The Val158Met polymorphism of the catechol-O-methyltransferase gene is associated with the PSA-progression-free survival in prostate cancer patients treated with estramustine phosphate.

OBJECTIVE: The aim of our study is to find out the good responders for estramustine phosphate (EMP) therapy in patients with prostate cancer. We have focused on the metabolism of EMP and studied the association between a functional single-nucleotide polymorphism in the catechol-O-methyltransferase gene (Val158Met of COMT) and PSA-progression-free survival in Japanese patients with prostate cancer treated by EMP. METHODS: Seventy-two Japanese patients with previously untreated prostate cancer who were found to be eligible for low-dose EMP therapy were enrolled in the study. Genotyping of the Val158Met polymorphism of COMT was conducted by both the polymerase chain reaction-based restriction fragment length polymorphism method and TaqMan assay. RESULTS: Patients with the Val/Val genotype of COMT had a significantly higher PSA-progression-free rate as compared to those with the Val/Met or Met/Met genotype (p=0.027). The adjusted hazard ratio of biochemical PSA failure for the Val158Met genotype of COMT was 2.164 (95% CI, 1.111 to 5.525). CONCLUSIONS: The Val158Met polymorphism of COMT is associated with the PSA-progression-free rate of EMP-treated patients in prostate cancer.

Enzyme-mediated precipitation of parent drugs from their phosphate prodrugs.

Many oral phosphate prodrugs have failed to improve the rate or extent of absorption compared to their insoluble parent drugs. Rapid parent drug generation via intestinal alkaline phosphatase can result in supersaturated solutions, leading to parent drug precipitation. The purpose was to (1) investigate whether parent drugs can precipitate from prodrug solutions in presence of alkaline phosphatase; (2) determine whether induction times are influenced by (a) dephosphorylation rate, (b) parent drug supersaturation level, and (c) parent drug solubility. Induction times were determined from increases in optical densities after enzyme addition to prodrug solutions of TAT-59, fosphenytoin and estramustine phosphate. Apparent supersaturation ratios (sigma) were calculated from parent drug solubility at intestinal pH. Precipitation could be generated for all three prodrugs. Induction times decreased with increased enzyme activity and supersaturation level and were within gastrointestinal residence times for TAT-59 concentration>/=21microM (sigma>/=210). Induction times for fosphenytoin were less than the GI residence time (199min) for concentrations of approximately 352 microM (sigma=4.0). At approximately 475 microM (sigma=5.3) the induction times were less than 90min. For estramustine-phosphate, no precipitation was observed within GI residence times. Enzyme-mediated precipitation will depend on apparent supersaturation ratios, parent drug dose, solubility and solubilization by the prodrug.

Differential uptake of estramustine phosphate metabolites and its correlation with the levels of estramustine binding protein in prostate tumor tissue.

Estracyt (EMP) has been used for the treatment of hormone refractory prostate cancer for many years. Recently, new data from combination studies have given rise to new interest in this old drug. Explanations for the synergy found in the clinic are many, but one major factor may be the previous indication that the drug accumulates in the prostate tumor. We have, therefore, examined the level of the four metabolites, estromustine (EoM), estramustine (EaM), estrone, and estradiol in the tumor and serum of 14 patients with T2 and T3 prostate cancer receiving a single i.v. dose of 600 mg of EMP, about 12 h before radical prostatectomy. Because it has been suggested that the uptake into the prostate tumor is due to binding to the estramustine binding protein (EMBP), we have in addition measured the level of EMBP in the prostate tumor tissue. The main serum and tissue metabolite in all patients was EoM followed by EaM, estrone, and estradiol. The levels for EoM ranged from 63.8-162.8 ng/ml in the serum and from 64.8-1209 ng/ml in the prostate tumor, resulting in a mean ratio for serum to tumor of 1:5. The levels for EaM ranged from 8.3-51.4 ng/ml in the serum and 73.9-563.4 ng/ml in the tumor, giving a mean ratio for serum to tumor of 1:13. The levels of EMBP were higher in T3 tumors than in T2 tumors, 54.1 and 40.7 ng/g tissue, respectively. A significant correlation was found between the levels of EaM (r = 0.60) and the levels of EMBP in the tumor. These data demonstrate that 12 h after a single i.v. dose of 600 mg of EMP the levels of the cytotoxic metabolites EoM and EaM are substantially higher in the tumor than in the serum of the same patient and that a correlation exists between the levels of EaM in the tumor and the levels of EMBP. Thus, this supports the hypothesis that the EMBP is responsible for the retention of EoM and EaM in the prostate tumor.

