Gene family of male-specific testosterone 16 alpha-hydroxylase (C-P-450(16 alpha)) in mice. Organization, differential regulation, and chromosome localization

Three genes in the testosterone 16 alpha-hydroxylase (C-P-450(16 alpha)) family, ca, cb, and cc, are characterized. The sizes of the genes are approximately 4.5 to 5.2 kilobase pairs, and all three consist of nine exons with junctions at identical sites. Gene ca is identified as the male-specific, androgen-dependent C-P-450(16 alpha) gene in adult mice, since the exonic sequence matched 100% to the cDNA, pc16 alpha-2 (Wong, G., Kawajiri, K., and Negishi, M. (1987) Biochemistry 26, 8683-8690). Gene cb and cc are organized in tandem within 18-kilobase pair DNA. Their encoded P-450s contain an approximate 94% nucleotide sequence similarity to the C-P-450(16 alpha). The high similarity in gene nucleotide sequences, including the introns and flanking regions, suggests a combination of an ancestral gene duplication and gene conversion as a mechanism for evolution of the C-P-450(16 alpha) family. Gene ca shows male-specific expression in mouse kidney as well as in liver; gene cb, neither sex-specific nor androgen-dependent, is seen only in liver; gene cc is not expressed in either adult mouse liver or kidney. Expression of these three genes is not detected in adult mouse lung. It appears, therefore, that the C-P-450(16 alpha) gene family includes a large number of genes whose expressions are differentially regulated. Southern hybridization of C-P-450(16 alpha) cDNA to genomic DNAs from mouse-hamster somatic hybrid cells localizes tentatively this gene family on mouse chromosome 15. The recombination frequency in BXD recombinant inbred mice suggests that the C-P-450(16 alpha) gene family is approximately 16M from the 55-kDa locus.     

Characterization and regulation of sex-specific mouse steroid hydroxylase genes

We characterized the genes of the male-specific mouse steroid 16 alpha-hydroxylase (C-P-45016 alpha) and the female-specific mouse steroid 15 alpha-hydroxylase (P-45015 alpha) within two distinct gene families. In spite of the high structural identities within each family, the expression of the hydroxylase genes is uniquely regulated. Moreover, the other family members encode the P-450s which are structurally very similar to the hydroxylases but are not able to catalyze steroid hydroxylase activities. For example, only a single amino acid substitution creates steroid 15 alpha-hydroxylase activity in another family-member P-450coh, which catalyzes coumarin 7-hydroxylase but little steroid hydroxylase activity. It appears, therefore, that the mouse P-450 gene families evolved through gene duplication and selective mutation to create new P-450s structurally as well as to establish novel regulatory elements for the gene expressions.     

Gene structure and nucleotide sequence for rat cytochrome P-450c

Two clones from rat genomic libraries that contain the entire gene for rat cytochrome P-450c have been isolated. lambda MC4, the first clone isolated from an EcoR1 library, contained a 14-kb insert. A single 5.5-kb EcoR1 fragment from lambda MC4, the EcoR1 A fragment, hybridized to a partial cDNA clone for the 3' end of the cytochrome P-450c mRNA. This fragment was sequenced using the dideoxynucleotide chain termination methodology with recombinant M13 bacteriophage templates. Comparison of this sequence with the complete cDNA sequence of cytochrome P-450MC [Yabusaki et al. (1984) Nucleic. Acids Res. 12, 2929-2938] revealed that the EcoR1 A fragment contained the entire cytochrome P-450c gene with the exception of a 90-bp leader sequence. The gene sequence is in perfect agreement with the cDNA sequence except for two bases in exon 2. A second genomic clone, lambda MC10, which was isolated from a HaeIII library, contains the missing leading sequence as well as 5' regulatory sequences. The entire gene is about 6.1 kb in length with seven exons separated by six introns, all of the intron/exon junctions being defined by GT/AG. Amino- and carboxy-terminal information are contained in exons 2 and 7, respectively. These exons contain the highly conserved DNA sequences that have been observed in other cytochrome P-450 species. Potential regulatory sequences have been located both 5' to the gene as well as within intron I. A comparison of the coding information for cytochrome P-450c with the sequence of murine cytochrome P3-450 and rat cytochrome P-450d revealed a 70% homology in both the DNA and amino acid sequence, suggesting a common ancestral gene. Genomic blot analyses of rat DNA indicated that the 3-methylcholanthrene-inducible family of cytochrome P-450 isozymes is more limited in number compared to the phenobarbital-inducible isozymes. Cross-hybridization studies with human DNA suggest a high degree of conservation between rat cytochrome P-450c and its human homolog although gross structural differences do exist between the two genes.     

