A Homozygous Nonsense Variant in UVSSA Causes UV-sensitive Syndrome from Very Large Kindred: The First Report from Iran.

Background: Recessive disruptive mutations in nucleotide excision repair genes are responsible for a wide range of cutaneous photosensitivity and, in some cases, are associated with multi-system involvement. The heterogeneous nature of these conditions makes next-generation sequencing the method of choice to detect disease-causing variants. Materials and Methods: A patient from a large multiplex inbred Iranian kindred with several individuals suffering from skin sun-sensitive manifestations underwent complete clinical and molecular evaluations. Whole exome sequencing (WES) was performed on the genomic sample of the proband, followed by bioinformatics analysis. Subsequently, co-segregation of the candidate variant with the condition was performed by Sanger sequencing. Results: A rare homozygous nonsense variant, c.1040G>A (p. Trp347*), was identified in the UVSSA gene, resulting in UV-sensitive syndrome (UVSS) complementation group A. The global minor allele frequency of the variant is < 0.001 in population databases. Tryptophan 347 residue is conserved among mammalians and vertebrates, and the null variant is believed to lead to a truncated protein with cellular mislocalization. Conclusions: Here, we report the first genetic diagnosis of UVSS-A in Iran via the successful application of Next-generation sequencing, which expands our understanding of the molecular pathogenesis of this condition.

A pathogenic variant in the transforming growth factor beta I (TGFBI) in four Iranian extended families segregating granular corneal dystrophy type II: A literature review.

OBJECTIVES: Granular and lattice corneal dystrophies (GCDs & LCDs) are autosomal dominant inherited disorders of the cornea. Due to genetic heterogeneity and large genes, unraveling the mutation is challenging. MATERIALS AND METHODS: Patients underwent comprehensive clinical examination, and targeted next-generation sequencing (NGS) was used for mutation detection. Co-segregation and in silico analysis was accomplished. RESULTS: Patients suffered from GCD. NGS disclosed a known pathogenic variant, c.371G>A (p.R124H), in exon 4 of TGFBI. The variant co-segregated with the phenotype in the family. Homozygous patients manifested with more severe phenotypes. Variable expressivity was observed among heterozygous patients. CONCLUSION: The results, in accordance with previous studies, indicate that the c.371G>A in TGFBI is associated with GCD. Some phenotypic variations are related to factors such as modifier genes, reduced penetrance and environmental effects.

Identification of a combined missense/splice-site mutation in FAH causing tyrosinemia type 1.

Tyrosinemia type I (HT1) is a genetic metabolic disorder characterized by progressive liver disease, kidney disease, and rickets. The disease is caused by mutations in the FAH gene that results in deficiency of fumarylacetoacetase, an enzyme that is involved in the tyrosine degradation pathway. We investigated the clinical characteristics and molecular cause of HT1 in an affected family from Iran. Molecular analysis identified a homozygous combined missense (c.G1009G>A, p.Gly337Ser) and aberrant splicing mutation removing the first 50 nucleotides of exon 12. This mutation was only described in HT1 patients from Scandinavian countries and this is the first report from another population. Although failure to thrive is one of the typical features in HT1, our proband, similar to the reported Scandinavian patients, had normal growth and development. The results of this study have applications in patient screening and genetic counselling.