Your search keyword '"Wang, Mingbang"' showing total 5 results

1. Dendritic Spine in Autism Genetics: Whole-Exome Sequencing Identifying De Novo Variant of CTTNBP2 in a Quad Family Affected by Autism Spectrum Disorder.

Author

Xie, Yingmei, Wang, Hui, Hu, Bing, Zhang, Xueli, Liu, Aiping, Cai, Chunquan, Li, Shijun, Chen, Cheng, Wang, Zhangxing, Yin, Zhaoqing, and Wang, Mingbang

Subjects

GENETICS of autism, DENDRITIC cells, GENETIC mutation, GENETIC variation, NEUROPLASTICITY, GENE expression, RESEARCH funding, GENOMICS, DATA analysis software, SPINE, PHENOTYPES

Abstract

Autism spectrum disorder (ASD) affects around 1% of children with no effective blood test or cure. Recent studies have suggested that these are neurological disorders with a strong genetic basis and that they are associated with the abnormal formation of dendritic spines. Chromosome microarray (CMA) together with high-throughput sequencing technology has been used as a powerful tool to identify new candidate genes for ASD. In the present study, CMA was first used to scan for genome-wide copy number variants in a proband, and no clinically significant copy number variants were found. Whole-exome sequencing (WES) was used further for genetic testing of the whole quad family affected by ASD, including the proband, his non-autistic sister, and his parents. Sanger sequencing and MassARRAY-based validation were used to identify and confirm variants associated with ASD. WES yielded a 151-fold coverage depth for each sample. A total of 98.65% of the targeted whole-exome region was covered at >20-fold depth. A de novo variant in CTTNBP2, p.M115T, was identified. The CTTNBP2 gene belongs to a family of ankyrin repeat domain-containing proteins associated with dendritic spine formation. Although CTTNBP2 has been associated with ASD, limited studies have been developed to identify clinically relevant de novo mutations of CTTNBP2 in children with ASD; family-based WES successfully identified a clinically relevant mutation in the CTTNBP2 gene in a quad family affected by ASD. Considering the neuron-specific expression of CTTNBP2 and its role in dendritic spine formation, our results suggest a correlation between the CTTNBP2 mutation and ASD, providing genetic evidence for ASD spine pathology. Although the present study is currently insufficient to support the assertion that the de novo mutation M115T in CTTNBP2 directly causes the autism phenotype, our study provides support for the assertion that this mutation is a candidate clinically relevant variant in autism. [ABSTRACT FROM AUTHOR]

Published

2023

2. Identifying Rare Genetic Variants of Immune Mediators as Risk Factors for Autism Spectrum Disorder.

Author

Cai, Chunquan, Yin, Zhaoqing, Liu, Aiping, Wang, Hui, Zeng, Shujuan, Wang, Zhangxing, Qiu, Huixian, Li, Shijun, Zhou, Jiaxiu, and Wang, Mingbang

Subjects

AUTISM spectrum disorders, GENETIC variation, AUTOANTIBODIES, CYTOKINE receptors, GENETIC mutation, NATURAL immunity

Abstract

Autism spectrum disorder (ASD) affects more than 1% of children, and there is no viable pharmacotherapeutic agent to treat the core symptoms of ASD. Studies have shown that children with ASD show changes in their levels of immune response molecules. Our previous studies have shown that ASD is more common in children with folate receptor autoantibodies. We also found that children with ASD have abnormal gut immune function, which was characterized by a significant increase in the content of immunoglobulin A and an increase in gut-microbiota-associated epitope diversity. These studies suggest that the immune mechanism plays an important role in the occurrence of ASD. The present study aims to systematically assess gene mutations in immune mediators in patients with ASD. We collected genetic samples from 72 children with ASD (2–12 years old) and 107 healthy controls without ASD (20–78 years old). We used our previously-designed immune gene panel, which can capture cytokine and receptor genes, the coding regions of MHC genes, and genes of innate immunity. Target region sequencing (500×) and bioinformatics analytical methods were used to identify variants in immune response genes associated with patients with ASD. A total of 4 rare variants were found to be associated with ASD, including HLA-B: p.A93G, HLA-DQB1: p.S229N, LILRB2: p.R322H, and LILRB2: c.956-4C>T. These variants were present in 44.44% (32/72) of the ASD patients and were detected in 3.74% (4/107) of the healthy controls. We expect these genetic variants will serve as new targets for the clinical genetic assessment of ASD, and our findings suggest that immune abnormalities in children with ASD may have a genetic basis. [ABSTRACT FROM AUTHOR]

