Somatic Cell Genetics最新文献

Hybridomas have been prepared that secrete monoclonal antibodies against three different surface antigens of normal human mammary epithelial cells by fusion of mouse myeloma cells with spleen cells from mice and rats immunized with delipidated human milk fat globules. Using a novel method for molecular weight determination, the three different monoclonal antibodies, BLMRL-HMFG-Mc3, BLMRL-HMFG-McR2, and BLMRL-HMFG-Mc5, were found to identify molecules with apparent molecular weights of 46,000, 70,000, and 400,000 daltons, respectively. The latter is a mucin-like glycoprotein with a high sugar content and has not previously been described as a component of the human milk fat globule or of human mammary epithelial cell membranes. Single-cell quantitation of binding of monoclonal BLMRL-HMFG-Mc5 to three breast tumor cell lines using a Microscope Spectrum Analyzer and indirect immunofluorescence revealed a heterogeneous expression. Further, using a competitive radioimmunoassay, it was found that breast tumor cell lines differed by at least 10-fold in the 400,000-molecular-weight antigen content. None of the three antigens are detectable on several nonbreast cell lines, including normal breast fibroblasts.

Enucleated chloramphenicol-resistant (CAPr) AMT cytoplasts were labeled with the mitochondrial-specific fluorophore rhodamine 123 (R-123) and fused to CAP-sensitive (CAPs) 984 whole cells. Using the fluorescence-activated cell sorter (FACS), the cybrids were separated on the basis of the amount of CAPr donor mitochondria which they received. The cybrids were then selected in the presence of various concentrations of CAP to examine the effect of donor mitochondrial dosage on the transfer of CAP resistance. Those cybrids which received the greatest amount of CAPr mitochondria (as determined using the FACS) were found to be approximately 3-fold more resistant to CAP selection than cybrids which had received fewer donor mitochondria. In addition, those cybrids which initially received the greatest CAPr mitochondrial dosage remained more stably resistant to subsequent selection in CAP. These results indicate that the amount of donor mitochondria the cybrid receives may be important in determining the expression of mitochondrial specific markers.

A Vero cell line (Vero 153) resistant to 8-azaguanine and unresponsive to viral induction of interferon was isolated. This primate (African green) cell line was fused with mouse myeloma (S194/5) and normal human lymphocytes from peripheral blood. All Vero 153--mouse hybrids, 8 primary and 12 secondary clones, produced virus-induced mouse but not primate interferon. This occurred even in cultures where greater than 90% of primate chromosomes were retained. Similarly 7 primary and 3 secondary Vero 153--human clones synthesized virus-induced interferon. This could be neutralized by anti-human fibroblast (beta) but not by anti-human leukocyte (alpha) interferon antisera. The unresponsive nature of Vero 153 cells to interferon induction by viruses was not changed by the presence of interferon producing genomes from other cells. However, despite the inability to produce interferon, the Vero cell was able to play a role in the determination of the type of interferon made in the hybrid cell.

We have examined the organization of integrated SV40 sequences in an uncloned population of a transformed human fibroblast cell line. Somatic cell hybrids between mouse B82 cells and human GM847 cells were examined for SV40 T-antigen expression and individual human chromosome presence. This analysis revealed that a functional SV40 genome is located on human chromosome 7. Restriction endonuclease digestion followed by blot hybridization of the parental human cell line revealed that it contains multiple normal and defective SV40 copies integrated into the host genome in tandem. A similar analysis of several T-ag+ hybrid cell lines indicated that the integrated viral sequences in different hybrid cell lines (thus in different cells of the original population) are very closely related but not always identical. Analysis of subclones of GM847 also revealed such differences. Based upon these results, we postulate that following the initial integration event, viral as well as the flanking host DNA sequences become unstable and are subject to deletions and rearrangements. This short-lived structural instability is followed by highly stable integration of SV40 which is maintained in these cells or their hybrid derivatives for at least hundreds of cell generations.

