Project description:<p>AHC is a rare and severe neurological disorder, and characterized by episodic hemiplegia or quadriplegia attacks, accompanied by other paroxysmal symptoms of oculomotor abnormalities, dystonia, seizures and autonomic disturbances; the age of onset usually occurrs before 18 months of life. Sodium-potassium ATPase alpha3 subunit (ATP1A3) has recently been identified as a causal gene for sporadic AHC by three groups. However, there has not been any large genetic study on a Chinese cohort.</p> <p>In the submitted data, whole-exome sequencing of three trios and three sporadic cases in a Chinese cohort produced an average of 18.8 gigabases of raw sequence. Through our analysis pipeline including BWA mapping, GATK recalibration, variant calling and filtering, all six patients contained missense mutations in ATP1A3 which were further confirmed as <i>de novo</i> mutations. Along with validation in additional patients, this study confirmed ATP1A3 as a causal gene in Chinese AHC patients, and reported six novel mutations. </p>

Project description:The identification of the genetic risk factors in patients with isolated cleft palate by whole genome sequencing analysis. Pathogenic or likely pathogenic variants were discovered in genes associated with CP (TBX22, COL2A1, FBN1, PCGF2, and KMT2D) in five patients; hence, rare disease variants were identified in 17% of patients with non-syndromic isolated CP. Our results are relevant to routine genetic counselling practice and genetic testing recommendations.

Project description:Variants of uncertain significance (VUS) limit the actionability of genetic testing. A prominent example is MUTYH, a base excision repair factor associated with polyposis and colorectal cancer, which has a pathogenic variant carrier rate approaching 1 in 50 individuals in some populations. To systematically interrogate variant function in MUTYH, we coupled deep mutational scanning with a DNA repair reporter containing its lesion substrate, 8OG:A. Our variant-to-function map covers >97% of all possible MUTYH point variants (n=10,941) and achieves 100% accuracy classifying pathogenicity of known clinical variants (n=247). Leveraging a large clinical registry, we observe significant associations with colorectal polyps and cancer, with more severely impaired missense variants conferring greater risk. We recapitulate known functional differences between pathogenic founder mutations and highlight sites of complete missense intolerance, including residues that intercalate DNA and coordinate essential Zn2+ or Fe-S clusters. This map provides a resource to resolve the 1,122 existing clinical missense VUS in MUTYH and demonstrates a scalable strategy to interrogate other clinically relevant DNA repair factors.

Project description:Germline BRCA2 loss-of function (LOF) variants identified by clinical genetic testing predispose to breast, ovarian, prostate and pancreatic cancer. However, variants of uncertain significance (VUS) (n>5000) limit the clinical use of testing results. Thus, there is an urgent need for functional characterization and clinical classification of all BRCA2 variants. Here we report on comprehensive saturation genome editing-based functional characterization of 99% of all possible single nucleotide variants (SNVs) in the BRCA2 DNA Binding Domain hotspot for pathogenic missense variants that is encoded by exons 15 to 26. The assay was based on deep sequence analysis of HAP1 haploid cells endogenously targeted using a CRISPR/cas9 knockin approach. A total of 6959 SNVs were characterized for effects on cell survival. The assay was validated relative to nonsense and synonymous variants, ClinVar pathogenic/likely pathogenic and benign/likely benign variants and homology directed repair cell based DNA repair assay results, all of which showed >94% sensitivity and specificity. Variants were assigned posterior probabilities of pathogenicity using a VarCall two component Bayesian mixture model and were further grouped according to ACMG strength of evidence under the PS3/BS3 rule resulting in Benign Strong (n=5430), Benign Moderate (n=190), Benign Supporting (n=61), VUS (122), Pathogenic Strong (n=1021), Pathogenic Moderate (n=88), and Pathogenic Supporting (n=47). Breast cancer case-control association studies showed that pooled SNVs encoding functionally pathogenic missense variants were associated with increased risks of breast (odds ratio (OR)3.81, 95%CI: 2.88-5.07) and ovarian cancer (OR 5.93, 95%CI: 4.12-8.52). The functional data were also combined with other sources of information in the ClinGen BRCA1/2 VCEP ACMG/AMP-classification model. A total of 785 SNVs, including 261 missense SNVs, were classified as pathogenic or likely pathogenic, while 5566 SNVs, including 3786 missense SNVs, were classified as benign or likely benign. These classified variants can now be used for risk assessment and clinical care of variant carriers.

Project description:Dominant defects in CHCHD10, a mitochondrial intermembrane space protein, lead to a range of neurological and muscle phenotypes including amyotrophic lateral sclerosis. Many patients present with spinal muscular atrophy Jokela type (SMAJ), which is caused by a heterozygous p.G66V variant. While most disease variants lead to aggregation of CHCHD10 and activation of proteotoxic stress responses, the pathogenic mechanisms of the p.G66V variant have been less investigated. We report here the first homozygous CHCHD10 patient, with variant p.G66V. We compare the metabolic findings in heterozygous and homozygous SMAJ patient skin fibroblasts, and in motor neurons differentiated from patient-specific stem cells as well as a novel mouse model of SMAJ. Our findings show that p.G66V variant leads to dose-depended reduction of the CHCHD10 protein in a cell type specific manner. In addition, CHCHD10 p.G66V dysregulates energy metabolism, leading to altered redox balance and energy buffering by creatine metabolism.

