Homozygous Paternally Inherited ASPA Variant in a Patient with Canavan Disease.

Introduction: Canavan disease is an autosomal recessive disorder that causes accumulation of N-acetyl ASPArtic acid in the brain due to ASPArtoacylase deficiency with homozygous or compound heterozygous pathogenic variants in the ASPA gene located on the short arm of chromosome 17. Clinical findings are hypotonia, progressive macrocephaly, deafness, nystagmus, blindness, and brain atrophy. Case Presentation: A one-year-old female case was evaluated in our medical genetics clinic for hypotonia, nystagmus, and strabismus. Chromosome analysis and array-comparative genomic hybridization showed no pathology. Clinical exome sequencing by next-generation sequencing was performed and a homozygous likely pathogenic variant NM_000049.4(ASPA):c.857C > A p.(Ala286Asp) was identified. Sanger sequencing of the parents showed that the index case had a homozygous genotype, the father was heterozygous and the mother had a wild genotype for the identified variant in ASPA. A single nucleotide polymorphism (SNP) array test was planned for the family to explain this homozygosity and a loss of maternal heterozygosity was determined in the 17p13.3-p13.2 region of the ASPA gene. Conclusion: In this report, we aimed to present the first case of Canavan disease with maternal loss of heterozygosity in the ASPA gene.

Investigation of Targeted Genes and Identification of Novel Variants with Next Generation Sequencing Method in Hearing Loss.

Hearing loss is a widespread condition throughout the world. It may affect patients from newborns to the elderly. There are too many reasons for hearing loss, including congenital hearing loss, virus infections, age-related situations, and traumatic situations, which may be related to the immune-mediated system. Fifty percent of hearing loss is related to genetic mutations and defects; genetic causes are highly heterogeneous, so the analysis of new variants are important for diagnosis. We aimed to describe the importance of detected gene variations by using targeted gene panels in the Next-Generation-Sequencing (NGS) platform. Eighty-one hearing loss targeted genes were investigated using Illumina NextSeq550 technology in 100 participants with hearing loss between 2017 and 2022 in our Genetic Diseases Evaluation Center. Targeted genes were performed on 100 patients with hearing loss diagnosis. The total number of detected variants was 77. Forty-seven cases have likely pathogenic/pathogenic variants. Thirty of them have uncertain clinical significance variants, and from the detected variants, 8 are novel. In this research, we highlighted that earlier detection of hearing loss using molecular genetic methods may help us understand the etiology and orient for a better prognosis. Results detected by using the NGS platform can assist and improve the diagnosis. In this study, the diagnostic rate with targeted genes was detected as 35.29%. It has an important role in clinical practice as the recommendation of cochlear implants. Clarifying the genotype and phenotype correlation helps us figure out the etiology of hearing loss and also the worth of genetic counseling in hereditary hearing loss.

Functional analysis of MMR gene VUS from potential Lynch syndrome patients.

Lynch syndrome is caused by inactivating variants in DNA mismatch repair genes, namely MLH1, MSH2, MSH6 and PMS2. We have investigated five MLH1 and one MSH2 variants that we have identified in Turkish and Tunisian colorectal cancer patients. These variants comprised two small deletions causing frameshifts resulting in premature stops which could be classified pathogenic (MLH1 p.(His727Profs*57) and MSH2 p.(Thr788Asnfs*11)), but also two missense variants (MLH1 p.(Asn338Ser) and p.(Gly181Ser)) and two small, in-frame deletion variants (p.(Val647-Leu650del) and p.(Lys678_Cys680del)). For such small coding genetic variants, it is unclear if they are inactivating or not. We here provide clinical description of the variant carriers and their families, and we performed biochemical laboratory testing on the variant proteins to test if their stability or their MMR activity are compromised. Subsequently, we compared the results to in-silico predictions on structure and conservation. We demonstrate that neither missense alteration affected function, while both deletion variants caused a dramatic instability of the MLH1 protein, resulting in MMR deficiency. These results were consistent with the structural analyses that were performed. The study shows that knowledge of protein function may provide molecular explanations of results obtained with functional biochemical testing and can thereby, in conjunction with clinical information, elevate the evidential value and facilitate clinical management in affected families.

First Report of Jacobsen Syndrome with Dextrocardia Diagnosed with del(11)(q24q25).

Jacobsen syndrome is a rare congenital disorder that is caused by the deletion of several genes in chromosome 11. A 10-year-old female with congenital heart disease, dextrocardia, and coarse facial appearance was examined in our medical genetics clinic. Chromosome analysis and array-CGH showed a copy number loss of 9 Mb in the 11q24.2q25 region. Herein, we report her clinical findings. This is the first case of Jacobsen syndrome with dextrocardia.