The metabolism and excretion of galantamine in rats, dogs, and humans.

Galantamine is a competitive acetylcholine esterase inhibitor with a beneficial therapeutic effect in patients with Alzheimer's disease. The metabolism and excretion of orally administered (3)H-labeled galantamine was investigated in rats and dogs at a dose of 2.5 mg base-Eq/kg body weight and in humans at a dose of 4 mg base-Eq. Both poor and extensive metabolizers of CYP2D6 were included in the human study. Urine, feces, and plasma samples were collected for up to 96 h (rats) or 168 h (dogs and humans) after dosing. The radioactivity of the samples and the concentrations of galantamine and its major metabolites were analyzed. In all species, galantamine and its metabolites were predominantly excreted in the urine (from 60% in male rats to 93% in humans). Excretion of radioactivity was rapid and nearly complete at 96 h after dosing in all species. Major metabolic pathways were glucuronidation, O-demethylation, N-demethylation, N-oxidation, and epimerization. All metabolic pathways observed in humans occurred in at least one animal species. In extensive metabolizers for CYP2D6, urinary metabolites resulting from O-demethylation represented 33.2% of the dose compared with 5.2% in poor metabolizers, which showed correspondingly higher urinary excretion of unchanged galantamine and its N-oxide. The glucuronide of O-desmethyl-galantamine represented up to 19% of the plasma radioactivity in extensive metabolizers but could not be detected in poor metabolizers. Nonvolatile radioactivity and unchanged galantamine plasma kinetics were similar for poor and extensive metabolizers. Genetic polymorphism in the expression of CYP2D6 is not expected to affect the pharmacodynamics of galantamine.

Strategies for absorption screening in drug discovery and development.

This review gives an overview of the current approaches to evaluate drug absorption potential in the different phases of drug discovery and development. Methods discussed include in silico models, artificial membranes as absorption models, in vitro models such as the Ussing chamber and Caco-2 monolayers, in situ rat intestinal perfusion and in vivo absorption studies. In silico models such as iDEA can help optimizing chemical synthesis since the fraction absorbed (Fa) can be predicted based on structural characteristics only. A more accurate prediction of Fa can be obtained by feeding the iDEA model with Caco-2 permeability data and solubility data at various pH's. Permeability experiments with artificial membranes such as the filter-IAM technology are high-throughput and offer the possibility to group compounds according to a low and a high permeability. Highly permeable compounds, however, need to be further evaluated in Caco-2 cells, since artificial membranes lack active transport systems and efflux mechanisms such as P-glycoprotein (PgP). Caco-2 and other "intestinal-like" cell lines (MDCK, TC-7, HT29-MTX, 2/4/A1) permit to perform mechanistic studies and identify drug-drug interactions at the level of PgP. The everted sac and Ussing chamber techniques are more advanced models in the sense that they can provide additional information with respect to intestinal metabolism. In situ rat intestinal perfusion is a reliable technique to investigate drug absorption potential in combination with intestinal metabolism, however, it is time consuming, and therefore not suited for screening purposes. Finally, in vivo absorption in animals can be estimated from bioavailability studies (ratio of the plasma AUC after oral and i.v. administration). The role of the liver in affecting bioavailability can be evaluated by portal vein sampling experiments in dogs.

Two linked mutations in transcriptional regulatory elements of the CYP3A5 gene constitute the major genetic determinant of polymorphic activity in humans.

Cytochrome P450 3A subfamily members (CYP3A) are the most abundant liver cytochrome P450 forms, responsible for the biotransformation of over 50% of all drugs. The expression and activity of isoforms CYP3A4 and CYP3A5 show wide inter-individual variation, influencing both drug response and disease susceptibility. The molecular basis for this variation has never been defined. In this study, we used midazolam to characterize CYP3A5 phenotype in a panel of liver samples. A clear bimodality in metabolism was observed. Analysis of the 5' flanking region of the CYP3A5 gene identified two linked polymorphisms, T-369G and A-45G, located in transcriptional regulatory elements which are associated with increased expression and activity of the gene. A polymerase chain reaction based detection assay is described facilitating future studies into both the metabolic consequences of this variation and disease association studies relating to CYP3A5.

Identification of the cytochrome P450 enzymes involved in the metabolism of cisapride: in vitro studies of potential co-medication interactions.

