-7 on the taxane ring, such as the 2'-hydroxy and the 10-position on 10-DAXT. In fact, oxidation does not appear to occur at these positions. Secondly, the introduction of an oxidizing agent to mixtures containing glycoside substituted taxanes and other non-glycoside substituted taxane compounds does not result in oxidation of the other taxanes. Such mixtures occur in biomass or partial separations of extracts of such biomass. This selectivity enables the oxidative cleavage of the glycosides to be conducted at various stages during the isolation of taxol from Taxus brevifolia or other naturally-occurring materials.

Finally, the oxidation reaction is efficient. The reactions provide relatively high yields of the oxo

compounds depending on the amount of taxane starting

material and the procedures employed in the isolation and purification of the reaction products. The oxo compounds may be converted to taxol or taxol precursors or themselves may be used as cytotoxic agents.

The oxidation of the xylopyranoside side chain is accomplished by using an effective amount of an oxidizing agent. Effective oxidizing agents include, but are not limited to, periodic acid and salts thereof, such as sodium or potassium periodate or metaperiodate, and lead

tetraacetate. Additional oxidizing agents may include an effective amount of one or more oxidizing agents can be utilized. In particular, one or more of these oxidizing agents can be employed. The relative effectiveness of the various possible oxidizing agents depends upon the

concentration employed and other conditions of the reaction. The preferred oxidizing agent is periodate.

Various amounts of the oxidizing agent can be employed, but generally the oxidizing agent should be present in the range of 1-10 molar equivalents of oxidizing agent per mole of xylopyranoside taxane. Preferably, at least 2

equivalents of oxidizing agent per molar equivalent of xylopyranoside taxane is needed for the reaction to proceed to completion.

To facilitate mixing of the starting materials, the oxidation is preferably accomplished utilizing an effective dissolution amount of a taxane solvent which is compatible with the particular oxidizing agent or agents employed.

Typical solvents include tetrahydrofuran, water, acetone, dioxane, acetic acid, or mixtures thereof or other taxane solvents known to one of ordinary skill in the art.

Methanol and other alcohols are particularly unacceptable and should not be used, because they interact with the intermediate hemialdal compound.

In a preferred embodiment of the invention the

oxidative conversion of the xylopyranoside functional group or mixtures thereof as the oxidizing agent. The xylose group is oxidized in two to twenty-four hours for solutions which are approximately 0.1 mg./ml. of taxane using 2-10 molar equivalents of the periodate reagent.

The oxidation process of the present invention has revealed the existence of novel taxane compounds, the "oxo" compounds, having the general formula:

Wherein R represents Ac or H;

R' represents:

;

;

OR

; and

R" represents:

;

OR

The process described herein appears superficially similar to that described in U.S. Patent No. 5,200,534 entitled "Process for the Preparation of Taxol and

10-Deacetyltaxol" by K.V. Rao. The "Rao Patent" describes a method for removing the glycoside from C-7 glycoside

substituted taxanes. However, Rao describes the

intermediate products as "dialdehydes;" there is no

recognition that the "hemialdals" of the present invention were formed. In fact, the alcohol solvents, e.g., methanol, used in the specific examples of the Rao patent will ensure that hemialdals are not formed.

The hemialdal side chain at the C-7 site in the "oxo" compounds of the present invention are in equilibrium with isomers of that side chain. These include hemialdals in open (i.e., non-cyclic) form. However, the equilibrium constant is such that the following hemialdal structure is greatly preferred.

As used herein, the structure shown above is intended to include the isomers of the C-7 hemialdal side chain in equilibrium with it.