Functional characterization of two cytochrome P-450s within the mouse, male-specific steroid 16 alpha-hydroxylase gene family: expression in mammalian cells and chimeric proteins

Two cDNAs, pc16 alpha-2 and pc16 alpha-25, which encode P-450s from within the mouse, male-specific steroid 16 alpha-hydroxylase (C-P-450(16 alpha)) gene family, were transfected into COS-1 cells in order to study catalytic activities of the expressed P-450s. pc16 alpha-2 was shown previously to encode the growth hormone dependent and androgen-dependent C-P-450(16 alpha) in adult male mice (Wong et al., 1987). The sequence of pc16 alpha-25-encoded P-450 (P-450cb) was identical with gene cb within the C-P-450(16 alpha) family. There was 94% and 87% nucleotide and amino acid sequence identity, respectively, between P-450cb and C-P-450(16 alpha). We expressed both P-450s by transfecting their cDNAs into COS-1 cells and found that steroid 16 alpha-hydroxylase activity was catalyzed by C-P-450(16 alpha) but not by P-450cb. In addition to testosterone, progesterone and estradiol were hydroxylated specifically at the 16 alpha-position by the expressed C-P-450(16 alpha). The results indicated that a broad steroid substrate specificity with high regio- and stereoselectivity at that position was a characteristic of C-P-450(16 alpha). We constructed and expressed chimeras between the two P-450s and found that the presence of about two-thirds of the C-P-450(16 alpha) molecule from its C-terminus was necessary for the chimeric cytochrome to maintain steroid 16 alpha-hydroxylase activity.     

Regulation of testosterone hydroxylation by rat liver microsomal cytochrome P-450

The pathways of testosterone oxidation catalyzed by purified and membrane-bound forms of rat liver microsomal cytochrome P-450 were examined with an HPLC system capable of resolving 14 potential hydroxylated metabolites of testosterone and androstenedione. Seven pathways of testosterone oxidation, namely the 2 alpha-, 2 beta-, 6 beta-, 15 beta-, 16 alpha-, and 18-hydroxylation of testosterone and 17-oxidation to androstenedione, were sexually differentiated in mature rats (male/female = 7-200 fold) but not in immature rats. Developmental changes in two cytochrome P-450 isozymes largely accounted for this sexual differentiation. The selective expression of cytochrome P-450h in mature male rats largely accounted for the male-specific, postpubertal increase in the rate of testosterone 2 alpha-, 16 alpha, and 17-oxidation, whereas the selective repression of cytochrome P-450p in female rats accounted for the female-specific, postpubertal decline in testosterone 2 beta-, 6 beta-, 15 beta-, and 18-hydroxylase activity. A variety of cytochrome P-450p inducers, when administered to mature female rats, markedly increased (up to 130-fold) the rate of testosterone 2 beta-, 6 beta-, 15 beta-, and 18-hydroxylation. These four pathways of testosterone hydroxylation were catalyzed by partially purified cytochrome P-450p, and were selectively stimulated when liver microsomes from troleandomycin- or erythromycin estolate-induced rats were treated with potassium ferricyanide, which dissociates the complex between cytochrome P-450p and these macrolide antibiotics. Just as the testosterone 2 beta-, 6 beta-, 15 beta-, and 18-hydroxylase activity reflected the levels of cytochrome P-450p in rat liver microsomes, so testosterone 7 alpha-hydroxylase activity reflected the levels of cytochrome P-450a; 16 beta-hydroxylase activity the levels of cytochrome P-450b; and 2 alpha-hydroxylase activity the levels of cytochrome P-450h. It is concluded that the regio- and stereoselective hydroxylation of testosterone provides a functional basis to study simultaneously the regulation of several distinct isozymes of rat liver microsomal cytochrome P-450.     

