DNA sequence comparison of human and mouse retinitis pigmentosa GTPase regulator (RPGR) identifies tissue-specific exons and putative regulatory elements.

Retinitis pigmentosa 3 (RP3) is a progressive retinal degeneration due to mutations in the X-linked RPGR gene. Transcription studies in human and mouse tissues have revealed ubiquitously expressed transcripts and also an exceptional high number of tissue-specific alternative splice variants. However, regulation of tissue-specific expression and splicing is unclear, but this is of particular interest as mutations in this ubiquitously expressed gene lead to severe retinal degeneration, while other tissues are unaffected. To elucidate the conservation pattern of RPGR and to identify additional tissue-specific exons and putative regulatory elements we performed comparative genomic sequencing of the human and mouse RPGR gene. Each of the genes spans a region of nearly 59 kb, and all previously identified exons are conserved between the two species. DNA sequence comparison identified 28 conserved sequence elements (CSEs) in introns, upstream of exon 1, within the promotor region, and downstream of the most 3' exon. Some of the intronic CSEs flank tissue-specific exons and therefore may represent important regulatory elements for alternative splicing. Comparative northern blot hybridization of ubiquitous and tissue-specific RPGR probes identified high molecular weight transcripts with similar expression patterns in both human and mouse. These transcripts range from 6 to 15 kb in size and suggest the presence of additional transcribed sequences within RPGR. Our cross-species sequence comparison enables us to define candidate regions that may explain these large transcripts and will therefore contribute to the understanding of RPGR expression and splicing.

A juvenile-onset, progressive cataract locus on chromosome 3q21-q22 is associated with a missense mutation in the beaded filament structural protein-2.

Juvenile-onset cataracts are distinguished from congenital cataracts by the initial clarity of the lens at birth and the gradual development of lens opacity in the second and third decades of life. Genomewide linkage analysis in a multigenerational pedigree, segregating for autosomal dominant juvenile-onset cataracts, identified a locus in chromosome region 3q21.2-q22.3. Because of the proximity of the gene coding for lens beaded filament structural protein-2 (BFSP2) to this locus, we screened for mutations in the coding sequence of BFSP2. We observed a unique C-->T transition, one that was not observed in 200 normal chromosomes. We predicted that this led to a nonconservative R287W substitution in exon 4 that cosegregated with cataracts. This mutation alters an evolutionarily conserved arginine residue in the central rod domain of the intermediate filament. On consideration of the proposed function of BFSP2 in the lens cytoskeleton, it is likely that this alteration is the cause of cataracts in the members of the family we studied. This is the first example of a mutation in a noncrystallin structural gene that leads to a juvenile-onset, progressive cataract.