The hemialdal nature of the "oxo" compounds can be partially elucidated using spectroscopic analyses such as nuclear magnetic resonance spectroscopy (NMR) and mass spectroscopy (MS). The ¹H-NMR and ¹³C-NMR spectra of the compounds can be used to differentiate the starting

material, the 7-xylopyranoside taxanes, from the oxidation products, the "oxo" compounds. In addition, several features of the NMR spectra are useful for determining the hemialdal structure of the "oxo" compounds as described in the preceding paragraph. The high-field NMR spectra were acquired using dimethyl sulfoxide-d₆ as solvent with residual dimethyl sulfoxide as an internal standard. The ¹H-NMR spectra of the starting compounds, the

7-xylopyranoside taxane derivatives, show well resolved resonances at 2.85, 3.05, 3.25, 3.60, 4.10, 4.25, 4.80, and 4.89 ppm. attributable to the xylopyranoside group. The ¹H-NMR spectra of the "oxo" compounds generally show no resonances at the positions listed for the xylopyranoside group. However, the ¹H-NMR spectra of the "oxo" compounds consistently show new multiple resonances at 3.40, 4.15, 5.10, 6.45, 6.6 and 6.8 ppm. attributable to the hemialdal group. The resonances in the ¹H-NMR spectra of the "oxo" compounds are generally not well resolved because the "oxo" compounds are an equilibrium mixture of the isomers at the C-7 site. The ¹³C-NMR spectra for the starting material, the 7-xylopyranoside taxanes, generally show a strong resonance in the region from 104 to 107 ppm for the

xylopyranoside acetal carbon. The ¹³C-NMR spectra of the "oxo" compounds generally show a strong resonance in the region from 96 to 99 ppm. Neither the ¹H-NMR or ¹³C-NMR spectra of the oxidation product show resonances in the regions expected for non-hydrated dialdehydes. It is clear that the intermediate compounds we have formed are

hemialdals.

The mass spectral data for four compounds, "oxo-XT" (4), "oxo-10-DAXT" (6), "oxo-10-DAXTB" (10), and "oxo-10-DAXTC" (14), show molecular ion signals that correspond with a mass for the hemialdal structure plus the mass of sodium ion. The additional mass of sodium ion is a commonly observed effect of the electrospray MS method. No strong ion signals were observed which would indicate the presence of the dialdehyde structure.

Because the "oxo" compound is an equilibrium of several isomers, it is difficult to absolutely establish its

existence only through the use of NMR and MS analyses. The existence of the hemialdal structure of the new "oxo" compounds, however, was further confirmed by chemical reduction of one of them, "oxo-10-DAXT, " with sodium cyanoborohydride (see Figure 8 and Example 5). This is a common chemical conversion method for hemialdal-type structures. When the side chain of the product of such a reduction is found to be:

it can be deduced that the original side chain was:

This deduction is a reliable one considering the data from the NMR and mass spectral analysis for the starting "oxo" compound

The hemialdal nature of the "oxo" compounds can be further elucidated by treating a solution of the "oxo" compound with a silylating agent, triethylsilyl chloride (see Figure 9). The product mixture from this reaction is stable to silica gel chromatography. The purified silylated product shows three triethylsilyl groups when analyzed by NMR and MS (see Example 6). The hemialdal-type structure has three reactive silylation sites available, the

dialdehyde-type structure has only one reactive silylation site. Therefore, the presence of three triethylsilyl groups in the product of the silylation is further evidence for the hemialdal-type structure as opposed to the dialdehyde-type structure.

Based on all of the foregoing indicia, it is quite clear that the compounds produced by the methods of this invention are hemialdals and not dialdehydes. The Rao

Patent does not disclose or suggest that the dialdehydes demonstrate tubulin binding or cytotoxic activity.

The process for converting "oxo" hemialdals to diols is illustrated in Example 5 and Figure 8. The process involves treatment of a tetrahydrofuran/water/acetic acid solution of the "oxo" derivative with a reducing agent , such as sodiumcyanoborohydride) at room temperature for a period of approximately 24 hours. The reaction can be monitored by TLC or HPLC. The diol product can be isolated by

conventional chromatography techniques.

B. Use of Compounds:

The "oxo" compounds show good tubulin binding and cytotoxicity activity with in vitro testing. The compounds of this invention have been successfully tested for tubulin binding and for their effect on B16 melanoma. The compounds tested demonstrated improved tubulin binding and

cytotoxicity over the precursors from which they were derived. In one particular case, oxo-XT (4), the tubulin binding and cytotoxicity data (see Table 1) are comparable to results for taxol.