Published

2022

3. High-throughput sequencing of autism spectrum disorders comes of age.

Author

WANG, MINGBANG, FAN, XIAOMEI, WANG, TAO, and WU, JINYU

Subjects

*AUTISM spectrum disorders, *NUCLEOTIDE sequence, *GENETIC mutation, *HUMAN genome, *DEVELOPMENTAL disabilities

Abstract

Autism spectrum disorders (ASDs) are lifelong neurodevelopmental disabilities that affect 1 in 88 children in the USA. Despite the high heritability, the genetic basis for a majority of the ASDs remains elusive. The considerable clinical and genetic heterogeneity pose a significant challenge technically. State-of-the-art high-throughput sequencing (HTS), which makes the analyses of any specific single/multiple genes or whole exomes feasible, has shown a promising perspective in disease gene discovery. To date, numerous genetic studies using HTS have been reported and many rare inherited or de novo mutations have been identified. This review will focus on the progress and prospective of genome studies of ASDs using HTS. [ABSTRACT FROM AUTHOR]

Published

2013

4. Design of a Targeted Sequencing Assay to Detect Rare Mutations in Circulating Tumor DNA.

Author

Chen, Jianxia, Chen, Jun, He, Fusheng, Huang, Yiqiong, Lu, Shan, Fan, Haibo, Wang, Mingbang, and Xu, Ruihuan

Subjects

*RENAL cell carcinoma, *CANCER diagnosis, *CANCER patients, *GENETIC mutation, *TARGETED drug delivery

Abstract

Background: Qualitative and quantitative detection of circulating tumor DNA (ctDNA) is a liquid biopsy technology used for early cancer diagnosis. However, the plasma ctDNA content is extremely low, so it is difficult to detect somatic mutations of tumors using conventional sequencing methods. Target region sequencing (TRS) technology, through enrichment of the target genomic region followed by next generation sequencing, overcomes this challenge and has been widely used in ctDNA sequencing. Methods: We designed a ctDNA sequencing panel to capture 128 tumor genes, and tested the performance of the panel by running TRS for ctDNA of a clear cell renal cell carcinoma (ccRCC) patient and 12 breast cancer patients. Results: TRS using the new ctDNA panel at more than 500 × coverage depth achieved almost the same accuracy as traditional whole-exome sequencing (WES). PBRM1 p.L641V was detected in the plasma sample of the ccRCC patient with an allele frequency of 0.2%. The ctDNA of 12 breast cancer patients was sequenced at a depth of 500-fold, achieving 99.89% coverage; 34 genes were detected with mutations, including the drug target genes BRCA2, PTEN, TP53, APC, KDR, and NOTCH2. Conclusions: This TRS new ctDNA panel can be used to detect mutations in cell-free DNA from multiple types of cancer. [ABSTRACT FROM AUTHOR]

Published

2019

5. Association between SCN1A and SCN2A mutations and clinical/EEG features in Chinese patients from epilepsy or severe seizures.

Author

Kong, Yanting, Yan, Kai, Hu, Liyuan, Wang, Mingbang, Dong, Xinran, Lu, Yulan, Wu, Bingbing, Wang, Huijun, Yang, Lin, and Zhou, Wenhao

Subjects

*EPILEPSY, *SPASMS, *PHENOTYPES, *ELECTROENCEPHALOGRAPHY, *GENETIC mutation

Abstract

Background We investigated the association between SCN1A and SCN2A mutations and clinical phenotype and electroencephalography (EEG) features. Methods In this study, 48 patients suffered from epilepsy or severe seizures with SCN1A and SCN2A mutations were recruited. Medical data and molecular diagnosis were analyzed. Results A total of 47 mutations were identified, including 33 novel mutations. The onset of most epilepsy caused by SCN1A mutations (1-6 m) was later than that of SCN2A mutations (neonatal). SCN1A mutations included truncating mutations and missense mutations occurred in the crucial region were associated with more severe phenotypes and developmental delay (85.7%, P  = 0.020). De novo mutations or truncating mutations of SCN2A mutations are mainly associated with severe phenotypes. The proportion of initial abnormal EEG of SCN2A mutation was higher than that of SCN1A mutation (54.2%, 100%). Patients with SCN1A mutations showed more focal epileptiform discharges (69.2%), while patients with SCN2A mutations had more multifocal epileptiform discharges (53.8%). Sodium channel blockers were less effective for patients with SCN1A mutations and SCN2A mutations with early seizures onset. Conclusions Our study expanded the mutation spectrum of the SCN1A and SCN2A , and led to a better understanding of the similarities and difference in the genetic and clinical features between the two genes. [ABSTRACT FROM AUTHOR]

Published

2018