Requirement of human chromosomes 19, 6 and possibly 3 for infection of hamster x human hybrid cells with baboon M7 type C virus.

The replication pattern of the endogenous baboon type C virus M7 was studied in 29 primary Chinese hamster × human hybrid clones generated with leukemic cells from two different patients with acute lymphoblastic or myeloblastic leukemia. There was no evidence of viral particulate RDDP or M7 antigen before viral infection. M7 virus replicated in human and some hybrid cells but not in Chinese hamster cells, indicating that M7 requires dominantly expressed human gene(s) for replication. Enzyme and cytogenetic analyses show that a gene(s) coded for by human chromosome 19 is necessary for M7 infection of these hybrids. Detailed cytogenetic correlations revealed, however, that the chromosome 19+/M7 + hybrid clones with intact chromosomes also had copies of chromosomes 3 and 6. Previously, Bevi, the putative integration site for M7 virus, has been assigned to human chromosome 6. Many clones with various combinations of chromosomes 3 and 6 lacked chromosome 19, however, and failed to replicate exogenously applied M7 virus, while tests of 27 secondary clones showed that M7 markers co-segregated with chromosome 19 markers. These findings all confirm the need for a chromosome 19-coded function in Chinese hamster × human hybrids. In addition, the yield of viral particulate RDDP produced into the culture fluid was 50–100 fold less per viral antigen-positive cell in the hybrids compared with human cells. Thus some form of regulation of viral components exists in the hybrid cells. When the virus replicating in hybrid cells was transferred back to human cells, this regulation was relaxed and the yield of RDDP per FA(+) cell greatly increased. We conclude that human chromosomes 6 and 19 code for functions involved in M7 virus metabolism, and we cannot exclude a function coded for by chromosome 3.     

Activation of human alpha 1-antitrypsin gene in rat hepatoma x human fetal liver cell hybrids depends on presence of human chromosome 14

In order to study the involvement of human chromosomes in the expression of liver-specific functions, we have produced somatic cell hybrids between a rat hepatoma (7777) cell line and human diploid skin fibroblasts (series XIX) or human fetal liver cells (series XXII). Production of human serum proteins was detected by immunoelectrophoretic analyses of concentrated serum-free hybrid culture supernatants. Human alpha 1-antitrypsin (AAT) was secreted by a subset of hybrids but not by the parental cells. The activated human AAT phenotype segregated concordantly with human chromosome 14 in 18 primarily HAT-selected and five azaguanine back-selected series XXII hybrids. All other chromosomes were excluded as playing a role in AAT expression. Therefore, the AAT gene (PI) is assigned to chromosome 14. This quasi-constitutive expression of a liver-specific function was not observed for the other serum proteins studied, nor was it seen in the skin fibroblast-derived hybrids (series XIX) although AAT was produced by some of them.     

Suppression of replication of SV40 and polyoma virus in mouse-human hybrids.

Mouse-human heterokaryons are permissive for the replication of both SV40 virus and polyoma virus. If the hybrids which develop from these heterokaryons segregate human chromosomes (mouse greater than human hybrids), the hybrids are permissive for replication of polyoma virus but not for replication of SV40 virus. If the subsequent hybrids segregate mouse chromosomes (human greater than mouse hybrids), such hybrids support the replication of SV40 virus but not the replication of polyoma virus, even when the hybrids contain at least one copy of each mouse chromosome. This indicates that during the transition from heterokaryon to hybrid cell, suppression of expression of species-specific function(s) required for the replication of these species-specific viruses occurs in parallel with the direction of chromosome loss and suppression of nucleolus organizer activity.     