Radioiodinated estramustine phosphate and estramustine binding protein antibody accumulate in the prostate of a mouse.

BACKGROUND: The purpose of this study was to determine the distribution of radioiodinated estramustine (RI-EMP) and a radioiodinated antibody against estramustine binding protein (RI-EMBP-AB) in mice. METHODS: RI-EMP and RI-EMBP-AB were injected in male mice intravenously, and the activities of tissue samples were measured 1-31 hr from the injection. Pure iodine-125 (RI) was used as a control. RESULTS: RI-EMP accumulated in the prostate, which contained 2.6% of injected activity (ID) per gram tissue at 7 hr. The liver had an activity of 21.4% ID/g at 1 hr, which decreased as RI-EMP was secreted in bile. The lung contained 2.3% ID/g at 7 hr, and it retained the activity longer than the prostate. RI-EMBP-AB accumulated in the prostate: The activity was 2.9% ID/g at 7 hr. The gallbladder contained 6.5% ID/g at 7 hr. CONCLUSIONS: Due to its cytotoxic and radiosensitizing properties, RI-EMP can possibly be used for treating prostate cancer and other tumors.

Interaction of estramustine with tubulin isotypes.

The interaction of the antimitotic agent estramustine with bovine microtubule proteins and purified tubulin was investigated. Direct photoaffinity labeling of microtubule protein with [14C]estramustine resulted in the labeling of both alpha- and beta-tubulin, and this was inhibited with unlabeled estramustine in a dose-dependent manner. [14C]Estramustine was incorporated into both the soluble and polymerized forms of tubulin. The affinity constant for estramustine binding to tubulin was determined by equilibrium dialysis to be 23 +/- 5 mM. Estramustine did not affect [3H]vinblastine binding, and vinblastine had no effect on direct labeling with [14C]estramustine. Both rhizoxin and paclitaxel decreased the covalent labeling of tubulin with [14C]estramustine in a dose-dependent fashion and were noncompetitive inhibitors of the binding of estramustine to tubulin. The binding of colchicine to tubulin was not inhibited by estramustine as detected by fluorescence and DEAE filter assays. The estramustine binding site on tubulin is therefore distinct from that of colchicine and vinblastine and may at least partially overlap with the binding site for paclitaxel. In both bovine brain microtubules and cytoskeletal proteins from human prostatic carcinoma cells, the incorporation of [14C]estramustine into the beta III isotype of tubulin was found to occur with a reduced efficiency compared to that of the other beta-tubulin isotypes and alpha-tubulin. Since this isotype is overexpressed in estramustine resistant human prostate carcinoma cells, these results indicate that beta III-tubulin may play a role in the response to the effects of estramustine.

Targeting microtubule-associated proteins in glioblastoma: a new strategy for selective therapy.

BACKGROUND: This report presents a summary of preclinical data concerning the use of estramustine, an antimicrotubule agent against human glioblastoma cells. The strategy for the investigation of estramustine is predicated on the unique affinity of this agent for microtubule-associated proteins (MAPs). METHODS: A series of laboratory investigations were used to demonstrate antiproliferative effects (MTT assay, colony forming assay, thymidine incorporation), cell cycle synchronization (flow cytometry), intracellular localization of binding sites (immunocytochemistry, electron microscopy), and activity in subcutaneous xenografts of human glioblastoma. RESULTS: Estramustine has potent in vitro activity against human glioblastoma cells and can enhance the cytotoxic effects of ionizing radiation. Estramustine-binding protein was abundantly expressed in glioblastoma cells and may contribute to the selective effects of estramustine on neoplastic cells. This agent has activity against subcutaneous xenografts of human glioblastoma. Synthesized novel estrogen carbamates also can inhibit proliferation of glioblastoma cells. CONCLUSIONS: Cytoskeletal elements (MAPs) of glioblastoma cells may provide a useful target for therapy with agents like estramustine because of the potent antimitotic effects of this agent and its affinity to a protein that is expressed in glioma cells. These observations have stimulated a search for other estrone carbamates with antimitotic activity that exceeds more conventional antimicrotubule agents.