Cisapride is a prokinetic drug that is widely used to facilitate gastrointestinal tract motility. Structurally, cisapride is a substituted piperidinyl benzamide that interacts with 5-hydroxytryptamine-4 receptors and which is largely without central depressant or antidopaminergic side-effects. The aims of this study were to investigate the metabolism of cisapride in human liver microsomes and to determine which cytochrome P-450 (CYP) isoenzyme(s) are involved in cisapride biotransformation. Additionally, the effects of various drugs on the metabolism of cisapride were investigated. The major in vitro metabolite of cisapride was formed by oxidative N-dealkylation at the piperidine nitrogen, leading to the production of norcisapride. By using competitive inhibition data, correlation studies and heterologous expression systems, it was demonstrated that CYP3A4 was the major CYP involved. CYP2A6 also contributed to the metabolism of cisapride, albeit to a much lesser extent. The mean apparent K(m) against cisapride was 8.6+/-3.5 microM (n = 3). The peak plasma levels of cisapride under normal clinical practice are approximately 0.17 microM; therefore it is unlikely that cisapride would inhibit the metabolism of co-administered drugs. In this in vitro study the inhibitory effects of 44 drugs were tested for any effect on cisapride biotransformation. In conclusion, 34 of the drugs are unlikely to have a clinically relevant interaction; however, the antidepressant nefazodone, the macrolide antibiotic troleandomycin, the HIV-1 protease inhibitors ritonavir and indinavir and the calcium channel blocker mibefradil inhibited the metabolism of cisapride and these interactions are likely to be of clinical relevance. Furthermore, the antimycotics ketoconazole, miconazole, hydroxy-itraconazole, itraconazole and fluconazole, when administered orally or intravenously, would inhibit cisapride metabolism.

Reduction of the prodrug loperamide oxide to its active drug loperamide in the gut of rats, dogs, and humans.

Loperamide oxide (LOPOX) is a prodrug of loperamide (LOP). The reduction of LOPOX to LOP was investigated to provide a pharmacokinetic basis for the pharmacodynamics and improved side effect profile of the prodrug. Reduction of LOPOX was studied in vitro in gut contents, gut flora, intestinal cells, and hepatocytes. In vivo pharmacokinetics and metabolism of LOPOX and LOP were compared in the dog. LOPOX could be efficiently reduced in the gut contents of rats, dogs, and humans, with the most extensive reduction found in cecal contents. Reduction was diminished to 13% of the anaerobic LOPOX reductase activity in the presence of oxygen and to 2.5% of the original activity by heat treatment of the contents. In human ileal effluents, LOPOX reductase activity was similar in oxygen and heat sensitivity. In the rat, the cecum contained on average 89.2% of the total activity in the contents of the upper part of the intestine. In the dog, there was a gradual increase in LOPOX reductase activity from the proximal small intestine toward the cecum. In germ-free rats, the cecum contained < 1% of the activity of the small intestine. Isolated intestinal microflora of rat and dog was able to reduce LOPOX to LOP under anaerobic conditions, indicating that the microflora was primarily involved in the reduction. In its absence (i.e. in germ-free rats), reduction could still be conducted by other unknown components of the gut contents. In isolated intestinal cells, the initial rate of drug uptake was approximately 3-10 times faster for LOP than for LOPOX.(ABSTRACT TRUNCATED AT 250 WORDS)

The metabolism and excretion of risperidone after oral administration in rats and dogs.

The metabolism and excretion of risperidone (RIS; 3-[2-[4-(6-fluoro-1,2-benzisoxazole-3-yl)-1-piperidinyl]ethyl]-6,7,8,9- tetrahydro-2-methyl-4H-pyrido[1,2-a]pyrimidin-4-one), a novel antipsychotic drug, were studied after single po administration of radiolabeled RIS to rats and dogs. In rats, the excretion of the radioactivity was very rapid. The predominant excretion in rat feces (78-82% of the dose) was related to an extensive biliary excretion of metabolites (72-79% of the dose), only a small part of which underwent enterohepatic circulation. In dogs, about 92% of the dose had been excreted after one week, and the fractions recovered in the urine and feces were comparable. Only a few percent of a po dose was excreted as unchanged RIS in rats as well as in dogs. Major metabolic pathways of RIS in rats and dogs were the same as those in humans. The main pathway was the hydroxylation at the alicyclic part of the 6,7,8,9-tetrahydro-2-methyl-4H-pyrido[1,2-a]pyrimidin-4-one moiety. The resulting 9-hydroxy-risperidone (9-OH-RIS) was the main metabolite in the excreta of dogs. In rats, the metabolism was more extensive, resulting in dihydroxy-RIS and hydroxy-keto-RIS, which were eliminated mainly via the bile. However, in male and in female rats, just as in dogs and humans, the active metabolite 9-OH-RIS was by far the main plasma metabolite. Other major metabolic pathways were the oxidative dealkylation at the piperidine nitrogen and the scission of the isoxazole in the benzisoxazole ring system. The latter pathway appeared to be effected primarily by the intestinal microflora.(ABSTRACT TRUNCATED AT 250 WORDS)

