The diagnostic yield, candidate genes, and pitfalls for a genetic study of intellectual disability in 118 middle eastern families.

Global Developmental Delay/Intellectual disability (ID) is the term used to describe various disorders caused by abnormal brain development and characterized by impairments in cognition, communication, behavior, or motor skills. In the past few years, whole-exome sequencing (WES) has been proven to be a powerful, robust, and scalable approach for candidate gene discoveries in consanguineous populations. In this study, we recruited 215 patients affected with ID from 118 Middle Eastern families. Whole-exome sequencing was completed for 188 individuals. The average age at which WES was completed was 8.5 years. Pathogenic or likely pathogenic variants were detected in 32/118 families (27%). Variants of uncertain significance were seen in 33/118 families (28%). The candidate genes with a possible association with ID were detected in 32/118 (27%) with a total number of 64 affected individuals. These genes are novel, were previously reported in a single family, or cause strikingly different phenotypes with a different mode of inheritance. These genes included: AATK, AP1G2, CAMSAP1, CCDC9B, CNTROB, DNAH14, DNAJB4, DRG1, DTNBP1, EDRF1, EEF1D, EXOC8, EXOSC4, FARSB, FBXO22, FILIP1, INPP4A, P2RX7, PRDM13, PTRHD1, SCN10A, SCYL2, SMG8, SUPV3L1, TACC2, THUMPD1, XPR1, ZFYVE28. During the 5 years of the study and through gene matching databases, several of these genes have now been confirmed as causative of ID. In conclusion, understanding the causes of ID will help understand biological mechanisms, provide precise counseling for affected families, and aid in primary prevention.

Further phenotypic delineation of Alazami syndrome.

Alazami syndrome (AS) is an autosomal recessive condition characterized by the cardinal features of severe growth restriction, moderate to severe intellectual disability, and distinctive facial features. Biallelic pathogenic variants of the LARP7, encoding a chaperone of 7SK noncoding RNA, is implicated in this disease. There are <35 reported cases in the literature. All reported cases share the same three cardinal features of the syndrome. Herein, we report on 12 patients with a confirmed diagnosis of AS from eight unrelated families. The cohort shares the same key feature of the syndrome. Moreover, we report additional phenotypic features, including genito-renal anomalies, ophthalmological abnormalities, and congenital heart disease. Whole-exome sequencing was used in all reported cases, implicating a clinical under-recognition of the syndrome. This report further expands the clinical and molecular characteristics of Alazami syndrome.

Biallelic PTRHD1 Frameshift Variants Associated with Intellectual Disability, Spasticity, and Parkinsonism.

BACKGROUND: PTRHD1 was proposed as a disease-causing gene of intellectual disability, spasticity, and parkinsonism. OBJECTIVES: To characterize the clinical phenotype and the molecular cause of intellectual disability in four affected individuals of a consanguineous family. METHODS: Clinical evaluation, whole-exome sequencing, Sanger sequencing, reverse transcription polymerase chain reaction (PCR), real-time PCR, immunoblot, and isoelectric focusing. RESULTS: A homozygous 28-nucleotide frameshift deletion introducing a premature stop codon in the PTRHD1 exon 1 was identified in the four affected members. We further confirmed the apparent transcript escape of the nonsense-mediated messenger RNA (mRNA) decay pathway. Real-time PCR showed that mRNA expression of the mutant PTRHD1 is higher compared to the wild-type. Western blotting and isoelectric focusing identified a truncated, but stable mutant PTRHD1 protein expressed in the patient's primary cells. CONCLUSIONS: We provide further evidence that PTRHD1 mutations are associated with autosomal-recessive childhood-onset intellectual disability associated with spasticity and parkinsonism.

LHFPL5 mutation: A rare cause of non-syndromic autosomal recessive hearing loss.

Hearing loss is a debilitating disorder that impairs language acquisition, resulting in disability in children and potential isolation in adulthood. Its onset can have a genetic basis, though environmental factors, which are often preventable, can also cause the condition. The genetic forms are highly heterogeneous, and early detection is necessary to arrange appropriate patient support. Here we report the molecular basis of hereditary hearing loss in a consanguineous family with multiple affected members from Oman. Combining homozygosity mapping with whole exome sequencing identified a novel homozygous nucleotide substitution c.575T > C in the lipoma HMGIC fusion partner-like 5 gene (LHFPL5), that converted the 192nd amino acid residue in the protein from a leucine to a proline, p.(Leu192Pro). Sanger sequencing confirmed segregation with the disease phenotype as expected for a recessive condition and the variant was absent in 123,490 subjects from various disease-specific and population genetic studies as well as 150 unrelated individuals and 35 deaf patients of Omani ethnicity. This study, which describes a novel LHFPL5 mutation in a family of Omani origin with hereditary hearing loss, supports previous clinical descriptions of the condition and contributes to the genetic spectrum of mutations in this form of deafness.

Reanalysis of exome sequencing data of intellectual disability samples: Yields and benefits.

Recently, with the advancement in next generation sequencing (NGS) along with the improvement of bioinformatics tools, whole exome sequencing (WES) has become the most efficient diagnostic test for patients with intellectual disability (ID). This study aims to estimate the yield of a reanalysis of ID negative exome cases after data reannotation. Total of 50 data files of exome sequencing, representing 50 samples were collected. The inclusion criteria include ID phenotype, and previous analysis indicated a negative result (no abnormality detected). These files were pre-processed and reannotated using ANNOVAR tool. Prioritized variants in the 50 cases studied were classified into three groups, (1) disease-causative variants (2) possible disease-causing variants and (3) variants in novel genes. Reanalysis resulted in the identification of pathogenic/likely pathogenic variants in six cases (12%). Thirteen cases (26%) were classified as having possible disease-causing variants. Candidate genes requiring future functional studies were detected in seven cases (14%). Improvement in bioinformatics tools, update in the genetic databases and literature, and patients' clinical phenotype update were the main reasons for identification of these variants in this study.

Diagnostic Yield of Chromosomal Microarray Analysis in a Cohort of Patients with Autism Spectrum Disorders from a Highly Consanguineous Population.

Autism Spectrum Disorders are a complicated group of disorders characterized with heterogeneous genetic etiologies. The genetic investigations for this group of disorders have expanded considerably over the past decade. In our study we designed a tired approach and studied the diagnostic yield of chromosomal microarray analysis on patients referred to the Genetic and Developmental Medicine clinic in Sultan Qaboos University in Oman for autism spectrum disorders in a highly consanguineous population. Copy number variants were seen in 27% of our studied cohort of patients and it was strongly associated with dysmorphic features and congenital anomalies.