Assignment of the βB1 Crystallin Gene (CRYBB1) to Human Chromosome 22 and Mouse Chromosome 5

By using primers complementary to the rat βB1 crystallin gene sequence, we amplified exons 5 and 6 of the orthologous human gene (CRYBB1). The amplified human segments displayed greater than 88% sequence homology to the corresponding rat and bovine sequences.CRYBB1was assigned to the group 5 region in 22q11.2–q12.1 by hybridizing the exon 6 PCR product to somatic cell hybrids containing defined portions of human chromosome 22. The exon 5 and exon 6 PCR products ofCRYBB1were used to localize, by interspecific backcross mapping, the mouse gene (Crybb1) to the central portion of chromosome 5. Three other β crystallin genes (βB2(−1), βB3, and βA4) have previously been mapped to the same regions in human and mouse. We demonstrate that the βB1 and βA4 crystallin genes are very closely linked in the two species. These assignments complete the mapping and identification of the human and mouse homologues of the major β crystallins genes that are expressed in the bovine lens.     

Extinction of Albumin Gene Expression in a Panel of Human Chromosome 2 Microcell Hybrids

Expression of the serum albumin gene is extinguished in rat hepatoma microcell hybrids that retain mouse chromosome 1. These data define atrans-dominant extinguisher locus,Tse-2,on mouse chromosome 1. To localize the human TSE2 locus, we prepared and characterized rat/human microcell hybrids that contained either human chromosome 1 or chromosome 2, the genetic homologues of mouse chromosome 1. Rat hepatoma microcell hybrids retaining a derivative human chromosome 1 [der 1 t(1;17)(p34.3;q11.2)] expressed their serum albumin genes at levels similar to those of parental hepatoma cells. In contrast, microcell transfer of human chromosome 2 into rat hepatoma recipients produced karyotypically heterogeneous collections of hybrid clones, some of which displayed dramatic albumin extinction phenotypes. For example, albumin mRNA levels in several extinguished microcell hybrids were reduced at least 500-fold, similar to albumin mRNA levels in hepatoma × fibroblast whole-cell hybrids. Expression of several other liver genes, including α1-antitrypsin, aldolase B, alcohol dehydrogenase, and phosphoenolpyruvate carboxykinase, was also affected in some of the microcell hybrids, but expression of these genes was not concordant with expression of albumin. Hybrid segregants were prepared from the albumin-extinguished hybrids, and reexpression of albumin mRNA and protein was observed in sublines that had lost or fragmented human chromosome 2. Finally, expression of mRNAs encoding the liver-enrichedtransactivators HNF-1, HNF-4, HNF-3α, and HNF-3β was not affected in any of the chromosome 2-containing hybrids. These data define and map a genetic locus on human chromosome 2 that extinguishes albumin gene expression intrans,and they suggest that TSE2-mediated extinction is independent of HNF-1, -4, -3α, and -3β expression.     

The Gene Encoding Protein Kinase SEK1 Maps to Mouse Chromosome 11 and Human Chromosome 17

We report the mapping of the human and mouse genes encoding SEK1 (SAPK/ERK kinase-1), a newly identified protein kinase that is a potent physiological activator of the stress-activated protein kinases. The human SERK1 gene was assigned to human chromosome 17 using genomic DNAs from human–rodent somatic cell hybrid lines. A specific human PCR product was observed solely in the somatic cell line containing human chromosome 17. The mouseSerk1gene was mapped to chromosome 11, closely linked toD11Mit4,using genomic DNAs from a (C57BL/6J ×Mus spretus)F₁×M. spretusbackcross.     

Five Subunit Genes of the Human Muscle Nicotinic Acetylcholine Receptor Are Mapped to Two Linkage Groups on Chromosomes 2 and 17

RFLPs were detected in the five subunit genes of the human muscle nicotinic acetylcholine receptor (nAChR) using genomic DNA or cDNA probes from the homologous mouse loci. The RFLPs at the alpha-, beta-, gamma-, delta-, and epsilon-subunit gene loci were analyzed for genetic linkage in 16 families (n = 188). Significant evidence was obtained for close linkage of the β- and ε-nAChR genes and much greater genetic distance between the α-nAChR gene and the γ/δ-nAChR gene complex. The linkage analysis program CRI-MAP was used to map the positions of the β- and ε-nAChR genes relative to seven markers on chromosome 17. The results indicate the β- and ε-nAChR genes are separated by about 5 cM and located in the region of chromosome 17p occupied by D17S1, D17S31, TP53, and D17S513. The statistical evidence was confirmed by hybridization of the β- and ε-nAChR probes to a panel of human-hamster somatic cell hybrids. The α-, γ-, and δ-nAChR genes were placed on a map of 13 chromosome 2 markers. The linkage analysis placed the nAChR genes at two sites on chromosome 2q about equidistant from the marker CRYGP1, with the α-nAChR gene about 27 cM proximal and the γ/δ-nAChR gene complex about 31 cM distal to CRYGP1.     

