A cytochrome P-450 gene family mapped to human chromosome 19

Glucuronidation: driving factors and their impact on glucuronide disposition

Glucuronidation is a well-recognized phase II metabolic pathway for a variety of chemicals including drugs and endogenous substances. Although it is usually the secondary metabolic pathway for a compound preceded by phase I hydroxylation, glucuronidation alone could serve as the dominant metabolic pathway for many compounds, including some with high aqueous solubility. Glucuronidation involves the metabolism of parent compound by UDP-glucuronosyltransferases (UGTs) into hydrophilic and negatively charged glucuronides that cannot exit the cell without the aid of efflux transporters. Therefore, elimination of parent compound via glucuronidation in a metabolic active cell is controlled by two driving forces: the formation of glucuronides by UGT enzymes and the (polarized) excretion of these glucuronides by efflux transporters located on the cell surfaces in various drug disposition organs. Contrary to the common assumption that the glucuronides reaching the systemic circulation were destined for urinary excretion, recent evidences suggest that hepatocytes are capable of highly efficient biliary clearance of the gut-generated glucuronides. Furthermore, the biliary- and enteric-eliminated glucuronides participate into recycling schemes involving intestinal microbes, which often prolong their local and systemic exposure, albeit at low systemic concentrations. Taken together, these recent research advances indicate that although UGT determines the rate and extent of glucuronide generation, the efflux and uptake transporters determine the distribution of these glucuronides into blood and then to various organs for elimination. Recycling schemes impact the apparent plasma half-life of parent compounds and their glucuronides that reach intestinal lumen, in addition to prolonging their gut and colon exposure.

CYP2B6: new insights into a historically overlooked cytochrome P450 isozyme

Human CYP2B6 has been thought to account for a minor portion (<1%) of total hepatic cytochrome P450 (CYP) content and to have a minor function in human drug metabolism. Recent studies, however, indicate that the average relative contribution of CYP2B6 to total hepatic CYP content ranges from 2% to 10%. An increased interest in CYP2B6 research has been stimulated by the identification of an ever-increasing substrate list for this enzyme, polymorphic and ethnic variations in expression levels, and evidence for cross-regulation with CYP3A4, UGT1A1 and several hepatic drug transporters by the nuclear receptors pregnane X receptor and constitutive androstane receptor. Moreover, 20- to 250-fold interindividual variation in CYP2B6 expression has been demonstrated, presumably due to transcriptional regulation and polymorphisms. These individual differences may result in variable systemic exposure to drugs metabolized by CYP2B6, including the antineoplastics cyclophosphamide and ifosfamide, the antiretrovirals nevirapine and efavirenz, the anesthetics propofol and ketamine, the synthetic opioid methadone, and the anti-Parkinsonian selegiline. The potential clinical significance of CYP2B6 further enforces the need for a comprehensive review of this xenobiotic metabolizing enzyme. This communication summarizes recent advances in our understanding of this traditionally neglected enzyme and provides an overall picture of CYP2B6 with respect to expression, localization, substrate-specificity, inhibition, regulation, polymorphisms and clinical significance. Emphasis is given to nuclear receptor mediated transcriptional regulation, genetic polymorphisms, and their clinical significance.

Polymorphic CYP2B6: molecular mechanisms and emerging clinical significance

Polymorphisms in drug-metabolizing enzymes and drug transporters contribute to wide and inheritable variability in drug pharmacokinetics, response and toxicity. One of the less well-studied human cytochrome P450s is (CYP)2B6, a homologue of the rodent phenobarbital-inducible CYP2B enzymes. Clinically used drug substrates include cytostatics (cyclophosphamide), HIV drugs (efavirenz and nevirapine), antidepressants (bupropion), antimalarials (artemisinin), anesthetics (propofol) and synthetic opioids (methadone). Contrary to the model polymorphisms of CYP2D6 and CYP2C19, which were discovered by adverse drug reactions, pharmacogenetic study of CYP2B6 was initiated by reverse genetics approaches and subsequent functional and clinical studies. With over 100 described SNPs, numerous complex haplotypes and distinct ethnic frequencies, CYP2B6 is one of the most polymorphic CYP genes in humans. In this review, we summarize general biomolecular and pharmacological features and present a detailed up-to-date description of genetic polymorphisms, including a discussion of recent clinical applications of CYP2B6 pharmacogenetics.

Organization, structure and evolution of the CYP2 gene cluster on human chromosome 19

The cytochrome P450 superfamily of mixed-function oxygenases has been extensively studied due to its many critical metabolic roles, and also because it is a fascinating example of gene family evolution. The cluster of genes on human chromosome 19 from the CYP2A, 2B, and 2F subfamilies has been previously described as having a complex organization and many pseudogenes. We describe the discovery of genes from three more CYP2 subfamilies inside the cluster, and assemble a complete map of the region. We comprehensively review the organization, structure, and expression of genes from all six subfamilies. A general hypothesis for the evolution of this complex gene cluster is also presented.