In addition, the cytotoxicity of the "oxo" compounds has been screened by the National Cancer Institute on more than forty-nine cancer cell lines. Based on those results the National Cancer Institute has selected these compounds for further testing.

The methods of formulating pharmaceutical compositions utilizing the compounds of the present invention and of applying those compositions in an effective amount to the treatment of various cancers is apparent to one skilled in the art. The synthesis, characterization and in vitro test methods for the new "oxo" taxol analogs are illustrated by the following examples. Examples 1-6 illustrate the

preparation of specific compounds of the present invention. Example 7 illustrates tests performed to measure tubulin binding and the effect of various compounds on B16 melanoma. Example 8 illustrates the results of "oxo" tests performed by the National Cancer Institute on the cytotoxic effects of various "oxo" compounds on a number of different cancer cell lines.

EXAMPLES

Materials and Methods: All solvents and reagents employed in the examples were used as received from the manufacturer. Xylosyl taxanes can be isolated from the bark of Taxus brevifolia in accordance with literature methods. Rao, Koppaka V., "Taxol and Related Taxanes I Taxanes of Taxus brevifolia Bark," supra. Reactions were monitored by thin-layer chromatography ("TLC") using 0.25 mm. Whatman Silica Gel 60A K6F (glass support) or 0.25 mm. E. M. Industries Silica Gel 60 (aluminum support) silica gel plates.

Reactions were also monitored by high-pressure liquid chromatography ("HPLC") using a system consisting of a model L-6200 pump, Model AS-4000 or L-3000 UV/VIS/DAD detector (Hitachi Instruments, Inc.). The system was equipped with an NEC 286 computer with 40M hard drive and Lab manager HPLC software (Hitachi Instruments, Inc.). HPLC columns used included a 4.6 mm. × 250 mm. Phenyl column, packed with 5 μm diphenyl material (Supelco, Inc.); a 4.6 mm. × 250 mm., 5 μm, 60 angstrom Pentafluorophenyl (PFP) column (ES

Industries); and a 4.6 mm. × 20 mm. phenyl guard column (Jones Chromatography). Silica Gel for flash chromatography (230) to 400 mesh) was supplied by Scientific Products.

Yields refer to chromatographically and spectroscopically pure compounds unless otherwise noted. "Chrom purity" as used herein refers to the HPLC normalized peak area

percentage at 227 nm for a given component. Melting points are uncorrected. NMR data was obtained using either a

Bruker WP-270 MHz, Bruker ACE-300 MHz, or a Bruker AM-500 MHz instrument. ¹H-NMR and ¹³C-NMR chemical shifts are reported in ppm. relative to tetramethylsilane using

residual non-deuterated NMR solvent for reference. Mass spectra were recorded on a VG Platform (API mass

spectrometer) - electrospray mode.

Example 1: This example illustrates the conversion of XT, i.e., 7-xylosyl taxol, to "oxo-XT."

Synthesis: A 5.1 g sample of 7-xylosyl-taxol (XT, 5.13 moles) was dissolved in 55:45 THF/H₂O (0.12 M solution). To this solution was added 5.5 g of NaIO₄ (5 eq), and the reaction was heated to 50ºC.

The reaction was monitored by HPLC, and after 18.3 hours no more starting material (XT) or intermediate

oxidation products remained, so the reaction was stopped. The crude mixture was diluted with ethyl acetate (EtOAc), and washed successively with saturated Na₂S₂O₃ and brine solutions. The EtOAc solution was then dried over MgSO₄ and concentrated to give 5.3 g of a yellow solid. The product, oxo-XT, was present at 88% chrom purity.

Purification: A 1.0 g sample of impure oxo-XT was dissolved in pyridine (0.08 M), and 1.6 g of Et₃SiCl (10 eq) was added. The reaction proceeded under nitrogen atmosphere at room temperature for 24 hours. The crude mixture was then diluted with CH₂Cl₂ and washed successively with water, 1N HCl, saturated NaHCO₃, and brine solutions. The CH₂Cl₂ solution was then dried over MgSO₄ and concentrated, to give 2.4 g of a yellow semi-solid.

