Phase I and pharmacologic study of a 3-hour infusion of paclitaxel followed by cisplatinum and 5-fluorouracil in patients with advanced solid tumors.

A Phase I and pharmacological study of paclitaxel administered as an outpatient, 3-h i.v. infusion just before a 5-day regimen of daily cisplatinum (CP) and a continuous infusion of 5-fluorouracil (5-FU) was performed in patients with advanced solid tumors. A secondary objective was to determine the objective response rate to this regimen. Forty-two patients were enrolled and were evaluable for toxicities. Eighteen patients were previously untreated, whereas the rest had received prior treatment with radiation (J. H. Schiller et al., J. Clin. Oncol., 12: 241-248, 1994), chemotherapy (M. J. Kennedy et al., Clin. Cancer Res., 4: 349-356, 1998), or both modalities (J. H. Schiller et al., J. Clin. Oncol., 12: 241-248, 1994). The paclitaxel dose was escalated from 100-135-170-200-225 to 250 mg/m2, whereas i.v. 5-FU and CP doses were fixed at 1.0 g/m2/day continuous infusion and 20 mg/m2/day, respectively, daily for 5 days. Granulocyte colony-stimulating factor (G-CSF; 5 microg/kg/day) was administered s.c. from day 6, routinely after 250 mg/m2 dose of paclitaxel or after a lower dose of paclitaxel if ANC <500/microl or febrile neutropenia was observed. Patients were treated every 28 days. Plasma and urine samples were collected to determine the pharmacokinetics of paclitaxel. In previously untreated patients, the maximally tolerated dose of paclitaxel in the drug regimen was determined to be 170 mg/m2 without and 250 mg/m2 with G-CSF support. At the higher dose level, mucositis and thrombocytopenia were dose-limiting. In previously treated patients, these toxicities were observed at all dose levels of paclitaxel > or =135 mg/m2. With increasing doses of paclitaxel, a disproportionate increase in the peak concentrations, as well as the area under plasma concentration time-curve, was seen. This nonlinearity was due to saturable total body clearance and volume of distribution of paclitaxel (P < 0.001). The apparent plasma elimination half-life was unaffected by the dose of paclitaxel. CP and 5-FU had no apparent effect on the metabolism of paclitaxel. Among 32 patients evaluable for response, 22 demonstrated an objective response, including five complete remissions. Therefore, a regimen of 3-h infusion of 250 mg/m2 paclitaxel before CP and FU is tolerable with G-CSF (as above) support in previously untreated patients. The regimen also seems to be highly active against breast and esophageal cancers.

S-adenosyl-L-methionine: transcellular transport and uptake by Caco-2 cells and hepatocytes.

S-adenosyl-L-methionine (SAMe) is an endogenous molecule that is known to be protective against hepatotoxic injury. Although oral SAMe appears to be absorbed across the intestinal mucosa, its systemic bioavailability is low. The reason for this is unknown. Using the Caco-2 cell culture model for enterocyte absorption, we determined the mode by which SAMe is transported across this cell monolayer. We also determined the extent it is taken up by both Caco-2 cells and hepatocytes. In Caco-2 cells transport was observed in both apical to basolateral and basolateral to apical directions. The apparent permeability coefficients (Papp) appeared to be concentration independent and were similar in both directions (0.7x10(-6) and 0.6x10(-6) cm s-1, respectively), i.e. identical to that of the paracellular transport marker mannitol (0.9x10(-6) and 0.7x10(-6) cm s-1). This mode of transport was supported by a four-fold increase in the Papp for SAMe transport in Ca++-free buffer. Cellular uptake of SAMe was examined in both Caco-2 cells and cultured rat hepatocytes. Uptake by hepatocytes was not saturable in a concentration range of 0.001-100 microM. Accumulation by both cell types was very low, with a cell:medium ratio at equilibrium of only 0.2-0.5. This low cell accumulation supports the finding of paracellular transport as the only mode of cell membrane transport. Increased hepatocellular protection for SAMe may be accomplished by converting SAMe to a more lipid-soluble prodrug.