The CL100 gene, which encodes a dual specificity (Tyr/Thr) MAP kinase phosphatase, is highly conserved and maps to human chromosome 5q34

Expression of the human CL100 gene is induced in skin fibroblasts in response to oxidative/heat stress and growth factors. The CL100 gene encodes a dual specificity (Tyr/Thr) protein phosphatase that specifically inactivates mitogen-activated protein (MAP) kinase in vitro. In addition, CL100 is able to suppress the activation of MAP kinase by oncogenic ras in extracts of Xenopus oocytes. Thus, the CL100 phosphatase may play an important role in the negative regulation of cellular proliferation and is a likely candidate for a tumour-suppressor gene. Here, we show that DNA sequences homologous to CL100 are present in genomic DNA isolated from mouse, chicken, Xenopus and Drosophila, indicating that the CL100 gene is highly conserved. Using an assay based on the polymerase chain reaction, in conjunction with genomic DNA obtained from human-rodent somatic-cell hybrids, we have determined that the CL100 gene is situated on chromosome 5. Fluorescence in situ hybridisation using a CL100 genomic probe confirms that the CL100 mRNA is transcribed from a single genetic locus and maps the gene to 5q34.

Localization of the retinoid X receptor alpha gene (RXRA) to chromosome 9q34

The retinoid X receptor alpha is one of a number of retinoic acid receptors which are members of the steroid/thyroid hormone superfamily. Localization of RXRA was achieved using the polymerase chain reaction on a panel of somatic cell hybrids. A cosmid clone was isolated using the RXRA PCR product, and this was used to further localize the gene by fluorescence in situ hybridization to chromosome 9q34 distal to the dopamine beta hydroxylase gene (DBH). This mapping position was confirmed by PCR on a panel of translocation hybrids.

Deduced amino acid sequence, gene structure and chromosomal location of a novel human class Mu glutathione S-transferase, GSTM4

The Mu-Class glutathione S-transferases (GSTs) are subject to marked inter-individual variation in man, owing to the fact that 40-50% of the population fail to express M1 subunits. Mu-Class GST from two lymphoblastoid cell lines (expressing M1 subunits and the other 'nulled' for M1) have been studied. Both cell lines were found to express a Mu-Class GST that has not been described previously. The cDNA encoding this novel transferase, designated 'GSTM4' has been isolated and the enzyme shown to be comprised of 218 amino acids (including the initiator methionine residue) with an M(r) of approx. 25.5 kDa. Molecular cloning demonstrated that the lymphoblastoid cell line which expressed GSTM1 possessed the b allelic variant (i.e. that with an asparagine residue at position 173). The genes for GSTM4 and GSTM1b have been cloned and found to contain seven introns and eight exons. The coding region of the GSTM4 gene, including the seven introns, encompasses 5.0 kb, whereas the same region of GSTM1b is 5.5 kb; the difference in the size of the two genes is due to the length of intron 7. DNA sequencing allowed a GSTM4-gene-specific oligo-primer to be designed which has been utilized in a PCR-based assay to determine that the GSTM4 gene is located on chromosome 1.

The P450 superfamily: update on new sequences, gene mapping, accession numbers, early trivial names of enzymes, and nomenclature

We provide here a list of 221 P450 genes and 12 putative pseudogenes that have been characterized as of December 14, 1992. These genes have been described in 31 eukaryotes (including 11 mammalian and 3 plant species) and 11 prokaryotes. Of 36 gene families so far described, 12 families exist in all mammals examined to date. These 12 families comprise 22 mammalian subfamilies, of which 17 and 15 have been mapped in the human and mouse genome, respectively. To date, each subfamily appears to represent a cluster of tightly linked genes. This revision supersedes the previous updates [Nebert et al., DNA 6, 1-11, 1987; Nebert et al., DNA 8, 1-13, 1989; Nebert et al., DNA Cell Biol. 10, 1-14 (1991)] in which a nomenclature system, based on divergent evolution of the superfamily, has been described. For the gene and cDNA, we recommend that the italicized root symbol "CYP" for human ("Cyp" for mouse), representing "cytochrome P450," be followed by an Arabic number denoting the family, a letter designating the subfamily (when two or more exist), and an Arabic numeral representing the individual gene within the subfamily. A hyphen should precede the final number in mouse genes. "P" ("p" in mouse) after the gene number denotes a pseudogene. If a gene is the sole member of a family, the subfamily letter and gene number need not be included. We suggest that the human nomenclature system be used for all species other than mouse. The mRNA and enzyme in all species (including mouse) should include all capital letters, without italics or hyphens. This nomenclature system is identical to that proposed in our 1991 update. Also included in this update is a listing of available data base accession numbers for P450 DNA and protein sequences. We also discuss the likelihood that this ancient gene superfamily has existed for more than 3.5 billion years, and that the rate of P450 gene evolution appears to be quite nonlinear. Finally, we describe P450 genes that have been detected by expressed sequence tags (ESTs), as well as the relationship between the P450 and the nitric oxide synthase gene superfamilies, as a likely example of convergent evolution.