A Second Gene for Cerulean Cataracts Maps to the β Crystallin Region on Chromosome 22

Congenital cataracts are one of the most common major eye abnormalities and often lead to blindness in infants. At least a third of all cases are familial. Within this group, highly penetrant, autosomal dominant forms of congenital cataracts (ADCC) are most common. ADCC is a genetically heterogeneous group of disorders, in which at least eight different loci have been identified for nine clinically distinct forms. Among these, Armitageet al.(Nature Genet.9: 37–40, 1995) mapped a gene for cerulean blue cataracts to chromosome 17q24. Bodkeret al.(Am. J. Med. Genet.37: 54–59, 1990) described a large family with cerulean blue cataracts, in which the affected daughter of affected first cousins was presumed to be homozygous for the purported gene. We report linkage in this family to the region on chromosome 22q that includes two β crystallin genes (CRYBB2, CRYBB3) and one pseudogene (CRYBB2P1). The affected female in question is homozygous at all markers.     

Human Rod Monochromacy: Linkage Analysis and Mapping of a Cone Photoreceptor Expressed Candidate Gene on Chromosome 2q11

We have performed linkage analysis in eight families with rod monochromacy, an autosomal recessively inherited condition with complete color blindness. Significant linkage was found with markers located at the pericentromeric region of chromosome 2. A maximum lod score of 5.36 was obtained for marker D2S2333 at θ = 0.00. Mapping of meiotic breakpoints localized the disease gene between markers D2S2187 and D2S2229. Homozygosity for a number of subsequent markers indicating identity by descent was found in two families and provides evidence for a further refinement of the locus proximal to D2S373. This defines an interval of ≈3 cM covering theACHM2locus for rod monochromacy. Radiation hybrid mapping of theCNGA3gene encoding the α-subunit of the cGMP gated cation channel in human cone photoreceptors resulted in a maximum lod score of 16.1 with marker D2S2311 combined with a calculated physical distance of 6.19cR_10,000. Screening of the CEPH YAC library and subsequent STS mapping indicated the physical order cen–D2S2222–D2S2175–(D2S2187/D2S2311)–qtel ofmarkers on 2q11 and showed that theCNGA3gene maps most closely to D2S2187 and D2S2311. These data indicate that theCNGA3gene maps within the critical interval of theACHM2locus for rod monochromacy and thus is a candidate gene for this disease.     

Genetic Linkage Mapping of the Dehydroepiandrosterone Sulfotransferase (STD) Gene on the Chromosome 19q13.3 Region

In the human liver and adrenal, there is a single hydroxysteroid sulfotransferase, which catalyzes the transformation of dehydroepiandrosterone to dehydroepiandrosterone sulfate, the most abundantly circulating steroid in humans, and also catalyzes the sulfation of a series of other 3β-hydroxysteroids as well as cholesterol. Dehydroepiandrosterone sulfate serves as precursor for the formation of active androgens and estrogens in several peripheral tissues, indicating that hydroxysteroid sulfotransferase plays a pivotal role in controlling the hormonal action of sex steroids by regulating their bioavailability. We recently elucidated the structure of the gene encoding hydroxysteroid sulfotransferase (STD), also designated dehydroepiandrosterone sulfotransferase, which spans 17 kb and contains six exons. The STD gene was preliminarily assigned to chromosome 19 by polymerase chain reaction (PCR) amplification of DNA from a panel of human/rodent somatic cell hybrids. To locate the STD gene, the novel biallelic polymorphism found in intron 2 was genotyped in eight CEPH reference families by direct sequencing of PCR products. Two-point linkage analysis was first performed between the latter polymorphism and chromosome 19 markers from Généthon and NIH/CEPH. The closest linkage was observed with D19S412 (Z_max= 9.23; θ_max0.038) and HRC (Z_max= 5.95; θ_max0.036), located on the 19q13.3 region. A framework map including six Généthon markers flanking the polymorphic STD gene was created by multipoint linkage analysis. Thereafter, a high-resolution genetic map of the region was constructed, yielding to the following order: qter–D19S414–D19S224–D19S420–D19S217–(APOC2–D19S412)–(STD–HRC)– KLK–D19S22–D19S180–PRKCG–D19S418–tel.     

