Regional mapping of the human MP70 (Cx50; connexin 50) gene by fluorescence in situ hybridization to 1q21.1.

PURPOSE: Gap junctions play a critical role in the metabolic homeostasis and maintenance of transparency of fibers within the ocular lens. As part of a long-term effort to establish the relationship between lens gap junction proteins, normal lens development, and cataractogenesis, we report here the regional localization of the human MP70 (Connexin 50) gene. METHODS: Fluorescence in situ hybridization (FISH) was used to regionally map the human MP70 gene. The DNA probe contained the entire MP70 coding region within a clone isolated from a human genomic DNA library. RESULTS: The human gene encoding the lens intrinsic membrane protein MP70 was regionally mapped to q21.1 on the long arm of chromosome 1. CONCLUSIONS: This study confirms the previous provisional assignment of MP70 to human chromosome 1 and regionally localizes the gene to 1q21.1. When combined with previous mapping information, these data are consistent with the hypothesis that a genetic lesion in the gene encoding the lens intrinsic membrane protein MP70 may be the underlying molecular defect for zonular pulverulent (Coppock) cataract. Furthermore, these combined data support the hypothesis that other forms of human hereditary cataract may be the result of a mutation in one or more of the genes encoding gap junction proteins found in the ocular lens.

Map refinement of locus RP13 to human chromosome 17p13.3 in a second family with autosomal dominant retinitis pigmentosa.

In order to elucidate the genetic basis of autosomal dominant retinitis pigmentosa (adRP) in a large eight-generation family (UCLA-RP09) of British descent, we assessed linkage between the UCLA-RP09 adRP gene and numerous genetic loci, including eight adRP candidate genes, five anonymous adRP-linked DNA loci, and 20 phenotypic markers. Linkage to the UCLA-RP09 disease gene was excluded for all eight candidate genes analyzed, including rhodopsin (RP4) and peripherin/RDS (RP7), for the four adRP loci RP1, RP9, RP10 and RP11, as well as for 17 phenotypic markers. The anonymous DNA marker locus D17S938, linked to adRP locus RP13 on chromosome 17p13.1, yielded a suggestive but not statistically significant positive lod score. Linkage was confirmed between the UCLA-RP09 adRP gene and markers distal to D17S938 in the chromosomal region 17p13.3. A reanalysis of the original RP13 data from a South African adRP family of British descent, in conjunction with our UCLA-RP09 data, suggests that only one adRP locus exists on 17p but that it maps to a more telomeric position, at band 17p13.3, than previously reported. Confirmation of the involvement of RP13 in two presumably unrelated adRP families, both of British descent, suggests that this locus is a distinct adRP gene in a proportion of British, and possibly other, adRP families.

Assignment of the zeta-crystallin gene (CRYZ) to human chromosome 1p22-p31 and identification of restriction fragment length polymorphisms.

zeta-Crystallin is a lens protein that has been associated with autosomal dominant congenital cataracts in guinea pigs and thus is a candidate for human congenital cataracts. We have assigned the zeta-crystallin gene (CRYZ) to human chromosome 1 using a Southern panel of 17 human-mouse somatic cell hybrids and regionally localized it to 1p22-p31 by fluorescence in situ hybridization. Five restriction fragment length polymorphisms were identified by analyzing the DNA from 10 unrelated, unaffected individuals. Our results will permit evaluation of its role in human cataractogenesis.

Linkage analysis of Norrie disease with an X-chromosomal ornithine aminotransferase locus.

Norrie disease is a rare disease of newborn males caused by prenatal or perinatal retinal detachment, which may be associated with mental retardation, psychosis, and/or hearing loss. DXS7 (L1.28) and MAO A and B loci have been linked to the ND locus on the short arm of the X chromosome. Sequences homologous to OAT also have been mapped to the short arm of the X chromosome. We performed linkage analyses between the ND locus and one of the OAT-like clusters of sequences on the X chromosome (OATL1), using a ScaI RFLP in a ND family, and increased the previously calculated lod score (z) to over 3 (3.38; theta = 0.05). Similarly, we calculated a lod score of 4.06 (theta = 0.01) between the OATL1 and DXS7 loci. Alone, the OATL1 ScaI RFLP system is expected to be informative in 48% of females. If this system were used in combination with the DXS7 TaqI polymorphism, 71% of females would be informative for at least one of the markers and 21% would be informative for both. Because the OATL1 ScaI RFLP is a relatively common polymorphism, this system should be useful for the identification of ND carriers and affected male fetuses and newborns.

The cytogenetics of ataxia telangiectasia.

Ataxia-telangiectasia (AT) is a heterogeneous autosomal recessive disorder marked by cerebellar ataxia, oculocutaneous telangiectases, hypersensitivity to ionizing radiation, immunodeficiency, and cancer susceptibility. AT is also a spontaneous chromosomal breakage syndrome, notable for tissue-specific cytogenetic changes and telomeric fusions. Molecular characterization of rearrangements specific to T-lymphocytes suggests that a DNA repair/processing defect is potentially responsible for the diverse array of chromosomal abnormalities observed in a variety of AT cell types.

Tissue specificity of chromosomal rearrangements in ataxia-telangiectasia.

Cytogenetic studies of lymphocytes and fibroblasts from individuals with ataxia-telangiectasia (AT) demonstrate spontaneous chromosomal breakage. In the AT lymphocytes, this damage results in a high frequency of balanced rearrangements involving chromosome bands 7p14, 7q35, 14q12, and 14q32. The T-cell receptor alpha, beta, and gamma chain gene complexes and the immunoglobulin heavy chain gene complex, all of which may be functional in lymphocytes, have been localized to these bands. To assess the relationship between genes at these breakpoints and the entirety of the AT phenotype, we undertook a detailed cytogenetic analysis of fibroblasts and lymphocytes from seven AT homozygotes. Our findings indicate that the rearrangements present in the lymphocytes are not commonly observed in the fibroblasts, despite the increased instability of chromosomes from the cells relative to lymphocytes. Furthermore, the changes in the fibroblasts are neither consistent within nor between patients, suggesting that chromosome rearrangement occurs more randomly in this tissue. Therefore, differential site-specific damage in separate tissue may generate the distinct features of the disease in those tissues and may account for the pleiotrophic effects of the AT gene.