Peter A. Lalley

Molecular cloning and functional expression of mouse connexin-30,a gap junction gene highly expressed in adult brain and skin.

A new gap junction gene isolated from the mouse genome codes for a connexin protein of 261 amino acids. Because of its theoretical molecular mass of 30.366 kDa, it is named connexin-30. Within the connexin gene family, this protein is most closely related to connexin-26 (77% amino acid sequence identity). The coding region of mouse connexin-30 is uninterrupted by introns and is detected in the mouse genome as a single copy gene that is assigned to mouse chromosome 14 by analysis of mouse × hamster somatic cell hybrids. Abundant amounts of connexin-30 mRNA (two transcripts of 2.0 and 2.3 kilobase pairs) were found after 4 weeks of postnatal development in mouse brain and skin. Microinjection of connexin-30 cRNA into Xenopus oocytes induced formation of functional gap junction channels that gated somewhat asymmetrically in response to transjunctional voltage and at significantly lower voltage (Vo = +38 and −46 mV) than the closely homologous connexin-26 channels (Vo = 89 mV). Heterotypic pairings of connexin-30 with connexin-26 and connexin-32 produced channels with highly asymmetric and rectifying voltage gating, respectively. This suggests that the polarity of voltage gating and the cationic selectivity of connexin-30 are similar to those of its closest homologue, connexin-26.

Chromosome assignment of genes encoding the α and Β subunits of glycoprotein hormones in man and mouse

The chromosomal locations of the genes for the common α subunit of the glycoprotein hormones and the Β subunit of chorionic gonadotropin in humans and mice have been determined by restriction enzyme analysis of DNA isolated from somatic cell hybrids. The CGα gene (CGA), detected as a 15-kb BamHI fragment in human DNA by hybridization to CGα 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 → q21 region. The >30- and 6.5-kb BamHI CGB fragments hybridizing to human CGΒ 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 CGΒ gene are all located on human chromosome 19. In the mouse, the α subunit gene, detected by a mouse thyrotropin (TSH) α subunit probe, and the CGΒ-like sequences (CGΒ-LHΒ), detected by the human CGΒ cDNA probe, are on chromosomes 4 and 7, respectively.

Identification of mouse chromosomes required for murine leukemia virus replication.

Abstract 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.

Assignment of the lactotransferrin gene to human chromosome 3 and to mouse chromosome 9

Lactotransferrin (LTF), a member of the transferrin family of genes, is the major iron-binding protein in milk and body secretions. The amino acid sequence of LTF consists of two homologous domains homologous to proteins in the transferrin family. Recent isolation of cDNA encoding mouse LTF has expedited the mapping of both mouse and human LTF genes. Southern blot analysis of DNA from mouse-Chinese hamster and human-mouse somatic cell hybrids maps the LTF gene to mouse chromosome 9 and to human chromosome 3, respectively. Furthermore, analysis of cell hybrids containing defined segments of human chromosome 3 demonstrates that the gene is located in the 3q21-qter region. These results suggest that LTF and associated genes of the transferrin family have existed together on the same chromosomal region for 300–500 million years.

Mouse chromosome 5 codes for ecotropic murine leukaemia virus cell-surface receptor

INFECTION of cells with murine leukaemia virus (MuLV) strains involves an initial interaction between the major viral glycoprotein (gp71) and specific cell surface receptors1. Virus adsorption and penetration occur only in cells having specific receptors2. Other cellular factors such as virogene integration sites may also be required for productive infections. There are three major classes of MuLV: ecotropic viruses which replicate preferentially in murine cells; xenotropic viruses which do not replicate in mouse cells but can replicate in cells from other species; and amphotropic viruses which replicate in mouse cells as well as in ells from other species. None of the three classes of virus infect hamster cells3,4. Previous studies with hamster × mouse somatic cell hybrid clones segregating mouse chromosomes showed that replication of ecotropic and amphotropic viruses required a cell function(s) coded by genes assigned to mouse chromosomes 5 and 8, respectively3. However, the function(s) of these genes was not determined. The third class of MuLV, the xenotropic viruses, could not be tested in this system since both parent cells were resistant5. In the present study, the replication patterns of ecotropic and amphotropic strains were correlated with the ability of hamster x mouse hybrid clones to bind gp71 of Rauscher leukaemia virus (RLV), an ecotropic strain of MuLV. By comparing the mouse chromosome segregation patterns of hybrid clones which retained the gp71 binding ability with those clones which had lost it, we have been able to assign the gene(s) coding for RLV cell surface receptor to mouse chromosome 5.