Pathway-selective sex differences in the metabolic clearance of propranolol in human subjects.

This study determined the total clearance of propranolol and the partial clearances through each of its three primary metabolic pathways after administration of an 80 mg single oral dose in 28 young, white subjects (13 women; 15 men). The oral clearance of propranolol was significantly higher (63%, p less than 0.02) in the men (65.7 +/- 7.7 ml/min/kg; mean +/- SE) than in the women (40.2 +/- 6.2 ml/min/kg). This sex difference was mainly attributable to a 137% higher clearance through the P-450-mediated side-chain oxidation in the men (p less than 0.001). There was also a 52% higher clearance through glucuronidation in the men (p less than 0.02). In contrast, the clearance through the P-450-mediated ring oxidation was not different between men and women. After administration of simultaneous intravenous doses of hexadeuterium-labeled drug (0.1 mg/kg) to 11 of the subjects, there were no differences between men and women in volume of distribution or half-life. Moreover, there were no sex differences in plasma and blood binding of propranolol. This study thus demonstrates that higher plasma levels of propranolol occur in women than in men after oral doses and suggests that some drug metabolizing enzymes, but not others, are regulated by sex hormones in human beings.

Stereoselective binding of propranolol to human plasma, alpha 1-acid glycoprotein, and albumin.

Our aim was to determine possible stereoselectivity in the plasma binding of propranolol. Equilibrium dialysis with plasma from seven healthy subjects and a deuterium-labeled pseudoracemate of propranolol was used. Plasma binding of the propranolol enantiomers differed with the unbound fraction of (-)-propranolol (22 +/- 2%; mean +/- SE) being smaller than that of (+)-propranolol (25.3 +/- 1.9%). The (-)/(+)-propranolol ratio for the unbound fraction, a measure of the stereoselectivity, was 0.86 +/- 0.02. There was an inverse correlation between the unbound (-)/(+)-propranolol ratio in individual subjects and overall binding of (+/-)-propranolol, indicating greater stereoselectivity at higher total binding. To assess the site of the stereoselective binding to plasma proteins, the binding of (+)- and (-)-propranolol to human alpha 1-acid glycoprotein (AGP) and human serum albumin (HSA) was examined. The binding to AGP was stereoselective for (-)-propranolol with a (-)/(+)-propranolol ratio for the unbound fraction of 0.79 +/- 0.01, whereas (+)-propranolol was bound to a greater extent to HSA with a (-)/(+)-propranolol ratio for the unbound fraction of 1.07 +/- 0.01. Although these results demonstrate opposite stereoselectivity in the binding of (+)- and (-)-propranolol to AGP and HSA, the stereoselective binding of (-)-propranolol to AGP predominates in plasma. This stereoselective plasma binding of the (-)-enantiomer of propranolol could limit the access of this more active enantiomer to beta-receptors or other active sites. The uptake of propranolol by red blood cells was not stereoselective.

Propranolol's metabolism is determined by both mephenytoin and debrisoquin hydroxylase activities.

The relative contributions of the debrisoquin and mephenytoin isozymes of hepatic cytochrome P-450 to the stereoselective metabolism of propranolol have been studied in a panel of volunteers of known oxidative phenotypes. Six subjects were extensive metabolizers of both debrisoquin and mephenytoin (EM). Four subjects were poor metabolizers of debrisoquin but rapid for mephenytoin (PMD). Five subjects were poor metabolizers of mephenytoin but rapid for debrisoquin (PMM), and one individual had a deficiency for both test compounds (PMD/M). Partial metabolic clearances of each propranolol enantiomer to 4-hydroxypropranolol (4-OH-P), the sulfate, and glucuronide conjugates of 4-OH-P, naphthoxylactic acid (NLA) and propranolol glucuronide, were estimated after a single oral dose of racemic propranolol (80 mg). The partial metabolic clearance of both enantiomers to total 4-OH-P in the PMD group was 75% less than in the EM and PMM groups, indicating the contribution of the debrisoquin isozyme to this route of metabolism. The R/S ratios for the clearance to 4-OH-P were similar between EM and PMD (2.5 +/- 0.5 vs 2.5 +/- 0.4, respectively), implying that the different enzymes involved in ring hydroxylation (i.e., the debrisoquin isozyme and other hydroxylases) have similar stereoselective preferences. The partial metabolic clearance to NLA was 55% less in the PMM group than in the EM and PMD groups, indicating that S-mephenytoin 4-hydroxylase contributes to the metabolic conversion of propranolol to NLA. The R/S ratios for the clearance to NLA were close to unity in all groups. The partial metabolic clearance to propranolol glucuronide also did not exhibit stereoselectivity and was similar in all groups.(ABSTRACT TRUNCATED AT 250 WORDS)

