Regional localization of the gene for clusterin (SP-40,40; gene symbol CLI) to human chromosome 8p12-->p21.

The human clusterin (SP-40,40) gene, designated CLI (complement lysis inhibitor) by the Human Gene Nomenclature Committee, has previously been assigned to chromosome 8. In situ hybridization allowed us to map the locus at 8p12-->p21.     

Assignment of defensin gene(s) to human chromosome 8p23

A relatively abundant component of the polymorphonuclear leukocyte granulocytes has been recently isolated and called defensin. Defensins have antimicrobial activity against gram-positive and gram-negative bacteria and enveloped viruses. A cDNA insert for defensin HNP-1 (DEF1) has been used to map the gene(s) to human chromosome 8p23 using a mouse/human somatic cell hybrid panel and in situ hybridization to normal human metaphase chromosomes. Because of the similarity of HNP-1 defensin to other defensins, it is likely that two of these genes map to this region.     

The gene for SP-40,40, human homolog of rat sulfated glycoprotein 2, rat clusterin, and rat testosterone-repressed prostate message 2, maps to chromosome 8

Sulfated glycoprotein 2 (SGP-2) is a rat glycoprotein that is particularly abundant in seminal fluid, where it is found associated with the acrosome and the tail of mature spermatozoa; for this reason it has been suggested that it has an important role in spermatogenesis. On the basis of nucleotide sequence homology, it has been proposed that the orthologous human gene is that coding for serum protein-40,40 (SP-40,40), a serum protein also called complement lysis inhibitor (CLI), SP-40,40 has been shown to act as a control mechanism of the complement cascade: in fact, it prevents the binding of a C5b-C7 complex to the membrane of the target cell and in this way inhibits complement-mediated cytolysis. SGP-2 and SP-40,40 seem then to be part of different biological systems. Furthermore it has been shown that another protein, testosterone-repressed prostate message 2 (TRPM-2), shares sequence homology with SGP-2 and SP-40,40. TRPM-2 is expressed at high levels and in a temporally precisely defined manner in dying cells, an observation that would suggest its involvement in the cascade of events leading to cell death. We have used a large panel of 24 mouse/human hybrid cell lines and a cDNA for SGP-2, which is also highly homologous to that for rat clusterin, to map the chromosomal location of the orthologous human gene. The mapping data and the Southern analysis presented in this paper, in addition to the data available from the literature, strongly suggest that in the human genome there is a single locus homologous to the probe used and that it codes for the protein which has been called, in different species, SP-40,40, SGP-2, clusterin, and TRPM-2. The chromosomal mapping of the locus for this multiname protein should facilitate its cloning and a better understanding of the apparently many biological functions of its product.     

Assignment of the human tissue-type plasminogen activator gene (PLAT) to chromosome 8

Summary Using 1.2kb 3-terminal Pst-I fragment of a full length tissue-type plasminogen activator (t-PA) cDNA clone (ptPA-8FL) and a set of rodent human somatic cell hybrids, the corresponding human gene PLAT was localized on chromosome 8.This work was submitted as an abstract entitled: Provisional assignment of human tissue-type plasminogen activator (PLAT) to chromosome 8, by R. Visse, G. T. G. Chang, J. Th. Wijnen, J. H. Verheijen, C. Kluft, and P. Meera Khan, for a poster presentation at the 8th International Conference on Human Gene Mapping, Helsinki, August 4–10, 1985     

Assignment of the human gene for histidine-rich glycoprotein to chromosome 3

Histidine-rich glycoprotein (HRG) is a monomeric plasma glycoprotein involved in the modulation of coagulation and fibrinolysis. Using Southern analysis of human-rodent somatic cell hybrid DNA with a human HRG-specific cDNA probe, the HRG gene was assigned to chromosome 3. One hybrid that was known to contain only a segment of chromosome 3 also reacted positively with the HRG probe. Hybridization analysis with a set of chromosome 3-specific probes showed that the segment of chromosome 3 present in this hybrid is missing the region pter-p14, which indicates that HRG is not located in this region. No restriction fragment length polymorphisms were detected for HRG with 10 commonly used restriction enzymes.     

Assignment of the human cytochrome c1 gene to chromosome 8

We previously isolated a cDNA clone for human cytochrome c1. The insert DNA of approximately 950 bp from this clone was used as a probe to identify the cytochrome c1 gene. High molecular weight DNAs extracted from a panel of 14 independent human-mouse somatic cell hybrids were digested with BamHI and analyzed by Southern blot hybridization. The results indicated that the gene for human cytochrome c1 is located on chromosome 8.     