Significance of trisomy 7 in thyroid tumors

Standard cytogenetic studies of a multifocal metastasizing papillary thyroid carcinoma revealed two clonal chromosome aberrations: rearranged 10q and trisomy 7. Trisomy 7 seemed to be restricted to tumor nodule A, whereas era (10q) was detected in tumor nodule B and in a metastatic lymph node. We applied fluorescent in situ hybridization to ask whether trisomy 7 was a feature of the original tumor nodule or an in vitro phenomenon changing quantitatively during early passages and to see whether trisomy 7 was restricted to tumor nodule A. We used the biotinylated chromosome 7 alpha-satellite probe D7Z1 on freshly dropped slides from metaphase harvests from tumor nodule A,B, and the lymph node and on touch preparations from the frozen specimen of tumor nodule A. Trisomy 7 was present in the original tumor nodule (6% of cells), as well as in early passages (P1-3) from both tumor nodules and the metastatic lymph node with a frequency of 10.7-13.2%. The detection of trisomy 7 as a stable component in short-term cell culture and its presence in the original tumor material indicates that this common numerical aberration is an in vivo phenomenon.

Chromosomal assignments of mouse connexin genes, coding for gap junctional proteins, by somatic cell hybridization.

The connexin genes Cx31 and Cx45 coding for proteins of gap junctional subunits have been assigned to mouse chromosomes 4 and 11 by Southern blot hybridization of specific gene probes to DNA from mouse × Chinese hamster somatic cell hybrids. In addition, our results confirm the recent assignment of mouse connexin genes Cx26, Cx32, Cx37, Cx40, Cx43, and Cx46 to mouse chromosomes 14, X, 4, 3, 10, and 14, respectively, by analysis of interspecific backcrosses and by somatic cell hybridization. Our assignment of the Cx31 gene to mouse chromosome 4 locates the fourth connexin gene on this mouse chromosome to which the genes for Cx31.1, Cx37, and Cx30.3 have previously been assigned. Interestingly three of them (coding for Cx31, Cx31.1, and Cx30.3) are preferentially expressed in skin. Possibly some of the connexin genes clustered on mouse chromosome 4 may be regulated coordinately.

Comparative mapping using somatic cell hybrids

SummaryComparative mapping, or ascertaining the gene linkage relationships between different species, is rapidly developing. This is possible because new techniques in chromosome identification and somatic cell hybridization, such as the generation of hybrids preferentially segregating chromosomes of any desired species including rodents, and the development of gene transfer techniques have yielded new information about the human and rodent gene maps. In addition, the discovery and characterization of mouse subspecies has generated new mouse sexual genetic linkage data. The following picture is emerging. Several X-linked genes in man are X-linked in all mammalian species tested. The linkage relationships of several tightly linked genes, less than 1 map unit apart, are also conserved in all mammalian species tested. Ape autosomal genes are assigned to ape chromosomes homologous to their human counterparts indicating extensive conservation in the 12 million years (MYR) of evolution from apes to man. Similarly, mouse and rat, 10 MYR apart in evolution, have several large autosomal synteny groups conserved. In comparing the mouse and human gene maps we find that human genes assigned to different arms of the same human chromosome are unlinked in the mouse; mouse genes large map distances (20 to 45 cM) apart are very likely to be unlinked in the human. However, several autosomal synteny groups 10 to 20 cM apart, including thePgd, Eno-1, Pgm-1 group on human chromosome arm lp, are conserved in mice and man. This suggests that homology mapping, the superimposition of one species gene map on the homologous conserved portion of another species genome may be possible, and that ancestral autosomal synteny groups should be detectable.

Mapping and conservation of the group-specific component gene in mouse

The group-specific component (GC), also known as the vitamin D-binding protein, transports vitamin D and its metabolites in plasma to target tissues throughout the body. The GC gene shares an evolutionary origin with genes encoding albumin (ALB) and alpha-fetoprotein (AFP). All three genes are descendants of an evolutionary ancestor that arose from an intragenic triplication. As a result, each gene is composed of three homologous domains. The study described here characterizes and compares mouse GC to the corresponding nucleotide and amino acid sequences of GC from human and rat. The deduced amino acid sequence of mouse GC was 78% identical to human and 91% identical to rat GC. The results suggest that, unlike the corresponding sequences in the ALB and AFP genes, chromosomal sequences encoding the first domain and the leader sequence of the GC gene have specifically been conserved throughout vertebrate evolution. Protection of domain I during evolution may correlate with an important functional aspect of its sequence. The mouse GC gene was mapped to chromosome 5, where the ALB and AFP genes are also located, demonstrating conservation of the three genes in vertebrate species.

Chromosome assignment of mouse insulin, colony stimulating factor 1, and low-density lipoprotein receptors

Receptors for insulin, low-density lipoprotein, and colony stimulating factor 1 are associated with diabetes, atherosclerosis, and cancer in man. Complementary DNA clones for Insr, Ldlr, and Csfmr were used to chromosomally assign the three genes in mouse. In contrast to their close linkage on the short arm of human Chromosome 19, Insr and Ldlr are asyntenic, residing on mouse Chromosomes 8 and 9, respectively. The genes for CSF1R, CSF1, CSF2, IL-3, and IL-5 form a cluster on the long arm of human Chromosome 5. In mouse, Csfm, Csfgm, and IL-3 are syntenic on Chromosome 11. The Csfmr gene was assigned to mouse Chromosome 18 and is thus unlinked to other members of this gene cluster. These gene assignments provide additional topographical information on conservation of linkage groups in man and mouse and provide a genetic framework for evaluating the possible roles for the three receptor genes in genetic diseases in mouse.