Human regeneration protein/lithostathine genes map to chromosome 2p12

The pancreatic stone protein (lithostathine) secreted by the exocrine pancreas is an inhibitor of CaCO3 crystal growth. This protein, which is also present in endocrine pancreas, has also been called the regeneration protein (reg). Here we report the mapping of the REG gene to chromosome 2 using the polymerase chain reaction for the specific amplification of human reg sequences in rodent/human somatic cell hybrid DNA. A regional assignment has been made by in situ hybridization to metaphase chromosomes using two different fluorescently labelled genomic probes corresponding to the REG gene and a related gene REGL. Both probes hybridized to chromosome 2p12 suggesting the tandem organization of these genes.

Localization of brain nitric oxide synthase (NOS) to human chromosome 12

Recent research has shown that nitric oxide is a novel neuronal second messenger and transmitter that may be involved in neuronal cell death and damage in neurological illness. To map the chromosomal localization of this important brain enzyme, a rat cDNA probe was prepared by RNA PCR from rat cerebellum RNA. This rat cDNA was used to isolate a human nitric oxide synthase (NOS) cDNA from a human cerebellum cDNA library. The human cDNA clone containing 1.2 kb of brain NOS cDNA was hybridized to Southern blots containing DNAs obtained from human-rodent hybrid cell line panels using EcoRI and HindIII digestion to ascertain the location of the human NOS gene. These data showed that the human brain nitric oxide synthase mapped within 12q14-qter on human chromosome 12.

Isolation of cDNA clones for a 50 kDa glycoprotein of the human erythrocyte membrane associated with Rh (rhesus) blood-group antigen expression

The Rh blood-group antigens are associated with human erythrocyte membrane proteins of approx. 30 kDa (the Rh30 polypeptides). Heterogeneously glycosylated membrane proteins of 50 and 45 kDa (the Rh50 glycoproteins) are coprecipitated with the Rh30 polypeptides on immunoprecipitation with anti-Rh-specific mono- and poly-clonal antibodies. We have isolated cDNA clones representing a member of the Rh50 glycoprotein family (the Rh50A glycoprotein). We used PCR with degenerate primers based on the N-terminal amino acid sequence of the Rh50 glycoproteins and human genomic DNA as a template and cloned and sequenced three types of PCR product of the expected size. Two of these products, Rh50A and Rh50B, gave the same translated amino acid sequence which corresponded to the expected Rh50 glycoprotein sequence but had only 75% DNA sequence similarity. The third product (Rh50C) contained a single base deletion, and the translated amino acid sequence contained an in-frame stop codon. We have isolated cDNA clones containing the full coding sequence of the Rh50A glycoprotein. This sequence predicts that it is a 409-amino acid N-glycosylated membrane protein with up to 12 transmembrane domains. The Rh50A glycoprotein shows clear similarity to the Rh30A protein in both amino acid sequence and predicted topology. Our results are consistent with the Rh30 and Rh50 groups of proteins being different subunits of an oligomeric complex which is likely to have a transport or channel function in the erythrocyte membrane. We mapped the Rh50A gene to human chromosome 6p21-qter, showing that genetic differences in the Rh30 rather than the Rh50 genes specify the major polymorphic forms of the Rh antigens.

The human gene (DSG2) coding for HDGC, a second member of the desmoglein subfamily of the desmosomal cadherins, is, like DSG1 coding for desmoglein DGI, assigned to chromosome 18

Desmoglein is a transmembrane glycoprotein of the cadherin superfamily present in the desmosomal junction in vertebrate epithelial cells. At least two variants of desmoglein are differentially expressed in human tissues: DGI, a characteristic desmosomal protein; and HDGC, which is, for example, expressed in the simple epithelium of the colon. Using a PCR assay, we were able to assign DSG2, the gene coding for desmoglein HDGC, to chromosome 18, the same chromosomal localization to which we have previously assigned DSG1 coding for desmoglein DGI.

The human gene (DSG3) coding for the pemphigus vulgaris antigen is, like the genes coding for the other two known desmogleins, assigned to chromosome 18

Pemphigus vulgaris (PV) is a potentially lethal skin disease in which epidermal blisters occur as the result of the loss of cell-cell adhesion caused by the action of autoantibodies against a keratinocyte cell surface glycoprotein, the PV antigen (PVA). This latter protein is a member of the desmoglein subfamily of the cadherin superfamily of cell-cell adhesion molecules, present in the desmosome type of intercellular junction. The other two known desmogleins are DGI, which is a target antigen in another autoantibody-mediated blistering disease of the epidermis, pemphigus foliaceous, and HDGC, which is expressed in the basal layer of the epidermis and in the simple epithelium of, for example, the colon. Genes coding for DGI (DSG1) and HDGC (DSG2) have previously been assigned to human chromosome 18. We now present evidence, using a polymerase chain reaction assay, that DSG3, the gene coding for PVA, is assigned to the same chromosome.