Flash silica gel chromatography yielded the purified fully silylated material. A 20-30% EtOAc/hexane gradient elution was used, and 770 mg of the fully silylated compound was recovered. This corresponds to a yield of 65% for this step.

A 770 mg sample of the fully silylated oxo-XT was dissolved in a 4:4:2 AcOH/THF/H₂O solution (0.1 M). After 24 hours the reaction was stopped and diluted with EtOAc. The solution was washed successively with saturated NaHCO₃ and brine solutions. It was then dried over MgSO₄ and concentrated. The resulting white solid was dissolved in 8 ml of acetone and precipitated with 50 ml of hexane, to give 505 mg of oxo-XT, at 96% chrom purity. The product had a melting point of 165-185 deg. C.; decomposed. The overall yield for this step was 89%.

An alternate method for purification of oxo-XT utilizes selective precipitation and flash silica gel chromatography. A 650 mg. sample of oxo-XT, at 84% chrom purity, was

dissolved in 7 ml. of acetone and precipitated with 100 ml. of hexane. The resulting white solid was then purified by flash silica gel chromatography. A gradient elution of 50-66% EtOAc/CH₂Cl₂ was used. The appropriate fractions were combined and concentrated to a residue. The residue was then dissolved in 7 ml. of acetone and precipitated with 100 ml. of hexane. Vacuum filtration yielded 393 mg . of oxo-XT at 97% chrom purity . The overall recovery for this method was 61%.

Example 2: This example illustrates the conversion of

10-DAXT, i.e., 10-deacetyl-7-xylosyl taxol, to "oxo-10-DAXT." Synthesis: A 5.1 g sample of 10-deacetyl-7-xylosyl-taxol (10-DAXT, 5.45 moles) was dissolved in 55:45 THF/H₂O (0.12 M. solution). To this solution was added 5.8 g of NaIO₄ (5 eq), and the reaction was heated to 50°C. The reaction was monitored by HPLC, and after 19 hours no more starting material or intermediate oxidation products remained, so the reaction was stopped. The crude mixture was diluted with EtOAc, and washed successively with saturated Na₂S₂O₃ and brine solutions. The solution was then dried over MgSO₄ and concentrated to give 5.4 g of a yellow solid. The product, oxo-10-DAXT, was present at 90% chrom purity.

Purification: A 647 mg sample of impure oxo-10-DAXT was dissolved in 7 ml of acetone at 30° C. This solution was transferred to 70 ml of hexane, resulting in a white precipitate. Vacuum filtration resulted in isolation of 643 mg of oxo-10-DAXT, at 95% chrom purity. Recovery for this step was 99%. The product had a melting point of 170-183 deg. C; decomposed.

Example 3 : This example illustrates the conversion of 10-DAXTB, i.e., 10-deacetyl- 7-xylosyl taxol B, to "oxo-10-DAXTB" .

Synthesis: A 209 mg sample of 10-deacetyl-7-xylosyl taxol B (0.23 mmoles) was dissolved in 55:45 THF/H₂O (0.12 M solution). To this solution was added 243 mg of NaIO₄

(5 eq), and the reaction was heated to 50°C. The reaction was monitored by HPLC, and after 23 hours no more starting material (10-DAXT B) or intermediate oxidation products remained, so the reaction was stopped. The crude mixture was diluted with EtOAc, and washed successively with

saturated Na₂S₂O₃ and brine solutions. The EtOAc solution was then dried over MgSO₄ and concentrated, to give 205 mg of a yellow solid. The product, oxo-10-DAXTB, was present at 93% chrom purity.

Purification: A 205 mg sample of impure oxo-10-DAXTB was dissolved in 6 ml of acetone and precipitated with 50 ml of hexane. Vacuum filtration yielded 164 mg of oxo-10-DAXTB at 96% chrom purity. The isolated yield was 79%. The product had a melting point of 168-182 deg. C.; decomposed.

Example 4: This example illustrates the conversion of

10-DAXTC, i.e., 10-deacetyl-7-xylosyl taxol C, to "oxo-10-DAXTC."

