(b) Description of Prior Art Paclitaxel is a natural product extracted from the bark of the Pacific yew (Taxus brevifolia). It was thereafter found in other members of the Taxacae family including the yew of Canada (Taxus canadensis) found in Gaspesia, eastern Canada and Taxus baccata found in Europe whose needles contain paclitaxel and analogs and hence provide a renewable source of paclitaxel and derivatives. The crude extract was tested for the first time during the 60s and its active principle was isolated in 1971 by Wani et al. who at the same time identified its chemical structure. It showed a wide range of activity over melanoma cells, leukemia, various carcinomas, sarcomas and non-Hodgkin lymphomas as well as a number of solid tumors in animals.

Clinical studies show that paclitaxel is a promising anti cancer agent. Paclitaxel is a microtubule blocker, but unlike other drugs inhibiting the mitosis by interaction with microtubules such as colchicin, vincristin and podophyllotoxin, paclitaxel does not prevent tubulin assembly. It rather accelerates the tubulin polymerization and stabilizes the assembled microtubules. The drug acts in a unique way that consists in binding to microtubules, preventing their depolymerization under conditions where usually depolymerization occurred (dilution, calcium, cold and microtubules disrupting drugs). Paclitaxel blocks the

cell cycle at prophase, which results in an accumulation of cells in G2+M. Because of its unique structure and mechanism of action, paclitaxel was submitted to clinical trials. Interesting activity against many tumors, especially breast cancer and ovarian cancer refractory to chemotherapy, has been observed. However, because of its poor solubility in water, the product had to be administered in ethanol, Cremophor-EL and 5% sucrose diluted in saline or water.

Cremophor-EL was responsible for hypersensitivity reactions observed in several patients (Rowinsky, E.

K., et al., J. Nat. Can. Inst., 82 (15), 1247-1259).

Premedication with anti-histamines had to be administered in order to reduce the toxicity.

Poor solubility of paclitaxel constitutes an important limitation to its administration to cancer patients. To increase paclitaxel availability, total and partial synthesis have been reported. The improvement of paclitaxel solubility was obtained by adjunction of solubilizing functions such as carbonyl or sulfonyl groups with good results. Some of the synthesized products were more active than paclitaxel, many others had a biological activity equivalent or slightly inferior to that of paclitaxel while being far more soluble in water (KINGSTON, D. G., Pharmacol.

Ther. (England), 52 (1) pl-34, 1991). The complexity of the paclitaxel chemical structure rendered its total synthesis very difficult until recently when it was achieved simultaneously by two different groups.

However the yield of this synthesis of the order of 2- 4% will have little impact on the paclitaxel availability (BORMAN, S., Total synthesis of anticancer agent paclitaxel was achieved by two different routes (C@EN. February, 32-34, 1994)).

Many attempts have been made to improve paclitaxel aqueous solubility with various components resulting in poorly stable products or inactive ones.

Moreover, sometimes the synthesis of these compounds required many chemical steps.

Paclitaxel has three hydroxyl groups at carbon 1,7 and 2'susceptible of undergoing an acylation.

Their reactivity varies according to the following order: 2'> 7> » 1 (MATHEW, A. E., et al., J. Med.

Chem., 35,145-151, 1992). Acylation on 2'C is the best way of paclitaxel modification because of its great reactivity, and because even if 2' acylpaclitaxels loose their property of promoting the microtubules polymerization in vitro, they are hydrolyzed in the cell and revert to paclitaxel and keep their cytotoxic activity (KINGSTON, D. G., et al., J. Nat. Prod., 1-13,1990 ; and MELLADO, W., et al., Biochem. Biophys. Res. Commun., 105,1082-1089, 1984).

Accordingly, to increase solubility, several derivatives have been synthesized by modification of the 2'or/and 7 hydroxyls. The 2'hydroxyl appears as a good candidate for chemical modification. The 7 hydroxyl requires more drastic conditions to react while the tertiary hydroxyl in position 1 is inert.

The 2'and 7 hydroxyls have been modified with several groups (Deutsch, H. M., et al., J. Med. Chem., 32,788- 792,1989 ; Rose, W. C., et al., Cancer Chemother.

Pharmacol., 39,486, 1997) but only a few derivatives were synthesized with a sugar moiety as reported by Kingston et al. (Kingston, D. G. I., Pharmac. Ther., 52,1-34, 1991). However, many derivatives were insufficiently soluble, inactive or too unstable to be applied in a clinical situation.

The synthesis of soluble derivatives of paclitaxel allows for one skilled in the art to use

these new derivatives in a drug targeting cancer treatment. Several coupling methods permit the linkage of a cytotoxic drug to a protein that targets a specific antigen expressed by a specific type of cell such as cancer cells. A coupling method of an anti- tumor to an antibody using glutaraldehyde preactivated anti-tumor agent is described in U. S. Patent No.<BR> <P>5,208, 323, the content of which is hereby incorporated by reference.

It would thus be highly desirable to be provided with new immunoconjugates to specifically target cancer cells.

It would also be highly desirable to be provided with new active paclitaxel derivatives having improved solubility with respect to paclitaxel.

It would be highly desirable to be provided with a simple, rapid and accurate immunological method for the measurement of paclitaxel in biological fluids and in Taxus crude extracts.

It would be highly desirable to be provided with a fluorescent derivative of paclitaxel, which binds to microtubules, to discriminate apoptotic cells.

SUMMARY OF THE INVENTION One aim of the present invention is to provide a new active paclitaxel derivative modified at the 2'or 7 position showing improved solubility.

Another aim of the present invention is to provide new paclitaxel derivatives made from glutarylpaclitaxel to which different amino acids or glucuronide were conjugated. These new compounds show cytotoxic activity similar to paclitaxel alone but with an improved aqueous solubility.

Another aim of the present invention is to provide a method to link a water-soluble derivative of paclitaxel to a protein using glutaraldehyde.

Another aim of the present invention is to provide a method for in vivo treatment or prophylaxis of cancer.

Another aim of the present invention is to provide a method for detecting apoptosis of cells.

Another aim of the present invention is to provide fluorescent derivatives of paclitaxel for the measurement of paclitaxel in biological specimens and in extracts of different Taxus species, with high sensitivity using a FPIA (Fluorescent Polarization ImmunoAssay).

Another aim of the present invention is to provide a method and a kit for the detection of paclitaxel in a medium.

Another aim of the present invention is to provide a method for the in vivo treatment or prophylaxis of cancer comprising the step of administering a therapeutically effective amount of a water-soluble paclitaxel derivative as defined above to a patient in need of such a treatment.

Another aim of the present invention is to provide a method for in vitro or in vivo labeling tubulin comprising the step of contacting patient's cells with a water-soluble derivative of paclitaxel as defined above.

Another aim of the present invention is to provide a pharmaceutical composition comprising a derivative as defined above with a pharmaceutically acceptable carrier.

In accordance with the present invention, there is provided an in vitro method for determining apoptosis of cancer cells comprising the steps of:

a) incubating cells with a labeled paclitaxel derivative under suitable condition for the derivative to penetrate in the cells, whereby the labeled paclitaxel derivative binds to microtubules of cancer cells, thereby preventing cell division; b) washing off the cells from unbound labeled paclitaxel derivative; and c) detecting a label on the labeled paclitaxel derivative bound to cancer cell, whereby detection of the label is indicative of apoptotic cancer cells.