Comparative metabolism of flunarizine in rats, dogs and man: an in vitro study with subcellular liver fractions and isolated hepatocytes.

1. The biotransformation of 3H-flunarizine ((E)-1-[bis(4-fluorophenyl)methyl]-4-(3-phenyl-2-propenyl)piperazine dihydrochloride, FLUN) was studied in subcellular liver fractions (microsomes and 12,000 g fraction) and in suspensions or primary cell cultures of isolated hepatocytes of rats, dogs and man. The major in vitro metabolites were characterized by h.p.l.c. co-chromatography and/or by mass spectrometric analysis. 2. The kinetics of FLUN metabolism was studied in microsomes of dog and man. The metabolism followed linear Michaelis-Menten kinetics over the concentration range 0.1-20 microM FLUN. 3. A striking sex difference was observed for the in vitro metabolism of FLUN in rat. In male rats, oxidative N-dealkylation at one of the piperazine nitrogens, resulting in bis(4-fluorophenyl) methanol, was a major metabolic pathway, whereas aromatic hydroxylation at the phenyl of the cinnamyl moiety, resulting in hydroxy-FLUN, was a major metabolic pathway in female rats. In incubates with hepatocytes, these two metabolites were converted to the corresponding glucuronides. 4. In human subcellular fractions, aromatic hydroxylation to hydroxy-FLUN was the major metabolic pathway. In primary cell cultures of human hepatocytes, oxidative N-dealkylation at the 1- and 4-piperazine nitrogen and glucuronidation of bis(4-fluorophenyl)methanol were observed. The in vitro metabolism of FLUN in humans, resembled more than in female rats and in dogs than that in male rats. 5. The present in vitro results are compared with data of previous in vivo studies in rats and dogs. The use of subcellular fractions and/or isolated hepatocytes for the study of species differences in the biotransformation of xenobiotics is discussed.

A predictive model for substrates of cytochrome P450-debrisoquine (2D6).

Molecular modeling techniques were used to derive a predictive model for substrates of cytochrome P450 2D6, an isozyme known to metabolize only compounds with one or more basic nitrogen atoms. Sixteen substrates, accounting for 23 metabolic reactions, with a distance of either 5 A ("5-A substrates", e.g., debrisoquine) or 7 A ("7-A substrates", e.g., dextromethorphan) between oxidation site and basic nitrogen atom were fitted into one model by postulating an interaction of the basic nitrogen atom with a negatively charged carboxylate group on the protein. This acidic residue anchors and neutralizes the positively charged basic nitrogen atom of the substrates. In case of "5-A substrates" this interaction probably occurs with the carboxylic oxygen atom nearest to the oxidation site, whereas in the case of "7-A substrates" this interaction takes place at the other oxygen atom. Furthermore, all substrates exhibit a coplanar conformation near the oxidation site and have negative molecular electrostatic potentials (MEPs) in a part of this planar domain approximately 3 A away from the oxidation site. No common features were found in the neighbourhood of the basic nitrogen atom of the substrates studied so that this region of the active site can accommodate a variety of N-substituents. Therefore, the substrate specificity of P450 2D6 most likely is determined by the distance between oxidation site and basic nitrogen atom, by steric constraints near the oxidation site, and by the degree of complementarity between the MEPs of substrate and protein in the planar region adjacent to the oxidation site.(ABSTRACT TRUNCATED AT 250 WORDS)

Pharmacokinetics of oral antifungals and their clinical implications.