Chromosomal assignment of human phenol and bilirubin UDP-glucuronosyltransferase genes (UGT1A-subfamily)

DNA probes were prepared from the 5'-terminal portion of four cDNA clones encoding human phenol and bilirubin UDP-glucuronosyltransferases (UGTs). An additional sequence common to all four clones was isolated from the 3'-terminal portion of one of the clones (UGT1A1). The four specific and the one common DNA sequences were used as probes on a panel of 16 human--rodent somatic cell hybrid DNAs by Southern-blot analysis. The results obtained indicate that all four cDNA clones are encoded by gene(s) located on human chromosome 2.

The human collagen X gene. Complete primary translated sequence and chromosomal localization

We report on the complete primary translated sequence of human alpha 1(X) collagen, deduced from a genomic clone, and the chromosomal localization of the human collagen X gene. The primary translated product of human collagen X is encoded by two exons of 169 bp and approx. 2940 bp. The 169 bp exon encodes 15 bp of 5'-end untranslated sequence, 18 amino acid residues (54 bp) of signal peptide and 33 1/3 amino acid residues (100 bp) of the N-terminal non-collagenous domain. The 2940 bp exon encodes 4 2/3 amino acid residues (14 bp) of the N-terminal non-collagenous domain, the complete triple-helical domain of 463 amino acid residues (1389 bp), the complete C-terminal non-collagenous domain of 161 amino acid residues (483 bp) and 1054 bp of 3'-end untranslated sequence up to and including a potential cleavage/polyadenylation signal. The size of the intron separating the two exons, as estimated by partial sequencing and Southern-blot analyses, is approx. 3200 bp. By a combination of somatic cell hybrid screening and hybridization in situ the human collagen X gene (COL10A1) has been assigned to the distal end of the long arm of chromosome 6 at the locus 6q21-6q22.3.

Assignment of the human gene for beta-microseminoprotein (MSMB) to chromosome 10 and demonstration of related genes in other vertebrates

The gene for beta-microseminoprotein MSMB has been studied by DNA hybridization and molecular cloning techniques. Comparative analysis of restriction endonuclease digests of the cloned gene and of leukocyte DNA strongly suggested that the gene is present in a single copy in the haploid human genome. By Southern blot analysis of DNA from somatic cell hybrids, the gene was assigned to chromosome 10. The coding nucleotides of the human gene are separated into four exons by relatively large introns. A related gene might be present in other mammals, birds, and amphibians as revealed by DNA hybridization under conditions of low stringency.

Confirmation of the assignment of the vitronectin (VNRA) and fibronectin (FNRA) receptor alpha-subunits

The receptors for the extracellular structural components fibronectin and vitronectin each consist of two subunits called alpha and beta. Using human-rodent somatic cell hybrids and cDNA probes corresponding to the alpha-subunits, we have confirmed the mapping of the fibronectin receptor (FNRA) to chromosome 12 and the vitronectin receptor (VNRA) to chromosome 2.

Chromosomal assignment of the human genes coding for the major proteins of the desmosome junction, desmoglein DGI (DSG), desmocollins DGII/III (DSC), desmoplakins DPI/II (DSP), and plakoglobin DPIII (JUP)

We have established PCR assays for the genes coding for the major proteins of the desmosome type of cell junction, the desmosomal cadherins DGI (desmoglein) and DGII/III (desmocollins), and the plaque proteins DPI/II (desmoplakin) and DPIII (plakoglobin) and used them to test human-mouse and human-rat somatic cell hybrids with different contents of human chromosomes. From these data we were able to assign DGI to chromosome 18 (DSG), DGII/III to chromosome 9p (DSC), DPI/II to chromosome 6p21-ter(DSP), and DPIII to chromosome 7 (JUP).

The human chromosome content in human x rodent somatic cell hybrids analyzed by a screening technique using Alu PCR

The ubiquitous nature of the Alu sequence throughout the human genome forms the basis of an assay we present here for analyzing the human chromosome content of human x rodent somatic cell hybrids. A human-specific Alu primer was used both to amplify sequences and to 32P label the products in a polymerase chain reaction (PCR) technique. Unlabeled inter-Alu PCR products from two series of human x rodent hybrids were used to prepare dot blots which were probed with labeled inter-Alu products prepared from between 10(3) and 10(4) hybrid cells. In the first series we demonstrate that a labeled inter-Alu probe from the hybrid DL18ts, containing a single chromosome 18, on a dot blot hybridized only with those inter-Alu products containing chromosome 18. Similar specificity for human chromosome 5 was shown when a Southern blot of the PCR products was hybridized with a probe made from the hybrid HHW 213, which contains only chromosome 5p. Using a dot blot from a second series of control hybrids, 15 of which contained single human chromosomes, hybridization of a labeled probe from the hybrid 18X4-1 was shown to react specifically with the controls that expressed chromosome 18. Application of the technique reported here allows simple and rapid characterization of the human chromosome content in human x rodent hybrids.