In accordance with the present invention there is also provided a water-soluble paclitaxel derivative or a salt thereof having the following Formula I: wherein R and R', identical or different, are a hydrogen or a -CO- (CH2) 3-COX, in which X is selected from the group consisting of a hydroxyl, a 6-aminohexanol group, a 1,6-diaminohexyl, and a polar amino acid residue, and with the proviso that R and R' are not both hydrogen. Preferably, R or R'is a hydrogen.

Preferably, the polar amino acid residue is selected from the group of residues consisting of arginine, asparagine, aspartic acid, cystein, glutamic acid, glutamine, glycine, histidine, lysine, phenylalanine, serine, threonin and tyrosine. More

preferably, the polar amino acid residue is asparagine or glutamine residue.

The paclitaxel derivative in accordance with one embodiment of the invention is labeled with a marker, such as without limitation, a fluorescent marker or a radioactive marker.

In accordance with the present invention, there is provided a derivative as described above, on which a glucuronide moiety is connected to the 6-aminohexanol group.

In accordance with the present invention, there is also provided a method for the in vivo treatment or prophylaxis of cancer comprising the step of administering a therapeutically effective amount of a water-soluble paclitaxel derivative as defined above to a patient in need of such a treatment.

In accordance with the present invention, there is also provided an immunoconjugate having the following formula II: wherein M is selected from the group consisting of a peptide residue and a protein residue linked to the carbon atom via an amino residue of Lysine present therein, and wherein R represents a water-soluble derivative of paclitaxel as defined above.

Further in accordance with the present invention, there is provided a method to link a water- soluble derivative of paclitaxel as defined above to a protein using glutaraldehyde, comprising the steps of :

a) reacting the water-soluble derivative of paclitaxel with glutaraldehyde; b) purifying the activated product obtained from step a); c) reacting the purified activated product of step b) with a protein for producing an immunoconjugate; and d) purifying the immunoconjugate of step c).

The method of the present invention as described above can be easily produced and is devoid of significant polymerization.

In accordance with the present invention, there is also provided a method for the in vivo treatment or prophylaxis of cancer comprising the step of administering a therapeutically effective amount of an immunoconjugate comprising a water-soluble paclitaxel derivative as defined above, linked to a protein by a glutaraldehyde, to a patient in need of such a treatment.

In accordance with the present invention, there is also provided a method for in vitro or in vivo labeling of tubulin comprising the step of contacting patient's cells with a water-soluble derivative of paclitaxel as defined above.

In accordance with the present invention, there <BR> <BR> is further provided a method for in vitro determining the concentrations of paclitaxel or paclitaxel derivative comprising the steps of: a) contacting a labeled paclitaxel derivative, preferably a fluorescent labeled derivative, with a biological fluid or a crude extract from a Taxus species, and an antibody raised against

paclitaxel, whereby said labeled paclitaxel derivative competes for said antibody against paclitaxel in said biological fluid or said crude extract; b) detecting a label on said labeled paclitaxel derivative; and c) determining the quantity of paclitaxel from said biological fluid or said extract with respect to a standard competition curve.

In accordance with the present invention, there is further provided an in vitro method for determining apoptosis of cancer cells comprising the steps of: a) incubating cells with a labeled paclitaxel derivative, preferably a fluorescent labeled derivative, under suitable condition for said derivative to penetrate in said cells, whereby said labeled paclitaxel derivative binds to microtubules of cancer cells, thereby preventing cell division; b) washing off said cells from unbound labeled paclitaxel derivative; and c) detecting a label on said labeled paclitaxel derivative bound to cancer cell, whereby detection of said label is indicative of apoptotic cancer cells.

In accordance with the present invention, there is further provided the use of a derivative as defined previously for the preparation of a medicament for treating cancer or for labeling tubulin.

Still in accordance with the present invention, there is provided the use of a derivative as defined above for determining a concentration of paclitaxel or a derivative thereof, or for determining apoptosis of cells.

In accordance with the present invention, the pharmaceutical composition described above can be used for preparing a medicament for treating cancer.

The derivative of the present invention or a composition containing same is useful for treating cancer or for labeling tubulin.

In accordance with the present invention, there is further provided a method of preparing compounds of Formula II: wherein M is selected from the group consisting of a peptide residue, and a protein residue linked to the carbon atom via an amino residue of lysine present therein, and wherein R represents a water-soluble derivative of paclitaxel as previously. The method comprises the steps of : a) reacting the water-soluble derivative of paclitaxel with glutaraldehyde for obtaining a water-soluble paclitaxel derivative- glutaraldehyde complex; and b) reacting the water-soluble paclitaxel derivative-glutaraldehyde complex of step a) with a protein or a peptide for obtaining an immunoconjugate.

This method may further comprises between step a) and b) a step of purifying the complex obtained in step a). Alternatively, the method may also comprise after step b) a step of purifying the immunoconjugate.

Preferably, the water-soluble paclitaxel derivative is 2'-glutaryl hexanediamine paclitaxel, 2'- glutamine derivative of glutarylpaclitaxel or 2'- asparagine derivative of glutarylpaclitaxel.

In a preferred embodiment of the invention, M is a protein selected from the group of BCM43 monoclonal antibody, BCM43 humanized antibody, BCM43 chimerized antibody, the (Fab), (Fab) 2 or scFv moiety of the BCM43 antibody, BCM17 monoclonal antibody, BCM17 humanized antibody, BCM17 chimerized antibody, the (Fab), (Fab) 2 or scFv moiety of the BCM17 antibody, anti- carcinoembryonic monoclonal antibody and anti- alphafetoprotein monoclonal antibody. BCM43 is a monoclonal antibody recognizing an epithelial mucin expressed by ovarian and breast cancer cells. BCM17 (monoclonal anti-P7) is a murine monoclonal antibody recognizing a P7 protein, which is overexpressed in resistant ovarian cancer.

The compound of formula II is preferably BCM43 monoclonal antibody-2'-glutaryl hexanediamine paclitaxel conjugate, BCM43 humanized antibody-2'- glutaryl hexanediamine paclitaxel conjugate, BCM43 chimerized antibody-2'-glutaryl hexanediamine paclitaxel conjugate or the Fab portion of the BCM43 monoclonal antibody-2'-glutaryl hexanediamine paclitaxel conjugate.

In accordance with the present invention, there is provided a method for treating cancer which comprises administering to a patient a therapeutic dosage of a compound of Formula II as defined previously.

The compound of the present invention may be formulated in a pharmaceutical composition. Such composition, or the compound itself, is preferably used for the preparation of a medicament for treating cancer.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 illustrates the H-NMR of 2'- glutarylpaclitaxel; Fig. 2 illustrates the thin layer chromatography (TLC) analysis of three compounds, namely 6- aminohexanol (1), 6-aminohexanolglucuronide before deprotection (2) and methyl 1,2, 3,4 tetra-O-acetyl-B-D- glucuronate (3) revealed with either molybdate (a), aniline (b) or ninhydrine (c); Fig. 3 illustrates the elution of the derivative 2'-glutarylpaclitaxel 6-aminohexanol glucuronide on HPLC; Figs. 4A and 4B illustrate absorption spectra for the different peaks obtained during purification of glutarylpaclitaxel 6-aminohexanol glucuronide on HPLC at 2.797 minutes, 3.147 minutes and 4.097 minutes (4A) and paclitaxel (4B); Fig. 5 illustrates the cytotoxicity of the glucuronide derivative of the present invention compared to the cytotoxicity of paclitaxel on teratocarcinoma, CRL-1572 cell line; Fig. 6 illustrates the effect of the two new derivatives (glutarylpaclitaxel asparagine and glutarylpaclitaxel glutamine of the present invention on murine melanoma B-16 cell cycle; Fig. 7 illustrates apoptosis of CCRF CEM cells detected with the fluorescent 7-BODIPY paclitaxel derivative in accordance with one embodiment of the present invention;

