Assignment of human pepsinogen A locus to the q12-pter region of chromosome 11

Summary A 0.9 kb cDNA fragment, corresponding to a large part of Rhesus monkey pepsinogen A mRNA, was used as probe for the chromosomal localization of the human pepsinogen A gene(s) using human-rodent somatic cell hybrids. Southern blot analysis of 14 human-Chinese hamster and three human-mouse cell hybrids, strongly indicates that the human PGA locus is on chromosome 11. The human-mouse hybrids, containing a translocation involving chromosome 11, allow sublocalization to the region q12-pter.     

Assignment of the gene locus for human phosphoglucomutase 3 to chromosome 6q12-qter

Segregation of human PGM3 has been analyzed in somatic cell hybrids between mouse A9 cells and human fibroblasts carrying a reciprocal translocation: 46,XX, t(6;7) (q12;p14). The enzyme marker segregates with the 7p+ chromosome indicating that the PGM3 gene is located on 6q12 greater than qter.     

Assignment of the pig apolipoprotein B locus (APOB) to chromosome region 3q24-qter

The locus for apolipoprotein-B (APOB) has been chromosomally assigned in swine by in situ hybridization of a genomic probe to metaphase chromosomes. As expected based on the observation of extensive linkage conservation and based on the previous assignment of the malate dehydrogenase locus (MDH1) in swine, APOB maps to chromosome 3, specifically to region 3q24-qter. Variations at APOB may represent both in humans and in swine risk factors for hypercholesterolaemia and atherosclerosis. Evidence presented here that the human and porcine APOB occupy evolutionarily conserved chromosome regions provides a basis for using the pig as an animal model to study the APOB associated atherosclerosis risk.     

Assignment of the human gene for cholesteryl ester transfer protein to chromosome 16q12-16q21

We have used a cDNA probe for human cholesteryl ester transfer protein (CETP) to determine the chromosomal location for the human gene. Southern blot analysis of DNA from 17 independent mouse-human somatic cell hybrids demonstrated the presence of the gene for human CETP on chromosome 16. Regional mapping of the gene by in situ hybridization was consistent with these results and indicated that the gene resides in the 16q12-21 region of the chromosome. These findings provide an additional polymorphic marker for chromosome 16, as several relatively common restriction fragment length polymorphisms of the gene have previously been reported, and they have significance for studies directed at the identification of genetic factors affecting plasma lipoprotein metabolism and atherosclerosis.     

Assignment of the human protein C gene (PROC) to chromosome region 2q14----q21 by in situ hybridization

The protein C gene (PROC) was mapped by in situ hybridization. A genomic DNA probe containing the first three exons was 3H-labeled by nick translation, and this was then hybridized in situ to human chromosome preparations. The results localize the gene to 2q14----q21.     

Assignment of human uroporphyrinogen I synthase locus to region 11qter by gene dosage effect

Summary Recently Meisler et al. (1980) reported the results of mouse/human somatic cell hybrid studies which indicated that the locus for human uroporphyrinogen I synthase (UPS) (EC 4.3.1.8) maps to chromosome 11. To evaluate further this assignment we have studied the expression of this enzyme in red cells of three children with a trisomy of the region 11qter. We confirm the results of Meisler et al. (1980) and demonstrate that uroporphyrinogen I synthase activity is increased by a factor of 1.5 in trisomy 11qter. In erythrocytes of one child with a trisomy 11p, the expression of this enzyme was normal.     

Assignment of the human 8.5 H gene to chromosome 5, region 5q35

The human 8.5 H probe was isolated from a human cerebellum cDNA library with a probe corresponding to the coding region of the murine 8.5 M cDNA. This cDNA isolated from a murine cDNA library constructed from newborn cerebral hemispheres was selected because of its strong expression in embryonic neurons. Consequently the corresponding human gene could be a candidate for hereditary neurodegenerative diseases. The human 8.5 H gene was assigned by somatic hybrid analysis to chromosome 5; this chromosome contains the gene(s) for spinal muscular atrophy (SMA), a group of heritable degenerative diseases that selectively affect the anterior horn motor neuron of the spinal cord. The localization by in situ hybridation of 8.5 H on 5q35 excluded the possibility that this gene is identical to SMA. The SMA gene(s) was (were) known, from linkage analysis, to be in a region (5q11.2-q13.3) very distant from 5q35.     

Assignment of the YT blood group locus to chromosome 7q.

The antithetical antigens YT1 and YT2 constitute the YT blood group system (International Society of Blood Transfusion system number 11). Despite being serologically well defined, the YT blood group locus (YT) has not secured a chromosomal location. In our report, peak lods of 3.61 at theta = 0.00 for YT:COL1A2 and of 3.31 at theta = 0.00 for YT:D7S13 allow us to assign YT to the long arm of chromosome 7.     

Five new microsatellite polymorphisms at the q21 region of human chromosome 21

Five clones, containing polymorphic CA-repeat sequences, have been isolated from a specific human chromosome 21 phage library and have been localised to band q21 of chromosome 21 using a somatic cell hybrid panel. These highly repetitive sequences (D21S1263, D21S1264, D21S1415, D21S1417 and D21S1420) have been characterised in the CEPH reference parents and have heterozygosities ranging from 0.30 to 0.81 and an average polymorphism information content (PIC) of 0.62. The relative order of these markers, based on the somatic cell hybrid panel, is cen-D21S1417, D21S1420-D21S1263, D21S1415-D21S1264-tel. The most polymorphic marker (D21S1264) has been included in the chromosome 21 genetic map. They have also been localised in the CEPH/ Généthon YAC panel, providing a refined localisation of these polymorphic sequences. These five CA-repeat markers should provide a better characterisation of the q21 region of chromosome 21.     