A monoclonal antibody has been obtained that recognizes an antigen encoded by human chromosome 11. We present evidence that this monoclonal antibody recognizes the same or a similar antigenic activity as that previously called a1. Genetic information necessary for a1 expression and recognition by the monoclonal antibody both map to 11p13 leads to 11pter. Mutants that have lost a1 are no longer recognized by the monoclonal antibody. The macroglycolipid fraction of human erythrocyte membranes which contains the a1 antigenic activity is able to convert antigen-negative Chinese hamster ovary cells into cells which are killed by the monoclonal antibody plus complement.

Interspecific somatic cell hybrids were generated by fusion of Chinese hamster spleen cells or primary fibroblasts with cells from an adenine phosphoribosyltransferase (APRT)-deficient mouse subline derived from LMTK- Cl.1D. Subclones which had been selected for either retention or loss of APRT were subjected to combined isozyme and chromosome segregation analysis. Concordant expression or segregation of Chinese hamster APRT, lactate dehydrogenase A (LDHA), isocitrate dehydrogenase 2 (IDH2), and alpha-glucosidase (GAA) with Chinese hamster chromosome 3 allowed provisional assignment of all four loci to that chromosome. Exceptional subclones, in which coordinate segregation of these syntenic markers was disrupted by chromosome breakage or deletions, allowed further localization of these genes to specific regions of the 3 chromosome.

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.

After mutagenesis of mouse mastocytoma P815, it is possible to obtain at high frequency stable tumor cell variants (tum-) that are rejected by syngeneic DBA/2 mice. Most of the variants express one or more new individual antigens specific for each variant, that are detectable in vitro by cytolytic T cells (CTL). Somatic hybrids were prepared either between tum- variants and the original P815 clone, or between different variants. Antigen expression of the hybrids was assessed by using long-term CTL clones that recognize specifically the new antigen present on the variants. Expression of tum- variant antigens behaved as a dominant trait in the hybrids. By submitting the somatic hybrids to selection with CTL clones, it was possible to obtain antigen-loss hybrid variants. The analyses of these antigen-loss variants showed that two variant-specific antigenic determinants associated with one of the variant fusion partners could be lost independently. Like the parental tum- variants, both the (tum+ X tum-) and (tum- X tum-) hybrids failed to form tumors in normal mice but formed tumors in irradiated mice.

Somatic cell hybrids between mouse and Chinese hamster fibroblasts have been used to identify the chromosome responsible for the synthesis of both mouse type I procollagen subunit chains (MCOLA1 and MCOLA2). Thirty-one separate hybrid clones and subclones from ten separate hybridization events were isolated in hypoxanthine-aminopterin-thymidine (HAT) selection medium and were used for detailed gene-mapping studies. ELISA and "Western blotting" immunochemical analysis were used to detect the production of mouse type I procollagen in each hybrid clone. Mouse and Chinese hamster chromosomes were identified in each hybrid clone by trypsin-Giemsa banding of metaphase chromosome spreads and by isozyme analysis. We have found that mouse type I procollagen production segregates concordantly with mouse superoxide dismutase-1, previously mapped to mouse chromosome 16, and with the presence of mouse chromosome 16 karyotypically. Western blotting immunochemical analysis of the separated mouse procollagen chains produced by each hybrid line demonstrated that apparently the genes for both subunit chains are located on the same chromosome. These studies, therefore, assign the structural genes for mouse type I procollagen pro alpha 1 (MCOLA1) and pro alpha 2 (MCOLA2) chains to mouse chromosome 16.

In humans, deficiency in the last two enzymes of UMP biosynthesis, orotate phosphoribosyltransferase (OPRT) and OMP decarboxylase results in the inborn error of metabolism hereditary orotic aciduria, type 1. In this manuscript, we present immunologic, molecular, biochemical, and genetic evidence that the gene coding for this set of enzymatic activities is located on the long arm of human chromosome 3. The evidence presented here is consistent with both these activities being carried on the same multifunctional protein in mammalian cells. These studies allow further genetic analysis of human chromosome 3, confirming that human markers ACY-1, previously assigned to 3p21, and beta-gal, previously assigned by others to the region 3(p21-q21), must be in the region 3 (cen-p21) and confirming the regional assignment of a human DNA segment, D3S1, to 3q12. The significance of these studies to genetic analysis of genes on human chromosome 3, some of which appear to play a role in some forms of malignancy, is discussed.