Fig. 8 illustrates the effect of a 72 hour incubation with 20 mg/ml hydrocortisone on human lymphocytes, revealed with a fluorescent 7-FITC paclitaxel derivative in accordance with one embodiment of the present invention; Fig. 9 illustrates the fluorescence for normal and apoptotic cells as obtained on the fluorescence activated cell sorter (FACS) using TUNEL labeling ; Fig. 10 illustrates the correlation of the TUNEL labeling and the 7-FITC paclitaxel derivative labeling in accordance with one embodiment of the present invention ; Fig. 11 illustrates a standard curve for paclitaxel concentration in bovine serum obtained with the fluorescence polarization immunoassay of the present invention; Fig. 12 illustrates the dynamic binding of 2'-FITC paclitaxel in an immunoassay in accordance with a preferred embodiment of the present invention; Fig. 13 illustrates the dynamic displacement of 2'-FITC paclitaxel in the immunoassay of Fig. 12; Fig. 14 illustrates the correlation of the FPIA with HPLC; and Fig. 15 illustrates the cytotoxicity of the immunoconjugate 2'-glutarylhexanediamine paclitaxel- glutaraldehyde-BCM 43 on CRL-1572 cells, in accordance with one embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION To increase solubility, while preserving cytotoxicity, in accordance with one embodiment of the present invention, there is provided a new paclitaxel derivative substituted at the 2'or 7 position of the paclitaxel molecule.

In accordance with a preferred embodiment of the invention, there is provided a water-soluble paclitaxel derivative having the following formula:

wherein R and R'are defined in the Table I below TABLE I Compound R R' 1) paclitaxel H H 2) 2'-glutaryl paclitaxel-CO-(CH2)3-COOH 3) 7-glutaryl paclitaxel H -CO - (CHZ) 3-COOH 4) 2'-glutaryl hexadiamine- 0 aclitaxel"taxamine"-co-cH23 C-NH- (CH2) 6-Nhlz 5) 7-glutaryl hexadiamine - H II BCitaxel -CO- (CH2) 3 C-NH- (CHz) 6-NH2 6) 2'-glutaryl paclitaxel 6- j coo H amino-hexanol glucuronide -co-cr-c-Nr. ccr pHl 1 HH OHH 2'amino acid derivatives of j H paclitaxel where X is: -o-ccHz3 C-NH-CHX-COOH 7) aspartate - CH2COOH 8) asparagine - CHzCONHZ 9) glutamate - CHzCH2COOH 10) glutamine CH2CH2CONH2 11) glycine H 12) serine - CH20H 13)2--FITC-paditaxel-c-NH.<cH-co.<c..coo 13) 2'-FITC-paclitaxel H I OH 0 OH i HIC-NH- (CFI6-NH-CO- (CFlt) -C00 14) 7-FITC-paclitaxel H I coo- OHOOH c 15)2'-BODIPY-paclitaxel=oH HpC H C HZ Ha 'B H3C F F CH3 tH- (CH g-NH-CO- (CH 3-COO- 16) 7-BODIPY-paclitaxel H 7 7=0 H; H3<<'T"2CH3 N, N

SYNTHESIS OF DERIVATIVES 2'glutarylpaclitaxel 2'glutarylpaclitaxel was prepared according to a modification of an already reported method by Deutsch et al. Briefly, 100 mg of paclitaxel dissolved in 1.2 ml of pyridine was added to 140 mg of glutaric anhydride. After 90 minutes of reaction at room temperature the solvent was evaporated to dryness. The residue was treated twice with water and the supernatant discarded. The precipitation from acetone gave 80 mg of an impure product. Further purification was made by reverse phase HPLC on a NOVA-PAK phenyl column 0.8/10 cm from Waters RCM. The solvent system was composed of methanol, acetonitrile and water. The gradient of acetonitrile and water was linear going from 10% to 35% in 30 minutes, methanol remaining constant at 40%. The reaction was followed by TLC on a silica plate, the eluant was composed of chloroform/methanol/water (40/13/2). Detection was made with vanillin (CARDELLINA II., J. H., J. Liq.

Chromatogr., 14,659-665, 1991). The reaction generates a product with a Rf of 0.74. The Rf of paclitaxel is 0.95 in the same conditions.

The 1H-NMR spectrum of glutarylpaclitaxel (Fig.

1) has shown a shift of the resonance of the C-2' proton from 4.71 to 5.77 PPM (KINGSTON, D. G., et al., J. Nat. Prod., 1-13,1990 ; and MELLADO, W., et al.,<BR> Biochem. Biophys. Res. Commun., 105,1082-1089, 1984).

In the present invention, the same shift from 4.78 PPM to 5.51 PPM was observed.

2'glutaryl hexanediamine paclitaxel :"taxamine" To 1 mol of 2'glutarylpaclitaxel dissolved in 100 . l of acetonitrile was added 5 ; umol of carbonyl diimidazole (CDI). The mixture was heated to 45°C during 15 minutes. After cooling to ambient

temperature 5 mol of 1,6-hexanediamine was added and reaction mixture was left at room temperature for one hour. The reaction was analyzed by TLC using two different solvent systems (acetonitrile: chloroform:<BR> water or chloroform: methanol: water). Two silica plates were prepared and the samples deposited in duplicate.

Vanillin detection was made on one half of each plate and ninhydrine revelation on the other half to reveal the amine component. The two systems have detected a new product with the Rf of 0.12 and 0.45, respectively in the two solvent systems. The excess of 1,6- hexanediamine was eliminated by washing. Further purification was made by reverse phase HPLC in the same conditions as for 2'glutarylpaclitaxel.

2'-glutarylpaclitaxel 6-aminohexanol glucuronide First, a glucuronide moiety must be activated.

To do so 112.6mg (0.3 mmole) of methyl 1,2, 3,4 tetra-O- acetyl- (3-D-glucuronate was added to HBr 30% in acetic acid. The reaction proceeded overnight in the dark at 4°C to give methyl (2,3, 4-tri-O-acetyl-l-bromo-l-deoxy-<BR> a-D-glucopyranosid) -uronate. The solvent was dried on a"SpeedVac"vacuum (Savant Instruments Inc., Holbrook, N. Y.) and ethanol 95% was added to the residue and left two days in the dark at 4°C. The mixture was centrifuged, the supernatant discarded and 1 ml of nitromethane was added to the pellet.

The synthesis of 6-aminohexanol glucuronide is then performed. Methyl (2,3, 4-tri-O-acetyl-l-bromo-l-<BR> deoxy-a-D-glucopyranosid) -uronate was added to 81.8 mg (0.70 mmole) of 6-aminohexanol, 59.3 mg (0.43 mmoles) of white drierite and 68.3 mg (0.27 mmole) of mercuric cyanide according to the method of Turgeon et al. (Turgeon et al., Drug Metab. Disp., 20: 762-769, 1992). A small amount of methanol and water was added in an attempt to achieve complete dissolution of the

products. The reaction mixture was stirred overnight in the dark at room temperature and the solvent was evaporated under vacuum. 6-aminohexanol glucuronide was extracted with chloroform and the most important part of the product was collected in the organic phase.