Gene assignments and syntenic groups in the sacred baboon (Papio hamadryas)

Eighteen genes were assigned to chromosomes in the sacred baboon, Papio hamadryas, by their concordant segregation with the chromosomes in a set of baboon X Chinese hamster somatic cell hybrids. ACY1 was assigned to P. hamadryas chromosome 2 (PHA 2); SOD1 and MDH2 to PHA 3; ME1 and SOD2 to PHA 4; NP, MPI, PKM2, and HEXA to PHA 7; PP to PHA 9; ADA and ITPA to PHA 10; LDHB and TPI1 to PHA 11; MDH1 to PHA 13; ESD to PHA 17; and GPI and PEPD to PHA 20. Regional assignments were possible for ACY1 (PHA 2pter----q1) and MDH2 and SOD1 (PHA 3p). Five other independently segregating markers or syntenic groups (PGD, PGM1; and PEPC; PGM2 and PEPS; IDH1; LDHA and ACP2; and GSR) were also identified. Gene assignments and syntenic groups described in P. hamadryas are compared to those found in P. papio, the rhesus monkey, and man. A possible primate model for human lymphoid disease is discussed.     

The human T cell antigen Leu-2 (T8) is encoded on chromosome 2

Summary The locus encoding the human T lymphocyte cell surface antigen Leu-2 has been assigned to chromosome 2 with a DNA mapping panel derived from somatic cell hybrids. The two genomic components identified by a cDNA clone for Leu-2 segregated with human chromosome 2 in all 24 independent hybrid clones examined. The cosegregation of the Leu-2 and immunoglobulin kappa (IgK) loci in hybrids with spontaneous rearrangements of chromosome 2 is consistent with the possibility that the Leu-2 locus is on proximal human 2p near IgK. In the mouse, a locus for a T lymphocyte cell surface antigen with properties similar to Leu-2 is closely linked to the IgK locus on mouse chromosome 6. Hence the syntenic relationship of a gene implicated in T cell killing with the immunoglobulin kappa locus would then be conserved in the mouse and human genomes.     

Identification of a mouse gene required for binding of Rauscher MuLV envelope gp70.

Mouse chromosome segregating somatic cell hybrids were established between a mouse thymic leukemai cell line (GRSL) and Chinese hamster E36 cells. The GRSL cells specifically bound purified Rauscher leukemia virus gp70 while the E36 cells exhibited no binding. The hybrids selectively bound Ruascher gp70 depending on the presence of a mouse cellular gene for the ecotropic murine luekemia gp70 receptor. A syntenic relationship was observed between the DIP-3 chromosome marker (on chromosome 5) and the gp70 receptor in primary clones and subclones of these hybrids; this was confirmed by chromosome analysis. The involvement of H-2 in the binding of Rauscher MuLV gp70 could be ruled out, because discordancies of the receptor presence and H-2 absence as well as of the receptor absence and H-2 presence type could be observed. Our results indicate that the Rec-1 (replication ecotropic MuLV) gene of Gazdar et al. (4) may well be the receptor gene for the ecotropic murine leukemia virus.     

Maintenance of replication patterns in human-mouse hybrids retaining only one human chromosome.

The time of termination of DNA replication of human chromosomes in human-mouse hybrids retaining only one human chromosome was analyzed. Hybrids between SV40-transformed human skin fibroblasts and mouse peritoneal macrophages were used for these studies. Data obtained from hybrids containing only human chromosome 7 or 17 were compared with data from related hybrids containing additional human chromosomes. When either human chromosome 7 or 17 was present alone, it terminated replication at the same stage of the S phase as in hybrids in which other human chromosomes were present (relative to the time of termination of replication of the mouse chromosomes). In comparing the hybrids containing single human chromosomes, it was found that chromosome 17 terminated replication much earlier than chromosome 7. Therefore, the relationship between the replication times of these chromosomes normally observed in human cells was maintained in the hybrids in the absence of all other human chromosomes. The results also indicate that the presence of SV40 gene sequences in chromosomes 7 and 17 did not alter the relative times of termination of replication of those chromosomes.     

