Identification of a null allele of CYP2C9 in an African-American exhibiting toxicity to phenytoin

Cytochrome P450 (CYP) 2C9 is the principal enzyme responsible for the metabolism of numerous clinically important drugs. Two polymorphic alleles CYP2C9*2 and CYP2C9*3 have been documented which affect the metabolism and clinical toxicity of drugs such as phenytoin, warfarin, glipizide, and tolbutamide. The present study reports the first example of a null polymorphism in CYP2C9. This mutation dramatically affects the half-life and clinical toxicity of phenytoin. The study subject was a female African-American presented to the emergency department with phenytoin toxicity evidenced by mental confusion, slurred speech, memory loss and the inability to stand. She exhibited extremely poor clearance of phenytoin with an elimination half-life of approximately 13 days. Genotyping studies demonstrated that the patient did not possess any known variant CYP2C9 alleles. Phenytoin is metabolized to a minor extent by the polymorphic CYP2C19, but this individual did not possess any variant CYP2C19 alleles. Sequencing studies revealed that the individual was homozygous for a new CYP2C9 allele (CYP2C9*6) with the deletion of an adenine at base pair 818 of the cDNA. The clearance of phenytoin in this individual is estimated to be approximately 17% of that observed in normal patients. The frequency of this allele was 0.6% (95% confidence limits of 0.1 to 3.5%) in 79 African-Americans and 0% (95% confidence limits of 0 to 1.1%) in 172 Caucasians. The study also demonstrates the severe clinical consequences to patients with a null mutation in CYP2C9 after treatment with normal doses of phenytoin.

A novel transversion in the intron 5 donor splice junction of CYP2C19 and a sequence polymorphism in exon 3 contribute to the poor metabolizer phenotype for the anticonvulsant drug S-mephenytoin

Cytochrome P-450 (CYP) 2C19 is responsible for the metabolism of a number of therapeutic agents such as S-mephenytoin, omeprazole, proguanil, certain barbiturates, diazepam, propranolol, citalopram and imipramine. Genetic polymorphisms in this enzyme are responsible for the poor metabolizers (PM) of mephenytoin, which represent approximately 13-23% of Asians and 3-5% of Caucasians. Several polymorphisms contribute to this phenotype. We have isolated two new allelic variants that contribute to the PM phenotype in Caucasians. CYP2C19*7 contained a single T --> A nucleotide transversion in the invariant GT at the 5' donor splice site of intron 5. The second PM allele, CYP2C19*8, consisted of a T358C nucleotide transition in exon 3 that results in a Trp120Arg substitution. In a bacterial expression system, CYP2C198 protein exhibited a dramatic (approximately 90% and 70%) reduction in the metabolism of S-mephenytoin and tolbutamide, respectively, when compared with the wild-type CYP2C191B protein. Restriction fragment length polymerase chain reaction tests were developed to identify the new allelic variants.

Pharmacokinetics of chlorpheniramine, phenytoin, glipizide and nifedipine in an individual homozygous for the CYP2C9*3 allele

Genetic polymorphisms in the cytochrome P450 (CYP) family are widely known to contribute to interindividual differences in the pharmacokinetics of many drugs. Several alleles for the CYP2C9 gene have been reported. Individuals homozygous for the Leu359 variant (CYP2C9*3) have been shown to have significantly lower drug clearances compared with Ile359 (CYP2C9*1) homozygous individuals. A male Caucasian who participated in six bioavailability studies in our laboratory over a period of several years showed extremely low clearance of two drugs: phenytoin and glipizide (both substrates of CYP2C9), but not for nifedipine (a CYP3A4 substrate) and chlorpheniramine (a CYP2D6 substrate). His oral clearance of phenytoin was 21% of the mean of the other 11 individuals participating in the study, and his oral clearance of glipizide, a second generation sulfonylurea structurally similar to tolbutamide, was only 188% of the mean of the other 10 individuals. However, his oral clearance of nifedipine and chlorpheniramine did not differ from individuals in other studies performed at our laboratories. An additional blood sample was obtained from this individual to determine if he possessed any of the known CYP2C9 or CYP2C19 allelic variants that would account for his poor clearance of the CYP2C9 substrates (phenytoin and glipizide) compared with the CYP3A4 (nifedipine) and CYP2D6 (chlorpheniramine) substrates. The results of the genotype testing showed that this individual was homozygous for the CYP2C9*3 allele and did not possess any of the known defective CYP2C19 alleles. This study establishes that the Leu359 mutation is responsible for the phenytoin and glipizide/tolbutamide poor metabolizer phenotype.

