Identification of a mutation in the MP19 gene, Lim2, in the cataractous mouse mutant To3.

PURPOSE: Lim2, the gene encoding the second most abundant lens specific integral membrane protein, MP19, has recently been proposed as an ideal candidate gene for the cataractous mouse mutant, To3. The aim of this study was to screen the Lim2 gene in the To3 mutant for a genetic lesion that was correlated and consistent with the mutant phenotype. METHODS: Genomic DNA was isolated from both normal mouse parental strains as well as the heterozygous and homozygous To3 cataract mutant. PCR was used to generate overlapping fragments of the entire Lim2 gene from these DNAs. The coding regions, including splice junctions and the translational termination site, of these fragments were then sequenced. RESULTS: A single G -> T transversion was identified within the first coding exon of the Lim2 gene in the To3 mutant DNA. This DNA change results in the nonconservative substitution of a valine for the normally encoded glycine at amino acid 15 of the MP19 polypeptide. CONCLUSIONS: The identified genetic lesion in the Lim2 gene of the cataractous mouse mutant, To3, confirms Lim2 as an ideal candidate gene. Future transgenic experiments should provide proof or disproof of a causative relationship between the identified mutation and the cataractous phenotype. These studies indicate that MP19 may play an important role in both normal lens development and cataractogenesis, and warrants more intense investigation of its role within the ocular lens.

Lim2(To3) transgenic mice establish a causative relationship between the mutation identified in the lim2 gene and cataractogenesis in the To3 mouse mutant.

PURPOSE: Lim2 is the gene encoding the ocular lens-specific intrinsic membrane protein MP19. We previously reported finding a single nonconservative G->T transversion in exon two of the Lim2 gene. This mutation was linked to the cataract in the To3 (Total opacity number 3) mouse mutant, confirming Lim2 as an ideal candidate gene for the To3 cataract. The aim of the present study was to substantiate a causative relationship between the mutation in the Lim2 gene and cataractogenesis in the To3 mouse mutant. To this end a Lim2To3 transgene cassette was engineered and introduced into fertilized normal mouse embryos to test its ability to induce cataractogenic lens development. METHODS: A Lim2 genomic clone was isolated and purified from a murine 129/SvJ genomic library. A restriction endonuclease map of the gene was generated using classical Southern techniques. The murine Lim2 promoter was characterized by transfecting primary chicken lens epithelial cells with Lim2 promoter-CAT reporter constructs and assaying promoter activity and specificity. This genomic clone was then used in conjunction with PCR to generate a Lim2To3 transgene cassette. After sequencing of the PCR engineered portion, the Lim2To3 transgene was then used to generate Lim2To3 transgenic mice via pronuclear injection. Founder mice and their offspring from outcrosses and intercrosses were characterized by ophthalmic examination, PCR and Southern DNA analysis, RT-PCR mRNA analysis, and histology of lens sections. RESULTS: Two mice, from independent microinjections, were identified as positive for presence of the Lim2To3 transgene cassette as well as presence of bilateral congenital cataracts and reduced eye size and mass. One of these founders was incapable of germline transmission of the transgene to offspring and was not characterized further. The other was capable of germline transmission and was characterized as described above. PCR DNA analysis revealed a perfect concordance between presence of the Lim2To3 transgene cassette and congenital cataract in offspring of this founder. Transgenic hemizygotes exhibited cataract and a reduction in eye and lens size and mass, while transgenic "homozygotes" presented with a more severe cataract and microphthalmic reduction in eye and lens size and mass. Southern analysis revealed approximately 2 copies of the transgene cassette integrated into a single chromosomal site in the founder and all hemizygous offspring. RT-PCR analysis revealed a very low ratio of Lim2To3 transgenic mRNA compared to endogenous normal Lim2. Finally, histology revealed that lens development was abnormal in mutant transgenic animals by embryonic day E15. By E19, just prior to birth, gross disorganization of secondary fibers was observed in mutants. CONCLUSIONS: These transgenic experiments firmly establish a causative relationship between the previously identified mutation in the Lim2 gene and cataractogenesis in the To3 mouse mutant. The low levels of mutant mRNA produced by the transgene cassette as compared to endogenous levels of normal Lim2 mRNA provides evidence that this dominant mutation results in a mutant MP19 protein with altered function rather than simply loss of function.

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.

A mutation in the connexin 50 (Cx50) gene is a candidate for the No2 mouse cataract.

PURPOSE: The No2 cataractous mouse mutant displays a bilateral, congenital, hereditary nuclear opacity of the ocular lens. The aim of this work was to identify and subsequently screen an optimal candidate gene for a mutation correlated and consistent with the observed phenotype. METHODS: The No2 cataract was mapped in relation to genes and microsatellite markers by crossing to the wild mouse strain Mus spretus and then backcrossing to the inbred strain C3H/ HeH. The Cx50 (MP70) protein coding region and flanking sequences were amplified from normal parental as well as heterozygous and homozygous mutant genomic DNAs. These PCR products were then sequenced directly. Sequence data was corroborated by restriction analysis of PCR products. RESULTS: Mapping of the No2 cataract placed it in the vicinity of Gja8, the gene encoding connexin 50 (MP70), a major component of lens fiber gap junctions. Amplification and subsequent sequencing of the Cx50 protein coding regions revealed a single A-->C transversion within codon 47. This sequence change resulted in the creation of an HhaI restriction endonuclease restriction site, allowing for corroboration of the sequence data via restriction analysis using this enzyme. The sequence alteration is also predicted to result in the nonconservative substitution of alanine (Ala) for the normally encoded aspartic acid (Asp) at this position within the polypeptide. CONCLUSIONS: The identified mutation in Gja8 is both correlated and consistent with the cataract observed in the No2 mouse mutant, making it an ideal candidate for the cataract. This study provides the first evidence that a mutation in a lens connexin can result in congenital hereditary cataract, highlighting the importance of lens connexins in maintaining lens transparency.