Orally active antifungals have different physicochemical and pharmacokinetic properties. Itraconazole is a broad-spectrum triazole antifungal with pronounced lipophilicity. This property determines to a large extent the pharmacokinetics of itraconazole and differentiates it from the hydrophilic bistriazole antifungal, fluconazole. The pharmacokinetics of itraconazole in man are characterised by good oral absorption (when taken with a meal), an extensive tissue distribution with tissue concentrations many times higher than in plasma, a relatively long elimination half-life of about one day, and biotransformation into a large number of metabolites. Distribution studies have shown that therapeutically active levels of intraconazole are maintained much longer in some infected tissues than in plasma. For instance, active levels persist for four days in the vaginal epithelium after a one-day treatment and for four weeks in the stratum corneum of the skin after treatment has been stopped. These unique distribution characteristics may explain why itraconazole with relatively low plasma concentrations (but with high tissue concentrations) is as effective as fluconazole. Fluconazole interacts with cytochrome P450-dependent enzyme activities in hepatic microsomes of rats and mice. These effects in rodents are seen at plasma and liver concentrations of fluconazole comparable to those obtained in man at therapeutic dose levels. Unlike fluconazole, itraconazole does not interfere with mammalian drug-metabolising enzymes, minimising the risk of interaction with concomitantly administered drugs. These pharmacokinetic properties may contribute to the high efficacy and safety of itraconazole in patients with various mycotic infections.

Biotransformation of sufentanil in liver microsomes of rats, dogs, and humans.

The biotransformation of sufentanil (SUF), an analog of the synthetic opioids fentanyl and alfentanil, was investigated in liver microsomes of rats, dogs, and humans. The drug was extensively metabolized and the metabolism was found to be very similar, both kinetically and metabolically, in the three species. The initial metabolism of SUF occurred monophasically in man and dog and biphasically in the rat over a concentration range of 0.13-20.1 microM. The apparent Vm values were 7.30 and 6.15 nmol metabolized.min-1.mg protein-1, and the apparent Km values were 4.98 microM and 15.2 microM for dog and human microsomes, respectively. In rat microsomes, apparent Km values were 0.10 and 20.8 microM, and the apparent Vm values were 0.10 and 7.32 nmol metabolized.min-1.mg protein-1 for the high and low affinity site, respectively. The major metabolic pathways were similar in the three species and included oxidative N-dealkylation at the piperidine nitrogen, oxidative N-dealkylation of the piperidine ring from the phenylpropanamide nitrogen, oxidative O-demethylation, and aromatic hydroxylation. Desmethyl-SUF was formed at the shorter incubation times but quickly metabolized into secondary metabolites. The major metabolites which could be detected at the end of the incubation were N-[4-(methoxymethyl)-4-piperidinyl]-N-phenylpropanamide, N-[4-(hydroxymethyl)-4-piperidinyl]-N-phenylpropanamide, and N-phenylpropanamide. The relevance of the in vitro results is discussed in relation to previous in vivo studies of the metabolism of SUF in rats, dogs, and humans.

Induction potential of fluconazole toward drug-metabolizing enzymes in rats.

The induction of drug-metabolizing enzymes in rat liver was studied after subchronic administration of the new triazole antifungal agent fluconazole. The administered doses were 10, 40, and 160 mg/kg per day for 7 days. Fluconazole behaved as a high-magnitude inducer and significantly increased cytochrome P-450 concentrations already at 10 mg/kg (+42%). Cytochrome P-450 induction by fluconazole was dose dependent and reached a value of 302% of the control value at the dose of 160 mg/kg. The induction effects on cytochrome P-450 were also reflected in the drug-metabolizing enzyme activities in hepatic microsomes of pretreated rats. Fluconazole (160 mg/kg per day) preferentially induced the demethylase activities of N,N-dimethylaniline and p-nitroanisole to 258 and 281% of the control values, respectively. The detoxification enzyme UDP-glucuronosyltransferase was significantly lowered by fluconazole at the highest dose. A possible link between the induction potential and the pharmacokinetic properties of triazole antifungal agents is discussed.

The clinical pharmacokinetics of itraconazole: an overview.