Tissue-specific regulation of cytochrome P-450 dependent testosterone 15 alpha-hydroxylase

Testosterone 15 alpha-hydroxylase activity in kidney microsomes is higher in male mice than in female mice, while in the liver the activity is higher in females than in males. Cytochrome P-450 15 alpha, a specific form of cytochrome P-450 having testosterone 15 alpha-hydroxylase activity, accounts for virtually all of the testosterone 15 alpha-hydroxylase activity in female kidney microsomes, while other isozymes of testosterone 15 alpha-hydroxylase are present in male kidney microsomes. In female kidney, P-450 15 alpha expression is regulated by a single sex-dependent locus, called Rsh for "regulation of steroid hydroxylase." The higher level of P-450 15 alpha expression in male kidneys is dependent on androgens. Of all mice strains, 129/J seems to be the least dependent on androgens to maintain a high expression of P-450 15 alpha in male kidneys. Castration of male mice lowers kidney levels of P-450 15 alpha but in the liver, P-450 15 alpha levels rise after castration. This reciprocal regulation of P-450 15 alpha genes in liver and kidney was investigated by isolating cDNA clones encoding P-450 15 alpha from liver and kidney cDNA libraries. Two highly homologous cDNA clones encoding P-450 15 alpha designated type I and type II were identified, and levels of type I and type II mRNA in liver and kidney were determined by differential restriction mapping of double-stranded cDNA prepared from mRNA from these tissues.(ABSTRACT TRUNCATED AT 250 WORDS)     

A gene structure of testosterone 6 beta-hydroxylase (P450IIIA)

Genomic clones of a rat testosterone 6 beta-hydroxylase have been isolated and characterized as the first gene (P450/6 beta A) among P450IIIA subfamily. This gene spans about 25Kb and consists of 13 exons, which is the largest number of exons among cytochrome P-450 genes reported previously. The nucleotide sequence of the exon region showed high similarity to those of P450PCN2 and P450PCN1 cDNA (Gonzalez, F.J. et al. (1987) Mol. Cell. Biol. 2969-2974), but several replacements and deletions of nucleotide were found between the P450/6 beta A gene and both cDNAs, indicating the existence of multiple P450IIIA genes in rats.     

Expression of a rat liver microsomal cytochrome P-450 catalyzing testosterone 16 alpha-hydroxylation in Saccharomyces cerevisiae: vitamin D3 25-hydroxylase and testosterone 16 alpha-hydroxylase are distinct forms of cytochrome P-450

Rat cytochrome P-450(M-1) cDNA was expressed in Saccharomyces cerevisiae TD1 cells by using a yeast-Escherichia coli shuttle vector consisting of P-450(M-1) cDNA, yeast alcohol dehydrogenase promoter and yeast cytochrome c terminator. The yeast cells synthesized up to 2 X 10(5) molecules of P-450(M-1) per cell. The microsomal fraction prepared from the transformed cells contained 0.1 nmol of cytochrome P-450 per mg of protein. The expressed cytochrome P-450 catalyzed 16 alpha- and 2 alpha-hydroxylations of testosterone in accordance with the catalytic activity of P-450(M-1), but did not hydroxylate vitamin D3 or 1 alpha-hydroxycholecalciferol at the 25 position. The expressed cytochrome P-450 also catalyzed the oxidation of several drugs and did not show 25-hydroxylation activity toward 5 beta-cholestane-3 alpha, 7 alpha, 12 alpha-triol. However, it cross-reacted with the polyclonal and monoclonal antibodies elicited against purified P-450cc25 which catalyzed the 25-hydroxylation of vitamin D3. These results indicated that P-450(M-1) cDNA coded the 2 alpha- and 16 alpha-hydroxylase of testosterone, and that these two positions of testosterone are hydroxylated by a single form of cytochrome P-450. Vitamin D3 25-hydroxylase and testosterone 16 alpha- and 2 alpha-hydroxylase are different gene products, although these two hydroxylase activities are immunochemically indistinguishable.     