Project description:Aims: Pathogenic truncating variants in the largest human protein TITIN are a leading cause of dilated cardiomyopathy. Because of the size of the gene encoding TITIN, many missense variations are identified. These are difficult to evaluate in genetic testing, as even individually rare variants are common in aggregate in normal populations. While the majority will be benign, a small subset is pathogenic, but distinction is challenging. Here, we describe the generation of a mouse model to investigate the underlying disease mechanism of a previously reported TITIN A178D missense variant identified in a family with non-compaction and dilated cardiomyopathy. Methods and Results: Heterozygous and homozygous mice carrying the TITIN A178D missense variant were characterised in vivo. Heterozygous mice had no detectable phenotype at any time point observed (up to 1 year). By contrast, homozygous mice developed dilated cardiomyopathy from 3 months. Chronic adrenergic stimulation aggravated the phenotype. Targeted transcript profiling revealed induction of the fetal gene programme and hypertrophic signalling pathways in homozygous mice, and these were confirmed at the protein level. Unsupervised proteomics identified down-regulation of TELETHONIN and FOUR-AND-A-HALF LIM DOMAIN 2, as well as the up-regulation of heat shock proteins and MYELOID LEUKEMIA FACTOR 1. Loss of TELETHONIN from the cardiac Z-disc was accompanied by proteasomal degradation; however, TELETHONIN also accumulated in the cytoplasm. In parallel, a proteo-toxic response was observed in the mice. Conclusions: We have shown that the TITIN A178D missense variant is pathogenic in homozygous mice, resulting in cardiomyopathy. We also provide evidence of the disease mechanism. Because the TITIN A178D variant abolishes binding of TELETHONIN, this leads to its abnormal cytoplasmic accumulation. Subsequent degradation of TELETHONIN by the proteasome results in proteasomal overload, and activation of a proteo-toxic response. The latter appears to be a driving factor for the cardiomyopathy observed in the mouse model.

Project description:We identified pathogenic and likely pathogenic variants in 17.8% of the patients within a wide range of cancer types. In particular, mesothelioma, ovarian cancer, cervical cancer, urothelial cancer, and cancer of unknown primary origin displayed high frequencies of pathogenic variants. In total, 22 BRCA1 and BRCA2 germline variant were identified in 12 different cancer types, of which 10 (45%) variants were not previously identified in these patients. Pathogenic germline variants were predominantly found in DNA repair pathways; approximately half of the variants were within genes involved in homologous recombination repair. Loss of heterozygosity and somatic second hits were identified in several of these genes, supporting possible causality for cancer development. A potential treatment target based on pathogenic germline variant could be suggested in 25 patients (4%).

Project description:Predicting the pathogenic effect of rare genetic variants is hampered by the limited cohort of diagnosed patients and the difficulty in evaluating the effect of existing and novel variants. To address this issue, we leveraged a protein Multiplexed Assay of Variants Effect (MAVE) to functionally assess the effect of ~2,300 missense variants of the TP63 gene, some of which cause autosomal dominant developmental disorders. The activity of each variant was measured using an optimized fibroblast-to-keratinocyte conversion protocol, and a subset of mutants was validated using a wide range of functional tests. To expand MAVEs to any disease-driving gene without a specific predefined assay, we developed SCRAMseq (Single Cell RNAseq Associated with MAVEs by sequencing), which can retrieve each variant and characterize the functional consequences at the single-cell level through full-length scRNAseq. The dataset generated and validated here reclassified hundreds of variants present in the general population and definitively classified a Variant of Unknown Significance as pathogenic in a patient with ectodermal dysplasia. This work provides a robust and easy-to-use workflow to dissect the effect of gene variants for any possible disease-driving gene.

Project description:Predicting the pathogenic effect of rare genetic variants is hampered by the limited cohort of diagnosed patients and the difficulty in evaluating the effect of existing and novel variants. To address this issue, we leveraged a protein Multiplexed Assay of Variants Effect (MAVE) to functionally assess the effect of ~2,300 missense variants of the TP63 gene, some of which cause autosomal dominant developmental disorders. The activity of each variant was measured using an optimized fibroblast-to-keratinocyte conversion protocol, and a subset of mutants was validated using a wide range of functional tests. To expand MAVEs to any disease-driving gene without a specific predefined assay, we developed SCRAMseq (Single Cell RNAseq Associated with MAVEs by sequencing), which can retrieve each variant and characterize the functional consequences at the single-cell level through full-length scRNAseq. The dataset generated and validated here reclassified hundreds of variants present in the general population and definitively classified a Variant of Unknown Significance as pathogenic in a patient with ectodermal dysplasia. This work provides a robust and easy-to-use workflow to dissect the effect of gene variants for any possible disease-driving gene.

Project description:Over 400 million people worldwide are living with a rare disease, with genetic variants determining 80% of cases. Next Generation Sequencing identifies potential disease causative genetic variants, however many of these are classified as variants of uncertain significance (VUS). Each VUS requires functional validation as pathogenic or benign in disease pathology in specialist laboratories creating major delays in patient diagnosis. In this study we test a rapid genetic variant assessment pipeline using an EHMT1 (Euchromatin histone methyltransferase 1; EHMT1 p.Gln1144Ter) genetic variant that is pathogenic for Kleefstra Syndrome. Precise CRISPR homology directed (HDR) gene editing introduced the single nucleotide genetic variant in iPS cells and EHMT1_SNV cell clones were rapidly identified with amplicon sequencing. Induction of neural differentiation and RNA sequencing determined differences in differentiation at the gene and transcription factor level. The applied CRISPR HDR methodology was rapid and reliable for the introduction of SNVs in iPSCs for subsequent neuronal cell differentiation. Key features of Kleefstra Syndrome were identified, with involvement of key transcription factors REST and SP1 in disease mechanisms. This study indicates that precise iPSC gene editing and changes in disease modelling pathways can contribute to disease diagnosis and understanding of mechanisms.