Role of cardiac troponin I in the evaluation of myocardial injury

Cardiac troponin I (cTnl) is highly specific for cardiac muscle. In this study, we compared the utility of CK and CK-MB index versus cTnl in the assessment of myocardial infarction in 155 patients being evaluated for myocardial damage. As a cardiac marker for MI, Troponin I seems to be superior to CK-MB. In the subset of patients with renal disease, cTnl has definite advantages over CK-MB. In addition, the use of cTnl has the potential to replace the measurement of lactate dehydrogenase isoenzymes.

Identification of new human CYP2C19 alleles (CYP2C19*6 and CYP2C19*2B) in a Caucasian poor metabolizer of mephenytoin

A genetic polymorphism in the metabolism of the anticonvulsant drug S-mephenytoin has been attributed to defective CYP2C19 alleles. This genetic polymorphism displays large interracial differences with the poor metabolizer (PM) phenotype representing 2-5% of Caucasian and 13-23% of Oriental populations. In the present study, we identified two new mutations in CYP2C19 in a single Swiss Caucasian PM outlier (JOB 1) whose apparent genotype (CYP2C19*1/CYP2C19*2) did not agree with his PM phenotype. These mutations consisted of a single base pair mutation (G395A) in exon 3 resulting in an Arg132-->Gln coding change and a (G276C) mutation in exon 2 resulting in a coding change Glu92-->Asp. However, the G276C mutation and the G395A mutation resided on separate alleles. Genotyping tests of a family study of JOB1 showed that the exon 2 change occurred on the CYP2C19*2 allele, which also contained the known splice mutation in exon 5 (this variant is termed CYP2C19*2B to distinguish it from the original splice variant now termed CYP2C19*2A). The exon 3 mutation resided on a separate allele (termed CYP2C19*6). In all other respects this allele was identical to one of two wild-type alleles, CYP2C19*1B. The incidence of CYP2C19*6 in a European Caucasian population phenotyped for mephenytoin metabolism was 0/344 (99% confidence limits of 0 to 0.9%). Seven of 46 Caucasian CYP2C19*2 alleles were CYP2C19*2B(15%) and 85% were CYP2C19*2A. The Arg132Gln mutation was produced by site-directed mutatgenesis and the recombinant protein expressed in a bacterial cDNA expression system. Recombinant CYP2C19 6 had negligible catalytic activity toward S-mephenytoin compared with CYP2C19 1B, which is consistent with the conclusion that CYP2C19*6 represents a PM allele. Thus, the new CYP2C19*6 allele contributes to the PM phenotype in Caucasians.

An additional defective allele, CYP2C19*5, contributes to the S-mephenytoin poor metabolizer phenotype in Caucasians