Localization of the receptor gene for type D simian retroviruses on human chromosome 19

Simian retrovirus (SRV) serotypes 1 to 5 are exogenous type D viruses causing immune suppression in macaque monkeys. These viruses exhibit receptor interference with each other, with two endogenous type D viruses of the langur (PO-1-Lu) and squirrel monkey, and with two type C retroviruses, feline endogenous virus (RD114/CCC) and baboon endogenous virus (BaEV), indicating that each utilizes the same cell surface receptor (M. A. Sommerfelt and R. A. Weiss, Virology 176:58-69, 1990). Vesicular stomatitis virus pseudotype particles bearing envelope glycoproteins of RD114, BaEV, and the seven SRV strains were employed to detect receptors expressed in human-rodent somatic cell hybrids segregating human chromosomes. The only human chromosome common to all the susceptible hybrids was chromosome 19. By using hybrids retaining different fragments of chromosome 19, a provisional subchromosomal localization of the receptor gene was made to 19q13.1-13.2. Antibodies previously reported to be specific to a BaEV receptor (L. Thiry, J. Cogniaux-Leclerc, R. Olislager, S. Sprecher-Goldberger, and P. Burkens, J. Virol. 48:697-708, 1983) did not block BaEV, RD114, or SRV pseudotypes or syncytia. Antibodies to known surface markers determined by genes mapped to chromosome 19 did not block virus-receptor interaction. The identity of the receptor remains to be determined.

Assignment of the polymorphic intestinal mucin gene (MUC2) to chromosome 11p15

A cDNA coding for a mucin expressed in intestine has recently been cloned (Gum et al. 1989). We describe here the use of this cDNA to map the gene (MUC2) to human chromosome 11 using somatic cell hybrids, and to make the regional localization to 11p15 by in situ hybridization. Analysis of the CEPH (Centre d'Etude du Polymorphisme Humain) families revealed that MUC2 forms part of the tight linkage group on 11p15 which contains HRAS, INS, TH and HBBC.

Human DNA ligase I cDNA: cloning and functional expression in Saccharomyces cerevisiae

Human cDNA clones encoding the major DNA ligase activity in proliferating cells, DNA ligase I, were isolated by two independent methods. In one approach, a human cDNA library was screened by hybridization with oligonucleotides deduced from partial amino acid sequence of purified bovine DNA ligase I. In an alternative approach, a human cDNA library was screened for functional expression of a polypeptide able to complement a cdc9 temperature-sensitive DNA ligase mutant of Saccharomyces cerevisiae. The sequence of an apparently full-length cDNA encodes a 102-kDa protein, indistinguishable in size from authentic human DNA ligase I. The deduced amino acid sequence of the human DNA ligase I cDNA is 40% homologous to the smaller DNA ligases of S. cerevisiae and Schizosaccharomyces pombe, homology being confined to the carboxyl-terminal regions of the respective proteins. Hybridization between the cloned sequences and mRNA and genomic DNA indicates that the human enzyme is transcribed from a single-copy gene on chromosome 19.

N-cadherin gene maps to human chromosome 18 and is not linked to the E-cadherin gene

cDNA clones encoding the human N-cadherin cell adhesion molecule have been isolated from an embryonic muscle library by screening with an oligonucleotide probe complementary to the chick brain sequence and chick brain cDNA probe lambda N2. Comparison of the predicted protein sequences revealed greater than 91% homology between chick brain, mouse brain, and human muscle N-cadherin cDNAs over the 748 amino acids of the mature, processed protein. A single polyadenylation site in the chick clone was also present and duplicated in the human muscle sequence. Immediately 3' of the recognition site in chick a poly(A) tail ensued; however, in human an additional 800 bp of 3' untranslated sequence followed. Northern analysis identified a number of major N-cadherin mRNAs. These were of 5.2, 4.3, and 4.0 kb in C6 glioma, 4.3 and 4.0 kb in human foetal muscle cultures, and 4.3 kb in human embryonic brain and mouse brain with minor bands of 5.2 kb in human muscle and embryonic brain. Southern analysis of a panel of somatic cell hybrids allowed the human N-cadherin gene to be mapped to chromosome 18. This is distinct from the E-cadherin locus on chromosome 16. Therefore, it is likely that the cadherins have evolved from a common precursor gene that has undergone duplication and migration to other chromosomal locations.

Molecular cloning of cDNAs derived from a novel human intestinal mucin gene

A human small intestinal lambda gt11 cDNA library was screened with antibodies to deglycosylated small intestinal mucin. Four partial cDNA clones were isolated that define a novel human mucin gene. These include two partial cDNA clones, SIB 124 and SIB 139, that contain 51 nucleotide tandem repeats which encode a seventeen amino acid repetitive peptide with a consensus sequence of HSTPSFTSSITTTETTS. SIB 139 hybridized to messages produced by small intestine, colon, colonic tumors and also by high mucin variant LS174T colon cancer cells. The gene from which cDNAs SIB 124 and SIB 139 are derived (proposed name MUC 3) maps to chromosome 7, distinct from other known human mucin genes.