Assignment of human pepsinogen C (PGC) gene to chromosome 6

cDNA of rat pepsinogen C (PGC) hybridizes to, among others, a 3.2-kb band in Southern blot analysis of BamHI-cleaved human genomic DNA. This property was employed to localize the human PGC gene. Use of flow-sorted human chromosomes and 12 human x mouse somatic cell hybrid lines demonstrated that the gene is located on chromosome 6.     

Assignment of a third purine biosynthetic gene (glycinamide ribonucleotide transformylase) to human chromosome 21.

Using a series of human-hamster hybrid cell lines, a gene coding for glycinamide ribonucleotide transformylase was mapped to human chromosome 21. The availability of hybrids containing only portions of chromosome 21 allowed the gene to be assigned to the region between the q11.2 and the q22.2 bands, inclusive. Differentiation of human and hamster glycinamide ribonucleotide transformylase was accomplished via an immunoprecipitation assay that employed a polyclonal antibody raised against the human enzyme.     

Assignment of a human DNA double-strand break repair gene (XRCC5) to chromosome 2.

The Chinese hamster ovary (CHO-K1) cell mutant XRS-6 is defective in rejoining of DNA double-strand breaks and is hypersensitive to X-rays, gamma-rays, and bleomycin. Radiation resistance or sensitivity of somatic cell hybrids constructed from the fusion of XRS-6 cells with primary human fibroblasts strongly correlated with the retention of human chromosome 2 isozyme and molecular markers. Discordancies between some chromosome 2 markers and the radiation resistance phenotype in some of the hybrid cells suggested the location of the X-ray repair cross complementing 5 (XRCC5) gene on the p arm of chromosome 2. Introduction of human chromosome 2 by microcell-mediated chromosome transfer into the radiation-sensitive XRS-6 cells resulted in hybrid cells in which the radiation sensitivity was complemented. The chromosome 2p origin of the complementing human DNA in the microcell hybrids was supported by fluorescent in situ hybridization analysis of human metaphases using human DNA amplified from the hybrids by inter-Alu-PCR as chromosome-painting probes. XRCC5 is therefore provisionally assigned to human chromosome 2p.     

Assignment of the glyoxalase II gene (HAGH) to human chromosome 16

Summary The human and rodent forms of glyoxalase II (hydroxyacylglutathione hydrolase, HAGH) can readily be separated by starch gel electrophoretic procedures. Fifty-one human-rodent somatic cell hybrid clones were examined for their human HAGH and for human enzyme markers whose genes are encoced on each autosome and the X chromosome. Sixteen clones were also examined for their human karyotypes. Human glyoxalase II segregated only with chromosome 16, demonstrating that the gene is located on this chromosome.     

Assignment of gene coding for cell surface glycoprotein with a molecular weight of 75,000 to human chromosome 11

The gene for a cell surface glycoprotein recognized by a mouse monoclonal antibody (Mab 4), has been assigned to human chromosome 11 by the study of mouse-human lymphocyte hybrids. The antigen is present on all human peripheral blood leukocytes, on human fibroblasts, and on human lymphoid and erythroid cell lines, but not on erythrocytes. Immunoprecipitation and polyacrylamide slab gel electrophoresis of both human cells and mouse-human hybrid clones carrying human chromosome 11 show that the apparent molecular weight of this glycoprotein is 75,000.     

Assignment of a structural gene for beta-glucuronidase to human chromosome C7.

An electrophoretic technique was developed which allows the separation of human beta-glucuronidase (GUS EC 3.2.1.3.1) from the enzyme present in cultured murine. Chinese and Syrian hamster cells in one buffer system on Cellogel. Using this technique a number of independent human-mouse somatic cell hybrids have been analyzed for the segregation of GUS, other enzyme markers, and all human chromosomes. The results indicate that a structural gene for human beta-glucuronidase is located on chromosome C7.     

Assignment of a gene for tryptophanyl-transfer ribonucleic acid synthetase (E.C. 6.1.1.2) to human chromosome 14

We describe a simple method for locating tryptophanyl-tRNA synthetase (E.C. 6.1.1.2) on cellulose acetate gels (Cellogel) following electrophoresis. Employing electrophoretic conditions which result in the separation of mouse and human tryptophanyl-tRNA synthetases, we have analyzed extracts of a number of independently derived mouse-human somatic cell hybrids and subclones derived from these hybrids for the presence of human tryptophanyl-tRNA synthetase. Electrophoretic patterns of hybrid extracts which contain human tryptophanyl-tRNA synthetase exhibit three bands. This is consistent with published evidence that the enzyme from mammalian cells is a homologous dimer. The electrophoretic patterns derived from some hybrids are unusual in that the human and hybrid bands of activity are more intense than the mouse band from the same hybrid. An analysis of hybrid cells and extracts indicates that human tryptophanyl-tRNA synthetase segregates with human chromosome 14 and with the only enzyme marker which has previously been assigned to this chromosome, nucleoside phosphorylase.R. M. D. was supported by a postdoctoral fellowship from the Damon Runyon Fund for Cancer Research. The work described was supported in part by grants from Cancer Research Campaign, the Medical Research Council, and NATO.     