Chromosome assignment of genes encoding the alpha and beta subunits of glycoprotein hormones in man and mouse

The chromosomal locations of the genes for the common alpha subunit of the glycoprotein hormones and the beta subunit of chorionic gonadotropin in humans and mice have been determined by restriction enzyme analysis of DNA isolated from somatic cell hybrids. The CG alpha gene (CGA), detected as a 15-kb BamHI fragment in human DNA by hybridization to CG alpha cDNA, segregated with the chromosome 6 enzyme markers ME1 (malic enzyme, soluble) and SOD2 (superoxide dismutase, mitchondrial) and an intact chromosome 6 in human-rodent hybrids. Cell hybrids containing portions of chromosome 6 allowed the localization of CGA to the q12 leads to q21 region. The greater than 30- and 6.5-kb BamHI CGB fragments hybridizing to human CG beta cDNA segregated concordantly with the human chromosome 19 marker enzymes PEPD (peptidase D) and GPI (glucose phosphate isomerase) and a normal chromosome 19 in karyotyped hybrids. A KpnI-HindIII digest of cell hybrid DNAs indicated that the multiple copies of the CG beta gene are all located on human chromosome 19. In the mouse, the alpha subunit gene, detected by a mouse thyrotropin (TSH) alpha subunit probe, and the CG beta-like sequences (CG beta-LH beta), detected by the human CG beta cDNA probe, are on chromosomes 4 and 7, respectively.     

X-Linkage of a Human Genetic Locus That Corrects the DNA Synthesis Lesion in tsC1AGOH Mouse Cells

GM 126 diploid fibroblasts were fused with a heat-sensitive mouse cell mutant defective in DNA synthesis, and primary hybrids were selected at permissive and nonpermissive temperatures in HAT medium. Primary hybrids, primary hybrid clones back-selected in 8-azaguanine at the permissive temperature, and subclones of heat-resistant primary hybrids isolated under nonselective conditions or after 8-azaguanine treatment were tested for heat sensitivity, the expression of 26 human enzymes assigned to 19 different human chromosomes, and the presence of human chromosomes. Only the human X chromosome and X-linked marker enzymes exhibited a clear pattern of concordant segregation with the heat-resistant phenotype. On the basis of these observations, we have defined the human genetic locus that corrects the heat-sensitive lesion in tsC1AGOH as hrC1AGOH and have assigned this locus to the X chromosome. This observation provides the first instance where two selectable markers (heat resistance and 8-azaguanine sensitivity) are found on a single human chromosome and suggests that these markers may prove to be a valuable push-pull selective system of use in determining the linear arrangement of genes on human chromosomes by somatic cell genetics.     

A glutaminase (gis) gene maps to mouse chromosome 1, rat chromosome 9, and human chromosome 2

A rat cDNA clone encoding a portion of phosphate-activated glutaminase was used to identify DNA restriction fragment length polymorphisms (RFLPs) in sets of somatic cell hybrids and between wild-derived and inbred strains of mice. Segregation of rat and mouse chromosomes among somatic cell hybrids indicated assignment to rat chromosome 9 and mouse chromosome 1. Analysis of chromosome 1 alleles for several genes in an interspecific cross between Mus spretus and C3H/HeJ-gld/gld mice indicates that glutaminase can be positioned within 5.5 +/- 2.0 cM proximal to Ctla-4. Similarly, human-hamster somatic cell hybrids were examined for RFLPs, and four human EcoRI restriction fragments were found to hybridize with the rat glutaminase probe. Two of these restriction fragments cosegregated and mapped to human chromosome 2 in a region that is syntenic with mouse chromosome 1 and rat chromosome 9.     

Identification of mouse chromosomes required for murine leukemia virus replication.