The glucuronide derivative is then deprotected.

The glucuronide was treated with 2.15 mg (39.8 ymoles) of sodium methoxyde (Omega Inc., Levis, Quebec) in anhydrous methanol. The reaction proceeded at room temperature during 24 hours with agitation.

The last part consisted in joining the deprotected 6-aminohexanol glucuronide part to glutarylpaclitaxel. Synthesis of glutarylpaclitaxel (glutaryltaxol) has been described previously. The final step consisted in activating 0.6 mg (0.62 mole) of 2'glutarylpaclitaxel with 0.95 mg (5. 9 moles) of carbonyl diimidazole in acetonitrile. The mixture was heated for 20 minutes at 45-50°C and left to stand at room temperature overnight. 6-aminohexanol glucuronide was added and the reaction was allowed to proceed once more overnight at room temperature.

TLC was performed after the synthesis of 6-aminohexanol glucuronide. Sample and standards were applied on silica plates. Migration was performed in chloroform: acetonitrile (7: 3). Chromatograms were revealed with three different solutions: ammonium molybdate + ceric sulfate in 10% sulfuric acid, solution prepared by dissolving 75g of ammonium molybdate and 49 g. of ceric sulfate in 500 ml of 10% sulfuric acid, aniline prepared by mixing one volume of solution 1 (130 , l aniline in 5 ml acetone), with one volume of solution 2 (60 Al phosphoric acid with 2 ml acetic acid and 3 ml acetone) and 4% ninhydrine in 95% ethanol. Fig. 2 shows the thin layer chromatography (TLC) analysis of three compounds, namely 6-

aminohexanol (1), 6-aminohexanolglucuronide before <BR> <BR> deprotection (2) and methyl 1,2, 3,4 tetra-O-acetyl--D- glucuronate (3) revealed with either molybdate (a), aniline (b) and ninhydrine (c). TLC analysis showed that the glucuronide moiety was effectively attached to 6-aminohexanol (Fig. 2). A positive reaction with ninhydrin indicates that the glucuronide position is attached to the hydroxyl group of 6-aminohexanol, which frees the amino group to form a peptide link with the carboxyl group of glutarylpaclitaxel.

The purification of the product glutarylpaclitaxel 6-aminohexanol glucuronide was performed on a SephadexT"'G-10 with a mixture of <BR> <BR> methanol: water (1: 1). The elution was monitored by optical density at 227 nm.

The product collected was purified by HPLC on a NOVA PAKT""phenyl reverse phase column. The system used was the Waters 625 LC System and a W996 photodiode array detector. The product was eluted with a gradient <BR> <BR> of acetonitrile: water: methanol from 10: 50: 40 to<BR> 45: 15: 40. The flow rate was 1 ml/min. during 30 minutes. The elution was monitored at 227 nm. The product was collected and evaporated to dryness on a SPEED VACT""vacuum. Fig. 3 illustrates the elution of the derivative glutarylpaclitaxel 6-aminohexanol glucuronide on HPLC and, Fig. 4A illustrates the spectrum for the different peaks obtained during the elution of glutarylpaclitaxel 6-aminohexanol glucuronide on HPLC. HPLC analysis of the final product (Fig. 3) showed the appearance of a new compound after four minutes. This new derivative showed an absorption spectrum similar to the one of paclitaxel (Fig. 4B). Furthermore, it was less strongly retained on an HPLC hydrophobic column than paclitaxel and 2'-glutarylpaclitaxel (elution after 4

minutes versus 18 to 20 minutes). This indicates an improved aqueous solubility compared to the parent compound. Two other peaks were also present but their absorption spectra indicate that they were not taxanes.

Amino acid derivatives of glutarylpaclitaxel Six (6) amino acid derivatives, still in accordance with the present invention, were synthesized. The first step consisted in synthesizing the glutarylpaclitaxel as reported by Deutsch et al.

Briefly, after 4 to 5 hours at room temperature, a solution of 65.3 moles of paclitaxel and 1040 moles of glutaric anhydride in 4 ml of pyridine was evaporated to dryness, solubilized in a minimal volume of methanol and water, and applied on a silica reverse phase C-18"minicolumn (PREP SEPT""C-18). Pyridine was eluted with water and glutarylpaclitaxel with methanol.

The product was evaporated to dryness on a SPEED VACT"" vacuum. To a solution of glutarylpaclitaxel (2-8 nmoles) in acetonitrile, was added a 10-20 fold excess of carbonyl diimidazole (CDI). The mixture was heated to 45°C for twenty minutes and left to stand at room temperature overnight. A large excess (50 fold) of the amino acids asparagine, aspartate, glutamate, glutamine, glycine, or serine, dissolved in water was added, slowly over a period of twenty minutes, and the reaction proceeded at room temperature overnight.

Small quantities were purified on HPLC. A Waters 625 LC system with a W996 photodiode array detector was used. The products were purified on a reverse phase Nova Pak Phenyl column (Waters, Milford, Massachusetts). Elution was performed with a gradient <BR> <BR> of acetonitrile: water: methanol from 10: 50: 40 to<BR> 45: 15: 40. The flow rate was 1 ml/min. for 30 minutes.

Elution was monitored at 228 nm. For larger amounts, a silica reverse phase C-18 minicolumn ("Prep Sep"C-18

from J. T. Baker, Phillipsburgh, N. J.) was used.

Products were eluted successively with water, with <BR> <BR> acetonitrile: water: methanol 10: 50: 40 and with the same<BR> solvents mixture, proportions being 45: 15: 40.

Fractions of 0.5 ml were collected and analyzed on HPLC in the conditions mentioned before. The fractions containing the pure derivatives (over 90% purity) were pooled and used for in vitro assays.

Of all the derivatives synthesized, the preferred compounds are the asparagine and glutamine derivatives (Fig. 6). Syntheses were successful and the yields varied from 80 to 100% for the glutarylpaclitaxel synthesis and around 60% overall for the asparagine and glutamine derivatives. The products were purified as described above. The new compounds were much less retained on HPLC (elution at 3 to 6 minutes) compared to glutarylpaclitaxel and paclitaxel (20-22 minutes). The absorption spectra were similar to that of paclitaxel and mass spectra analysis of the serine derivative showed that the taxane ring was intact indicating that the reaction occurred at the side chain 2'hydroxyl.

Synthesis of the Immunoconjugate First the compound 2'-glutarylhexanediamine paclitaxel is activated with glutaraldehyde. To do so, 1 mg of 2'-glutarylhexanediamine paclitaxel is dissolved in 200 pl of methanol. Then, 100 . 1 of DMSO and 200 pl of PBS (Phosphate Buffer Saline) are added, followed by an additional 1 ml of DMSO. 60 pl of glutaraldehyde 25% is then slowly added to the solution and the mixture is gently stirred for 15 minutes. The reaction is monitored by thin layer chromatography and stopped by the addition of 5 ml of dichloromethane.

Second, the excess of glutaraldehyde is removed by 6 liquid extractions with aqueous solutions. The

first one is performed with one volume of water. Four additional washes are then performed with a glycine : bicarbonate buffer pH 8.0 and the final wash with water. All aqueous fractions are discarded. The organic phase, which contains the activated compound, is dried in vacuo and stored at -80°C.

Third, the activated compound is then linked to an antibody. To do so, the antibody is dissolved in PBS and the activated 2'-glutarylhexanediamine paclitaxel-glutaraldehyde is solubilized in a solution of methanol: DMSO (1: 1) and 0. 2% of Triton X-100".

