Segregation of mitochondrial DNA in human somatic cell hybrids

Summary The maintenance of mtDNA has been examined in human intraspecific hybrid cells constructed from the fusion of HEB7A, a HeLa tumor cell line carrying the mitochondrially coded chloramphenical (CAP) resistance mutation, and GM 2291, a limited lifespan human diploid fibroblast which is CAP sensitive. These two cells can be distinguished by a polymorphism in a site for the restriction endonuclease, HaeIII. Independently isolated clones of hybrid cells were characterized for their growth properties (either normal limited lifespan or transformed and immortal). Whole cell DNA preparations were made from each hybrid, digested with HaeIII, and the resultant fragments were detected by hybridization to ³²P labelled mouse mtDNA as probe. Experiments with mixtures of HEB7A and GM2291 DNA reveal that HEB7A mtDNA can be detected when it constitutes as little as 5% of the total cell mtDNA.The results indicate that the HEB7A mtDNA is lost from most hybrids, and when it does persist it is usually a minor component of total mtDNA. The addition of CAP at the time of fusion slightly increases the quantity of HEB7A mtDNA, but not enough to confer CAP resistance. Furthermore, five limited lifespan hybrids contained no detectable HEB7A mtDNA, while three transformed hybrids contained varying quantities of HEB7A mtDNA, suggesting that retention of this tumor form of mtDNA is associated with tumor growth behavior. These results suggest that cytoplasmic genetic incompatibility occurs in intraspecific hybrids.     

Assignment of the catechol-O-methyltransferase gene to human chromosome 22 in somatic cell hybrids

Summary Catechol-O-methyltransferase (COMT) plays an important role in the inactivation of catecholamines. It has been demonstrated that erythrocyte COMT activity is genetically determined and controlled by a major autosomal locus with two alleles. The recent development of a method which allows the detection of COMT isozymes directly in autoradiozymograms has provided the means to investigate the chromosome location of the gene by using somatic cell hybrids. We have found that a single form of the COMT enzyme is expressed in several mouse-human fibroblast cell lines. The data obtained from the segregation analysis of the COMT enzyme in these hybrids and their subclones have provided evidence for the location of a major gene for COMT activity on human chromosome 22.     

Localization of human gene loci using spontaneous chromosome rearrangements in human-Chinese hamster somatic cell hybrids.

Analysis of human-Chinese hamster somatic cell hybrids with spontaneously derived chromosome structural changes has provided data for the regional and subregional localization of gene loci which have previously been assigned to human chromosomes 2, 12, and X. Correlation of the expression of human gene loci with the human chromosome complements present in somatic cell hybrids indicates that the cytoplasmic malate dehydrogenase (MDH1) locus is in the 2p23yields2pter region, and red cell acid phosphatase (AcP1) is at or adjacent to 2p23. The cytoplasmic isocitrate dehydrogenase (IDH1) locus is at or adjacent to 2q11, peptidase B (Pep B) is at or adjacent to 12q21, lactate dehydrogenase B (LDH B) is in the 12q21yiedls12pter region, glucose-6-phosphate dehydrogenase (G6PD) is in the Xq24yieldsXqter region, and the gene loci for phosphoglycerate kinase (PGK), alpha-galactosidase (alpha-gal), and hypoxanthine guanine phosphoribosyltransferase (GPRT) are in the Xp21yieldsXq24 region.     

Genetic demonstration of mitotic recombination in cultured Chinese hamster cell hybrids

Chinese hamster ovary cell hybrids were constructed that are heterozygous for two markers, leuS and emtB, linked to the long arm of chromosome 2. In addition, the chromosome 2 carrying the wild-type leuS and emtB alleles contains, on its short arm, a homogeneously staining region (hsr) in which the gene encoding dihydrofolate reductase (dhfr) is amplified approximately 50-fold. This provides a convenient cytogenetic and biochemical means to distinguish the chromosome 2s from the different parents. Analysis of emetine-resistant segregants isolated from such hybrids identified three distinct classes of segregants. One rare class of segregants loses the wild-type leuS and emtB gene functions on the long arm of the hsr chromosome 2 (H-2) but retains the amplified dhfr genes on the opposite arm. Detailed genetic analysis of two such segregants that did not arise by chromosome loss or deletion revealed that new gene linkage relationships had been established on the H-2 chromosome in each, demonstrating that the segregation events in these cell lines involved mitotic recombination.     

Quantitative analysis of human chromosome segregation in man-mouse somatic cell hybrids.

The presumed random and independent process of human chromosome segregation in man-mouse somatic cell hybrids was studied. The results of chromosome analysis on 196 cells from 15 related hybrid strains have provided the first convincing evidence that segregation of human chromosomes can be nonindependent and often concordant. Different human chromosomes were not retained with equal frequency in these hybrid clones. Some were present in 80% of all the cells, whereas others appeared in less than 10% of the same cells. Linear regression analysis was used to test for correlation of the frequencies of all pair-wise combinations of human chromosomes present in these hybrid clones. Twenty-two of 136 possible correlations were statistically significant, indicating that concordant segregation of particular pairs of human chromosomes is a rather frequent occurrence.     

The impact of imprinting: Prader-Willi syndrome resulting from chromosome translocation, recombination, and nondisjunction.