Assignment of the human prohibitin gene (PHB) to chromosome 17 and identification of a DNA polymorphism.

Prohibition is a recently identified antiproliferative protein whose exact role in the cell is under investigation. To determine the human chromosomal location of the prohibition gene (PHB) and whether this site corresponds to that of any suspected tumor suppressor gene, we have analyzed DNA from three sources by hybridization analysis: mouse--human hybrid cell lines, hybrid cell lines containing portions of human chromosomes, and human metaphase chromosomes in situ. All three techniques confirm a location in the region 17q21-q22, a region genetically linked to early-onset human breast cancer. Further analysis will be required to establish the significance of this relationship; Southern hybridizations show a polymorphic EcoRI site that may be useful for this purpose.     

Identification of the disulfide bonds in human plasma protein SP-40,40 (apolipoprotein-J).

SP-40,40, a human plasma protein, is a modulator of the membrane attack complex formation of the complement system as well as a subcomponent of high-density lipoproteins. In the present study, the positions of the disulfide bonds in SP-40,40 were determined. SP-40,40 was purified from human seminal plasma by affinity chromatography using an anti-SP-40,40 monoclonal antibody and reversed-phase, high-performance liquid chromatography (HPLC). The protein was digested with trypsin and the fragments were separated by reversed-phase HPLC. The peptides containing disulfide bonds were fluorophotometrically detected with 4-(aminosulfonyl)-7-fluoro-2,1,3-benzoxadiazole (ABD-F). The peptides containing more than two disulfide bonds were further digested with Staphylococcus aureus V8 protease and lysylendopeptidase, and the fragments were isolated by HPLC. The amino acid compositions and the amino acid sequences of the peptides containing only a disulfide bond were determined. Disulfide bonds thus determined were between Cys58(alpha)-Cys107(beta), Cys68(alpha)-Cys99(beta), Cys75(alpha)-Cys94(beta), and Cys86(alpha)-Cys80(beta). Since there was no free sulfhydryl groups in the SP-40,40 molecule, Cys78(alpha) and Cys91(beta) should also be linked by a disulfide bond. It is notable that all of the disulfide bonds in SP-40,40 are not only formed by inter-chain pairing, but also appear to form an antiparallel ladder-like structure between the two chains. The unique structure could be related to the functions of SP-40,40.     

Assignment of the erythropoietin receptor (EPOR) gene to mouse chromosome 9 and human chromosome 19

Erythropoietin (EPO), the primary regulator of mammalian erythropoiesis, binds and activates a specific receptor on erythroid progenitors. The human and mouse cDNAs for this receptor (EPOR) have recently been isolated. These cDNAs were used to establish the genomic location of the EPOR gene. By somatic cell hybrid analysis, the locus for the EPOR maps to human chromosome (Chr) 19pter-q12. By interspecific backcross mapping the locus is tightly linked to the murine Ldlr locus near the centromere of mouse Chr9. This region of mouse Chr9 is homologous to a region of human Chr 19p13 carrying the human LDLR and MEL loci, strongly suggesting that the human EPOR gene is at 19p13 near the human LDLR locus.     

Assignment of human pancreatic lipase gene (PNLIP) to chromosome 10q24-q26.

Human pancreatic lipase (EC 3.1.1.3) is a 56-kDa protein secreted by the acinar pancreas and is essential for the hydrolysis and absorption of long-chain triglyceride fatty acids in the intestine. In vivo, the 12-kDa protein cofactor, colipase, is required to anchor lipase to the surface of lipid micelles, counteracting the destabilizing influence of bile salts. Southern blot analysis, using a pancreatic lipase cDNA to probe DNA from mouse-human somatic cell hybrids, indicated that the pancreatic lipase gene (PNLIP) resides on human chromosome 10. In situ hybridization to human metaphase chromosomes confirmed the cell hybrid results and further localized the gene to the 10q24-qter region with the strongest peak at q26.1.