Mapping of theARIXHomeodomain Gene to Mouse Chromosome 7 and Human Chromosome 11q13

The recently described homeodomain protein ARIX is expressed specifically in noradrenergic cell types of the sympathetic nervous system, brain, and adrenal medulla. ARIX interacts with regulatory elements of the genes encoding the noradrenergic biosynthetic enzymes tyrosine hydroxylase and dopamine β-hydroxylase, suggesting a role for ARIX in expression of the noradrenergic phenotype. In the study described here, the mouse and human ARIX genes are mapped. Using segregation analysis of two panels of mouse backcross DNA, mouseArixwas positioned approximately 50 cM distal to the centromere of chromosome 7, nearHbb.HumanARIXwas positioned through analysis of somatic cell hybrids and fluorescencein situhybridization of human metaphase chromosomes to chromosome 11q13.3–q13.4. These map locations extend and further define regions of conserved synteny between mouse and human genomes and identify a new candidate gene for inherited developmental disorders linked to human 11q13.     

Cloning of cDNA and Genomic DNA Encoding Human Type XVIII Collagen and Localization of the α1(XVIII) Collagen Gene to Mouse Chromosome 10 and Human Chromosome 21

Types XV and XVIII collagen belong to a unique and novel subclass of the collagen superfamily for which we have proposed the name the MULTIPLEXIN family. Members of this class contain polypeptides with multiple triple-helical domains separated and flanked by non-triple-helical regions. In this paper, we report the isolation of human cDNAs and genomic DNAs encoding the α1(XVIII) collagen chain. Utilizing a genomic clone as probe, we have mapped the COL18A1 gene to chromosome 21q22.3 by fluorescence in situ hybridization. In addition, using an interspecific backcross panel, we have shown that the murine Col18a1 locus is on chromosome 10, close to the loci for Col6a1 and Col6a2.     

Assignment of a human DNA double-strand break repair gene (XRCC5) to chromosome 2

The Chinese hamster ovary (CHO-K1) cell mutant XRS-6 is defective in rejoining of DNA double-strand breaks and is hypersensitive to X-rays, γ-rays, and bleomycin. Radiation resistance or sensitivity of somatic cell hybrids constructed from the fusion of XRS-6 cells with primary human fibroblasts strongly correlated with the retention of human chromosome 2 isozyme and molecular markers. Discordancies between some chromosome 2 markers and the radiation resistance phenotype in some of the hybrid cells suggested the location of the X-ray repair cross complementing 5 (XRCC5) gene on the p arm of chromosome 2. Introduction of human chromosome 2 by microcell-mediated chromosome transfer into the radiation-sensitive XRS-6 cells resulted in hybrid cells in which the radiation sensitivity was complemented. The chromosome 2p origin of the complementing human DNA in the microcell hybrids was supported by fluorescent in situ hybridization analysis of human metaphases using human DNA amplified from the hybrids by inter-Alu-PCR as chromosome-painting probes. XRCC5 is therefore provisionally assigned to human chromosome 2p.     

The Gene for PAX7, a Member of the Paired-Box-Containing Genes, Is Localized on Human Chromosome Arm 1p36

The murine Pax-7 gene and the cognate human gene, formerly designated HuP1, are members of the multi-gene paired-box-containing class of developmental regulatory genes first identified in Drosophila. By analysis of somatic cell hybrids segregating human chromosomes, the gene encoding PAX7 was localized to human chromosome 1. Fluorescence in situ hybridization confirmed this assignment and allowed mapping of the gene to the terminal region of the short arm (1p36) of the chromosome. Additionally, these results confirm the extensive homology between human chromosome 1p and the distal segment of mouse chromosome 4, extending from bands C5 through E2.     

The Gene for Human Glutaredoxin (GLRX) Is Localized to Human Chromosome 5q14

Glutaredoxin is a small protein (12 kDa) catalyzing glutathione-dependent disulfide oxidoreduction reactions in a coupled system with NADPH, GSH, and glutathione reductase. A cDNA encoding the human glutaredoxin gene (HGMW-approved symbol GLRX) has recently been isolated and cloned from a human fetal spleen cDNA library. The screening of a human genomic library in Charon 4A led to the identification of three genomic clones. Using fluorescencein situhybridization to metaphase chromosomes with one genomic clone as a probe, the human glutaredoxin gene was localized to chromosomal region 5q14. This localization at chromosome 5 was in agreement with the somatic cell hybrid analysis, using DNA from a human–hamster and a human–mouse hybrid panel and using a human glutaredoxin cDNA as a probe.     