The replication patterns of five ecotropic and two amphotropic strains of murine leukemia virus (MuLV) were studied by infecting 41 Chinese hamster x mounse hybrid primary clones segregating mouse (Mus musculus) chromosomes. Ecotropic and amphotropic strains replicated in mouse and some hybrid cells, but not in hamster cells, indicating that replication of exogenous virus requires dominantly expressed mouse cellular genes. The patterns of replication of the five ecotropic strains in hybrid clones were similar; the patterns of replication of the two amphotropic strains were also similar. When compared to each other, however, the replication patterns of ecotropic and amphotropic viruses were dissimilar, indicating that these two classes of MuLV require different mouse chromosomes for replication. Chromosome and isozyme analyses assigned a gene, Rec-1 (replication of ecotropic virus), to mouse chromosome 5 that is necessary and may be sufficient for ecotropic virus replication. Because of preferential retention of mouse chromosomes 15 and 17 in the hybrid clones, however, the possibility that these chromosomes carry genes that are necessary but not sufficient for ecotropic virus replication cannot be excluded. Similarly, the data indicate that mouse chromosome 8 (or possibly 19) carried a gene we have designated Ram-1 (replication of amphotropic virus) which is necessary and may be sufficient for amphotropic virus replication. Because chromosomes 8 and 19 tended to segregate together and two of the three clones excluding 19 have chromosome reaggrangements, we cannot exclude 19 as being independent of amphotropic virus replication. In addition, because of preferential retention, chromosomes 7, 12, 15, 16 and 17 cannot be excluded as being necessary but not sufficient. Hybrid cell genetic studies confirm the assignment of the Fv-1 locus to chromosome 4 previously made by sexual genetics. In addition, our results demonstrate that hybrid cells which have segregated mouse chromosome 4 but have retained 5 become permissive for replication of both N and B tropic strains of MuLV.     

Locus determining the human sperm-specific lactate dehydrogenase, LDHC, is syntenic with LDHA

From the data presented in this report, the human LDHC gene locus is assigned to chromosome 11. Three genes determine lactate dehydrogenase (LDH) in man. LDHA and LDHB are expressed in most somatic tissues, while expression of LDHC is confined to the germinal epithelium of the testes. A human LDHC cDNA clone was used as a probe to analyze genomic DNA from rodent/human somatic cell hybrids. The pattern of bands with LDHC hybridization is easily distinguished from the pattern detected by LDHA hybridization, and the LDHC probe is specific for testis mRNA. The structural gene LDHA has been previously assigned to human chromosome 11, while LDHB maps to chromosome 12. Studies of pigeon LDH have shown tight linkage between LDHB and LDHC leading to the expectation that these genes would be syntenic in man. However, the data presented in this paper show conclusively that LDHC is syntenic with LDHA on human chromosome 11. The terminology for LDH genes LDHA, LDHB, and LDHC is equivalent to Ldh1, Ldh2, and Ldh3, respectively.     

Coreactivation of four inactive X genes in a hamster x human hybrid and persistence of late replication of reactivated X chromosome

Hamster-human hybrids which contained an inactive human X chromosome were treated by 5-azacytidine. Hypoxanthine guanine phosphoribosyltransferase derepressed hybrids were selected and derepression of three other loci, phosphoglycerate kinase, alpha-galactosidase, and glucose-6-phosphate dehydrogenase were studied. Among 32 hybrids selected for hypoxanthine guanine phosphoribosyltransferase, two were found to be reactivated at four X loci. The independence or nonindependence of the reactivation events will be discussed. No correlation was found between the time of replication and the expression or nonexpression of the X chromosome genes: X chromosomes reactivated at four loci remained late replicating; conversely early replication can exist without the expression of some X genes.     

Replication of human chromosomes in human-mouse hybrids: evidence that the timing of DNA synthesis is determined independently in each human chromosome.

The terminal phase of DNA replication was studied by autoradiography in hybrids between human lymphocytes and mouse fibroblasts. The hybrids contained on the average only 11 human chromosomes. It was found that the sequence of terminal DNA replication for the human chromosomes in the hybrids was the same as the sequence of terminal replication for the corresponding chromosomes in the human lymphocytes. Furthermore, it was shown that the maintenance of the normal terminal replication sequence of the human chromosomes in the hybrids was not dependent on the presence of any specific human chromosome. The results suggest that the timing of terminal DNA replication is determined independently in each human chromosome.     

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.     