This latter solution is then slowly added to the antibody solution in order to get a ratio of one molecule of antibody for 10 molecules of the activated compound. The mixture is stirred and incubated at 37°C for one hour. The resulting immunoconjugate (2'- glutarylhexanediamine paclitaxel-glutaraldehyde- antibody) is purified on a PD-10"column (Amersham Pharmacia).

Fluorescent derivatives of paclitaxel In a further embodiment of the present invention, fluorescent paclitaxel derivatives, such as 2'-FITC paclitaxel, 7-BODIPY or 7-FITC paclitaxel, were synthesized and used to develop a new flow cytometry method for the discrimination of apoptotic from non- apoptotic cells. The 2'-FITC paclitaxel was also used for the development of an immunoassay (FPIA).

2'-FITC-labeled paclitaxel was prepared by reacting 2'-glutaryl hexadiamine paclitaxel with fluorescein isothiocyanate (FITC). FITC (2.5 mg) dissolved in methanol was added to a solution of 2'- glutaryl-hexadiamine paclitaxel (500 . g) dissolved in 0. 1M carbonate buffer/methanol (50: 50, v/v) pH 9.0.

The mixture was allowed to react in the dark for 8 hours at 4°C. The product was purified by gel

permeation chromatography on a Sephadex G10 gel column (0.7/25 cm) (Bio-Rad) using a solvent system of methanol/water (50: 50).

Cytotoxicity of derivatives Cytotoxicity assays were performed on several cell lines to determine IDsos. The cells used were the ovarian teratocarcinoma (CRL-1572), the ovarian carcinoma (SK-OV-3) and the corresponding drug- resistant cell line (SKVLB 600), the prostate carcinoma (LNCaP), the breast carcinoma (MCF-7), the leukemia (CCRF/CEM) and the drug-resistant line (CEM/VBL 0. 3), the murine melanoma (B-16) and finally, the mouse fibroblasts (3T3). The cells were maintained in RPMI 1640 supplemented with fetal calf serum 10% at 37°C, under a 5% CO2 atmosphere. For the resistant cell lines, vinblastine, concentrations of 300 ng/ml for the CEM/VBL and 600 ng/ml for the SKVLB, was added to the medium.

Cells were plated at 1000 to 2000 cells per well in 96 well plates. Drugs, derivatives or immunoconjugates were added the next day ranging from 0 to 2500 ng/ml in drug content. After three to four days in contact with the drugs, the medium was removed and replaced with 100 l per well of new medium containing Alamar Blue 5% as reported by Page et al.

(Page, B., et al., Int. J. Oncol., 3,473-476, 1993).

For cells growing in suspension, only 10 fit of Alamar Blue was added to the medium. The proportion of viable cells was assessed by measuring the fluorescence produced following the reduction of Alamar Blue by mitochondrial dehydrogenases (excitation: 530 nm, emission 590 nm) after two to four hours. The assays have been made in quadruplicates. Cytotoxicity was expressed as IDSos in nmoles per liter. Table 2 Relative Ratio IDso of derivative/IDso of paclitaxel Drugs tested Cell lines SKO SKV CCR CEM CRL- MCF LNC B-16 3T3 V-3 LB F/CE VBL 1572 -7 aP 600 M 0.3 paclitaxel 1 1 1 1 1 1 1 1 1 2'12. 3 < 1. 0 3. 7 > 1. 2 3. 7 6. 3 5. 2-9.0 9. 4- 6. 2- glutarylpaclitaxel 42.2 19.4 2'-glutaryl n/a n/a n/a > 1000 27. 0 15. 5 n/a 33. 8 n/a hexadiamine paclitaxel glutarylpaclitaxel n/a n/a 7. 9 n/a 3. 3 18. 9 12. 8 asparagine glutarylpaclitaxel n/a n/a 6.3 n/a 9.2 18.9 11.5 glutamine glutarylpaclitaxel 1.2 1.4 0.9 2.7 1.7 2.3 2.9 glycine glutarylpaclitaxel 6.0 3.3 2.2 7.5 6.1 5.3 3.7 serine

The four derivatives tested (asparagine, glutamine, glycine and serine) showed good cytotoxic activity against several sensitive cell lines (Table 2). Cytotoxicity was similar to paclitaxel alone. The asparagine and glutamine derivatives seem slightly less active than the other derivatives on some cell lines.

The IDsos ratios for the derivatives/paclitaxel vary from 0.9 to 42.2 depending on the derivative and the cell line tested.

The biological activity of 2'glutaryl paclitaxel, 2'glutaryl hexadiaminepaclitaxel and paclitaxel was tested by evaluating their capacity to inhibit the growth of H69 cells. 2'glutaryl paclitaxel had an activity 1.5 times less than that of paclitaxel (relative activity of 0. 67), 2'glutaryl

hexadiaminepaclitaxel was 8 times more active than paclitaxel (relative activity of 8), while transferrin paclitaxel conjugate was 5.4 times less active than paclitaxel (relative activity of 0. 18).

The IDSOs obtained were 110 ng/ml on CRL-1572 (87 nmoles/liter) for the glucuronide derivative (eluted after 4.1 minutes on HPLC) and 4.5 ng/ml (5.3 nmoles/liter) for paclitaxel, the parent compound (Fig. 5). The glucuronide derivative was about 16 times less active than paclitaxel alone.

The biological activity of the immunoconjugate 2'-glutarylhexanediamine-glutaraldehyde-BCM43 was tested by evaluating its capacity to inhibit the growth of CRL-1572 cells. As shown in FIG. 15, the immunoconjugate is more active on cancer cells than on normal cells.

Cell cycle analysis The effect of the derivatives was assessed on the mouse melanoma B-16 cell cycle. Cells were plated, 25000 cells per well, in six well plates, incubated for 24 hours in the conditions described for the cytotoxicity assays. The next day, drugs (paclitaxel, glutarylpaclitaxel, glutarylpaclitaxel asparagine and glutarylpaclitaxel glutamine) were added, concentrations ranging from 0 to 200 ng/ml. The cells were trypsinized 24 hours later and treated with Triton X-100 0.01% for 30 minutes at 0°C. The nuclei were collected following centrifugation. The DNA was marked with 50. 1 propidium iodide 1 mg/ml in 1 ml of FACS Flow (Becton Dickinson, Mississauga, Ontario). Fluorescence was measured with a cytofluorometer, FACS SORT, (Becton Dickinson, Mississauga, Ontario).

The results obtained for the cell cycle analysis show that the asparagine and glutamine derivatives block the cell cycle in prophase (G2+M) (Fig. 10) which

is consistent with the results obtained for paclitaxel alone.

Solubility of amino acid derivatives and chemistry To evaluate the solubility of the derivatives in water, the procedure as described by Swindell et al. was followed (Swindell, C. S., et al., J. Med. Chem., 34,1176-1184, 1991). Each compound was distributed between a two-phase mixture of chloroform-water and octanol-water respectively. The samples were mixed vigorously for one hour, and after separation of the two phases, each phase was examined by HPLC. (Table 3) For the second experiment, an excess of drug was added to water. The suspension was centrifuged, the supernatant collected and analyzed for drug concentration.

The derivatives extracted with chloroform were recovered in the aqueous phase especially the asparagine derivative. For the extraction performed with octanol, the derivatives were found essentially in the organic phase. Paclitaxel alone was almost exclusively in the organic phase.