The metabolism of the anticonvulsant drug mephenytoin exhibits a genetic polymorphism in humans. This polymorphism exhibits marked racial heterogeneity, with the poor metabolizer PM phenotype representing 13-23% of oriental populations, but only 2-5% of Caucasian populations. Two defective CYP2C19 alleles (CYP2C19*2 and CYP2C19*3) have been described, which account for more than 99% of Oriental poor metabolizer alleles but only approximately 87% of Caucasian poor metabolizer alleles. Therefore, additional defects presumably contribute to the poor metabolizer in Caucasians. Recent studies have found a third mutation CYP2C19*4, which accounts for approximately 3% of Caucasian poor metabolizer alleles. A fourth rare mutation (CYP2C19*5A) (C99,A991,Ile331;C1297T,Arg433-->Trp) resulting in an Arg433 to Trp substitution in the heme-binding region has been reported in a single Chinese poor metaboliser outlier belonging to the Bai ethnic group. The present study identifies a second variant allele CYP2C19*5B (C99-->T; A991-->G, Ile331-->Val; C1297-T, Arg433-->Trp in one of 37 Caucasian poor metabolizers. The frequency of the CYP2C19*5 alleles is low in Chinese (approximately 0.25% in the Bai ethnic group) and Caucasians (< 0.9%). However, these alleles contribute to the poor metabolizer phenotype in both ethnic groups and increases the sensitivity of the genetic tests for identifying defective alleles to approximately 100% in Chinese poor metabolizers and 92% in Caucasian poor metabolizers genotyped in our laboratory. The Arg433 to Trp mutation in the heme-binding region essentially abolishes activity of recombinant CYP2C19*5A toward S-mephenytoin and tolbutamide, which is consistent with the conclusion that CYP2C19*5 represents poor metabolizer alleles.

Isolation of a new canine cytochrome P450 CDNA from the cytochrome P450 2C subfamily (CYP2C41) and evidence for polymorphic differences in its expression

Two members of the canine cytochrome P4502C subfamily [CYP2C21 and CYP2C41 (sequence has been submitted to Genbank with accession number AF016248)] were cloned from three beagle liver cDNA libraries. The two canine CYP2C cDNAs exhibited 70% nucleotide and amino acid identity as well as 74-83% nucleotide and 67-76% amino acid identity with the human CYP2Cs. Canine CYP2C41 is more homologous to the human CYP2Cs than CYP2C21. The two canine CYP2C cDNAs exhibited a slightly lower nucleotide and amino acid identity (66-77%) with the rat P450CYPs, 2C11 and 2C12. Reverse transcription-polymerase chain reaction-based restriction enzyme tests for CYP2C21 and 2C41 mRNAs as well as polymerase chain reaction-based tests for genomic DNA were developed. CYP2C21 cDNA was present in the livers of all dogs tested (N = 9), but CYP2C41 was present in only 1 of the 9 (11%). Genomic tests found that the gene coding for CYP2C21 was also present in all dogs tested (N = 25), of which 15 were beagles and 10 mixed breeds. In contrast, the gene coding for CYP2C41 was present in only 16% (4 out of 25) of the dogs. An even distribution of the CYP2C41 gene was found between the sexes and between beagles and mixed breeds. This unique polymorphism in the canine CYP2C subfamily may be a source of variability in the metabolic clearance in dogs of xenobiotics that are metabolized by the cytochrome P450 2C subfamily of enzymes.

A new genetic defect in human CYP2C19: mutation of the initiation codon is responsible for poor metabolism of S-mephenytoin