Synthesis: A 237 mg sample of 10-deacetyl-7-xylosyl taxol C (10-DAXTC, 0.25 mmoles) was dissolved in 55:45

THF/H₂O (0.12 M solution). To the solution was added 271 mg of NaIO₄ (5 eq), and the reaction was heated to 50°C. The reaction was monitored by HPLC, and after 48 hours no more starting material (10-DAXTC) or intermediate oxidation products remained, so the reaction was stopped. The crude mixture was diluted with EtOAc and washed successively with saturated Na₂S₂O₃ and brine solutions. The EtOAc solution was then dried over MgSO₄ and concentrated, to give 237 of an off-white solid. The product, oxo-10-DAXTC, was present at 90% chrom purity.

Purification: A 237 mg sample of impure oxo-10-DAXTC was dissolved in 6 ml of acetone and precipitated with 50 ml of hexane. Vacuum filtration yielded 186 mg of oxo-10-DAXTC at 94% chrom purity. The isolated yield was 80%. The product had a melting point of 159-186 deg. C.; decomposed.

Example 5: This example illustrates the reduction of "oxo-10-DAXT" to the 7-oxo-10-DAXT diol form.

Synthesis: A 724 mg sample of oxo-10-DAXT was

dissolved in 55:45 THF/H₂O (0.18 M solution) with a trace of methyl orange indicator. To this solution was added 196 mg of NaBH₃CN (4 eq) along with 1.7 ml of AcOH. The reaction proceeded at r.t. After 6.25 hours the reaction was not complete, so 49 mg of NaBH₃CN (1 eq) was added along with 0.5 ml of AcOH. After 23 hours the reaction was complete. The crude mixture was then diluted with EtOAc and washed successively with saturated NaHCO₃ solution, water, and brine. The solution was then dried over MgSO₄ and

concentrated to give 685 mg of a white solid. Purification: Flash silica gel chromatography yielded the final product. A 685 mg sample of the crude diol was eluted with a 7% MeOH/CH₂Cl₂ solution to give 579 mg of oxo-10-DAXT diol, at 96% chrom purity. The overall yield for this conversion was 81%. The product had a melting point of 175-178 deg. C.

Example 6: This example illustrates the silylation of "oxo-XT."

Synthesis: A 1.0 g sample of impure oxo-XT was dissolved in pyridine (0.08 M), and 1.6 g of Et₃SiCl (10 eq) was added. The reaction proceeded under nitrogen at room temperature for 24 hours. The crude mixture was then diluted with CH₂Cl₂ and washed successively with water, IN HCl, saturated NaHCO₃, and brine solutions. The CH₂Cl₂ solution was then dried over MgSO₄ and concentrated to give 2.4 g of a yellow semi-solid.

Purification: Flash silica gel chromatography yielded the fully silylated material. A 20-30% EtOAc/hexane

gradient elution was used, and 770 mg of the fully silylated compound was recovered. This corresponds to a yield of 65% for this conversion. The product had a melting point of 113-120 deg. C. Example 7: This example illustrates the results of

biological tests on the compounds of this invention and certain "controls" with respect to tubulin binding and the effect of these compounds on B16 melanoma. The following procedures were employed:

Tubulin Preparation and Assembly. The tubulin testing was done exactly as described by Himes (Georg, G. I.,

et al . , "Synthesis of Biologically Active Taxol Analogs with Modified Phenylisoserine Side Chains", J Med. Chem. Vol. 35: 4230, (1992)), incorporated herein by reference.

Tubulin free of microtubule-associated proteins was purified from bovine brain as described in Algaier, J.; Himes, R.H., "The Effect of Dimethyl Sulfoxide on the Kinetics of Tubulin Assembly" Biochim. Biophys. Acta, Vol 954, pp 235-243, 1998. The assembly reaction was done at 37°C in PEM buffer (0.,1 M Pipes, pH 6.9, 1 mM EGTA, and 1 mM MgSo₄) at a protein concentration of 1 mg/ml (10 μK) in the presence of taxol or taxol analogs and 0.5 mM GTP. The reaction was monitored by the increase in the apparent absorbance at 350 nm.