Presystemic and systemic glucuronidation of propranolol.

The relative importance of presystemic and systemic glucuronidation of propranolol was examined in normal subjects given single oral and intravenous doses of propranolol. The areas under the plasma concentration--time curves (AUCs) of propranolol glucuronide (PG), 41 +/- 15 ng . hr/ml, and propranolol, 48 +/- 15 ng . hr/ml, were of the same order after the intravenous dose (0.05 mg/kg). After oral doses of 20 and 80 mg, the AUCs of PG were 302 +/- 105 and 1,398 +/- 409 ng . hr/ml; these were 7 times the AUCs of propranolol, 44 +/- 15 and 220 +/- 38 ng . hr/ml. The time lapse to peak concentration, 1.5 to 3.0 hr, and the plasma half-life, 3.2 to 3.7 hr, were the same for PG and propranolol. These results demonstrate glucuronidation as an important determinant of propranolol bioavailability.

Stereoselective clearance and distribution of intravenous propranolol.

Our objective was to determine the kinetics of (+)- and (-)-propranolol after intravenous doses of racemic drug. Five normal subjects received 0.1 mg/kg of a pseudoracemate of propranolol that consisted of deuterium-labeled (+)-propranolol and unlabeled (-)-propranolol. Plasma concentrations of (+)- and (-)-propranolol as measured by gas chromatography-mass spectrometry demonstrated enantiomeric differences in systemic clearance (Cls) [(+)-propranolol, 1.21 +/- 0.15 l/min; (-)-propranolol, 1.03 +/- 0.12 l/min; P less than 0.01] and apparent volume of distribution (Vd) [(+)-propranolol, 4.82 +/- 0.34 l/kg; (-)-propranolol, 4.08 +/- 0.33 l/kg; P less than 0.001], but no difference in distribution or elimination t1/2s (t1/2 beta 3.5 hr). The higher Cls of (+)-propranolol suggests stereoselective hepatic elimination. The higher apparent Vd of (+)-propranolol is mainly related to its lower plasma binding [(+)-propranolol, 20.3 +/- 0.8% unbound; (-)-propranolol, 17.6 +/- 0.7% unbound; P less than 0.001]. There was no stereoselective uptake by red blood cells. These findings demonstrate that multiple stereoselective mechanisms are involved in the disposition of propranolol and determine the access of the drug to active sites.

4-Hydroxypropranolol and its glucuronide after single and long-term doses of propranolol.