The injection on HPLC of the asparagine and glutamine derivatives revealed that the solubility of glutarylpaclitaxel asparagine and glutarylpaclitaxel glutamine was 1550 moles per liter and 900 moles per liter, respectively. The solubility obtained for the glutarylpaclitaxel and the paclitaxel were 2.6 and 0.95 moles per liter. The asparagine and glutamine derivatives were respectively 1980 and 947 times more soluble in aqueous solution than the parent compound.

Table 3 Proportion of derivatives, glutarylpaclitaxel asparagine and glutarylpaclitaxel glutamine, in organic and aqueous phases following extraction with chloroform and octanol Glutarylpaclitaxei Giutarylpaclitaxel asparagine glutamine 1 st trial 2nd trial 1 st trial 2nd trial Total amount extracted 45.5 46.2 44.9 60.5 (nmoles) Aqueous phase 24 26 18 26 (nmoles) Chloroform Organic phase 3.2 1.7 17.5 37 (nmoles) Aqueous phase/organic 7.5 15 1.0 0.7 phase % of product recovered 65 60 79 102 Total amount extracted 45.5 46.2 44.9 60.5 (nmoles) Aqueous phase 9.4 4.8 4.9 24 (nmoles) Octanol Organic phase 6.2-9. 4 35 27 48 (nmoles) Aqueous phase/organic 1.0-1. 5 0.7 0.2 0.5 phase % of product recovered 34-41 86 71 119

Hydrolysis of derivatives was performed as follows; the derivatives were incubated for two days in acetate buffer 0. 1M, pH 4, at room temperature. The composition of the mixtures was analyzed by TLC. The samples were deposited on silica plates. The migration <BR> <BR> was performed in chloroform: methanol: water (40: 10: 5) and the chromatograms were revealed with ammonium

molybdate 0.012M + ceric sulfate 0.015M in sulfuric acid 10% and with a vaniline solution prepared by mixing a solution of vaniline 1% in ethanol with phosphoric acid 3% (1: 1).

It has been shown that the 2'hydroxyl is essential to tubulin binding. Intracellular hydrolysis could be responsible for the cytotoxic activity (Table 2) and effects observed on the cell cycle (Fig. 6).

Determination of apoptotic cells using fluorescent derivatives of paclitaxel In accordance with one embodiment of the invention, there is provided a new method to discriminate apoptotic cells using fluorescent derivatives of paclitaxel. Cell death occurs by two main mechanisms: apoptosis and necrosis. Necrosis is thought to be a non regulated mechanism occurring when a cell is subjected to harsh treatment overcoming its natural resistance while apoptosis is thought to be a controlled mechanism during which a precise sequence of reactions leads to cell death.

Apoptotic cells undergo important morphological ultrastructural and biochemical changes such as budding and bleeding of the plasmic membrane, ending in the formation of apoptotic bodies. Chromatin and nuclear condensation and DNA internucleosomal cleavage are also observed.

Several methods based on the change observed in cells undergoing apoptosis have been developed to identify and quantify apoptotic cells. Morphological changes such as chromatin condensation are used in optical microscopy. In TUNEL and ISNT methods, enzymatically labeled ends of DNA fragments are used to identify apoptotic cells by flow cytometry or fluorescence microscopy.

Microtubules and associated proteins seem to play an important role in apoptosis. Martin et al.

(Martin et al., Cell Tissue Kinet., 23: 545-559,1990) and more recently Subrata et al. (Subrata et al., <BR> <BR> Cancer Research, 57 : 229-233, 1997) showed that the microtubule disruption induces Bcl 2 phosphorylation and apoptotic cell death while Pittman and Ireland <BR> <BR> (Biochem. Pharm., 49: 1491-1494,1995) found that apoptosis is always accompanied by prominent and consistent tubulin reorganization independent of the cell cycle or the cell line, during both spontaneous and induced apoptosis. Thus, it would be highly desirable to be provided with fluorescent derivatives of paclitaxel, which bind to microtubules, to discriminate apoptotic cells.

In a further embodiment of the present invention, fluorescent paclitaxel derivatives, such as <BR> <BR> 2'-FITC paclitaxel, 7-BODIPY or 7-FITC paclitaxel, were synthesized as described above and used to develop a new flow cytometry method for the discrimination of apoptotic from non-apoptotic cells. Apoptosis was studied on peripheral human lymphocyte and CCRF CEM cells. After various periods of incubation with or without 10-8 M hydrocortisone or 1M of dexamethasone, cells were fixed in 70% cold methanol and double labeled either with propidium iodine and 7-FITC paclitaxel, propidium iodine and TUNEL labeling mixture (DUTP-FITC and terminal desoxynucleotidyl transferase) or TUNEL labeling and 7-BODIPY paclitaxel. Bivariate analysis of forward scatter plot versus green fluorescence (microtubules) showed that cells were distributed into two populations, one with a low forward scatter and low tubulin labeling, the second with a high forward scatter and high tubulin labeling similar to that of control cells. Propidium iodide DNA labeling and TUNEL labeling showed that the first cell population was composed of apoptotic cells while the

second was normal. Double labeling with BODIPY- paclitaxel and TUNEL gave similar results. Percentage of apoptotic cells detected by the TUNEL labeling method correlated well with the percentage of apoptotic cells detected by a new assay in accordance with this particular embodiment of the present invention (correlation r=0. 96). Thus, the new flow cytometric assay allows both identification and quantification of apoptotic cells.

Apoptosis of CCRF CEM cells is shown in Fig. 7.

The apoptosis was induced by incubation with 1 M dexamethasone for 72 hours. The cells were then labeled with 7 FITC-paclitaxel and analyzed by flow cytometry.

The effect of a 72 hour incubation with 20 mg/ml hydrocortisone on human lymphocytes is shown in Fig. 8.

The first peak of the figure around 102 illustrates the apoptosis detected by labeling human lymphocytes with 7-FITC-paclitaxel.

The correlation of the TUNEL labeling and the FITC-paclitaxel derivative labeling is shown in Fig.

10. The correlation noted between the two apoptosis methods is of 0.96. Red and green fluorescence (microtubules labeled with 7-BODIPY-paclitaxel derivative and DNA fragmentation labeled with TUNEL, respectively) was detected on double labeled CCRF CEM cells.

Fig. 9 illustrates that apoptotic cells have greater green fluorescence and less red fluorescence than normal cells.

Immunoassay for the determination of paclitaxel in biological fluids and Taxus crude extracts using a fluorescent derivative of paclitaxel In a further embodiment of the present invention there is provided a kit for the determination of paclitaxel in a medium. This medium may be serum,

plant extracts, bacterial culture medium, etc.

Accordingly, a fluorescence polarization immunoassay (FPIA) has been developed. The FPIA comprises a fluorescent derivative of paclitaxel in accordance with the present invention and an anti-paclitaxel monoclonal antibody. The fluorescent paclitaxel used in the kit of this embodiment is a 2'paclitaxel derivative coupled with FITC as described above. However, the person skilled in the art would recognize that the paclitaxel derivative coupled with any fluorescent moiety such as FITC or BODIPY in either the position 2' or 7 would be suitable to be used in the fluorescence polarization immunoassay in accordance with the present invention.

Fluorescence polarization immunoassay comprises the steps of adding the fluorescent derivative at a fixed concentration with an unknown specimen to be measured, measuring fluorescence, adding an antibody specific for paclitaxel, waiting 10 minutes and measuring polarized fluorescence on the instrument.