Estramustine in malignant glioma.

Estramustine, a carbamate ester combining 17 beta-estradiol and nornitrogen mustard, has primarily been employed in the treatment of advanced prostatic carcinoma. However, a significant amount of preclinical investigation has been directed toward estramustine's activity against human malignant glioma. These studies have demonstrated that estramustine has potent antiproliferative effects against malignant glioma both in vitro and in vivo. Similar antimitotic effects also have been demonstrated for other carbamate esters. Estramustine does not impair proliferation of nonneoplastic astrocytes at concentrations that inhibit glioma cells. Although the reasons for this selective activity remain to be determined, it has been shown that malignant gliomas expresses an estramustine-specific binding site, estramustine-binding protein, more than brain tissue. In the clinical situation, an uptake and accumulation of estramustine in human glioma tissue have been demonstrated. Estramustine has been shown to enhance the cytotoxic effects of irradiation in relatively radioresistant glioma cells both in cell culture and in a rat glioma model. Estramustine has been regarded as mainly an anti-mitotic drug but recently other effects such as inhibition of DNA synthesis, induction of apoptosis, and membrane alterations have been shown. This report summarizes the preclinical observations concerning the effects of estramustine and related compounds on human malignant gliomas. These findings form the basis for proposing further laboratory and clinical investigation regarding estramustine and human malignant gliomas.

Binding of vinblastine and estramustine to isolated plasma membrane fractions from human prostate and prostatic tumors.

The binding of vinblastine (VLB) and estramustine (EM) to plasma membranes isolated from human prostate, prostatic tumors as well as from Dunning rat prostatic AT-1 tumors was studied. In addition, the uptake of these drugs in AT-1 tumor cells in culture was examined. Binding of VLB was six-fold lower than that of EM in membrane preparations from all three sources. The uptake of VLB in the intact AT-1 cells was nearly five-fold lower than that of EM. At concentrations comparable to those achieved clinically the binding of EM was 100-fold higher than that of VLB. The data suggest that, owing to a very high membrane concentration of EM relative to that of VLB, the active efflux VLB in drug resistant cells would be impeded. This in turn would lead to a higher accumulation of VLB in cells that actively transport cytotoxic drugs.

Estramustine-binding protein (EMBP) content in four different cell lines and its correlation to estramustine induced metaphase arrest.

It is known that estramustine (EM) accumulates in cells at the G2/M-phase and causes metaphase arrest of various cell types. The inhibitory effect is mediated by interaction with microtubule-associated proteins (MAPs) and/or tubulin. Estramustine-binding protein (EMBP) is a secretory protein which has been found in a number of different tumor cells and has been shown to faciliate the uptake of EM into cells. In this study the efficacy of EM in arresting cells at metaphase was studied, using four different human cell lines; the prostatic cancer cell line DU 145, the breast cancer cell line MDA 231, the colon cancer cell line Colon 320, and the urinary bladder cancer cell line RT4. The cells were incubated with EM at a concentration of 10 micrograms/ml for 24 hours. The data reveal an increase in metaphase arrests in the DU 145 and in Colon 320 cell lines. Both of these cell lines were found to contain high amounts of EMBP using a dot-blot assay. The other two cell lines, MDA 231 and RT4 had undetectable intracellular amounts of the protein and exhibited a low increase in metaphase arrests. The cell lines were analysed regarding S-phase fraction with flow-cytometry (FCM) to exclude the growth rate of the cells as a limiting factor. The results from the FCM confirmed the cytogenic analysis, that is a higher percentage of cells were in the G2/M phase in both the DU 145 and Colon 320 cell line compared to MDA 231 and RT4. EM causes mitotic arrest in those cell lines that contain detectable amounts of EMBP.

Estramustine-binding protein in carcinoma and benign hyperplasia of the human prostate.