Isolation of a cDNA probe for the human intestinal dipeptidylpeptidase IV and assignment of the gene locus DPP4 to chromosome 2

We report the nucleotide sequence and derived amino-acid sequence of a cDNA clone encoding the 3' end of human intestinal dipeptidylpeptidase IV (DPP-IV). This cDNA probe identifies a 4 kb mRNA in the human colon cancer cell line Caco-2. We demonstrate here an extensive homology between this human DPP-IV cDNA and the recently published rat liver DPP-IV cDNA. Using the human DPP-IV cDNA to probe genomic DNA from a panel of somatic cell hybrids we have assigned the gene encoding human DPP-IV to chromosome 2.

The human CYP2F gene subfamily: identification of a cDNA encoding a new cytochrome P450, cDNA-directed expression, and chromosome mapping

A cDNA coding for a P450, designated IIF1, was isolated from a human lung lambda gt11 library by screening with a human IIC9 cDNA probe. The cDNA-encoded IIF1 protein had 491 amino acids and a calculated molecular weight of 55,507. IIF1 cDNA, expressed by using a vaccinia virus vector, produced a cytochrome with a lambda max of 454 nm when reduced and complexed with carbon monoxide. This enzyme was able to dealkylate ethoxycoumarin, propoxycoumarin, and pentoxyresorufin but possessed no activity toward ethoxyresorufin and only trace dearylation activity toward benzyloxyresorufin. A variant cDNA, designated IIF1v, was isolated that was identical with IIF1 except for the loss of two segments of 161 and 388 bp within the cDNA coding region. Two mRNAs, consistent with the predicted size of the IIF1 and IIF1v transcripts, were found at very low abundance in lung specimens by Northern blot analysis. A 2-kb transcript, hybridizing with the human IIF1, was also detected as an abundant mRNA in rat lung. The CYP2F gene subfamily was localized to human chromosome 19 and mouse chromosome 7. On the basis of Southern blotting analysis with multiple restriction enzymes, we conclude that the CYP2F1 gene is flanked by a second highly similar gene.

Localization of the gene for human simple epithelial keratin 18 to chromosome 12 using polymerase chain reaction

Many human genes encoding keratin intermediate filament proteins are clustered on chromosomes 17 (the type I genes) and 12 (the type II genes). Some have not yet been localized, notably the genes for the primary embryonic keratins 8 and 18, normally expressed in simple epithelia: this is because the numerous pseudogenes for these keratins have made it difficult to identify the true functional gene in each case. Through the use of human-specific primers from within introns of the published gene sequence for human type I keratin 18, human genomic DNA has been specifically amplified using the polymerase chain reaction. A single reaction product was obtained. DNA from a characterized series of mouse-human somatic cell hybrid lines was tested for the presence of sequences able to initiate the chain reaction from these primers, and the presence or absence of this genomic DNA PCR product allowed us to assign a gene for human keratin 18 to chromosome 12 unambiguously. This differs from the location of other human type I keratins on chromosome 17 and may indicate the early divergence of the genes for stratifying cell keratins from that of simple, or embryonic, keratin 18.

Chromosomal assignment of human uracil-DNA glycosylase to chromosome 12

Using Southern blot analysis of DNA from a panel of rodent-human somatic cell hybrids with known karyotypes, we have assigned the human uracil-DNA glycosylase gene to chromosome 12.

Localisation of the gene encoding the catalytic gamma subunit of phosphorylase kinase to human chromosome bands 7p12-q21

Skeletal muscle phosphorylase kinase has the structure (alpha beta gamma delta)4 where the alpha and beta subunits are regulatory components, the gamma subunit possesses catalytic activity and the delta subunit is identical to the calcium binding protein calmodulin. A rabbit skeletal muscle cDNA for the gamma subunit has been used to map the human gene (PYKG1) to 7p12-q21, by analysis of somatic cell hybrids and in situ hybridisation. The data suggest that the skeletal muscle gamma subunit gene is located just above the centromere of chromosome 7, with further cross-hybridising sequences at 7q21 and 11p11-14. The liver gamma subunit is distinct and its mRNA does not cross-hybridize with the skeletal muscle gamma subunit cDNA. These results indicate that autosomal human phosphorylase kinase deficiencies affecting both liver and muscle are likely to be caused by a defect in the autosomally determined beta subunit, rather than the gamma subunit.

The gene for the muscle-specific enolase is on the short arm of human chromosome 17

The human gene encoding the muscle-specific beta-enolase has been isolated. The beta-enolase gene was mapped to chromosome 17 by analysis of a panel of rodent-human somatic cell hybrids. The gene was further localized to the short arm and tentatively to the region 17pter-p11 by analysis of cell hybrids and transfectant cell lines carrying different portions of chromosome 17.