The 4'-hydroxylation of the S-enantiomer of the anticonvulsant drug mephenytoin exhibits a genetic polymorphism in humans. This polymorphism shows marked interracial heterogeneity, with the poor metabolizer (PM) phenotype representing 2 to 5% of Caucasian and 13 to 23% of Asian populations. Two defective CYP2C19 alleles, CYP2C19*2 and CYP2C19*3, have been described which account for approximately 87% of Caucasian and > 99% of Oriental PM alleles. The present study identifies a new allele (CYP2C19*4) in Caucasian PMs which contains an A-->G mutation in the initiation codon. A new polymerase chain reaction-restriction fragment length polymorphism genotyping test was developed, and the incidence of this allele was examined in a European Caucasian population which had been phenotyped for mephenytoin metabolism. One of nine putative PMs was heterozygous for CYP2C19*2/CYP2C19*4, which suggests that CYP2C19*4 represents a defective allele. Six of the seven remaining putative PMs available for genotyping were explained by CYP2C19*2. The frequency of the CYP2C19*4 allele in Caucasians was 0.6%. An additional Caucasian PM from a separate study was also heterozygous for CYP2C19*2 and CYP2C19*4. To verify that CYP2C19*4 represented a defective CYP2C19 allele, the initiation codon of the normal CYP2C19*1 cDNA was mutated to a GTG, and both cDNAs were expressed in yeast. Recombinant CYP2C19 protein was detected by Western blot analysis of colonies transformed with CYP2C19*1 cDNA, but not in those transformed with CYP2C19*4 cDNA. The two cDNAs were also used in an in vitro coupled transcription/translation assay. CYP2C19 protein was translated only from the CYP2C19*1 allele. These data indicate that CYP2C19*4 represents a new PM allele.

Differences in the incidence of the CYP2C19 polymorphism affecting the S-mephenytoin phenotype in Chinese Han and Bai populations and identification of a new rare CYP2C19 mutant allele

The incidence of the S-mephenytoin polymorphism was compared in two Chinese ethnic groups, Han (n = 101) and Bai (n = 202) by phenotype and genotype analysis. The frequency of poor metabolizers (PMs) in Han vs. Bai subjects was 19.8% vs. 13.4%. Han subjects had a higher frequency of the mutant CYP2C19m1 allele (0.366 vs. 0.257, P < .01) and a lower frequency of the wild-type allele (0.559 vs. 0.688, P < .01) than Bai subjects, which is consistent with the difference in the frequencies of PMs between the two ethnic groups. This results in a lower percentage of homozygous wild-type extensive metabolizers of mephenytoin (EMs) in Han subjects than in Bai subjects (40% vs. 59%, P = .005). Therefore, Han subjects may be more susceptible than Bai subjects to the drugs metabolized by the CYP2C19 enzyme. Ratios of urinary S/R-mephenytoin in homozygous EMs were lower than those of heterozygous EMs for both Han and Bai subjects, which shows a gene-dosage effect. Genotype analysis identified all but one PM as homozygous or heterozygous for the two known mutant CYP2C19m1 and/or CYP2C19m2 alleles. A single Bai PM outlier was shown to be heterozygous for CYP2C19m1 and a new mutant CYP2C19 allele containing a single amino acid change of Arg433 --> Trp433. A genotyping test demonstrated that only this one individual carried this rare allele (frequency of 0.0025 in Bai subjects).

Identification of a new genetic defect responsible for the polymorphism of (S)-mephenytoin metabolism in Japanese

A genetic polymorphism in the metabolism of the anticonvulsant drug (S)-mephenytoin has been well documented in humans. There are marked interracial differences in the frequency of the poor metabolizer phenotype, which comprises 2-5% of Caucasian but 18-23% of Asian populations. We have recently reported that the principal genetic defect responsible for the poor metabolizer phenotype is a single-base pair mutation in exon 5 of CYP2C19 (CYP2C19m), which accounts for approximately 75-83% of the defective alleles in both Japanese and Caucasians subjects. In the present study, we have identified a new mutation (CYP2C19m2) in Japanese poor metabolizers, consisting of a guanine to adenine mutation at position 636 of exon 4 of CYP2C19, which creates a premature stop codon. Genotyping of seven Japanese poor metabolizers who were not homozygous for the previously described CYP2C19m defect (now designated CYP2C19m1) indicated that they were either homozygous for the new defect (CYP2C19m2/CYP2C19m2) or heterozygous (CYP2C19m1/CYP2C19m2) for the two defects. CYP2C19m1 accounts for 25 of 34 alleles in Japanese poor metabolizers, whereas CYP2C19m2 accounts for the remaining nine alleles. Hence, CYP2C19m1 and CYP2C19m2 explain 100% of the available Japanese poor metabolizers (34 alleles). In contrast, the CYP2C19m2 defect was not detected in nine Caucasian poor metabolizers (83% of available poor metabolizer alleles were CYP2C19m1), indicating the existence of another, as yet unidentified, mutation. Genetic testing of the families of two Japanese poor metabolizer probands showed that coinheritance of the CYP2C19m1 and CYP2C19m2 alleles was concordant with the autosomal recessive inheritance of the poor metabolizer phenotype.