The disposition of the pharmacologically active 4-hydroxypropranolol (HO-P), its glucuronic acid conjugate (HO-P-G), and propranolol were compared after single intravenous and oral doses of propranolol in 6 normal subjects and after long-term therapy in 32 patients with hypertension or coronary artery disease. The areas under the plasma concentration/time curves (AUCoo, ng . hr/ml) after 4-mg intravenous doses of propranolol were 6.6 +/- 2.2 (mean +/- SEM) for HO-P and 55 +/- 11 for propranolol. After 20- and 80-mg oral doses the AUCoo for HO-P were 59 +/- 9 and 162 +/- 21 and for propranolol were 72 +/- 9 and 306 +/- 46. Peak HO-P concentrations were reached at 1 to 1.5 hr after the oral doses. Although there was a rapid decline in plasma HO-P between 1.5 and 3 hr when HO-P-G was still rising to levels above HO-P levels 3.5- to 5-fold, the apparent half-lifes (t1/2s) after 3 hr were in the same range for HO-P, HO-P-G, and propranolol (3.0 to 4.2 hr). While during long-term therapy plasma HO-P rose over the whole dose range (40 to 960 mg daily) in an apparently linear fashion, the HO-P/propranol plasma level ratio fell from 1.07 +/- 0.13 at 40 mg daily to only 0.09 +/- 0.01 at 640 mg daily. Plasma HO-P-G rose exponentially with dose and demonstrated significant cumulation. HO-P and HO-P-G in urine accounted for about 9% of long-term propranolol doses. This study suggests a significant contribution of HO-P to pharmacologic effects, in particular at low single and long-term oral doses of propranolol and saturation of naphthalene ring oxidation as a main determinant of propranolol bioavailability.

Propranolol glucuronide cumulation during long-term propranolol therapy: a proposed storage mechanism for propranolol.

The comparative disposition of propranolol glucuronide (PG) and propranolol was determined in 35 patients with hypertension or coronary artery disease during initiation of propranolol therapy, during steady-state conditions, and after discontinuation of propranolol (dose range, 40 to 960 mg daily, every 6 hr). The 2.3-fold PG cumulation in plasma was identical to propranolol cumulation. PG plasma levels were about 4 times as high as propranolol levels over the whole dose range. Unexpectedly slow terminal elimination rate of propranolol (t1/2 approximately 16 to 24 hr) on discontinuation of propranolol appeared to be related to equally slow PG elimination. PG and propranolol could be detected in plasma and urine up to 3 to 5 days after propranolol discontinuation. The PG formed in man was deconjugated to propranolol in the dog after intravenous administration, suggesting that PG may serve as a storage pool for propranolol. Observations consistent with systemic and enteric deconjugation of PG, including enterohepatic recirculation, may, at least in part, explain the observed propranolol cumulation as well as the slow elimination of propranolol after its discontinuation. PG renal clearance (29 to 70 ml/min) and PG plasma levels were highly dependent on glomerular filtration rate, suggesting that PG may cumulate abnormally in patients with severe renal disease.

Food-induced increase in propranolol bioavailability--relationship to protein and effects on metabolites.

The influence of a meal on the disposition and metabolism of oral propranolol was examined in six normal subjects. The meal induced a mean 53% increase in propranolol bioavailability (range 2% to 92%; P less than 0.01) without affecting time to maximum concentration, half-life, or the amount of unchanges drug in urine. There was no effect on the plasma concentrations of 4-hydroxypropranolol or four other metabolites. The increased bioavailability was linearly related to the protein content of the meal (r = 0.884, P less than 0.02) above a threshold content of about 7 gm.

Food effects on propranolol systemic and oral clearance: support for a blood flow hypothesis.

The influence of a high-protein meal as compared to fasting on the disposition of simultaneous intravenous and oral doses of propranolol, as well as on indocyanine green clearance, was examined in six normal subjects. The intravenous dose (0.1 mg/kg) was unlabeled propranolol and the oral dose (80 mg) was a stereospecifically deuterium-labeled pseudoracemate of propranolol. Systemic clearance of propranolol increased 38%, from 1005 +/- 57 to 1384 +/- 115 ml/min (mean +/- SE; P less than 0.05) as a result of the meal, with no change in t1/2 or apparent volume of distribution. A 12% decrease in oral clearance occurred with the meal but was not statistically significant (3717 +/- 185 ml/min, fasting; 3245 +/- 498 after meal), whereas bioavailability increased 67% (27.2% +/- 1.7% fasting; 45.5% +/- 4.3% after meal; P less than 0.01). Estimated hepatic blood flow, as measured by indocyanine green clearance, rose 34% 60 minutes after the meal (1719 +/- 155 ml/min fasting; 2304 +/- 218 ml/min after meal; P less than 0.02). A difference was observed in the oral clearance of the propranolol enantiomers in the fasting state, but this difference was unaffected by the meal. These alterations in propranolol disposition, as the result of a high-protein meal, are consistent with a transient increase in hepatic blood flow.

