Use of a targeted, combinatorial next-generation sequencing approach for the study of bicuspid aortic valve

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• 作者：Elizabeth M Bonachea (1) r> Gloria Zender (2) r> Peter White (1) (3) r> Don Corsmeier (3) r> David Newsom (3) r> Sara Fitzgerald-Butt (1) (2) r> Vidu Garg (1) (2) (4) r> Kim L McBride (1) (2) r>r>1. Department of Pediatrics ; The Ohio State University ; Columbus ; OH ; USA r> 2. Center for Cardiovascular and Pulmonary Research and The Heart Center ; Nationwide Children鈥檚 Hospital ; 700 Children鈥檚 Drive Room WB4275 ; Columbus ; Ohio ; 43205 ; USA r> 3. Biomedical Genomics Core. The Research Institute at Nationwide Children鈥檚 Hospital ; Columbus ; OH ; USA r> 4. Department of Molecular Genetics ; The Ohio State University ; Columbus ; OH ; USA r>
• 关键词：Bicuspid aortic valve ; Genetics ; Next ; generation sequencing ; Targeted capture ; Combinatorial pooling
• 刊名：BMC Medical Genomics
• 出版年：2014
• 出版时间：December 2014
• 年：2014
• 卷：7
• 期：1
• 全文大小：298 KB
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The pre-publication history for this paper can be accessed here:ref="http://www.biomedcentral.com/1755-8794/7/56/prepub" class="a-plus-plus">http://www.biomedcentral.com/1755-8794/7/56/prepub r>
• 刊物主题：Human Genetics; Microarrays;
• 出版者：BioMed Central
• ISSN：1755-8794

文摘

Background Bicuspid aortic valve (BAV) is the most common type of congenital heart disease with a population prevalence of 1-2%. While BAV is known to be highly heritable, mutations in single genes (such as GATA5 and NOTCH1) have been reported in few human BAV cases. Traditional gene sequencing methods are time and labor intensive, while next-generation high throughput sequencing remains costly for large patient cohorts and requires extensive bioinformatics processing. Here we describe an approach to targeted multi-gene sequencing with combinatorial pooling of samples from BAV patients. Methods We studied a previously described cohort of 78 unrelated subjects with echocardiogram-identified BAV. Subjects were identified as having isolated BAV or BAV associated with coarctation of aorta (BAV-CoA). BAV cusp fusion morphology was defined as right-left cusp fusion, right non-coronary cusp fusion, or left non-coronary cusp fusion. Samples were combined into 19 pools using a uniquely overlapping combinatorial design; a given mutation could be attributed to a single individual on the basis of which pools contained the mutation. A custom gene capture of 97 candidate genes was sequenced on the Illumina HiSeq 2000. Multistep bioinformatics processing was performed for base calling, variant identification, and in-silico analysis of putative disease-causing variants. Results Targeted capture identified 42 rare, non-synonymous, exonic variants involving 35 of the 97 candidate genes. Among these variants, in-silico analysis classified 33 of these variants as putative disease-causing changes. Sanger sequencing confirmed thirty-one of these variants, found among 16 individuals. There were no significant differences in variant burden among BAV fusion phenotypes or isolated BAV versus BAV-CoA. Pathway analysis suggests a role for the WNT signaling pathway in human BAV. Conclusion We successfully developed a pooling and targeted capture strategy that enabled rapid and cost effective next generation sequencing of target genes in a large patient cohort. This approach identified a large number of putative disease-causing variants in a cohort of patients with BAV, including variants in 26 genes not previously associated with human BAV. The data suggest that BAV heritability is complex and polygenic. Our pooling approach saved over $39,350 compared to an unpooled, targeted capture sequencing strategy.