The major genetic defect responsible for the polymorphism of S-mephenytoin metabolism in humans

The metabolism of the anticonvulsant drug mephenytoin exhibits a genetic polymorphism in humans, with the poor metabolizer trait being inherited in an autosomal recessive fashion. There are large interracial differences in the frequency of the poor metabolizer phenotype, with Oriental populations having a 5-fold greater frequency compared to Caucasians. Impaired metabolism of mephenytoin and a number of other currently used drugs results from a defect in a cytochrome P450 enzyme recently identified as CYP2C19. Attempts over the past decade to define the molecular genetic basis of the polymorphism have, however, been unsuccessful. We now report that the principal defect in poor metabolizers is a single base pair (G-->A) mutation in exon 5 of CYP2C19, which creates an aberrant splice site. This change alters the reading frame of the mRNA starting with amino acid 215 and produces a premature stop codon 20 amino acids downstream, which results in a truncated, non-functional protein. We further demonstrate that 7/10 Caucasian and 10/17 Japanese poor metabolizers are homozygous for this defect, indicating that this is the major defect responsible for the poor metabolizer phenotype. Finally, the familial inheritance of the deficient allele was found to be concordant with that of the phenotypic trait.

Gene structure and upstream regulatory regions of human CYP2C9 and CYP2C18

There is a genetic polymorphism in humans in the metabolism of S-mephenytoin which has been suggested to be mediated by either CYP2C18 or CYP2C9. We have isolated genomic clones for CYP2C9 and CYP2C18 from the liver of an individual phenotyped in vitro as an extensive metabolizer of S-mephenytoin. Analysis of the genes reveals nine coding exons spanning approximately 55 kb. The intron-exon organization was similar to that of other members of the CYP2C subfamily. Analysis of 2200 bp of 5' upstream sequence for CYP2C9 and 1300 bp 5' upstream sequence for CYP2C18 reveals canonical TATA boxes situated 57 bp upstream from the first codon, multiple consensus sequences for glucocorticoid regulatory elements, and identification of a 15 base sequence with high homology to a 5'-flanking sequence responsible for barbiturate-inducible expression of P450BM-3 in Bacillus megaterium. The upstream region for CYP2C9 was highly homologous (75%) to that of human CYP2C8 through most of the 2200 bp sequenced, but the upstream region of CYP2C18 was similar to CYP2C8 and CYP2C9 for only the first 200 bases. The availability of the sequences of the upstream regions and intron-exon junctions of CYP2C9 and CYP2C18 will allow future analysis of these genes in humans which differ in their ability to metabolize S-mephenytoin and other drugs.

Transient activation of c-myc protooncogene expression in Leydig cells by human chorionic gonadotropin

This study evaluated the effects of in vivo administration of human chorionic gonadotropin (hCG) on c-myc oncogene expression in Leydig cells. Sprague-Dawley rats (46-50 days old) were treated with hCG (10 units, i.p.), and purified Leydig cells were isolated 1-24 h later. HCG caused a transient elevation of c-myc mRNA in 4 h and returned to normal or lower than normal levels at 24 h. There was no change in c-fos or beta-actin mRNA levels. Our results suggest that the growth promoting effects of hCG on Leydig cells may be mediated by the transient expression of c-myc protooncogene.