For the purpose of elucidating whether the biological characteristics of estramustine-binding protein (EMBP) are different in benign prostatic hypertrophy (BPH) and prostatic carcinoma (PC) and also to determine the clinical value of EMBP in the tissue, the EMBP concentration in 19 patients with BPH and 26 with untreated PC was measured by means of radioimmunoassay (RIA) using an antibody raised against EMBP obtained from the rat ventral prostate and compared simultaneously with the dihydrotestosterone (DHT) level in the same tissue. The level of serum prostate-specific antigen (PSA) was also measured in these patients. The EMBP concentration was significantly correlated with the tissue DHT level in BPH and well-differentiated PC (r = 0.745, p < 0.0001), whereas it did not correlate in moderately and poorly differentiated PC (r = -0.159, p = 0.542). By comparing well-differentiated PC with moderately and poorly differentiated PC, the EMBP concentration was significantly lower in the former than in the latter two conditions (p < 0.005) in spite of the highest tissue DHT level in well-differentiated PC. The ratio of the EMBP concentration to the DHT level in moderately and poorly differentiated PC was significantly higher when compared with that observed in either BPH or well-differentiated PC (p < 0.005, respectively). However, the level of serum PSA did not reflect the histological differentiation of PC. These results suggest that: (i) the correlation of the EMBP concentration to the DHT level changed with the progression of the histological grade, and (ii) the ratio of the EMBP concentration to the DHT level in the tissue is clinically valuable in elucidating the biological potential of individual tumors.

Modulation of P-glycoprotein activity by estramustine is limited by binding to plasma proteins.

BACKGROUND: Estramustine previously has been shown to interact with P-glycoprotein and to restore intracellular accumulation of vinblastine and paclitaxel in cells overexpressing this drug transporter. However, the ability of estramustine to potentiate the cytotoxicities of several drugs was less than that expected. To resolve this apparent discordance, the authors examined the effects of serum on the actions of estramustine. METHODS: The cytotoxicities of anticancer drugs with or without estramustine or verapamil toward MCF-7 breast carcinoma cells and a P-glycoprotein-overexpressing subline MCF-7/ADR were determined using the sulforhodamine-binding assay. The extent of intracellular accumulation of [3H]vinblastine and [3H]paclitaxel was determined for each using standard methods, and the binding of radiolabeled drugs to plasma proteins was characterized by equilibrium dialysis. RESULTS: Without serum, the sensitivities of MCF-7/ADR cells to several P-glycoprotein-transported drugs were increased by estramustine and verapamil. Conversely, when the cells were treated with a 10% serum, the cytotoxicities of these drugs were increased by verapamil, but not by estramustine. Without serum, intracellular accumulation of [3H]vinblastine and [3H]paclitaxel by MCF-7/ADR cells was increased markedly by verapamil and estramustine; however, serum suppressed the effects of estramustine much more strongly than those of verapamil. Equilibrium dialysis experiments demonstrated that [3H]estramustine binds to plasma proteins, predominantly albumin, whereas [3H]paclitaxel binds to albumin and alpha 1-acid-glycoprotein, and [3H]vinblastine binds predominantly to alpha 1-acid-glycoprotein. CONCLUSION: Although estramustine can bind to P-glycoprotein, its effectiveness as a reversing agent in vivo likely is limited by binding to plasma proteins.

Interaction of an estramustine photoaffinity analogue with cytoskeletal proteins in prostate carcinoma cells.

To identify specific drug targets of the antimitotic drug estramustine, a photoaffinity analogue, 17-O-[[2-[3-(4-azido-3-[125I] iodophenyl)propionamido]ethyl]carbamyl]estradiol-3-N-bis(2- chloroethyl)carbamate, was synthesized and reacted in competition assays with cytoskeletal protein preparations. By attaching the photoaffinity ligand to the 17 beta-position of the steroid D-ring, the cytotoxic properties of the drug were maintained. In cytoskeletal protein preparations from human prostate carcinoma cells (DU 145) or a clonally selected, estramustine-resistant cell line (E4), the major microtubule-associated protein (MAP) present was MAP4. In both cytoskeletal fractions and reconstituted microtubules, 17-O-[[2-[3-(4-azido-3-[125I]iodophenyl)propionamido] ethyl]carbamyl]estradiol-3-N-bis(2-chloroethyl)carbamate bound to both MAP4 and tubulin. From competition assays, the apparent binding constant for MAP4 from DU 145 cells was 15 microM. Similar calculations for tubulin gave values of 13 microM (bovine brain), 19 microM (DU 145 wild-type cells), and 25 microM (E4 cells). The identification of these cytoskeletal proteins as specific drug targets provides a direct explanation for the antimicrotubule and antimitotic effects of estramustine.