Assignment of a second Charcot-Marie-Tooth type II locus to chromosome 3q.

Charcot-Marie-Tooth disease (CMT) is the most common inherited motor and sensory neuropathy. The neuronal form of this disorder is referred to as Charcot-Marie-Tooth type II disease (CMT2). CMT2 is usually inherited as an autosomal dominant trait with a variable age at onset of symptoms associated with progressive axonal neuropathy. In some families, the locus that predisposes to CMT2 has been demonstrated to map to the distal portion of the short arm of chromosome 1. Other families with CMT2 do not show linkage with 1p markers, suggesting genetic heterogeneity in CMT2. We investigated linkage in a single large kindred with autosomal dominant CMT2. The gene responsible for CMT2 in this kindred (CMT2B) was mapped to the interval between the microsatellite markers D3S1769 and D3S1744 in the 3q13-22 region. Study of additional CMT2 kindreds should serve to further refine the disease gene region and may ultimately lead to the identification of a gene defect that underlies the CMT2 phenotype.     

Assignment of the tibial muscular dystrophy locus to chromosome 2q31.

Tibial muscular dystrophy (TMD) is a rare autosomal dominant distal myopathy with late adult onset. The phenotype is relatively mild: muscle weakness manifests in the patient's early 40s and remains confined to the tibial anterior muscles. Histopathological changes in muscle are compatible with muscular dystrophy, with the exception that rimmed vacuoles are a rather common finding. We performed a genomewide scan, with 279 highly polymorphic Cooperative Human Linkage Center microsatellite markers, on 11 affected individuals of one Finnish TMD family. The only evidence for linkage emerged from markers in a 43-cM region on chromosome 2q. In further linkage analyses, which included three other Finnish TMD families and which used a denser set of markers, a maximum two-point LOD score of 10.14 (recombination fraction of .05) was obtained with marker D2S364. Multipoint likelihood calculations, combined with the haplotype and recombination analyses, restricted the TMD locus to an approximately 1-cM critical chromosomal region without any evidence of heterogeneity. Since all the affecteds share one core haplotype, the dominance of one ancestor mutation is obvious in the Finnish TMD families. The disease locus that was found represents a novel muscular dystrophy locus, providing evidence for the involvement of one additional gene in the distal myopathy group of muscle disorders.     

The human QARS locus: assignment of the human gene for glutaminyl-tRNA synthetase to chromosome 1q32–42

Summary We have used a cDNA encoding the core region of the human glutaminyl-tRNA synthetase to determine the chromosomal localization of the corresponding gene. Southern blots of restricted DNA from a panel of rodent-human cell lines and in situ chromosome hybridization gave identical results showing that the human gene locus for glutaminyl-tRNA synthetase resides on the distal long arm of chromosome 1. There are now nine mapped aminoacyl-tRNA synthetase genes in the human genome.     

Assignment of uroporphyrinogen decarboxylase (UROD) to the pter----p21 region of human chromosome 1

The assignment of the human gene for uroporphyrinogen decarboxylase (UROD) to chromosome 1 is confirmed and further localized to the pter----p21 region through the use of human-mouse somatic cell hybrids. Human and mouse UROD were separated by electrophoresis and identified with antibodies to the human enzyme after electrophoretic transfer to nitrocellulose membranes.     

Regional localization of the LCA oncogene to human chromosome region 2q14----q21

A novel human oncogene, LCA, was assigned to region 2q14----q21 by in situ molecular hybridization. The present regional mapping substantiates the previous assignment that was performed by Southern blot analyses of DNAs from flow-sorted human chromosomes and human-mouse somatic cell hybrids.     

Assignment of the human dihydrofolate reductase gene to the q11----q22 region of chromosome 5.

Cells from a dihydrofolate reductase-deficient Chinese hamster ovary cell line were hybridized to human fetal skin fibroblast cells. Nineteen dihydrofolate reductase-positive hybrid clones were isolated and characterized. Cytogenetic and biochemical analyses of these clones have shown that the human dihydrofolate reductase (DHFR) gene is located on chromosome 5. Three of these hybrid cell lines contained different terminal deletions of chromosome 5. An analysis of the breakpoints of these deletions has demonstrated that the DHFR gene resides in the q11----q22 region.     

Assignment of the human ferrochelatase gene (FECH) and a locus for protoporphyria to chromosome 18q22.

We have mapped the human gene for ferrochelatase (FECH; ferroheme-protolyase, EC 4.99.1.1) to chromosome 18 by hybridization of cDNA to sorted chromosomes. The probe was obtained by PCR-directed amplification of a human marrow cDNA library in lambda gt 10. Subchromosomal localization of ferrochelatase to 18q22 was determined by chromosomal hybridization in situ using a human ferrochelatase genomic clone in lambda EMBL 3 that contained a 20-kb insert. Since ferrochelatase activity is deficient in patients with the inherited disease erythropoietic protoporphyria, a locus for this disease may be assigned to 18q22, one of few monogenic defects that have been mapped to this chromosome.