Gene for human CD59 (likely Ly-6 homologue) is located on the short arm of chromosome 11

The CD59 (MEM-43) antigen, which probably is a human homologue of mouse Ly-6 antigens, is a broadly expressedM _r 18000–25000 human leucocyte surface glycoprotein recognized by monoclonal antibody MEM-43. Ten mouse-human T-lymphocyte hybrids, carrying all mouse chromosomes and a limited number of human chromosomes, were analyzed for expression of CD59 by indirect immunofluorescence and immunoblotting with MEM-43 antibody. Karyotypic analysis of the tested clones showed that the presence of human chromosome 11 correlated with the expression of CD59 in all clones tested. Three other human chromosome 11-encoded antigens, 4F2 (Trop-4), Leu 7 (HNK-1, CD57), and lymphocyte homing receptor, were expressed concordantly with CD59. A more exact localization of the gene for CD59 was obtained by the study of Chinese hamster-human cell hybrids containing short or long arm deletions of human chromosome 11. CD59 segregated with hybrids containing part of the short arm of human chromosome 11, but not with the hybrids containing the long arm. Based on these studies we assign the gene for CD59 to regionP14–p13 of the short arm of chromosome 11.     

Levels of fos, ets2, and myb proto-oncogene RNAs correlate with segregation of chromosome 11 of normal cells and with suppression of tumorigenicity in human cell hybrids.

The tumorigenicity in nude mice of human carcinoma-derived D98AH2 (D98) cells is suppressed when cell hybrids are made by fusing these cells with normal human diploid cells. Selection for hybrids that have segregated chromosomes results in the recovery of tumorigenic segregants. These segregants have all lost at least one copy of chromosome 11 of the diploid cell parent. Earlier we found that the parental D98 cells had detectable levels of mRNA specific for 13 of 21 proto-oncogenes examined. To determine if transregulation of proto-oncogenes by genes of the normal cell occurs in such hybrids, the steady-state levels of mRNA specific to 22 proto-oncogenes in the parental cells were compared with those of nontumorigenic D98 X human diploid hybrids as well as with those of their tumorigenic segregants and with the cells of the resulting tumors. The only chromosome consistently segregated in the latter was chromosome 11 of the diploid cell. fos and ets2 RNA levels and the amount of fos protein were consistently elevated in the segregants compared with amounts in the original hybrids. An unexpected finding was the inverse relationship for myb RNA that was barely detected in the parental D98 cells but was at least 10-fold elevated in hybrids that did not have segregated chromosomes compared with those that did. These patterns were evident in RNAs prepared from both subconfluent and confluent cell cultures. The findings suggest that genes of the normal cell parent can affect proto-oncogene expression. Whether the genes affecting fos, ets2, and myb RNA levels are on chromosome 11 and whether these alterations are causally related to the tumorigenic phenotype of the hybrid remain to be determined.     

Replication of baboon endogenous virus in human cells. Kinetics of DNA synthesis and integration

For the baboon endogenous virus to infect human cells a specific region on chromosome 6 is required for viral DNA replication and integration. In studying the kinetics of baboon endogenous virus DNA replication we show that linear DNA was synthesized as the predominant species after infection and that unintegrated DNA persisted after many cell passages. Examination of integrated DNA revealed the failure of the virus to integrate at early passages. With continuous replication, however, virus integration was observed, but at multiple sites in the host cell.     

Genetic effects of chromosomal rearrangements in Chinese hamster ovary cells: expression and chromosomal assignment of TK, GALK, ACP1, ADA, and ITPA loci.

Polyethylene glycol-mediated fusion of Chinese hamster ovary (CHO) cells with mouse Cl1D cells produced interspecific somatic cell hybrids which slowly segregated CHO chromosomes. Cytogenetic and isozyme analysis of HAT- and bromodeoxyuridine-selected hybrid subclones and of members of a hybrid clone panel retaining different combinations of CHO chromosomes enabled provisional assignments of the following enzyme loci to CHO chromosomes: TK, GALK, and ACP1 to chromosome 7; TK and GALK to chromosome Z13; ACP1, ADA, and ITPA to chromosome Z8; and ADA and ITPA to chromosome Z9. These genetic markers reflect the origin of each of these Z group chromosomes and indicate the functional activity of alleles located on rearranged chromosomes. Identification of diploid electrophoretic shift mutations for ADA and ITPA was consistent with those observations. Assignment of the functional TK locus in TK+/- CHO-AT3-2 cells indicated that gene deletion may be responsible for TK hemizygosity in this subline.