Estramustine-binding protein and specific binding of the anti-mitotic compound estramustine in astrocytoma.

Estramustine-binding protein (EMBP) is a M(r) 46,000 heterodimeric protein originally isolated from prostatic tissue. It has a demonstrated high affinity for, and selective binding of, estramustine, which is a derivative of 17 beta-estradiol and nornitrogen mustard with antimitotic activity. In this study, we have analysed the expression of an EMBP-like protein in astrocytoma specimens. Immunohistochemistry revealed a pronounced reactivity for EMBP in astrocytoma grades III-IV as well as in metastatic prostatic adenocarcinoma used as positive control. In astrocytoma grades I-II, the expression was weak. The EMBP-like protein was quantified by radioimmunoassay in astrocytoma tumor tissue with higher concentrations in malignant astrocytoma, grades III-IV, compared to grades I-II tumors. Western immunoblotting of immunoaffinity purified EMBP-like protein under nonreducing conditions revealed an immunoreactivity corresponding to M(r) 138,000 and 200,000, indicating a different structure of EMBP in astrocytoma compared to prostatic tissue. Specific binding and the presence of saturable binding sites for 3H-labeled estramustine were demonstrated in astrocytoma tissues expressing EMBP-like protein. Scatchard plot analysis showed a Kd at approximately 30 nM, which suggests a binding affinity for estramustine in the same range as previously reported for EMBP in the prostate. Moreover, the number of estramustine binding sites/g tumor as calculated from the Scatchard plots was well correlated with the EMBP levels determined in the radioimmunoassay. In conclusion, an EMBP-like protein is expressed in astrocytoma. This protein may be responsible for the specific binding of estramustine in the tumor tissue. Whether this specific binding of estramustine is of importance for the cytotoxic effect in glioma cells remains to be evaluated.

Elevated expression of estramustine binding protein (EMBP) in prostatic intraepithelial neoplasia (PIN) compared with malignant and benign prostatic epithelia.

The expression of estramustine-binding protein (EMBP) was studied immunohistochemically in whole-mount prostate sections. Specimens were taken from the prostates of 15 patients who had undergone total prostatectomy due to localized (TOd-T2 NO MO) prostatic cancer (PC). Almost all the examined whole-mount sections displayed areas with prostatic intraepithelial neoplasia (PIN). PIN is regarded as the main precursor of invasive PC. High- and low-grade PIN expressed EMBP. The average positively stained areas accounted for averages of 69.2% and 48.7%, respectively. High-grade PIN contained the highest EMBP levels of all the investigated (benign and malignant) epithelia, followed by moderately differentiated PC. With regard to areas with PC, the highest levels of EMBP expression (61.3%) were observed in moderately differentiated PC; poorly differentiated PC came second. Of all the examined epithelia, EMBP levels were lowest in well-differentiated PC (25.8%). Normal prostatic epithelia and hyperplasia were characterized by low EMBP expression, although somewhat higher than well-differentiated PC. A moderate expression (45%) was observed in the seminal vesicles. According to these results, EMBP was expressed mainly in the diseased peripheral zone (PZ), where PIN and prostatic cancer have their highest prevalence.

Expression of estramustine-binding protein in ependymomas and in human and developing rat ependymal cells.

The mainstays of primary treatment of ependymoma are aggressive surgery followed by radiotherapy. Although spreading occasionally occurs in the cerebrospinal pathways, chemotherapy is still not established and no ultimate drug has so far been found. Estramustine-phosphate (EMP), with a demonstrated effect on astrocytoma in vitro, has been shown to penetrate the blood-tumor barrier and to accumulate in human brain tumor tissue including ependymoma. It has been proposed that the cytotoxic effect of EMP depends on the presence of a binding protein, estramustine-binding protein (EMBP). In the present paper we have, for the first time, immunohistochemically demonstrated an EMBP-like protein in a series of ependymomas. Immunoreactivity was found within the cytoplasm of the tumor cells with a tendency to increase with increasing malignancy of the tumor. In addition, the occurrence of EMBP-like protein was demonstrated in human ependymal cells. In the rat brain, a weak immunoreactivity was detected in early fetal neuroepithelial cells while the staining intensity was increased in mature ependymal cells in late fetal, neonatal, and adult rat. Thus; immunoreactivity for an EMBP-like protein was demonstrated in ependymoma tissue, normal human ependyma and in the developing rat ependymal cells.