B16 Melanoma Cell Proliferation. Cells were seeded in

24-well plates at 7.5×10₄ cells/well and grown in Delbecco's modified minimal essential medium (MEM) containing 10% bovine calf serum at 37°C for 24 hours in a 97% humidified atmosphere of 5.5% CO₂, the medium was then replaced with fresh medium containing taxol or its derivatives and dissolved in DMSO in concentrations ranging from 7.5 × 10⁹ M to 1 × 10_-7 M for taxol and other derivatives. The final concentration of DMSO in the cell medium was 0.5% or less. This amount of DMSO did not have any effect on cell

proliferation as determined from control experiments. After 40 hours, the cells were released by trypsinization and counted in a Coulter counter.

The data for tubulin binding and B16 melanoma

cytotoxicity for certain "oxo" compounds and the

7-xylopyranoside taxanes from which the "oxo" compounds were derived (as described herein) are reported in Table 1.

Taxol has been included in Table 1 for reference. In addition, each sample is compared to a control sample of taxol as reported in the columns: "ED₅₀/ED₅₀ Taxol" (for Tubulin Assembly), and "ED₅₀/ED₅₀ Taxol" (for B16

Proliferation); taxol shows a value of approximately 1 in these columns. A number less than 1 in these columns indicates greater activity than taxol. A number greater than 1 in these columns indicates lower activity than taxol. These tests have been used and relied upon by researchers in this field to determine the potential efficacy of taxol and/or a taxol analog for the treatment of cancer.

The data clearly shows that the "oxo" compounds and th reduced "oxo" derivatives have activity comparable to or superior to taxol with respect to in vitro tubulin assembly. In addition, in each case the table demonstrates that the "oxo" compound has significantly improved tubulin binding and cytotoxicity over the material from which it was

derived. Example 8 :

A number of "oxo" compounds were submitted to the

National Cancer Institute for testing using standard

procedures employed by that organization for determining th cytotoxic effect of various materials. The test procedures are generally described in Boyd, M.R. et al. "Data Display and Analysis Strategies for the NCI Disease-Oriented In Vitro Antitumor Drug Screen," contained as Chapter 2 in

Cytotoxic Anticancer Drugs: Models and Concepts for Drug Discovery and Development. Proceedings of the Twenty-Second Annual Cancer Symposium, Detroit, Michigan (April 26-28, 1990) and edited by Frederick A. Valeriote et al. of Wayne State University (the "Boyd article"). The Boyd article is incorporated by reference herein. As described in that article, the National Cancer Institute test comprises the application of the prospect compound (in this case six "oxo" compound) to 50-60 different live cancer cell lines and a determination of the percentage growth ("PG") of each live cell line thereafter. The test includes the recording and analysis of data in several different formats as described in the Boyd article.

Six "oxo" compounds were submitted to the National Cancer Institute which tested the compounds and reported the results to applicants. The compounds submitted were:

A. oxo-10-deacetyl-7-xylosyl taxol, i.e., oxo-10-DAXT ╌ Table 2;

B. oxo-7-xylosyl taxol, i.e., oxo-XT ╌ Table 3;

C. oxo-10-deacetyl-7-xylosyl taxol diol, i.e., oxo-10-DAXT diol ╌ Table 4;

D. oxo-7-deacetyl-7-xylosyl taxol C, i.e., oxo-10-DAXT C ╌ Table 5;

E. oxo-10-deacetyl-7-xylosyl taxol B, i.e, oxo-10-DAXT B ╌ Table 6; and

F. oxo-7-xylosyl taxol diol, i.e., oxo-XT diol ╌ Table 7. Tables 2 through 7 are summaries of data for different cytotoxic "oxo" compounds of this invention. In each table are listed the "panel" or type of human cancer cell line, the specific cell line (coded by the discoverer or the National Cancer Institute), and the log₁₀ values for: GI50 (for the oxo compound), GI50 TAX (for taxol), TGI (for the compound), TGI TAX (for taxol), LC50 (for the compound), an LC50 TAX (for taxol). The listed values are derived from dose response curves for each compound and for taxol.