Itraconazole (R 51211) is the prototype of a class of triazole antifungals characterized by a high lipophilicity. This property determines to a large extent the pharmacokinetics of itraconazole and differentiates it from the hydrophilic triazole antifungal fluconazole. The pharmacokinetics of itraconazole in man are characterized by a good oral absorption, an extensive tissue distribution with tissue concentrations many times higher than in plasma, a relatively long elimination half-life of about one day and a biotransformation into a large number of metabolites. One of them, hydroxy-itraconazole, is antifungally active and explains why antifungal plasma levels, when measured by bioassay, are about three times the itraconazole levels measured by a specific HPLC-method. Distribution studies have shown that therapeutically active levels of itraconazole are maintained much longer in some infected tissues than in plasma. For instance, active levels persist for four days in the vaginal epithelium after a one-day treatment and for 3 weeks in the stratum corneum of the skin after treatment has been stopped. Unlike fluconazole, itraconazole does not interfere with mammalian drug metabolizing enzymes, minimizing the risk of interaction with concomitantly administered drugs. These pharmacokinetic properties may contribute to the high efficacy and safety of itraconazole in patients with various mycotic infections. New pharmaceutical formulations are being explored in order to broaden the application field of itraconazole to intravenous and oral therapy of patients with malabsorption.

Is the metabolism of alfentanil subject to debrisoquine polymorphism? A study using human liver microsomes.

The present study was designed to investigate whether the metabolism of the opiate analgesic alfentanil in humans is subject to the debrisoquine 4-hydroxylation polymorphism. The role of a specific cytochrome P-450 form, debrisoquine 4-hydroxylase, in the metabolism of alfentanil was investigated by competitive inhibition experiments over the concentration range 4-100 microM. Alfentanil was incubated with human liver microsomes in the presence of an NADPH-generating system. Alfentanil and its major metabolites were quantified in the incubates by reversed phase high-performance liquid chromatography (HPLC). Alfentanil was rapidly metabolized, yielding noralfentanil as the main metabolite. Kinetically, alfentanil metabolism occurred monophasically and the kinetic parameters were 22.8 microM for Km app and 3.86 nmol alfentanil metabolized min-1.mg protein-1 for Vm app. Debrisoquine was a weak, noncompetitive inhibitor of alfentanil metabolism and of the formation of its major metabolites, with Ki values between 2.00 and 3.21 mM. It can be concluded that alfentanil is not metabolized in vitro by the human cytochrome P-450 form involved in debrisoquine 4-hydroxylation; therefore, the in vivo disposition of the drug is most likely not affected by deficiency of this enzyme.

Metabolism of alfentanil by isolated hepatocytes of rat and dog.

1. The biotransformation of 3H-alfentanil was studied using suspension cultures of isolated hepatocytes of male and female rats and of dogs. 2. In hepatocytes of the male rat, alfentanil was readily metabolized, following linear Michaelis-Menten kinetics over the concentration range 5-400 microM. The metabolism was strongly inhibited by the cytochrome P-450 inhibitors metyrapone, alpha-naphthoflavone and piperonyl butoxide. 3. The major metabolites of alfentanil, which were formed in suspension cultures of male rat hepatocytes, were identified by h.p.l.c. co-chromatography and by mass spectrometry and included N-[4-(hydroxymethyl)-4-piperidinyl]-N-phenylpropanamide, N-[4-(methoxymethyl)-4-piperidinyl]-N-phenylpropanamide or noralfentanil and N-[1-[2-(4-ethyl-4,5-dihydro-5-oxo-1-H-tetrazol-1-yl)ethyl]- 4-(hydroxymethyl)-4-piperidinyl]-N-phenylpropanamide or desmethylalfentanil. 4. The major in-vitro metabolic pathways of alfentanil in hepatocytes of the three sources were oxidative N-dealkylation at the piperidine nitrogen and oxidative O-demethylation at the methoxymethyl moiety.

Interaction of miconazole, ketoconazole and itraconazole with rat-liver microsomes.

The interaction of the antimycotics miconazole, ketoconazole and itraconazole with liver microsomes from untreated rats or from rats pretreated with phenobarbital or 3-methylcholanthrene, gave rise to type II difference spectra. The interactions of the antimycotics with control, phenobarbital-induced or 3-methylcholanthrene-induced microsomes were biphasic, except for the monophasic binding of ketoconazole to phenobarbital-induced microsomes. The N-demethylation of N,N-dimethylaniline, the O-demethylation of p-nitroanisole and the hydroxylation of aniline in microsomes from untreated and inducer-treated rats were lowered by miconazole and ketoconazole, the former being the more potent inhibitor. Control microsomes were less sensitive than induced microsomes. Itraconazole was almost devoid of inhibitory properties. The three antimycotics were non-competitive (mixed) inhibitors of enzyme activities in phenobarbital-induced microsomes. The Ki values were of the same order of magnitude as the Ks values, except for itraconazole. For the latter drug, Ki values were much greater than could be expected from the spectral studies. It is concluded that the antimycotics affect microsomal enzyme activities via a direct interaction of an azole-nitrogen with the haem group of cytochrome P-450. The interaction with mammalian cytochrome P-450 decreases from miconazole greater than ketoconazole much greater than itraconazole and is much weaker than the interaction of the antimycotics with yeast cytochrome P-450.