Hormonal regulation of type I insulin-like growth factor receptors of Leydig cells in hypophysectomized rats

The effects of hCG and various pituitary hormones on type I insulin-like growth factor (IGF) receptors of purified Leydig cells of hypophysectomized rats were studied. The number of type I IGF receptors of Leydig cells obtained from hypophysectomized rats (18.0 +/- 1.5 fmol/10(6) cells) was lower than that in normal rats (54.6 +/- 5.3 fmol/10(6) cells; P less than 0.05). After a single administration of hCG (10 U, ip), specific binding of [125I]IGF-I to purified Leydig cells increased 3-fold. Scatchard analyses of the binding data suggested that increased binding was the result of an increase in receptor number, whereas binding affinity remained unaltered. Type I IGF receptor increased within 12 h and remained persistently elevated 96 h after hCG treatment. Administration of hCG (10 U, ip) daily for 5 days increased type I IGF receptor levels to 73.2 +/- 8 fmol/10(6) cells (P less than 0.001). FSH caused a small but significant increase in type I IGF receptors. Concomitant administration of FSH and hCG further enhanced IGF-I-binding capacity. IGF-I-binding affinity of Leydig cells treated with FSH or FSH plus LH was not significantly different from that in the control hypophysectomized rats. Daily administration of GH for 5 days also upregulated type I IGF receptors, whereas PRL had no effect. FSH, GH, and PRL administration had no effect on serum testosterone levels. Serum testosterone levels increased to 3.99 +/- 0.35 ng/ml after 5 days of treatment with hCG. Concomitant administration of FSH and hCG caused a further increased in serum testosterone levels (6.13 +/- 0.46 ng/ml; P less than 0.01). The present study suggests that type I IGF receptors of Leydig cells can be up-regulated by LH, FSH, and GH. However, hCG/LH seems to be the most important factor in maintaining and regulating type I IGF receptors of Leydig cells. Steroidogenic and growth-promoting effects of hCG and pituitary hormones on Leydig cells may be mediated by increased type I IGF receptors.

Type I IGF receptors of Leydig cells are upregulated by human chorionic gonadotropin

The effects of human chorionic gonadotropin (hCG) on type I insulin-like growth factor (IGF) receptors of purified Leydig cells were investigated. Sprague-Dawley rats (50 day-old) were treated with a single injection of hCG 10 units intraperitoneally, type I IGF receptors were then determined daily for 4 days. HCG caused a rapid increase in type I IGF receptors within 24 h, which returned to basal by 72 h. There was no significant change in binding affinity. Our present study indicates that type I IGF receptors of Leydig cells are up regulated by hCG, and this may be one mechanism by which hCG and IGF-I interact to enhance Leydig cell steroidogenesis.

Transforming growth factor-beta inhibits Leydig cell steroidogenesis in primary culture

The effects of transforming growth factor (TGF) on Leydig cell steroidogenesis in primary culture were investigated. Basal testosterone levels were 3.7 +/- 0.54 ng/ml (mean +/- SE, N = 7). In the presence of hCG (10 ng/ml), testosterone levels increased to 22.77 +/- 3.05 ng/ml. TGF-beta caused a dose dependent inhibition of hCG-stimulated testosterone formation but without effects on basal levels. TGF-beta also inhibited 8-bromo cyclic AMP-induced testosterone formation and hCG-stimulated cyclic AMP formation. In contrast, TGF-alpha had no effect on either basal or hCG-stimulated testosterone formation and did not modify the inhibitory effect of TGF-beta. Present study indicates that TGF-beta can modulate Leydig cell steroidogenesis.