Cloning and mapping of a testis-specific gene with sequence similarity to a sperm-coating glycoprotein gene

A testis-specific gene Tpx-1, located between Pgk-2 and Mep-1 on mouse chromosome 17, was isolated from a cosmid clone, and its cDNA sequences were determined. The predicted coding sequence of Tpx-1 isolated from BALB/c mice showed 64.2% nucleotide and 55.1% amino acid sequence similarity with that of a rat sperm-coating glycoprotein gene, the protein product of which is secreted by the epididymis. To examine the evolutionary relationship between Tpx-1 and a sperm-coating glycoprotein gene, the cDNA sequence of TPX1, the human counterpart of Tpx-1, was determined. The comparison of the predicted coding sequences of Tpx-1 and TPX1 showed 77.8% nucleotide and 70% amino acid sequence similarity. Since Tpx-1 (from mouse) is more similar to TPX1 (from man) than it is to a rat sperm-coating glycoprotein gene, we conclude that Tpx-1 (TPX1) and a sperm-coating glycoprotein gene are closely related, but distinct, genes belonging to the same gene family. The predicted Tpx-1 protein of a t mutant mouse CRO437 differs from that of BALB/c mice by one amino acid insertion in the putative signal peptide. TPX1 was mapped to 6p21-qter by Southern blot analysis of interspecies somatic hybrid cell lines.

Isolation of a human cytochrome P-450 reductase cDNA clone and localization of the corresponding gene to chromosome 7q11.2

We have isolated and sequenced cDNA clones that code for rat and human NADPH-dependent cytochrome P-450 reductase. The cDNA coding for the human protein was used to analyse, by Southern blot hybridization, DNA isolated from a panel of 8 independent human-rodent somatic cell hybrids. The results indicate that cytochrome P-450 reductase is encoded by a single gene (POR) located on human chromosome 7(pter-q22). Analysis of human metaphase chromosomes by hybridization in situ confirmed the results and refined the localization to 7q11.2. Northern blot hybridization revealed that in human liver the expression of the gene varies by less than 3-fold between different individuals.

The gene coding for the p68 calcium-binding protein is localised to bands q32-q34 of human chromosome 5, and to mouse chromosome 11

The gene coding for human p68, a membrane-associated calcium-binding protein, has been assigned to chromosome 5, using a cDNA clone to probe genomic DNA from rodent-human somatic cell hybrids by Southern hybridisation. The gene was localised, by in situ hybridisation, to 5q32-34. The murine gene was assigned to chromosome 11, using a murine cDNA clone to probe genomic DNA from rodent-rodent somatic cell hybrids.

An autosomal transcript in skeletal muscle with homology to dystrophin

The Duchenne muscular dystrophy (DMD) gene has been localized to chromosome Xp21 and codes for a 14-kilobase (kb) transcript and a protein called dystrophin, of relative molecular mass 427,000. Dystrophin is associated with the cytoplasmic face of muscle fibre membranes and its C-terminal domain is thought to mediate membrane attachment. Although N-terminal and central domain structures share common features with other cytoskeletal components, no significant sequence similarity between the C-terminal region of dystrophin and other previously characterized proteins has been described. Here we report that fragments from the C-terminal domain of the DMD complementary DNA detect a closely related sequence which exhibits nucleic-acid and predicted amino-acid identities with dystrophin of approximately 65 and 80%, respectively. The dystrophin-related sequence identifies a 13-kb transcript in human fetal muscle and maps to chromosome 6. Thus, dystrophin may be a member of a family of functionally related large structural proteins in muscle.

Cloning, expression and chromosomal localization of a member of the human cytochrome P450IIC gene sub-family

We have isolated and sequenced a cDNA clone (pB8) that codes for a novel member of the cytochrome P450IIC sub-family of man. Analysis, by Southern blot hybridization, of DNA isolated from a panel of nine independent human-rodent somatic cell hybrids demonstrated that the corresponding gene (CYP2C) is located on human chromosome 10. Northern blot hybridization of RNA isolated from human livers revealed a 10-fold inter-individual variation in the expression of the gene.

The P450 superfamily: updated listing of all genes and recommended nomenclature for the chromosomal loci

In this update we provide a list of the 71 P450 genes and the four P450 pseudogenes that have been characterized as of September 30, 1988. The chromosomal locations of many of these genes are also summarized. A modest revision of the initially proposed nomenclature of the P450 superfamily (Nebert et al., DNA 6, 1-11, 1987) is described specifically for the human and mouse chromosomal loci. The motivation for this revision is to conform to the rules of nomenclature for human and mouse genes. Recommendations for the naming of chromosomal loci include the root symbol "CYP" for human ("Cyp" for mouse), denoting "cytochrome P450." We recommend that this root also be used for other organisms. For a chromosomal locus, the root symbol is followed by an Arabic numeral designating the P450 family, a letter indicating the subfamily, and an Arabic numeral representing the individual gene within the family or subfamily. Numbers of the individual genes usually will be assigned in the order the genes are identified. This system is consistent with our earlier proposed nomenclature for P450 families and gene products from all eukaryotes and prokaryotes.

The human cytochrome P450 CYP3 locus: assignment to chromosome 7q22-qter

The cytochrome P-450s are a large multigene family of enzymes involved in the metabolism and detoxification of drugs and chemicals. Using a full length cDNA clone for the human nifedipine oxidase gene (CYP3) and a panel of human-rodent somatic cell hybrids, we have assigned this gene family to chromosome 7q22-qter. A search for RFLPs using this probe yielded no results.