Growth of prostatic cancer cells, DU 145, as multicellular spheroids and effects of estramustine.

The human prostatic carcinoma cell line DU 145 was grown as multicellular spheroids in vitro. The volume doubling time during the early exponential growth phase was about 5 days. The saturation volume, in the plateau phase of the growth curve, was in the order of 1.4 mm3. The spheroids developed a central degenerative region surrounded by a 0.1-0.3 mm layer of viable cells. The DU 145 spheroid system is planned to be used as a model in studies on chemotherapy and targeted radiotherapy of micrometastases of prostatic cancer. Some effects of the drug estramustine, EM, a conjugate of estradiol and nornitrogen mustard, were analysed in this introductory study. Tritium-labelled estramustine, 3H-EM, bound both in the viable cell layers and in the degenerative region of the spheroid already after 1 hour of incubation which indicated good penetration. The viable cells bound only low levels of 3H-EM while the degenerative region bound 3H-EM to a higher extent. The amount of bound 3H-EM increased after incubation for 24 hours. The binding was nonspecific since it could not be inhibited by pretreatment with an excess of non-radioactive EM. Furthermore, 3H-EM bound to a similar extent in glioma and colon carcinoma spheroids used for comparison. Incubation of DU 145 spheroids for 24 hours with EM (20 mg/ml) induced a growth delay of 6-7 days and a transient increase in the volume of the extracellular spaces for a few days following the treatment. The results showed that the binding of EM to prostate DU 145 cells growing as spheroids was not specific and that the toxic action was limited. An interesting result was that EM works as an extracellular space expander. This might be exploited in combination treatments with other agents.

Uptake and retention of estramustine and the presence of estramustine binding protein in malignant brain tumours in humans.

Estraumustine phosphate (EMP), a cytotoxic drug used in the treatment of prostatic carcinoma, has been shown to exert cytotoxic effects on glioma cells in vitro. The drug uptake is assumed to depend on a specific estramustine binding protein (EMBP). One of the main difficulties in achieving cytotoxic effect in malignant brain tumours is believed to be due to the poor penetration of cytotoxic drugs into tumour tissue. In patients with malignant supratentorial brain tumours we have analysed the uptake of EMP metabolites in tumour tissue after oral administration and demonstrated EMBP in the same tissue specimens. Sixteen patients were given 280 mg EMP orally 14 h prior to surgery. Specimens from brain tumour tissue, cystic fluid, and serum were collected during surgery. Using gas chromatography the metabolites of EMP, estramustine (EaM) and estromustine (EoM), were quantified, EMBP was demonstrated by immunohistochemistry. The mean concentrations of EaM and EoM, expressed in ng g-1, were 60.3 and 38.4 in tumour tissue and 3.5 and 56.3 in serum, respectively. An accumulation of EaM in tumour tissue was found with a mean concentration gradient of 16.1 versus serum, while the gradient for EoM was 0.76. EMBP was demonstrated with a high degree of staining in all but one tumour. The high concentrations of EaM and EoM found in malignant brain tumour tissue correspond to potentially cytotoxic levels. The present results as well as the earlier in vitro demonstrated cytotoxic effects on glioma cells strengthen the possibility of a therapeutic effect of EMP in the treatment of malignant brain tumours.

The antineoplastic agent estramustine and the derivative estramustine-phosphate inhibit secretion of interleukin-3 in leukemic cells. Possible roles of MAPs.

