Novel Biallelic Variant in the BRAT1 Gene Caused Nonprogressive Cerebellar Ataxia Syndrome

Clinical characteristics of BRAT1-related disease: a systematic literature review

BACKGROUND

BRAT1 (BRCA1-associated ataxia telangiectasia mutated activator 1) is involved in many important biological processes, including DNA damage response and maintenance of mitochondrial homeostasis. Dysfunctional BRAT1 causes variable clinical phenotypes, which hinders BRAT1-related disease from recognition and diagnosis.

METHODS

Preferred Reporting Items for Systematic Reviews and Meta-Analyses statement was the guideline for this systematic review. MEDLINE was searched by terms ("BAAT1" and "BRAT1") from inception until June 21, 2022.

RESULTS

Twenty-eight studies, screened out of 49 records, were included for data extraction. The data from fifty patients with mutated BRAT1 were collected. There are 3 high relevant phenotypes, 4 medium relevant phenotypes and 3 low relevant phenotypes. Eye-related abnormal features were most frequently reported: 27 abnormal features were observed. Thirty-nine kinds of pathogenic nucleotide change in BRAT1 were reported. Top three common mutations of BRAT1 were c.638_639insA (16 cases), c.1395G > A (5 cases) and c.294dupA (4 cases). Homozygous mutations in BRAT1 presented a more severe phenotype than those who are compound heterozygotes.

CONCLUSIONS

This is the first comprehensive systematic review to present quantitative data about clinical characteristics of BRAT1-related disease, which helps doctors to recognize and diagnose it easier.

A novel non-sense variant in the OFD1 gene caused Joubert syndrome

Background: Joubert syndrome (JBS) is a rare neurodevelopmental disorder associated with progressive renal, liver, and retinal involvement that exhibits heterogeneity in both clinical manifestations and genetic etiology. Therefore, it is difficult to make a definite prenatal diagnosis. Methods: Whole-exome sequencing and Sanger sequencing were performed to screen the causative gene variants in a suspected JBS family. RNA-seq and protein model prediction were performed to clarify the potential pathogenic mechanism. A more comprehensive review of previously reported cases with OFD1 variants is presented and may help to establish a genotype-phenotype. Results: We identified a novel non-sense variant in the OFD1 gene, OFD1 (NM_003611.3): c.2848A>T (p.Lys950Ter). Sanger sequencing confirmed cosegregation among this family. RNA-seq confirmed that partial degradation of mutant transcripts, which was predicted to be caused by the non-sense-mediated mRNA decay (NMD) mechanism, may explain the reduction in the proportion of mutant transcripts. Protein structure prediction of the non-sense variant transcript revealed that this variant may lead to a change in the OFD1 protein structure. Conclusion: The genetic variation spectrum of JBS10 caused by OFD1 was broadened. The novel variants further deepened our insight into the molecular mechanism of the disease.

Compound heterozygous loss-of-function variants in BRAT1 cause lethal neonatal rigidity and multifocal seizure syndrome

BACKGROUND

Lethal neonatal rigidity and multifocal seizure syndrome (RMFSL, OMIM 614498) is a rare autosomal recessive disease characterized by the onset of rigidity and intractable seizures at or soon after birth. The BRAT1 has been identified to be the disease-causing gene for RMFSL. This study aimed to determine the underlying pathogenic mutations of a Chinese family with RMFSL and to confirm the effect of the splice-site mutation by reverse transcription analysis.

METHODS

Detailed family history and clinical data were recorded, and peripheral blood samples were collected from all available family members. Whole exome sequencing (WES), Sanger sequencing, and bioinformatics analysis were performed to investigate the causative variants. The impact of the intronic variant on splicing was subsequently analyzed by RT-PCR analysis.

RESULTS

We identified two compound heterozygous variants in the BRAT1, c.431-2A>G in intron 3 and c.1359_1361del(p.Leu454del) in exon 9 in the proband, one inherited from each parent. Furthermore, the 3'-splice site acceptor (c.431-2A>G) variant was found to activate a cryptic acceptor splice site, which resulted in the loss of 29 nucleotides and generation of a premature stop codon at code 180, producing a truncated BRAT1 (c.432_460del; p.Ala145Argfs*36).

CONCLUSIONS

This research identified two mutations in the BRAT1 of one Chinese family with RMFSL. These data can aid in developing clinical diagnoses as well as providing genetic counseling and prenatal interventions to the family. These findings also expand our knowledge of the spectrum of BRAT1 pathogenic variants in RMFSL syndrome.