Increased clearance of propranolol and theophylline by high-protein compared with high-carbohydrate diet.

The objective of this study was to determine whether changes in dietary protein and carbohydrate influence the oral clearance of propranolol, a high-clearance drug, and theophylline, a low-clearance drug. Six normal subjects studied in a clinical research center each received a single oral dose of propranolol, 80 mg, and theophylline, 5 mg/kg, after having been on each of two well-defined diets for a period of 10 days. When the diet was altered from high carbohydrate/low protein to low carbohydrate/high protein, the oral clearance of propranolol increased by 74% +/- 20% (mean +/- SE; range 9% to 156%; P less than 0.01) with no change in plasma half-life or plasma binding. This dietary change resulted in an increase in theophylline clearance of 32% +/- 6% (range 18% to 50%; P less than 0.02) and a corresponding decrease in plasma half-life of 26% +/- 6% (range 6% to 42%; P less than 0.05) with no alteration in the apparent volume of distribution. These observations reemphasize the importance of diet in drug disposition and suggest that the clearance of high-clearance drugs like propranolol is more susceptible than the clearance of low-clearance drugs to dietary manipulations, effects that may have to be considered in drug therapy.

Transport of the flavonoid chrysin and its conjugated metabolites by the human intestinal cell line Caco-2.

Chrysin (5,7-dihydroxyflavone), a natural product present in our daily diet, is a potent inhibitor of drug-metabolizing enzymes. However, its oral bioavailability is not known. This study examined the intestinal epithelial transport of chrysin (20 microM), using the human colonic cell line Caco-2 as a model of human intestinal absorption. The apical to basolateral flux of chrysin, with an apparent permeability coefficient (P(app)) during the first hour of 6.9 +/- 1.6 x 10(-6) cm x sec(-1) (mean +/- SEM), was more than 10-fold higher than for the paracellular transport marker mannitol, 0.42 +/- 0.12 x 10(-6) cm x sec(-1). Interestingly, the reverse, basolateral to apical flux of chrysin, P(app) = 14.1 +/- 1.6 x 10(-6) cm x sec(-1), was about 2-fold higher than the apical to basolateral flux (P < 0.01). In transport studies beyond 1 hr, there was a rapid decline in P(app). This correlated with the appearance of two metabolites, M1 (chrysin glucuronide) and M2 (chrysin sulfate), identified by enzymatic hydrolysis procedures and HPLC. Following apical loading of chrysin, as much as 90% of M1 + M2 appeared on the apical side, thus indicating clear efflux of the chrysin metabolites. The addition of the anion transport inhibitor MK-571 (50 microM) on the apical side produced a 71% (P < 0.0001) and 20% (P < 0.05) inhibition of the efflux of M1 and M2, respectively, suggesting the involvement of the multidrug resistance protein MRP2 pump. Indeed, using specific antibodies, MRP2 was in fact detected by western blotting in Caco-2 plasma membranes, whereas MRP1 was not. These observations suggest that chrysin has favorable membrane transport properties but that its intestinal absorption may be seriously limited by surprisingly efficient glucuronidation and sulfation by the enterocytes and almost quantitative efflux by MRP2 of the metabolites formed.

Transport of quercetin and its glucosides across human intestinal epithelial Caco-2 cells.