Induction potential of antifungals containing an imidazole or triazole moiety. Miconazole and ketoconazole, but not itraconazole are able to induce hepatic drug metabolizing enzymes of male rats at high doses.

Male Wistar rats were dosed with miconazole, ketoconazole and itraconazole by gastric intubation once daily for up to 7 days. A dose- and time-dependent induction of the hepatic drug metabolizing enzyme system was observed for miconazole and ketoconazole, while itraconazole proved to be devoid of inductive properties even at the highest dose studied (160 mg/kg). No effect on drug metabolizing enzymes could be demonstrated for either drug at a dose level of 10 mg/kg, which is just above the antifungally active dose. At a dose of 40 mg/kg, miconazole, but not ketoconazole, significantly increased cytochrome P-450 content. At the highest dose of 160 mg/kg, both miconazole and ketoconazole increased the relative liver weight, the cytochrome P-450- and b5-content and NADPH-cyt c-reductase. Furthermore, miconazole, but not ketoconazole, increased specific microsomal aminopyrine and N,N-dimethylaniline N-demethylase activity, p-nitroanisole O-demethylase activity and UDP-glucuronyltransferase activity towards 4-nitrophenol while the specific aniline hydroxylase activity was unaffected. Ketoconazole at 160 mg/kg only induced O-demethylase activity and UDP-glucuronyltransferase activity, while it lowered the specific activities towards the other substrates. Miconazole was a relatively more potent inducer when compared to ketoconazole. Both drugs displayed biphasic effects on the mixed-function oxidase activities, which were lowered after acute administration (160 mg/kg, 1 hr before death) and were induced when determined after 23 hr had elapsed or after multiple dosage. Both drugs bound strongly to their respective induced cytochromes, giving rise to type II difference spectra, and inhibited the O-demethylase activity of the induced microsomes with an I50 of 5.2 microM for miconazole and 15.1 microM for ketoconazole. On the basis of a comparison of the enzymatic activities induced by both antimycotics with those induced by PB or 3-MC, it was concluded that miconazole behaved as a PB-type inducer, whereas ketoconazole did not belong to either category of inducers. A comparison of electrophoretograms of microsomes from different origins on SDS-PAGE revealed that miconazole increased the concentration of several proteins, whereas ketoconazole selectively induced a protein with Mr of 47,800. The protein pattern in the 50 kDa region of miconazole-induced microsomes resembled that of PB-microsomes qualitatively.

The effect of progesterone on hemoglobin synthesis in suspension cultures of fetal erythroid cells from calf liver.

When fetal calf liver erythroid cells were incubated in the presence of small amounts of progesterone (10(-7)-10(-8) M), the hemoglobin synthesis in these cells was significantly increased. The increase in the amount of radioactivity in de novo synthesized hemoglobins could be demonstrated when techniques such as isoelectric focusing, chromatography on DEAE-cellulose and gel chromatography on Sephadex G-100 were used to isolate the hemoglobin fraction. Using the latter technique, it was shown that the synthesis of cytoplasmic non-hemoglobin proteins in erythroid-cell lysates was also stimulated by progesterone. The presence of hepatocytes in culture nullified the hormone action. It was necessary that progesterone was present during the first hours of culture. Delayed addition of the steroid to the cells had no effect on hemoglobin synthesis. Erythropoietin was necessary to obtain stimulation by progesterone. These results suggest that the target cell of the hormone is an erythropoietin-sensitive cell. High concentrations of progesterone (10(-4) M) strongly inhibited hemoglobin synthesis in fetal calf erythroid cells. Culture of cells under this condition, however, gives rise to a cell population that preferentially synthesizes adult hemoglobin. Our results suggest that in the erythropoietic calf liver, high concentrations of progesterone may preferentially stimulate adult hemoglobin synthesis, or that those cells which have a high capacity to synthesize adult hemoglobins are less sensitive to toxic concentrations of the hormone. The effects of stimulation of hemoglobin synthesis in fetal calf erythroid cells occur at hormone concentrations that suggest a possible physiological role of progesterone in fetal, and eventually also in maternal, erythropoiesis.