N-Cadherin Gene Maps to Human Chromosome 18 and Is Not Linked to the E-Cadherin Gene

cDNA clones encoding the human N-cadherin cell adhesion molecule have been isolated from an embryonic muscle library by screening with an oligonucleotide probe complementary to the chick brain sequence and chick brain cDNA probe lambda N2. Comparison of the predicted protein sequences revealed greater than 91% homology between chick brain, mouse brain, and human muscle N-cadherin cDNAs over the 748 amino acids of the mature, processed protein. A single polyadenylation site in the chick clone was also present and duplicated in the human muscle sequence. Immediately 3' of the recognition site in chick a poly(A) tail ensued; however, in human an additional 800 bp of 3' untranslated sequence followed. Northern analysis identified a number of major N-cadherin mRNAs. These were of 5.2, 4.3, and 4.0 kb in C6 glioma, 4.3 and 4.0 kb in human foetal muscle cultures, and 4.3 kb in human embryonic brain and mouse brain with minor bands of 5.2 kb in human muscle and embryonic brain. Southern analysis of a panel of somatic cell hybrids allowed the human N-cadherin gene to be mapped to chromosome 18. This is distinct from the E-cadherin locus on chromosome 16. Therefore, it is likely that the cadherins have evolved from a common precursor gene that has undergone duplication and migration to other chromosomal locations.     

Assignment of the CD45-AP Gene to the Centromeric End of Mouse Chromosome 19 and Human Chromosome 11q13.1–q13.3

CD45-AP is a recently identified phosphorylated protein that specifically associates with the leukocyte-specific transmembrane glycoprotein CD45. The gene for CD45-AP,Ptprcap(protein tyrosine phosphatase, receptor type c polypeptide associated protein), was mapped in mouse by typing the progeny of two multilocus crosses using the mouse CD45-AP cDNA as a Southern hybridization probe. The CD45-AP gene mapped to the centromeric region of Chr 19 proximal to the genesFth, Cd5,andPcna-rs.The gene for the human CD45-AP homologue,PTPRCAP,was localized to chromosome band 11q13.1–q13.3 by fluorescencein situhybridization using human genomic CD45-AP DNA as a hybridization probe. The genetic mapping of thePtprcap/PTPRCAPgenes extends the previously defined synteny conservation of various genes that have been assigned to these regions of the mouse and the human chromosomes.     

A deletion mutation in the βA1/A3 crystallin gene (CRYBA1/A3) is associated with autosomal dominant congenital nuclear cataract in a Chinese family

Congenital cataracts are an important cause of blindness worldwide. In a family of Chinese descent, a dominant congenital nuclear cataract locus was mapped to chromosome 17q11.1-12. The maximum LOD score, 2.49, at recombination fraction 0, was obtained for marker D17S1294. The results of both linkage and haplotype analyses defined a disease-gene to an 11.78-cM region harboring the gene coding for A1/A3 crystallin (CRYBA1/A3). Mutation analysis of the CRYBA1/A3 gene identified a 3-bp deletion in exon 4, which cosegregated with the disease risk in this family and was not observed in 100 normal chromosomes. This mutation resulted in the deletion of a highly conserved glycine at codon 91 (G91) and could be associated with an incorrect folding of A1/A3 crystallin. It highlights the physiological importance of crystallin and supports the role of CRYBA1/A3 in human cataracts formation.Y. Qi and H. Jia contributed equally to this work     

Linkage of the Murine Transforming Growth Factor α Gene with Igk, Ly-2, and Fabp1 on Chromosome 6

TGFα is a mitogenic polypeptide found in the conditioned media of transformed cell lines as well as in various solid tumors. Although its physiological role in normal tissues is uncertain, the autocrine action of TGFα on the EGF receptor is postulated to play a role in tumorigenesis. To explore the possibility that pre-existing mouse mutants might have concordance with the mouse TGFα locus (Tgfa) we sought to establish the chromosomal localization of the murine TGFα gene. Using Southern analysis we have detected NcoI and PvuII RFLP in the TGFα gene of progenitor RI mouse strains. These RFLPs have been used to analyze four different RI sets of DNA and to assign Tgfa to the 35-cM region of chromosome 6. Linkage has been established and the data suggest that the distance between Igk and wa-1 anchor loci may be less than 8 cM and that the gene order for the proximal to mid region of mouse chromosome 6 may be: Ggc-Xmmv27-[Brp-1, Lvp-1, Ms6-4]-[Igk, Ly2, Ly3 Odc-rs5, Rn7s-6, Fabp1]-[Tgfa/wa-1]-IL5-R. Homology of synteny has been further defined between the proximal region of mouse chromosome 6 and with the 2p 13-p11 region of human chromosome 2 encompassing TGFA, IGK, CD8A, and FABP1 .