A homozygous deletion in RPE65 in a small Sardinian family with autosomal recessive retinal dystrophy.

PURPOSE: We have been engaged in an ongoing study to screen candidate genes for mutations in small families with various forms of autosomal recessive retinal dystrophy. Here we report the screening of a cohort of 14 families from Sardinia for mutations in the genes encoding the alpha- and beta-subunits of cGMP-phosphodiesterase and RPE65 (PDE6A, PDE6B, and RPE65). METHODS: Haplotype analysis was performed on each family using simple sequence repeat markers closely flanking or within each of the three gene candidates. For families in which a gene could not be ruled out from segregating with disease, exons of the gene from proband DNAs were screened for mutations by SSCPE (single strand conformation polymorphism electrophoresis). All variants found by SSCPE were sequenced directly. RESULTS: By haplotype analysis, 6/14, 11/14, and 4/13 families were ruled out for PDE6A, PDE6B, and RPE65, respectively. A few variants were found in the proband DNAs of the remaining families, but only one was significant: a 20 bp deletion in exon 4 of RPE65. The deletion co-segregated with disease in one family and caused a frame shift that produces a stop codon downstream. It was absent from the other Sardinian families that we tested, and from Sardinian and North American controls. Results of studies of phenotype in homozygotes and heterozygotes in this Sardinian family are compared with those from a non-Sardinian family recently reported to have the same RPE65 mutation. CONCLUSIONS: This RPE65 mutation, which appears to be quite restricted in its occurrence in Sardinia, leads to childhood onset severe retinal dystrophy or Leber congenital amaurosis. Affecteds of the other 13 plus two additional families were diagnosed with arRP. This family lived in an area of Sardinia where none of the others lived suggesting different ancestral origins.

Metabolite activation of crassulacean Acid metabolism and c(4) phosphoenolpyruvate carboxylase.

The effects of glycine, alanine, serine, and various phosphorylated metabolites on the activity of phosphoenolpyruvate (PEP) carboxylase from Zea mays and Crassula argentea were studied. The maize enzyme was found to be activated by amino acids at a site that is separate from the glucose 6-phosphate binding site. The combination of glycine and glucose 6-phosphate synergistically reduced the apparent K(m) of the enzyme for PEP and increased the apparent V(max). Of the amino acids tested, glycine showed the lowest apparent K(a) and caused the greatest activation. d-Isomers of alanine and serine were more effective activators than the l-isomers. Unlike the maize enzyme, the Crassula enzyme was not activated by amino acids. Activation of either the Crassula or maize enzyme by glucose 6-phosphate occurred without dephosphorylation of the activator molecule. Furthermore, the Crassula enzyme was activated by two compounds containing phosphonate groups whose carbon-phosphorus bonds were not cleaved by the enzyme. A study of analogs of glucose 6-phosphate with Crassula PEP carboxylase revealed that the identity of the ring heteroatom was a significant structural feature affecting activation. Activation was not highly sensitive to the orientation of the hydroxyl group at the second or fourth carbon positions or to the presence of a hydroxyl group at the second position. However, the position of the phosphate group was found to be a significant factor.