Gene structure of a major form of phenobarbital-inducible cytochrome P-450 in rat liver

The gene structure of cytochrome P-450b, a major form of phenobarbital-inducible cytochrome P-450 in rat livers was elucidated by sequence analysis of the cloned genomic DNAs and was compared with the previously determined gene structures of cytochrome P-450e, a minor form of phenobarbital-inducible cytochrome P-450 and two forms of 3-methylcholanthrene-inducible cytochrome P-450 (P-450c and -d). The gene for cytochrome P-450b is 23 kilobase pairs (kb) long and is separated into 9 exons by 8 intervening sequences. This gene structure is very similar to that of cytochrome P-450e except for the first intron, the first intron being much longer in cytochrome P-450b gene (approximately 12 kb) than in cytochrome P-450e gene (3.2 kb), but differs greatly from the gene structures of two 3-methylcholanthrene-inducible cytochrome P-450s as pointed out previously (Sogawa, K., Gotoh, O., Kawajiri, K. & Fujii-Kuriyama, Y. (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 5066-5070). The nucleotide sequences in all 9 exons and their flanking regions in introns show very close homology between the two phenobarbital-inducible cytochrome P-450 genes. Forty base substitutions are found in approximately 1900 nucleotides of all exonic sequences, and 15 of them result in 14 amino acid replacements. These base substitutions occur in relatively limited regions of the gene sequences. Most of them are found in exons 6, 7, 8, and 9, most frequently in exon 7 as described previously (Mizukami, Y., Sogawa, K., Suwa, Y., Muramatsu, M. & Fujii-Kuriyama, Y. (1983) Proc. Natl. Acad. Sci. U.S.A. 80, 3958-3962). The close sequence homology between the two phenobarbital-inducible cytochrome P-450 genes is also found to extend to the promoter region with one notable exception. The simple repeated sequences of (CA)n which is present at -254 position in cytochrome P-450e gene is also observed at the equivalent position in cytochrome P-450b gene, but the repetitiveness is greatly reduced in cytochrome P-450b gene ((CA)5 for P-450b versus (CA)19 for P-450e), and this may somehow be related to the difference in the level of cytochrome P-450b and P-450e in the inductive phase of phenobarbital administration.     

The cDNA and protein sequence of a phenobarbital-induced chicken cytochrome P-450

Several cDNA clones complementary to a chicken phenobarbital-inducible cytochrome P-450 have been isolated and sequenced, representing the first non-mammalian eukaryotic cytochrome P-450 sequence to be analyzed. The cDNA clones hybridized to two mRNAs of 3.5 and 2.5 kilobases in length, but further analysis indicated that the clones were derived from the larger mRNA. The sequence contains a 5'-noncoding region of 39 nucleotides and an open reading frame of 1473 nucleotides. The remainder of the sequence is due to the 3'-noncoding region and poly(A) tail. The open reading frame encodes a protein of 491 amino acids with a molecular weight of 56,196. The chicken cytochrome P-450 shows an overall homology of 45-54% compared with the mammalian phenobarbital-induced cytochrome P-450s. The degree of homology is not uniform, with some short regions showing much greater levels of sequence conservation. In particular, the chicken cytochrome P-450 contains the conserved cysteinyl domain near the carboxyl terminus, found in all cytochrome P-450s and which is thought to be involved in heme binding. Using the chicken sequence, a more accurate estimate of the evolutionary rates of cytochrome P-450s has been made. It is suggested that the phenobarbital-, 3-methylcholanthrene, and pregnenolone 16 alpha-carbonitrile-induced cytochrome P-450 gene families diverged from a common ancestral gene 600 million years ago. Furthermore the phenobarbital-inducible gene apparently underwent gene duplication events at about the time of the divergence of the chicken and mammalian lineages. The results imply that most mammals should have at least four rather distantly related phenobarbital-inducible gene subfamilies.     