The concentration of paclitaxel in the unknown specimen may be determined from a standard curve made from paclitaxel solutions of known concentrations.

With such a kit for the determination of paclitaxel in a medium, it was thus possible to detect paclitaxel in concentrations as low as about 2 nM. The simplicity and sensitivity of this method makes it useful for estimating paclitaxel concentration in extracts or media such as yew tree crude extracts or culture media. This sensitive method also makes the assay and/or monitoring of paclitaxel levels possible in patients under treatment.

A standard curve for paclitaxel concentration in bovine serum obtained with the fluorescence polarization immunoassay of the present invention is

shown in Fig. 11. The serum dilution used in this <BR> <BR> assay was 1: 20 in PBS buffer containing 0.2% sodium salicylate.

Figs. 12 and 13 illustrate the dynamic binding and the displacements of FITC-paclitaxel incubated with anti-paclitaxel monoclonal antibodies in PBS buffer pH 7.2 containing 0.2% sodium salicylate. After reaching an equilibrium, an excess of non-labeled paclitaxel was added. Polarization was read every 30 seconds.

The least detectable dose that could be detected with the method of the present invention was found to be about 2 nM.

The correlation of the FPIA with HPLC is shown in Fig. 14. In this experiment to determine the correlation between FPIA and HPLC, a Erwinia taxi culture medium was spiked with known quantities of paclitaxel and extracted with 8 g of C-18 bonded silica gel. After two washes with water, paclitaxel was eluted with methanol and assayed simultaneously by FPIA and HPLC. In accordance with the present invention, the FPIA technique was successfully used to quantify paclitaxel in various media such as plant crude extracts, bacterial culture medium and bovine serum.

The FPIA has a sensitivity detection limit of about 2 nM with a recovery of > 96%. No matrix interference was noted at working dilutions. The FPIA technique of the present invention is a simple one step method. The FPIA could also be automated to handle a great number of samples simultaneously.

The present invention will be more readily un- derstood by referring to the following examples, which are given to illustrate the invention rather than to limit its scope.

EXAMPLE I Synthesis of 2'glutarylpaclitaxel 100 mg of paclitaxel dissolved in 1.2 ml of pyridine was added to 140 mg of glutaric anhydride.

After 90 minutes of reaction at room temperature the solvent was evaporated to dryness. The residue was treated twice with water and the supernatant discarded.

The precipitation from acetone gave 80 mg of an impure product. Further purification was made by reverse phase HPLC on a NOVA-PAK phenyl column 0.8/10 cm from Waters RCM. The solvent system was composed of methanol, acetonitrile and water. The gradient of acetonitrile and water was linear going from 10% to 35% in 30 minutes, methanol remaining constant at 40%. The reaction was followed by TLC on a silica plate, the eluant was composed of chloroform/methanol/water (40/13/2). Detection was made with vanillin (CARDELLINA II., J. H., J. Liq. Chromatogr., 14,659- 665, 1991).

EXAMPLE II Synthesis of 2'glutarylhexadiamine paclitaxel To 1 , mol of 2'glutarylpaclitaxel dissolved in 100 . l of acetonitrile was added 5 . mol of carbonyl diimidazole (CDI). The mixture was heated to 45°C during 15 minutes. After cooling to ambient temperature 5 . mol of 1,6-hexanediamine was added and reaction mixture was left at room temperature for one hour. The reaction was analyzed by TLC using two different solvent systems. Two silica plates were prepared and the samples deposited in duplicate.

Vanillin detection was made on one half of each plate and ninhydrine revelation on the other half to reveal the amine component. The two have detected a new product with the same Rf in the two solvent systems.

The excess of 1,6-hexanediamine was eliminated by washing. Further purification was made by reverse

phase HPLC in the same conditions as for 2'glutarylpaclitaxel.

EXAMPLE III Synthesis of glutarylpaclitaxel 6-aminohexanol glucuronide 112.6mg (0.3 mmole) of methyl 1,2, 3,4 tetra-O- acetyl-D-glucuronate was added to HBr 30% in acetic acid. The reaction proceeded overnight in the dark at <BR> <BR> 4°C to give methyl (2,3, 4-tri-O-acetyl-l-bromo-l-deoxy-<BR> a-p-D-glucopyranosid) -uronate (Bollenbach, G. N., et al., J. Am. Chem. Soc. 77,3310-3315, 1954). The solvent was dried on a"SpeedVac"vacuum (Savant Instruments Inc., Holbrook, N. Y.) and ethanol 95% was added to the residue and left two days in the dark at 4°C. The mixture was centrifuged, the supernatant discarded and 1 ml of nitromethane was added to the pellet.

Methyl (2,3, 4-tri-O-acetyl-1-bromo-1-deoxy-a-D-<BR> glucopyranosid) -uronate was added to 81.8 mg (0.70 mmole) of 6-aminohexanol, 59.3 mg (0.43 mmoles) of white drierite and 68.3 mg (0.27 mmole) of mercuric cyanide according to the method of Turgeon et al.

(Turgeon, J., et al., Drug Metab. Disp., 20 (5), 762- 769, 1992). A small amount of methanol and water was added in an attempt to achieve complete dissolution of the products. The reaction mixture was stirred overnight in the dark at room temperature and the solvent was evaporated under vacuum. 6-aminohexanol glucuronide was extracted with chloroform and the most important part of the product was collected in the organic phase.

The glucuronide was treated with 2.15 mg (39.8 Hmoles) of sodium methoxyde in anhydrous methanol (Turgeon, J., et al., Drug Metab. Disp., 20 (5), 762- 769, 1992). The reaction proceeded at room temperature during 24 hours with agitation.

The last part consisted in joining the deprotected 6-aminohexanol glucuronide part to glutarylpaclitaxel. Synthesis of glutarylpaclitaxel (glutaryltaxol) has been described previously.

Briefly, paclitaxel was dissolved in pyridine and reacted with an excess of glutaric anhydride at room temperature for four to five hours. Pyridine was discarded when the mixture was applied on a silica reverse phase C-18 PREP SEPTM minicolumn (J. T. Baker, Phillipsburgh, N. J.) and the product was eluted with methanol. The final step consisted in activating 0.6 mg (0.62 mole) of 2'glutarylpaclitaxel with 0.95 mg (5.9 moles) of carbonyl diimidazole in acetonitrile.

The mixture was heated for 20 minutes at 45-50°C and left to stand at room temperature overnight.

6-aminohexanol glucuronide was added and the reaction was allowed to proceed once more overnight at room temperature.

The mixture was first eluted on a SEPHADEXTM G-10 (Pharmacia BioProcess Technology AB, Uppsala, Sweden) with a mixture of methanol: water (1 : 1). The elution was monitored by optical density at 227 nm.

The product collected was purified by HPLC on a NOVA PAKTM phenyl reverse phase column. The system used was the Waters 625 LC System and a W996 photodiode array detector. The product was eluted with a gradient of acetonitrile: water: methanol from 10: 50: 40 to<BR> 45: 15: 40. The flow rate was 1 ml/min. during 30 minutes. The elution was monitored at 227 nm. The product was collected and evaporated to dryness on a SPEED VAC"vacuum.