Cloning and chromosomal mapping of human cytochrome b5 reductase (DIA1)

We have isolated a cDNA clone that codes for human cytochrome b5 reductase. The cDNA was used to analyse, by Southern-blot hybridization, DNA isolated from a panel of 11 independent human-rodent somatic cell hybrids. The results indicate that cytochrome b5 reductase is encoded by a single gene located on human chromosome 22.

Applications of coding theory to the design of somatic cell hybrid panels

The somatic cell hybridization technique for gene mapping depends on assembling panels of rodent-human hybrid clones containing random subsets of the human chromosomes. Such panels should be as informative as possible and permit error detection and error correction for assays of the human gene in the various clones. We derive estimates of the number of randomly generated clones required to be reasonably confident of accurately and unambiguously assigning a gene to a particular human chromosome. The collection of clones in such a random panel is contrasted with minimal panels suggested by algebraic coding theory. To approximate minimal panels we suggest the method of simulated annealing for selecting small, informative panels from larger existing collections of clones. These theoretical insights emphasize the need for more collaboration and coordination among gene mapping groups so that optimal clone panels can be assembled, stored, and distributed.

A novel human cytochrome P450 gene (P450IIB): chromosomal localization and evidence for alternative splicing

We have isolated from a single human liver cDNA library two clones which are highly homologous (78% over the coding region) to the major phenobarbital-inducible P450 from rat (P450IIB1). This is the first direct demonstration of the presence of the P450IIB gene subfamily in humans. This subfamily is much less extensive than the rodent homologues, but does appear to contain at least two genes. Of the cDNA clones isolated one is apparently normally spliced, whereas the other lacks exon 8 and retains all or part of intron 5. Both clones contain transcribed Alu sequences. The human P450IIB gene has been located to chromosome 19q12----19q13.2 using a probe derived from intron 5, and is close to the CYP 2A locus encoding cytochrome P450IIA2. Restriction fragment length polymorphisms have been found with the enzymes BamHI and MspI which will enable linkage to be determined between these two loci.

Characterization and chromosomal localization of the gene encoding the human cell adhesion molecule uvomorulin

We have isolated an approximately 2.0-kb human cDNA clone containing coding sequences for the human cell adhesion molecule, uvomorulin. Comparison of human and mouse cDNA revealed extensive homology of 82% for the nucleotide and 83% for the deduced amino acid sequence. This and other structural features common to both cDNAs demonstrate that uvomorulin is evolutionarily highly conserved in mammals and underline its functional importance in histogenesis. Moreover, with the use of human x mouse somatic-cell hybrids, the human uvomorulin gene was localized on chromosome 16, in the region 16p11-16qter.

The major phenobarbital-inducible cytochrome P-450 gene subfamily (P450IIB) mapped to the long arm of human chromosome 19

We have recently isolated a cloned cDNA that codes for a human orthologue of the major phenobarbital-inducible cytochrome P450IIB subfamily of rodents. The cloned human cDNA was used to analyse, by Southern blot hybridization, DNA extracted from a panel of 9 independent human-rodent somatic cell hybrids. The results indicate that all members of the P450IIB gene subfamily of man are located on chromosome 19. Evidence from hybrids containing different regions of human chromosome 19 localizes this cytochrome P-450 gene subfamily further to the long arm of chromosome 19 in the region cen-q13.3. We propose the designation CYP2B for this locus.

Regional assignment of the gene coding for human sucrase-isomaltase (SI) to chromosome 3q25-26

The gene coding for sucrase-isomaltase (SI) has recently been mapped to chromosome 3 using a cDNA probe to analyse DNA from somatic cell hybrids (Green et al. 1987). We have now used this same cDNA probe to obtain a regional localization of this gene. In situ hybridization to normal metaphase chromosomes and to chromosomes from individuals with balanced translocations suggests a regional assignment to chromosome 3q25-26.

Characterization of a panel of highly variable minisatellites cloned from human DNA

Five of the most variable loci detected in human DNA by hybridization with DNA fingerprint probes have been cloned and characterized. Each locus consists of a tandem-repetitive minisatellite, with repeat units ranging in length from 9 to 45 base pairs depending on the locus. All of these cloned minisatellites act as locus-specific hybridization probes, and detect extremely variable Mendelian loci with heterozygosities ranging from 90 to 99%. These five hypervariable loci, together with a previously-isolated minisatellite designated p lambda g3, are dispersed over four autosomes (chromosomes 1, 5, 7 and 12). Syntenic pairs on chromosomes 1 and 7 show no detectable pair-wise linkage, and thus these hypervariable loci show no evidence of clustering within the genome and should provide valuable markers for mapping inherited disease. The locus-specific minisatellites act as very sensitive hybridization probes, and can be pooled to detect several hypervariable loci simultaneously. The applications of these probes in individual identification, paternity testing and analysis of cell chimaerism are discussed, and are illustrated by an analysis of forensic specimens from two victims who had been sexually assaulted and murdered.

Localization of PEPD to the long arm of chromosome 19

A panel of human-rodent somatic cell hybrids containing different regions of chromosome 19 has been used to obtain a regional localization for peptidase D. The results assign PEPD to the long arm of chromosome 19, in the region cen-q13.2