Examples of dose response curves used by the National Cance Institute are shown in the Boyd article. The curves show that at increasing concentration of compound added to the cancer cells, the PG of the live cancer cells in each panel slows, stops or decreases if the compound is a growth inhibitor, cytostatic, or cytotoxic.

As indicated in the Boyd article, the terms GI50, TGI and LC50 are defined as follows:

GI50 is the concentration of the "oxo" compound for which the PG = + 50. At this value, the increase from time t_zero (the time the compound is introduced into the cells) in the number or mass of cells in the test well is only 50% as much as the corresponding increase in the control well during this period of the experiment. A drug effect of this intensity is interpreted as "primary growth inhibition." TGI is the concentration for which the PG = 0. At this value, the number or mass of cells in the test well at the end of the experiment equals the number or mass of cells in the well at time t_zero. A drug effect of this intensity is regarded as "cytostasis."

LC50 is the concentration for which the PG = -50. At this value, the number or mass of cells in the test well at the end of the experiment is half that at time t_zero. A drug effect of this intensity is regarded as "cytotoxicity." The values in each table are listed for comparison.

The GI50 value for a specific cell line is compared with the value listed for GI50 TAX. The TGI value for a specific cell line is compared with the value listed for TGI TAX. The LC50 value for a specific cell line is compared with the value listed for LC50 TAX. The lower number (more negative) of the two corresponds with a lower relative concentration needed to reach the GI50, TGI or LC50 parameter.

Consequently, the compound is either more potent than taxol if it has a lower number, or less potent than taxol if it is a higher number. For example, looking at Table 2, the GI50 and GI50 TAX values for melanoma cell line M14 for oxo-10-DAXT and for taxol are -6.65 and -11.73, respectively. At this point in the dose response curve, taxol is more potent than oxo-10-DAXT. However, the TGI and TGI TAX values for oxo-10-deacetyl-7-xylosyl taxol and taxol are -5.60 and -4.62, respectively. Oxo-10-DAXT is more potent than taxol at this point in the dose response curve. The other values in Tables 2 through 7 can be evaluated similarly.

A total of 50 to 60 cell lines were tested for each compound by the National Cancer Institute. Not all of the cell lines are listed in Tables 2 through 7. The cell lines included in the tables are those that were more sensitive to the listed compound compared to taxol for at least one of the dose response parameters. With regard to drug efficacy, the fact that some cell lines are more sensitive to, for example, oxo-10-deacetyl-7-xylosyl taxol than taxol, could be of great benefit in treating cancer. If a compound is significantly more potent for a specific cell line compared to taxol, an established cancer chemotherapeutic agent, then it may be useful in treating cancerous tumors with tissue composed of similar cells. In summary, differential cancer cell line cytotoxic activity for the "oxo" compounds

relative to taxol indicates that the "oxo" compounds are of great potential benefit for treating cancer. The National Cancer Institute has selected these compounds for further testing as potential cancer-treating drugs.

The description and examples set forth herein are intended to illustrate representative embodiments of the invention. The claims which follow are not intended to be limited to the specific disclosed embodiments. The invention is susceptible to modification, variation and change without departing from the proper scope or fair meaning of the following claims.

Claims

What is claimed is :

1. A method for inhibiting growth of cancer cells comprising contacting said cells with an effective amount of a composition comprising:

Wherein R represents Ac or H;

R' represents:

;

OR

;

OR ;

OR

OH; and

R" represents:

;

OR

2. The method of claim 1 wherein:

R is Ac;

R' is:

;

and R" is:

3. The method of claim 1 wherein:

R is H;

R' is: ;

and R" is

4. The method of claim 1 wherein:

R is H;

R' is:

;

and R" is:

5. The method of claim 1 wherein:

R is H;

R' is: ;

and R" is:

6. The method of claim 1 wherein:

R is H;

R' is:

;

and R" is:

7. The method of claim 1 wherein: R is Ac;

is:

and R" is:

8. The method of claim 1 wherein: R is Ac;

R' is:

and R" is: