Chromosome mapping of the growth hormone receptor gene in man and mouse

Pituitary growth hormone (GH) is essential for normal growth and development in animals and GH deficiency leads to dwarfism. This hormone acts via specific high-affinity cell surface receptors found in liver and other tissues. The recent cloning and sequencing of cDNAs encoding human and rabbit GH receptors (GHR) has demonstrated that this receptor is unrelated to any previously described cell membrane receptor or growth factor receptor. We have used the cloned human GHR cDNA to map the GHR locus to the proximal short arm of human chromosome 5, region p13.1----p12, and to mouse chromosome 15 by Southern blot analysis and in situ hybridization. While human chromosome 5 carries several genes for hormone and growth factor receptors, GHR is the only growth-related gene so far mapped to the short arm. Inasmuch as GHR is the first gene with apparently homologous loci on human chromosome 5 and mouse chromosome 15, it identifies a new homologous conserved region. In humans, deficiency of GH receptor activity probably causes Laron-type dwarfism, an autosomal recessive disorder prevalent in Oriental Jews. In mice, the autosomal recessive mutation miniature (mn) is characterized by severe growth failure and early death and has been mapped to chromosome 15. Our assignment of Ghr to mouse chromosome 15 suggests this as a candidate gene for the mn mutation.     

Localization of the D5 dopamine receptor gene to human chromosome 4p15.1-p15.3, centromeric to the Huntington's disease locus.

Genes encoding G-protein-coupled receptors, including dopamine, serotonin, muscarinic cholinergic, and adrenergic receptors, play an important role in neurotransmission and may be involved in the pathophysiology of diseases such as Alzheimer's disease, Parkinson's disease, or Huntington's disease (HD). We mapped the gene encoding the D5 dopamine receptor (DRD5) to human chromosome 4p, an area implicated in HD and the Wolf-Hirschhorn syndrome, using gene-specific amplification with the polymerase chain reaction on a panel of somatic cell hybrids carrying different human chromosomes. Further localization of the DRD5 gene was carried out through the isolation and analysis of yeast artificial chromosomes, fluorescence in situ suppression hybridization to human metaphase chromosomes, and analysis of a panel of somatic cell hybrids subdividing human chromosome 4 into nine regions. The human DRD5 gene is located at 4p15.1-p15.33, centromeric to the location of the Huntington's disease locus although not in the obligate area containing the HD gene. The localization of the DRD5 gene to 4p15.1-p15.33 suggests the possibility that cis-position effects could be responsible for the altered D1-type dopamine receptor number observed in HD tissues or that the DRD5 gene could be a candidate for some of the abnormalities associated with the Wolf-Hirschhorn syndrome.     

Chromosomal localization of GABAA receptor subunit genes: relationship to human genetic disease

Hybridization of GABAA receptor probes to human chromosomes in situ and to DNA from sorted human chromosomes has localized the genes encoding a beta subunit and three isoforms of the alpha subunit. The alpha 2 and beta genes are both located on chromosome 4 in bands p12-p13 and may be adjacent. The alpha 1 gene is on chromosome 5 (bands q34-q35) and the alpha 3 gene is on the X chromosome. The alpha 3 locus was mapped also on the mouse X chromosome using genetic break-point analysis in an interspecies pedigree. The combined results locate the human alpha 3 gene within band Xq28, in a location that makes it a candidate gene for the X-linked form of manic depression.     

The gene for autosomal dominant cerebellar ataxia type II is located in a 5-cM region in 3p12-p13: genetic and physical mapping of the SCA7 locus.

Two families with autosomal dominant cerebellar ataxia with pigmentary macular dystrophy (ADCA type II) were investigated. Analysis of 23 parent-child couples demonstrated the existence of marked anticipation, greater in paternal than in maternal transmissions, with earlier age at onset and a more rapid clinical course in successive generations. Clinical analysis revealed the presence of a great variability in age at onset, initial symptom, and associated signs, confirming the characteristic clinical heterogeneity of ADCA type II. The gene for ADCA type II previously was mapped to the spinocerebellar ataxia 7 (SCA7) locus on chromosome 3p12-p21.1. Linkage analysis of the two new families of different geographic origin confirmed the characteristic genetic homogeneity of ADCA type II, distinguishing it from ADCA type I. Haplotype analysis permitted refinement of the SCA7 region to the 5-cM interval between markers D3S1312 and D3S1600 on chromosome 3p12-p13. Eighteen sequence-tagged sites were used for the construction of an integrated map of the candidate region, based on a YACs contig. The entire candidate region is contained in a single nonchimeric YAC of 660 kb. The probable involvement of a CAG trinucleotide expansion, suggested by previous studies, should greatly facilitate the identification of the gene for ADCA type II.     

Dominant intermediate Charcot-Marie-Tooth type C maps to chromosome 1p34-p35

Dominant intermediate Charcot-Marie-Tooth (DI-CMT) neuropathy is a genetic and phenotypic variant of classical CMT, characterized by intermediate nerve conduction velocities and histological evidence of both axonal and demyelinating features. We report two unrelated families with intermediate CMT linked to a novel locus on chromosome 1p34-p35 (DI-CMTC). The combined haplotype analysis in both families localized the DI-CMTC gene within a 6.3-cM linkage interval flanked by markers D1S2787 and D1S2830. The functional and positional candidate genes, Syndecan 3 (SDC3), and lysosomal-associated multispanning membrane protein 5 (LAPTM5) were excluded for pathogenic mutations.     

Smallest region of overlap in Wilms tumor deletions uniquely implicates an 11p13 zinc finger gene as the disease locus.

The development of Wilms tumor (WT) has been associated with the inactivation of a "tumor suppressor" locus in human chromosome 11 band p13. Several WTs that exhibit homozygous deletions of an 11p13 candidate WT gene in its entirety have been reported. We report here a partial deletion of the candidate gene which, upon comparison with other documented homozygous deletions, permitted a precise definition of the critical genomic target in Wilms tumor. The smallest region of overlap between these deletions is a 16-kb segment of DNA encompassing the 5' exon(s) of an 11p13 gene coding for a zinc finger protein, together with an associated CpG island. This finding supports the notion that the candidate gene in question corresponds to the 11p13 WT1 Wilms tumor locus.     

Localization of the gene for autosomal recessive congenital hereditary endothelial dystrophy (CHED2) to chromosome 20 by homozygosity mapping.

Congenital hereditary endothelial dystrophy (CHED) is a corneal disorder that presents with diffuse bilateral corneal clouding. Vision may be severely impaired, and many patients require corneal transplantation. Both autosomal dominant (AD) and autosomal recessive (AR) forms of the disorder have been described. The gene responsible for AD CHED (HGMW-approved symbol CHED1) has been mapped to the pericentromeric region of chromosome 20. Investigating a large, consanguineous Irish pedigree with autosomal recessive CHED, we have previously excluded linkage to this AD CHED locus. We now describe a genome-wide search using homozygosity mapping and DNA pooling. Evidence of linkage to chromosome 20p was demonstrated with a maximum lod score of 9.30 at a recombination fraction of 0.0 using microsatellite marker D20S482. A region of homozygosity in all affected individuals was identified, narrowing the disease gene locus to an 8-cM region flanked by markers D20S113 and D20S882. This AR CHED (HGMW-approved symbol CHED2) disease gene locus is physically and genetically distinct from the AD CHED locus.     

秦川牛GHR基因SNPs及其与生长性状关系的研究

利用PCR-SSCP技术研究了136头秦川牛GHR基因第10外显子多态性, 所研究的秦川牛群体GHR基因该座位存在多态性, 发现了A、B、C 3个等位基因, 其基因频率依次为0.5956、0.2905、0.1140, 并且群体处于Hardy-Weinberg平衡状态。对纯合基因型个体进行测序, 测序结果, 该座位存在两个突变位点。通过构建最小二乘线性模型, 分析了生长激素受体基因与生长性状的关系, 表明生长激素受体基因的AB基因型效应在部分生长性状上高于其他基因型, 差异达到显著水平, 提示GHR基因有可能作为秦川牛生长性状的侯选基因。     

Polymorphism within the 3' flanking region of the bovine growth hormone receptor gene

Growth hormone receptor (GHR) has a major role in the regulation of growth hormone action, and thus, is an obvious candidate gene associated with milk production traits in mammals. The present authors have sequenced 273 bp of the 3' flanking region of the bovine GHR , and found three length variants and one base substitution polymorphism in this region. Allele frequencies of the length variants differ between Finnish native and commercial dairy cattle breeds. The chromosomal localization of GHR was confirmed to bovine chromosome 20 by synteny mapping and linkage analysis.     

Chromosome 7p disruptions in Silver Russell syndrome: delineating an imprinted candidate gene region

Silver-Russell syndrome (SRS) is characterised by pre- and postnatal growth restriction (PNGR) and additional dysmorphic features including body asymmetry and fifth finger clinodactyly. The syndrome is genetically heterogeneous, with a number of chromosomes implicated. However, maternal uniparental disomy for chromosome 7 has been demonstrated in up to 10% of all cases. Three SRS probands have previously been described with a maternally inherited duplication of 7p11.2-p13, defining this as a candidate region. Over-expression of a maternally transcribed, imprinted gene with growth-suppressing activity located within the duplicated region, or breakpoint disruption of genes or regulatory sequences, may account for the phenotype in these cases. Here we describe two additional SRS patients and four probands with PNGR with a range of cytogenetic disruptions of 7p, including duplications, pericentric inversions and a translocation. An incomplete contig consisting of 80 PACs and BACs from the centromere to 7p14 was constructed. Individual clones from this contig were used as FISH probes to map the breakpoints in the six new cases and the three duplication probands previously described. Our data provide further evidence for a candidate SRS region at 7p11.1-p14. A common breakpoint region was identified within 7p11.2 in all nine cases, pinpointing this specific interval. The imprinting status of genes within the 7p11.1-p14 region flanked by the most extreme breakpoints have been analysed using both somatic cell hybrids containing a single full-length maternally or paternally derived chromosome 7 and expressed single nucleotide polymorphisms in paired fetal and maternal samples.     

Loss of heterozygosity in a gene coding for a thyroid hormone receptor in lung cancers

The ERBA beta gene codes for a DNA-binding thyroid hormone receptor (THR) and maps to chromosome 3p21-p25, overlapping a 3p deletion characterizing small-cell lung carcinoma (SCLC). A DNA clone detecting an RFLP at the ERBA beta locus has been used to probe a large number of lung tumors. Virtually all SCLC had lost heterozygosity, showing that the 3p deletion in SCLC includes this gene. A substantial but smaller proportion of non-small-cell carcinomas had lost heterozygosity at ERBA beta. Among all non-small-cell tumors some had lost heterozygosity at the proximal locus DNF15S2 (band 3p21) but not at ERBA beta, whereas none were found where the reverse was true. Therefore, the locus which plays a role in non-small-cell tumorigenesis probably lies closer to DNF15S2 than to ERBA beta and is almost certainly not the latter.     

Assignment of a gene (NEM1) for autosomal dominant nemaline myopathy to chromosome 1

Nemaline myopathy (NEM) is a neuromuscular disorder characterized by the presence, in skeletal muscle, of nemaline rods composed at least in part of alpha-actinin. A candidate gene and linkage approach was used to localize the gene (NEM1) for an autosomal dominant form (MIM 161800) in one large kindred with 10 living affected family members. Markers on chromosome 19 that were linked to the central core disease gene, a marker at the complement 3 locus, and a marker on chromosome 1 at the alpha-actinin locus exclude these three candidate genes. The family was fully informative for APOA2, which is localized to 1q21-q23. NEM1 was assigned to chromosome 1 by close linkage for APOA2, which is localized to 1q21-q23. NEM1 was assigned to chromosome 1 by close linkage to APOA2, with a lod score of 3.8 at a recombination fraction of 0. Recombinants with NGFB (1p13) and AT3 (1q23-25.1) indicate that NEM1 lies between 1p13 and 1q25.1. In total, 47 loci were investigated on chromosomes 1, 2, 4, 5, 7-11, 14, 16, 17, and 19, with no indications of significant linkage other than to markers on chromosome 1.     

Molecular genetic investigations of the mechanism of tumourigenesis in von Hippel-Lindau disease: analysis of allele loss in VHL tumours

Von Hippel-Lindau (VHL) disease is a dominantly inherited familial cancer syndrome characterised by the development of retinal and central nervous system haemangioblastomas, renal cell carcinoma (RCC), phaeochromocytoma and pancreatic tumours. The VHL disease gene maps to chromosome 3p25-p26. To investigate the mechanism of tumourigenesis in VHL disease, we analysed 24 paired blood/tumour DNA samples from 20 VHL patients for allele loss on chromosome 3p and in the region of tumour suppressor genes on chromosomes 5, 11, 13, 17 and 22. Nine out of 24 tumours showed loss of heterozygosity (LOH) at at least one locus on chromosome 3p and in each case the LOH included the region to which the VHL gene has been mapped. Chromosome 3p allele loss was found in four tumour types (RCC, haemangioblastoma, phaeochromocytoma and pancreatic tumour) suggesting a common mechanism of tumourigenesis in all types of tumour in VHL disease. The smallest region of overlap was between D3S1038 and D3S18, a region that corresponds to the target region for the VHL gene from genetic linkage studies. The parental origin of the chromosome 3p25-p26 allele loss could be determined in seven tumours from seven familial cases; in each tumour, the allele lost had been inherited from the unaffected parent. Our results suggest that the VHL disease gene functions as a recessive tumour suppressor gene and that inactivation of both alleles of the VHL gene is the critical event in the pathogenesis of VHL neoplasms. Four VHL tumours showed LOH on other chromosomes (5q21, 13q, 17q) indicating that homozygous VHL gene mutations may be required but may not be sufficient for tumourigenesis in VHL disease.     

Chromosomal localization of three human D5 dopamine receptor genes

It is currently thought that genetic predisposition to imbalances in dopaminergic transmission may underlie several neurological disorders, including schizophrenia, manic depression, Tourette syndrome, Parkinson disease, Huntington disease, and alcohol abuse. Originally two receptors, D1 and D2, were thought to account for all of the pharmacological actions of dopamine. However, through homology screening three additional genes, D3, D4, and D5, and two pseudogenes closely related to D5 have been characterized. To begin our genomic and evolutionary analyses of the human D5 dopamine receptor gene and its two pseudogenes, we have mapped each of them to their respective chromosomes. By combining in situ hybridization results with sequence analysis of PCR products from microdissected chromosomes, somatic cell hybrids, and radiation hybrids, we have assigned DRD5 (the locus containing the functional human D5 receptor gene) to chromosome 4p16.1, DRD5P1 (the locus containing D5 pseudogene 1) to chromosome 2p11.1-p11.2, and DRD5P2 (the locus of D5 pseudogene 2) to chromosome 1q21.1.     

A gene for X-linked idiopathic congenital nystagmus (NYS1) maps to chromosome Xp11.4-p11.3

Congenital nystagmus (CN) is a common oculomotor disorder (frequency of 1/1,500 live births) characterized by bilateral uncontrollable ocular oscillations, with onset typically at birth or within the first few months of life. This condition is regarded as idiopathic, after exclusion of nervous and ocular diseases. X-linked, autosomal dominant, and autosomal recessive modes of inheritance have been reported, but X-linked inheritance is probably the most common. In this article, we report the mapping of a gene for X-linked dominant CN (NYS1) to the short arm of chromosome X, by showing close linkage of NYS1 to polymorphic markers on chromosome Xp11.4-p11.3 (maximum LOD score of 3.20, over locus DXS993). Because no candidate gene, by virtue of its function, has been found in this region of chromosome Xp, further studies are required, to reduce the genetic interval encompassing the NYS1 gene. It is hoped that the complete gene characterization will address the complex pathophysiology of CN.     