The antineoplastic drug estramustine is an adduct of estradiol and nor-nitrogen mustard. It has been shown that this drug interferes with microtubule assembly, an effect mediated by estramustine interaction with microtubule-associated proteins (MAPs). In the present report we demonstrate that estramustine and the phosphorylated derivative of the drug, estramustine-phosphate, inhibit the secretion of interleukin-3 by WEHI-3B cells. These studies also show that the estramustine derivative specifically interacts with a MAPs component found in these cells, which exhibited characteristics ressembling those of tau protein isoforms. Western blots using a unique monoclonal antibody MTB6.22 that recognizes microtubule-binding domains on MAPs, indicated that this WEHI protein factor contained the antigenic determinant that are functionally significant for microtubule assembly. ELISA assays using this antibody, also showed a decrease in the levels of the immunoreactive protein in WEHI cells after treatment with EMP. Interestingly, it has been recently described that the action of estramustine-phosphate is mediated by a direct interaction with MAP-binding sites on the microtubule surface, which are recognized by the site-specific monoclonal antibody. These findings together with immuno-precipitation experiments using anti-interleukin-3 antibodies and the inhibitory effect of the estramustine derivative on WEHI secretion process suggest that this anti-mitotic agent may block IL-3 secretion by a mechanism involving its interaction with a 'tau-like' MAPs component present in these cells.

Estramustine-phosphate binds to a tubulin binding domain on microtubule-associated proteins MAP-2 and tau.

Estramustine-phosphate (EMP), a phosphorylated conjugate of estradiol and nor-nitrogen mustard binds to microtubule-associated proteins MAP-2 and tau. It was shown that this estramustine derivative inhibits the binding of the C-terminal tubulin peptide beta-(422-434) to both MAP-2 and tau. This tubulin segment constitutes a main binding domain for these microtubule-associated proteins. Interestingly, estramustine-phosphate interacted with the synthetic tau peptides V187-G204 and V218-G235, representing two major repeats within the conserved microtubule-binding domain on tau and also on MAP-2. This observation was corroborated by the inhibitory effects of estramustine-phosphate on the tau peptide-induced tubulin assembly into microtubules. On the other hand, the nonphosphorylated drug estramustine failed to block the MAP peptide-induced assembly, indicating that the negatively charged phosphate moiety of estramustine-phosphate is of importance for its inhibitory effect. These findings suggest that the molecular sites for the action of estramustine-phosphate are located within the microtubule binding domains on tau and MAP-2.

The effect of estramustine derivatives on microtubule assembly in vitro depends on the charge of the substituent.

Estramustine, and derivatives of estramustine with a charged substituent at position 17 on the estrogen moiety, have been investigated for their effects on bovine brain microtubules in vitro. The negatively charged estramustine phosphate has been found previously to be a microtubule-associated protein (MAP)-dependent microtubule inhibitor [Wallin M, Deinum J and Fridén B, FEBS Lett 179: 289-293, 1985]. In the present study the binding of estramustine phosphate to MAP2 and tau was investigated. Both these MAPs were found to have two to three binding sites for estramustine phosphate which is compatible with the reported number of basic amino acid repeats of these MAPs, considered to be the ultimate tubulin binding domains. The Kd for the binding of estramustine phosphate to MAP2 was estimated to be 20 microM at 4 degrees, and for the binding of tau, 200 microM. The rate of dissociation was very low (T1/2 greater than 2 hr), which indicates that the binding of estramustine phosphate may stabilize the protein-drug complex by changing the protein conformation. Two new negatively charged estramustine derivatives, estramustine sulphate and estramustine glucuronide, were found to be similar MAP-dependent microtubule inhibitors. The concentration for 50% inhibition of assembly was 100 microM for the sulphate derivative, the same as found previously for estramustine phosphate, and 250 microM for the more bulky estramustine glucuronide. A positively charged derivative, estramustine sarcosinate, did not inhibit microtubule assembly or alter the composition of the coassembled MAPs. The morphology of the microtubules was, however, affected. The uncharged estramustine bound to both tubulin and MAPs, but no effects were seen on microtubule assembly, the composition of coassembled MAPs or the microtubule morphology. Our results suggest that only negatively charged estramustine derivatives have a MAP-dependent microtubule inhibitory effect. The two new negatively charged derivatives could therefore be valuable tools in the study of tubulin-MAP interactions. The results also confirm that these interactions between tubulin and MAPs are mainly electrostatic.