Location of DNA sequences complementary to small nuclear repeat RNA (fr 3-RNA) in relation to DNA sequences coding for albumin and alpha-fetoprotein in rat liver cells

Rat liver nuclei contain a 29-nucleotides-long RNA (fr 3-RNA) which is transcribed from middle repetitive DNA sequences. By Southern analysis of restriction fragments of rat albumin and alpha-fetoprotein genomic clones, DNA sequences complementary to this RNA were detected on a 4.6 kbp Eco RI fragment located 600 bp downstream from the termination exon of the albumin gene and on a 2 kbp Eco RI-HindIII fragment located 10 kbp downstream from the restriction fragment containing the alpha-fetoprotein site. No sequence complementary to this RNA was found either in the introns of exons of both genes or in the regions extending 7 kbp upstream from the first albumin exon and 10 kbp upstream of the first alpha-fetoprotein exon. We concluded that sequences complementary to fr 3-RNA are present at the 3'-end flanking regions of the rat albumin and alpha-fetoprotein gene complexes.     

Mouse liver testosterone 16 alpha-hydroxylase (cytochrome P-450(16) alpha). Purification, regioselectivity, stereospecificity, and immunochemical characterization

Microsomal testosterone 16 alpha-hydroxylase (cytochrome P-450(16) alpha) was purified from the livers of male 129/J mice based on enzyme activity in the eluates from columns of DEAE Bio-Gel A, hydroxylapatite, and isobutyl-Sepharose 4B. The specific cytochrome P-450 content of the purified P-450(16) alpha fraction was 9.5 nmol/mg of protein. The specific testosterone 16 alpha-hydroxylation activity of the purified P-450(16) alpha fraction was 80 nmol/min/nmol of cytochrome P-450 or 764 nmol/min/mg of protein, and these values were about 40- and 400-fold higher, respectively, than the activity of solubilized microsomes. The purified P-450(16) alpha showed extremely high regioselectivity and stereospecificity for testosterone hydroxylation; more than 90% of the testosterone metabolites formed by the purified P-450(16) alpha fraction was 16 alpha-hydroxytestosterone. The purified anti-P-450(16) alpha antibody exhibited absolute specificity for inhibition of testosterone 16 alpha-hydroxytestosterone was inhibited by the anti-P-450(16) alpha. Anti-P-450(16) alpha inhibited the 16 alpha-hydroxylation activity of intact microsomes prepared from livers of male or female 129/J mice more than 90%, indicating that P-450(16) alpha is the major cytochrome P-450 isozyme catalyzing 16 alpha-hydroxylation activity of testosterone in these microsomal preparations. The purified P-450(16) alpha fraction also possessed high benzphetamine N-demethylation activity relative to the rates found with other xenobiotic substrates tested in this report.     

Location of DNA sequences complementary to small nuclear repeat RNA (fr 3-RNA) in relation to DNA sequences coding for albumin and α-fetoprotein in rat liver cells

Rat liver nuclei contain a 29-nucleotides-long RNA (fr 3-RNA) which is transcribed from middle repetitive DNA sequences. By Southern analysis of restriction fragments of rat albumin and α-fetoprotein genomic clones, DNA sequences complementary to this RNA were detected on a 4.6 kbp EcoRI fragment located 600 bp downstream from the termination exon of the albumin gene and on a 2 kbp EcoRI-HindIII fragment located 10 kbp downstream from the restriction fragment containing the α-fetoprotein site. No sequence complementary to this RNA was found either in the introns of exons of both genes or in the regions extending 7 kbp upstream from the first albumin exon and 10 kbp upstream of the first α-fetoprotein exon. We concluded that sequences complementary to fr 3-RNA are present at the 3′-end flanking regions of the rat albumin and α-fetoprotein gene complexes.