A mutation in the SOS1 gene causes hereditary gingival fibromatosis type 1

Hereditary gingival fibromatosis (HGF) is a rare, autosomal dominant form of gingival overgrowth. Affected individuals have a benign, slowly progressive, nonhemorrhagic, fibrous enlargement of the oral masticatory mucosa. Genetic loci for autosomal dominant forms of HGF have been localized to chromosome 2p21-p22 (HGF1) and chromosome 5q13-q22 (HGF2). To identify the gene responsible for HGF1, we extended genetic linkage studies to refine the chromosome 2p21-p22 candidate interval to approximately 2.3 Mb. Development of an integrated physical and genetic map of the interval identified 16 genes. Sequencing of these genes, in affected and unaffected HGF1 family members, identified a mutation in the Son of sevenless-1 (SOS1) gene in affected individuals. In this report, we describe the genomic structure of the SOS1 gene and present evidence that insertion of a cytosine between nucleotides 126,142 and 126,143 in codon 1083 of the SOS1 gene is responsible for HGF1. This insertion mutation, which segregates in a dominant manner over four generations, introduces a frameshift and creates a premature stop codon, abolishing four functionally important proline-rich SH3 binding domains normally present in the carboxyl-terminal region of the SOS1 protein. The resultant protein chimera contains the wild-type SOS1 protein for the N-terminal amino acids 1-1083 fused to a novel 22-amino acid carboxyl terminus. Similar SOS1 deletion constructs are functional in animal models, and a transgenic mouse construct with a comparable SOS1 chimera produces a phenotype with skin hypertrophy. Clarification of the functional role of this SOS1 mutant has implications for understanding other forms of gingival fibromatosis and corrective gingival-tissue management.     

Genetic aberration in primary hepatocellular carcinoma：correlation between p53 gene mutation and loss—of—heterozygosity on chromosome 16q21—q23 and 9p21—p23

To elucidate the molecular pathology underlying the development of hepatocellular carcinoma (HCC),we used 41 highly polymorphic microsatellite markers to examine 55 HCC and corresponding non-tumor liver tissues on chromosome 9,16 and 17.Loss-of-heterozygosity(LOH) is observed with high frequency on chromosomal region 17p13(36k/55,65%),9q21-p23(28/55,51%),16q21-23(27/55,49%) in tumors.Meanwhile,microsatellite instability is rarely found in these microsatellite loci.Direct sequencing was performed to detect the tentative mutation of tumor wuppressor genes in these regions:p53,MTS1/p16,and CDH1/E-cadherin.Wihin exon 5-9 of p53 gene,14 out of 55 HCC specimens(24%) have somatic mutations,and nucleotide deletion of this gene is reported in HCC for the first time.Mutation in MTS1/p16 is found only in one tumor case.We do not find mutations in CDH1/E-cadherin.Furthermore,a statistically significant correlation is present between p53 gene mutation and loss of chromosome region 16q21-q23 and 9p21-p23,which indicates that synergism between p53 inactivation and deletion of 16q21-q23 and 9p21-p23 may play a role in the pathogenesis of HCC.     

Localization of the human KRAB finger gene ZNF117 (HPF9) to chromosome 7q11.2.

A cluster of Krüppel type zinc finger genes of the KRAB subclass has recently been localized on human chromosome 19p12-p13.1. We now report that ZNF117 (HPF9), a closely related zinc finger gene of this KRAB subfamily, has been assigned to a distinct locus in the human genome: chromosome band 7q11.2.