EXAMPLE IV Synthesis of amino acid derivatives of glutarylpaclitaxel Six (6) amino acid derivatives, still in accordance with the present invention, were

synthesized. The first step consisted in synthesizing the glutarylpaclitaxel as described above. Briefly, after 4 to 5 hours at room temperature, a solution of <BR> <BR> 65. 3 moles of paclitaxel and 1040 moles of glutaric anhydride in 4 ml of pyridine was evaporated to dryness, solubilized in a minimal volume of methanol and water, and applied on a silica reverse phase C-18T"" minicolumn (PREPSEPT""C-18). Pyridine was eluted with water and glutarylpaclitaxel with methanol. The product was evaporated to dryness on a SPEEDVACT"" vacuum. To the solution of glutarylpaclitaxel (2-8 nmoles) in acetonitrile, was added a 10-20 fold excess of carbonyl diimidazole (CDI). The mixture was heated to 45°C. for twenty minutes and left to stand at room temperature overnight. A large excess (50 fold) of the amino acids asparagine, aspartate, glutamate, glutamine, glycine, or serine, dissolved in water was added, slowly over a period of twenty minutes, and the reaction proceeded at room temperature overnight.

Small quantities were purified on HPLC. A Waters 625 LC system with a W996 photodiode array detector was used. The products were purified on a reverse phase Nova Pak Phenyl column (Waters, Milford, Massachusetts). Elution was performed with a gradient of acetonitrile: water: methanol from 10: 50: 40 to<BR> 45: 15: 40. The flow rate was 1 ml/min. for 30 minutes.

Elution was monitored at 228 nm. For larger amounts, a silica reverse phase C-18 minicolumn ("Prep Sep"C-18 from J. T. Baker, Phillipsburgh, N. J.) was used.

Products were eluted successively with water, with acetonitrile: water: methanol 10: 50: 40 and with the same<BR> solvents mixture, proportions being 45: 15: 40.

Fractions of 0.5 ml were collected and analyzed on HPLC in the conditions mentioned before. The fractions

containing the pure derivatives (over 90% purity) were pooled and used for in vitro assays.

EXAMPLE V Cytotoxicity of paclitaxel derivatives and of the immunoconjugate 2'-glutarylhexanediamine paclitaxel- glutaraldehyde-BCM 43 The cells used were the ovarian teratocarcinoma (CRL-1572), the ovarian carcinoma (SK-OV-3) and the corresponding drug-resistant cell line (SKVLB 600), the prostate carcinoma (LNCaP), the breast carcinoma (MCF- 7), the leukemia (CCRF/CEM) and the drug-resistant line (CEM/VBL 0. 3), the murine melanoma (B-16) and finally, the mouse fibroblasts (3T3). The cells were maintained in RPMI 1640 supplemented with fetal calf serum 10% at 37°C, under a 5% CO2 atmosphere. For the resistant cell lines, vinblastine, concentrations of 300 ng/ml for the CEM/VBL and 600 ng/ml for the SKVLB, was added to the medium.

Cells were plated at 1000 to 2000 cells per well in 96 well plates. Drugs or immunoconjugate, concentrations ranging from 0 to 2500 ng/ml in drug content, were added the next day. After three to four days in contact with the drugs, the medium was removed and replaced with 100 , l per well of new medium containing Alamar Blue 5% as reported by Page et al. <BR> <BR> <P>(Page, B., et al., Int. J. Oncol., 3, 473-476, 1993).

For cells growing in suspension, only 10 , l of Alamar Blue was added to the medium. The proportion of viable cells was assessed by measuring the fluorescence produced following the reduction of Alamar Blue by mitochondrial dehydrogenases (excitation: 530 nm, emission 590 nm) after two to four hours. The assays have been made in quadruplicates. Cytotoxicity was expressed as IDsos in nmoles per liter.

EXAMPLE VI Determination of apoptotic cells using fluorescent derivatives of paclitaxel Cells were fixed in cold 70% methanol and incubated for 10 min. on ice in 4% paraformaldehyde at room temperature for 30 minutes. Then, they were washed once with PBS and treated with 0.1% Triton X-100 for 2 minutes at room temperature, washed again with cold PBS and incubated 60 min. in the dark with appropriated dilution of the fluorescent paclitaxel (2'- or 7-FITC paclitaxel) at 37°C. Then, cells were washed with 0. 1% Tween 20 in PBS. This was followed by a 30 min. incubation in the presence of 50 g/ml of propidium iodide. Analysis was performed on a FACSort flow cytometer equipped with an argon laser set at 488 nm (Becton Dickinson). All flow cytometry data were collected and analyzed using LYSIS II software.

EXAMPLE VII Synthesis of the immunoconjugate BCM43 monoclonal antibody-2'-glutaryl hexanediamine paclitaxel conjugate First the compound 2'-glutarylhexanediamine paclitaxel is activated with glutaraldehyde. To do so, 1 mg of 2'glutarylhexanediamine paclitaxel is dissolved in 200 . l of methanol. Then, 100 , 1 of DMSO and 200 ill of PBS (Phosphate Buffer Saline) are added, followed by an additional 1 ml of DMSO. 60 fit of glutaraldehyde 25% is then slowly added to the solution and the mixture is gently stirred for 15 minutes. The reaction is monitored by thin layer chromatography and stopped by the addition of 5 ml of dichloromethane.

Second, the excess of glutaraldehyde is removed by 6 liquid extractions with aqueous solutions. The first one is performed with one volume of water. Four additional washes are then performed with a <BR> <BR> glycine: bicarbonate buffer pH 8.0 and the final wash with water. All aqueous fractions are discarded. The

organic phase, which contains the activated compound, is dried in vacuo and stored at -80°C.

Third, the activated compound is then linked to the BCM43 monoclonal antibody which is an antibody recognizing an epithelial mucin expressed by ovarian and breast cancer cells. To do so, BCM43 is dissolved in PBS and the activated 2'-glutarylhexanediamine paclitaxel-glutaraldehyde is solubilized in a solution of methanol: DMSO (1: 1). This latter solution is then slowly added to the antibody solution in order to get a ratio of one molecule of antibody for 10 molecules of the activated compound. The mixture is stirred and incubated at 37°C for one hour. The resulting immunoconjugate (2'-glutarylhexanediamine paclitaxel- glutaraldehyde-BCM 43) is purified on a PD-lOT""column (Amersham Pharmacia).

EXAMPLE VIII Quantification of paclitaxel from unknown samples using a Fluorescence Polarization ImmunoAssay (FPIA) All assays were performed at room temperature.

The optimal antibody working dilution was determined by incubating sequential dilutions of the antibody with a fixed amount of 2'-FITC labeled paclitaxel and the dilution giving the optimal signal was chosen as the working dilution. This dilution was then incubated with sequential dilutions of the tracer and the concentration of 2'-FITC paclitaxel giving the highest signal was chosen. 2'-FITC paclitaxel was thus used at a final concentration of 500 pg/ml and the monoclonal <BR> <BR> antibody was used at a dilution of 1: 1000. For assaying, 5 pl of tracer diluted in PBS was added to 320 pl of buffer, followed by an additional 10 fil of sample (standard or unknown). Polarization was read, each tube served as its own blank. Diluted antibody (5 Hl) was added, the tubes were mixed gently, and

incubated at room temperature for 60 minutes. The polarization of fluorescence was then measured.

While the invention has been described in con- nection with specific embodiments thereof, it will be understood that it is capable of further modifications and this application is intended to cover any varia- tions, uses, or adaptations of the invention following, in general, the principles of the invention and including such departures from the present disclosure as come within known or customary practice within the art to which the invention pertains and as may be applied to the essential features hereinbefore set forth, and as follows in the scope of the appended claims.