Prader-Willi syndrome (PWS) is most often the result of a deletion of bands q11.2-q13 of the paternally derived chromosome 15, but it also occurs either because of maternal uniparental disomy (UPD) of this region or, rarely, from a methylation imprinting defect. A significant number of cases are due to structural rearrangements of the pericentromeric region of chromosome 15. We report two cases of PWS with UPD in which there was a meiosis I nondisjunction error involving an altered chromosome 15 produced by both a translocation event between the heteromorphic satellite regions of chromosomes 14 and 15 and recombination. In both cases, high-resolution banding of the long arm was normal, and FISH of probes D15S11, SNRPN, D15S10, and GABRB3 indicated no loss of this material. Chromosome heteromorphism analysis showed that each patient had maternal heterodisomy of the chromosome 15 short arm, whereas PCR of microsatellites demonstrated allele-specific maternal isodisomy and heterodisomy of the long arm. SNRPN gene methylation analysis revealed only a maternal imprint in both patients. We suggest that the chromosome structural rearrangements, combined with recombination in these patients, disrupted normal segregation of an imprinted region, resulting in uniparental disomy and PWS.     

Regional localization of human gene loci on chromosome 9: studies of somatic cell hybrids containing human translocations.

Somatic cell hybrids were derived from the fusion of (1) Chinese hamster cells deficient in hypoxanthine guanine phosphoribosyltransferase (HPRT) and human cells carrying an X/9 translocation and (2) Chinese hamster cells deficient in thymidine kinase (TK) and human cells carrying a 17/9 translocation. Several independent primary hybrid clones from these two series of cell hybrids were analyzed cytogenitically for human chromosome content and electrophoretically for the expression of human markers known to be on human chromosome 9. The results allow the assignment of the loci for the enzymes galactose-1-phosphate uridyltransferase (GALT), soluble aconitase (ACONs), and adenylate kinase-3 (AK3) to the short arm of chromosome 9 (p11 to pter) and the locus for the enzyme adenylate kinase-1 (AK1) to the distal end of the long arm of human chromosome 9 (hand q34). Earlier family studies have shown that the locus for AK1 is closely linked to the ABO blood group locus and to the locus of the nail-patella (Np) syndrome. Thus the regional localization of AK1 locus permits the localization of the AK1-Np-ABO linkage group.     

Human beta interferon gene localization and expression in somatic cell hybrids.

The human fibroblast interferon gene beta 1 was mapped to human chromosome 9. Sequence homology with a beta 1 cDNA clone was detected in both genomic DNA and induced mRNA of human/mouse or human/hamster somatic cell hybrids containing human chromosome 9, but not in lines lacking this chromosome or those retaining a complex translocation involving chromosomes 9 and 11. Interferon mRNA that did not share sequence homology with the beta 1 cDNA clone was detected in lines containing human chromosomes 2 and 5 but lacking chromosome 9, suggesting the presence of other unlinked interferon sequences in the human genome.     

Simultaneous identification and banding of human chromosome material in somatic cell hybrids

We have developed a method that identifies human chromosomes in human x hamster somatic cell hybrids and simultaneously bands these same metaphases. Other methods generally require separate slides for banding and detection of human chromosome material, making the precise characterization of human material difficult. Our procedure involves denaturing metaphase chromosomes, followed by in situ hybridization of biotinylated whole human DNA. Fluoresceinated avidin is then bound to the biotinylated DNA, staining the human chromosomes yellow-green when excited with UV light. Chromosome banding is achieved by staining the slides with DAPI and actinomycin D. The fluorescein and DAPI excite maximally at 488 and 355 nm and emit at 520 and 450 nm, respectively. This permits identification of the human material at one excitation wavelength and visualization of the banding patterns at another wavelength. With this procedure, we have successfully identified both intact and broken human chromosomes, as well as human material involved in human x hamster translocations. The results indicate that this procedure is more accurate and considerably more rapid than previous methods and can be routinely employed for the cytogenetic analysis of human x rodent hybrids.     

Regional localization of DNA sequences on chromosome 21 using somatic cell hybrids.

We have used a panel of Chinese hamster X human somatic cell hybrids, each containing various portions of chromosome 21 as the only detectable human chromosome component, for regional mapping of cloned, chromosome 21-derived DNA sequences. Thirty unique and very low-repeat sequences were mapped to the short arm and three sections of the long arm. Three unique sequences map to the proximal part of the terminal band 21q22.3, and five to the distal part of this band. Some of these may represent parts of gene sequences that may be relevant to the pathogenesis of Down syndrome, as 21q22 is the area required to be present in triplicate for the full clinical picture.     

The chromosome variability of the Indian muntjac in somatic cell hybrids]

Hybrids were produced between the Indian muntjak fibroblasts and rat Jensen sarcoma cell line (JF1) auxotrophic for asparagine. They were selected without cloning under conditions providing survival of parental Indian muntjak and hybrid cells. This allowed to compare the Indian muntjak chromosome variability in the parental cells and hybrids under identical culture conditions. The frequency of muntjak chromosome aberrations proved to de higher in the hybrids (up to 47%) than in the parental cells (6.5%). Predominant are chromosomal breaks and dicentrics. The latter are mainly formed by fusion of chromosomes 1 and 2. The most fragile are 1 and X-chromosomes. Chromosomal breaks are evenly distributed along chromosome 1, and "hot" points are observed in X-chromosome. Possible mechanisms of the Indian muntjak chromosome rearrangements induced by somatic cell hybridization are discussed.