There is mounting evidence from human epidemiological, animal in vivo, and in vitro studies to suggest beneficial effects related to the consumption of quercetin and its glucosides. However, there is limited knowledge on the oral bioavailability of these natural products. This study examined the intestinal epithelial membrane transport of quercetin, quercetin 4'-glucoside, and quercetin 3,4'-diglucoside, using the Caco-2 human colonic cell line, a model of human intestinal absorption. The apparent permeability (Papp) of each agent was measured in both apical to basal and basal to apical directions. The apical to basolateral flux of quercetin, Papp 5.8 +/- 1.1 x 10(-6) cm x sec(-1) (mean +/- SEM), was more than 10-fold higher than for the paracellular transport marker mannitol, 0.48 +/- 0.09 x 10(-6) cm x sec(-1) (P < 0.01). Under identical conditions, the Papp for the transcellular marker propranolol was about 5-fold higher than for quercetin (P < 0.001). Interestingly, the reverse, basolateral to apical, flux of quercetin (Papp 11.1 +/- 1.2 x 10(-6) cm x sec(-1)) was almost 2-fold higher than the apical to basolateral flux (P < 0.001). In similar experiments, quercetin 4'-glucoside demonstrated no absorption, Papp < 0.02 x 10(-6) cm x sec(-1) in the apical to basal direction, but did demonstrate basal to apical flux, Papp 1.6 +/- 0.2 x 10(-6) cm x sec(-1). Quercetin 3,4'-diglucoside showed a low apical to basolateral transport (Papp 0.09 +/- 0.03 x 10(-6) cm x sec(-1)); its reverse, basolateral to apical, transport was, however, 4-fold higher (P < 0.05). In these cells, glucose was actively transported with an apical to basolateral Papp of 36.8 +/- 1.1 x 10(-6) cm x sec(-1). These observations suggest facile absorption of quercetin through the human intestinal epithelium, but contrary to a previous proposal, they do not support an active transport process for quercetin glucosides.

Quercetin, a potent and specific inhibitor of the human P-form phenosulfotransferase.

The natural product quercetin was a potent inhibitor of the human P-form phenolsulfo-transferase with an IC50 value of 0.10 +/- 0.03 microM (mean +/- SEM; N = 5), which was three to four orders of magnitude more potent than its inhibition of other human sulfotransferases. The inhibition was noncompetitive with a Ki value of 0.10 microM. The potency and mechanism of this inhibition appear similar to those of the current standard P-form inhibitor, 2,6-dichloro-4-nitrophenol. Among other flavonoids examined, kaempferol was found to have an IC50 value of 0.39 +/- 0.07 microM, naringenin 10.6 +/- 1.6 microM and naringin 265 +/- 90 microM (N = 3). These observations suggest the potential for clinically important pharmacologic and toxicologic interactions by flavonoid-containing foods and beverages.

Taxol metabolism in rat hepatocytes.

Metabolism of the anticancer drug taxol was investigated in freshly isolated rat hepatocytes. Two main metabolites were separated by reversed-phase HPLC and shown by tandem mass spectrometry to be monohydroxylated metabolites. Kinetic studies revealed apparent Km values of 68 and 61 microM with identical Vmax values for the two metabolites. Verapamil and midazolam, but not phenacetin, showed concentration-dependent inhibition of taxol metabolism with both metabolites being affected equally. The IC50 was about 100 microM for verapamil and 25 microM for midazolam. These observations demonstrate for the first time in vitro metabolism of taxol and suggest that the metabolism may be subject to potentially important interactions with numerous other drugs.

Stereoselective delivery and actions of beta receptor antagonists.