Inconsistent effects of all-trans retinoic acid on different clones of chemically transformed rat liver epithelial cells

The effects of all-trans retinoic acid (RA) on the growth and biochemical properties of five clonal strains of neoplastically transformed rat liver epithelial cells were studied. These cell strains were derived clonally from a single line of normal diploid rat liver epithelial cells that had been transformed by treatment with N-methyl-N'-nitro-N-nitrosoguanidine. The results show that RA induces inconsistent alterations in selected phenotypic properties of these five different cell strains. Retinoic acid either depressed, enhanced or produced no effect on the colony-forming ability in soft agar, on the activity of gamma-glutamyl transpeptidase, on the amount of cell-associated fibronectin, and on the binding capacity of 125I-epidermal growth factor (EGF). The only consistent correlation observed among cell strains was between the cellular ability to grow in soft agar and the amount of cell-associated fibronectin. Enhancement of anchorage-independent growth by retinoic acid was not mediated through changes in the number of EGF receptors. Our data demonstrate that the responses to retinoic acid of clonal subpopulations of chemically transformed rat liver epithelial cells are inconsistent, even when the clonal subpopulations are derived from a common precursor.

Epidermal growth factor (EGF) stimulates EGF receptor synthesis

Epidermal growth factor (EGF) binds to the extracellular domain of a specific 170,000-dalton transmembrane glycoprotein; this results in rapid removal of both ligand and receptor from the cell surface. In WB cells, a rat hepatic epithelial cell line, ligand-directed receptor internalization leads to receptor degradation. We tested whether the EGF receptor was replenished at a constitutive or enhanced rate following EGF binding by immunoprecipitating biosynthetically labeled EGF receptor from cells cultured with [35S]methionine. EGF stimulated receptor synthesis within 2 h in a dose-dependent manner; this was particularly evident when examining the nascent form of the receptor. To determine the site of EGF action, total WB cell RNA was transferred to nitrocellulose paper after electrophoresis and was hybridized to cDNA probes from both the external and cytoplasmic coding regions of the human EGF receptor. EGF increased receptor mRNA by 3-5-fold. Therefore, at least in some cells, the surface action of EGF that leads to EGF receptor degradation is counterbalanced by a positive effect on receptor synthesis.

Insulin inhibits the glucocorticoid-mediated increase in hepatocyte EGF binding

Hydrocortisone and dexamethasone produced a time-dependent increase [125I]epidermal growth factor [( 125I]EGF) binding in primary cultures of isolated rat hepatocytes. Maximally effective doses of glucocorticoids resulted in a 70-100% increase in binding. The effect was similar when hepatocytes were maintained on collagen-coated plates or directly on culture dishes. The glucocorticoid-mediated increase in [125I]EGF binding could be detected after 4 h exposure to glucocorticoid and was substantial by 8 h. The major effect of glucocorticoid appeared to be to increase the number of EGF receptors. While insulin (100 nM) had no effect on basal [125I]EGF binding, it significantly inhibited the increase produced by the glucocorticoid. Since the inhibitory effect of insulin was only observed when insulin was added with the inducing glucocorticoid, insulin appears to inhibit an early hydrocortisone-mediated event.

Dimethyl sulfoxide decreases specific EGF binding

Dimethyl sulfoxide (DMSO) stimulates tyrosine phosphorylation of the hepatic EGF receptor in isolated membrane preparations. To determine whether DMSO affects EGF binding, primary cultures of rat hepatocytes were incubated with 1-10% DMSO for 30 min prior to the addition of 125I-EGF. DMSO (1-2%) reduced specific 125I-EGF binding; the effect was maximal (a 40-60% reduction) at 5-7.5% DMSO and was reversed by removing the DMSO. Scatchard analysis showed that the reduction in binding was due to a change in receptor affinity. The decrease in binding was not seen when other, slightly less polar, solvents (eg, acetone and ethanol) were tested. DMSO also reduced 125I-EGF binding to purified rat liver plasma membranes. This reduction was seen in the absence of added ATP and in membranes that had been pretreated with TLCK, a tyrosine kinase inhibitor. Thus, completion of the receptor autophosphorylation reaction was not necessary to effect the change. The data are consistent with a DMSO-induced alteration of receptor conformation that reversibly reduces receptor affinity.