Novel mutations in the L1CAM gene support the complexity of L1 syndrome

X-linked hydrocephalus, MASA syndrome, X-linked complicated Spastic Paraplegia Type I and X-linked partial agenesis of the corpus callosum are the four rare diseases usually referred to L1 syndrome, caused by mutations in the L1CAM gene. By direct sequencing of L1CAM in 16 patients, we were able to identify seven mutations, five of which were never described before. Patients' phenotype evaluation revealed a correlation between the number of clinical features typical of L1 syndrome and the chance to find causative mutation. Our findings support that L1CAM mutations are associated with widely heterogeneous phenotypes, however the occurrence of several clinical features remains the best criterion for planning molecular testing both in familial and apparently sporadic cases

A deletion 3' to the PAX6 gene in familial aniridia cases

PURPOSE: PAX6 mutations cause aniridia as well as other various congenital eye abnormalities. Aniridia can be due to both point mutations and chromosomal deletions/rearrangements. Therefore, a complete search for PAX6 gene alterations in aniridia subjects requires a technically complex approach involving the comprehension of fluorescence in situ hybridization (FISH) analysis. In the present study, an Italian casistic of aniridia patients has been investigated and a quantitative polymerase chain reaction (PCR) assay to detect PAX6 gene deletions was set up. METHODS: Twenty-one aniridia patients were screened for point mutations (missense, nonsense, splicing-affecting, and short insertion/deletion) by using single-stranded conformational polymorphism (SSCP) and denaturing high performance liquid chromatography (dHPLC). To reveal deletions not detectable by SSCP or dHPLC, a quantitative PCR approach was set up for the PAX6 structural gene and for regions 5' and 3' to it at the level of WT1 and ELP4, respectively. RESULTS: Point mutations were found in 7 out of 21 patients. Three out of twenty-one patients showed deletions at the level of the PAX6 structural gene. In addition, two familial cases showed an undamaged PAX6 gene but a deletion in the region 3' to it at level of the ELP4 gene. In one of the families, the presence of the deletion has been confirmed by linkage analysis of polymorphic markers. CONCLUSIONS: In our casistic, a significant fraction of familial aniridia patients appears to be caused by a 3' deletion to PAX6, suggesting that evaluation of this alteration should be included in routine procedures of aniridia patients analysis. The quantitative PCR assay described here represents a simple approach to accomplish this task