These studies have revealed that the delivery and actions of beta receptor antagonist drugs are controlled by a cascade of stereoselective processes involving multiple enzymes, transport proteins and receptors. In essence, the free concentration of the pharmacologically active (-)-enantiomer species of these drugs presented to cell surface beta receptors appears to be a function of the stereoselective clearance by hepatic cytochrome P-450 isoenzymes, enantiomer selective binding to alpha 1-acid glycoprotein and albumin and perhaps predominantly by stereoselective sequestration (and release) by the vesicular amine transport protein within adrenergic neurons. Stereoselectivity in the clearance of beta blocking drugs, which can favor either the (+)- or (-)-enantiomer, only appears to be important for the lipophilic drugs which are cleared by hepatic metabolism. Such stereoselectivity is due to differential stereochemical substrate requirements of individual hepatic cytochrome P-450 isoenzymes. Interindividual variations in the stereoselectivity can occur as a result of differences in the amount and expression of cytochrome P-450 isoenzymes due to genetic predisposition or other factors. In the same context, we have observed a significant correlation between the extent and stereoselectivity of binding of beta blocking drugs to plasma proteins. This is another finding which suggests that variability in the expression of individual proteins involved in the beta blocking drug-protein cascade determines the free concentration of the pharmacologically active enantiomer. However, since most observations have been made in young normal subjects, the extent of stereoselectivity in metabolism, binding and other processes is unknown in the general population where steady-state plasma concentrations can vary widely due to multiple biological factors. The observations from neural studies support the concept that adrenergic nerve endings provide a depot for the stereoselective storage and release of the active enantiomer of beta receptor antagonists. The mechanism of this release appears to involve exocytotic secretion of drug that has been stereoselectively accumulated by the neurotransmitter storage vesicles. In terms of this idea, beta receptor antagonists released during nerve stimulation may achieve concentrations of the (-)-enantiomer within the adrenergic synapse greatly in excess of those found in plasma. Such a mechanism could significantly influence both the intensity and duration of beta receptor blockade in the heart, blood vessels, brain and other target tissues.(ABSTRACT TRUNCATED AT 400 WORDS)

Quercetin and resveratrol potently reduce estrogen sulfotransferase activity in normal human mammary epithelial cells.

Estrogen sulfotransferase (EST) is the sole sulfotransferase expressed in normal human breast epithelial cells and has an important function in determining free estrogen hormone levels in these cells. In the present study we examined the inhibitory effect of the dietary polyphenols quercetin and resveratrol on EST activity, i.e. 17beta-estradiol (E2) sulfation. Both the compounds potently inhibited recombinant human EST in a competitive fashion with K(i) values of about 1 microM. In fact, both polyphenols could serve as substrates for EST. In order to extend the studies to more physiologically relevant conditions, we examined whether inhibition of EST also occurred in the intact cultured human mammary epithelial (HME) cells. The mean baseline EST activity (E2 sulfate formation) in the HME cells was 4.4 pmol/h per mg protein. The IC(50) for resveratrol was very similar to that for recombinant EST, i.e. about 1 microM. Surprisingly, quercetin was 10 times more potent in the HME cells with an IC(50) of about 0.1 microM, a concentration that should be possible to achieve from the normal dietary content of this flavonoid.

Extensive and saturable accumulation of paclitaxel by the human platelet.

Little is known about the cellular distribution of paclitaxel in humans. In the present study we examined the distribution of [3H]-paclitaxel in human blood. When 1 microM paclitaxel was incubated with fresh blood at 37 degrees C, the platelet/plasma concentration ratio was 240 +/- 17 (mean +/- SEM), whereas the red blood cell (RBC)/plasma concentration ratio was only 0.59 +/- 0.05. In kinetics experiments using platelet-rich plasma, we observed that the platelet accumulation of paclitaxel was highly temperature- and concentration-dependent. Scatchard analysis of the 37 degrees C uptake data demonstrated a dissociation constant (Kapp) of 0.80 +/- 0.10 microM and a maximal binding capacity of 672 +/- 102 pmol/10(9) platelets. It is proposed that the platelet accumulation of paclitaxel reflects binding to microtubules and may serve as a useful model for binding to less accessible cellular sites.

Human phenol sulfotransferases: chiral substrates and expression in Hep G2 cells.

Enzymatic sulfation of chiral phenolic ethanolamine drugs, e.g. beta-agonists, has been shown to be stereoselective in humans. The reaction appears to be specific for the monoamine (M) form of the phenol sulfotransferases (PSTs). In further studies of the stereochemistry of this reaction, we have found the hepatoblastoma-derived cell line Hep G2 to be an excellent human model. These cells contain the M form PST in quantities exceeding those of human liver by about 4-fold. Thus, sulfate conjugates of the beta-agonist drugs can easily be synthesized for subsequent structural and enzyme kinetic studies. Although less abundant, the phenol (P) form PST as well as dehydroepiandrosterone sulfotransferase are also expressed in the Hep G2 cells.