Background/Aims: Allgrove syndrome is a rare autosomal recessive disorder characterized by alacrima, achalasia, and adrenal insufficiency. It is caused by mutations of the AAAS gene located on chromosome 12q13 encoding the WD-repeat protein ALADIN. The c.1331+1G>A mutation is one of the most common mutations described in the literature and was identified in Tunisian and Algerian populations. Herein, we describe the clinical and genetic profile of two families from Libya in North Africa associated with Allgrove syndrome. Methods: Two unrelated families clinically diagnosed with Allgrove syndrome were evaluated for sequence variations in the AAAS gene. Blood samples were collected, and isolated DNA derived from the subjects was amplified. The entire sequence of the AAAS gene was analyzed by PCR-RFLP and direct sequencing. Results: Molecular analysis revealed the major homozygous mutation (c.1331+1G>A) in all patients. The presence of a major mutation in Tunisia, Algeria and, as discovered in this report, in Libya in patients with Allgrove syndrome suggests the existence of an ancestral mutation and a founder effect in North Africa. Conclusions: The findings allow for a fast genetic counseling in North African families with Allgrove syndrome. To the best of our knowledge, this is the first report of Allgrove syndrome in Libya.
The Bloom syndrome (BS) is an autosomic recessive disorder comprising a wide range of abnormalities, including stunted growth, immunodeficiency, sun sensitivity and increased frequency of various types of cancer. Bloom syndrome cells display a high level of genetic instability, including a 10-fold increase in the sister chromatid exchanges (SCE) level. Bloom syndrome arises through mutations in both alleles of the BLM gene, which was identified as a member of the RecQ helicase family. In this study, we screened a Tunisian family with three BS patients. Cytogenetic analysis showed several chromosomal aberrations, and an approximately 14-fold elevated SCE frequency in BS cells. A significant increase in SCE frequency was observed in some family members but not reaching the BS patients values, leading to suggest that this could be due to the heterozygous profile. Microsatellite genotyping using four fluorescent dye-labeled microsatellite markers revealed evidence of linkage to BLM locus and the healthy members, sharing higher SCE frequency, showed heterozygous haplotypes as expected. Additionally, the direct BLM gene sequencing identified a novel homozygous frameshift mutation c.3617-3619delAA (p.K1207fsX9) in BS patients and a heterozygous BLM mutation in the family members with higher SCE frequency. Our findings suggest that this latter mutation likely leads to a reduced BLM activity explaining the homologous recombination repair defect and, therefore, the increase in SCE. Based on the present data, the screening of this mutation could contribute to the rapid diagnosis of BS. The genetic confirmation of the mutation in BLM gene provides crucial information for genetic counseling and prenatal diagnosis.
Genetic polymorphisms in DNA repair genes might influence the repair activities of the enzymes predisposing individuals to cancer risk. Owing to the presence of these genetic variants, interethnic differences in DNA repair capacity have been observed in various populations. The present study was undertaken to determine the allele and genotype frequencies of two common non-synonymous SNPs, XRCC3 p.Thr241>Met (C > T, rs861539) and XPD p.Lys751>Gln (T > G, rs13181) in a healthy Tunisian population and to compare them with HapMap ( http://www.hapmap.org/ ) populations. Also, we predicted their eventual functional effect based on bioinformatics tools. The genotypes of 154 healthy and unrelated individuals were determined by PCR-RFLP procedure. Our findings showed a close relatedness with Caucasians from European ancestry which might be explained by the strategic geographic location of Tunisia in the Mediterranean, thus allowing exchanges with Europeans countries. The in silico predictions showed that p.Thr241>Met substitution in XRCC3 protein was predicted as possibly damaging, indicating that it is likely to have functional consequences as well. To the best of our knowledge, this is the first study in this regard in Tunisia. So, these data could provide baseline database and help us to explore the relationship of XRCC3 and XPD polymorphisms with both cancer risk and DNA repair variability in our population.
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