Can-Seq:一种用于鉴定已知基因和候选基因新等位基因的聚合酶链式反应(PCR)及DNA测序策略。
Can-Seq: a PCR and DNA sequencing strategy for identifying new alleles of known and candidate genes.
作者信息
Cao Jiangling, Gursanscky Nial R, Fletcher Stephen J, Sawyer Anne, Wadia Mehershad, McKeough Lachlan, Coleman Marek, Dressel Uwe, Taochy Christelle, Mitter Neena, Vaucheret Hervé, Carroll Bernard J
机构信息
1School of Chemistry and Molecular Biosciences, The University of Queensland, Brisbane, QLD 4072 Australia.
2Queensland Alliance for Agriculture and Food Innovation, The University of Queensland, Brisbane, QLD 4072 Australia.
出版信息
Plant Methods. 2020 Feb 13;16:16. doi: 10.1186/s13007-020-0555-0. eCollection 2020.
BACKGROUND
Forward genetic screens are a powerful approach for identifying the genes contributing to a trait of interest. However, mutants arising in genes already known can obscure the identification of new genes contributing to the trait. Here, we describe a strategy called Candidate gene-Sequencing (Can-Seq) for rapidly identifying and filtering out mutants carrying new alleles of known and candidate genes.
RESULTS
We carried out a forward genetic screen and identified 40 independent mutants with defects in systemic spreading of RNA interference (RNAi), or more specifically in () To classify the mutants as either representing a new allele of a known or candidate gene versus carrying a mutation in an undiscovered gene, bulk genomic DNA from up to 23 independent mutants was used as template to amplify a collection of 47 known or candidate genes. These amplified sequences were combined into Can-Seq libraries and deep sequenced. Subsequently, mutations in the known and candidate genes were identified using a custom Snakemake script (https://github.com/Carroll-Lab/can_seq), and PCR zygosity tests were then designed and used to identify the individual mutants carrying each mutation. Using this approach, we showed that 28 of the 40 mutants carried homozygous nonsense, missense or splice site mutations in one or more of the 47 known or candidate genes. We conducted complementation tests to demonstrate that several of the candidate mutations were responsible for the defect. Importantly, by exclusion, the Can-Seq pipeline also identified mutants that did not carry a causative mutation in any of the 47 known and candidate genes, and these mutants represent an undiscovered gene(s) required for systemic RNAi.
CONCLUSIONS
Can-Seq offers an accurate, cost-effective method for classifying new mutants into known versus unknown genes. It has several advantages over existing genetic and DNA sequencing approaches that are currently being used in forward genetic screens for gene discovery. Using Can-Seq in conjunction with map-based gene cloning is a cost-effective approach towards identifying the full complement of genes contributing to a trait of interest.
背景
正向遗传学筛选是鉴定影响目标性状基因的有力方法。然而,已知基因中产生的突变体可能会掩盖对影响该性状新基因的鉴定。在此,我们描述了一种称为候选基因测序(Can-Seq)的策略,用于快速鉴定和筛选携带已知和候选基因新等位基因的突变体。
结果
我们进行了一次正向遗传学筛选,鉴定出40个独立的突变体,这些突变体在RNA干扰(RNAi)的系统性传播方面存在缺陷,或者更具体地说,在()方面存在缺陷。为了将这些突变体分类为代表已知或候选基因的新等位基因,还是在未发现的基因中携带突变,我们使用多达23个独立突变体的大量基因组DNA作为模板,扩增了47个已知或候选基因的集合。这些扩增序列被组合成Can-Seq文库并进行深度测序。随后,使用自定义的Snakemake脚本(https://github.com/Carroll-Lab/can_seq)鉴定已知和候选基因中的突变,然后设计并使用PCR纯合性测试来鉴定携带每个突变的单个突变体。使用这种方法,我们发现40个突变体中有28个在47个已知或候选基因中的一个或多个中携带纯合的无义、错义或剪接位点突变。我们进行了互补测试,以证明几个候选突变是导致该缺陷的原因。重要的是,通过排除法,Can-Seq流程还鉴定出在47个已知和候选基因中均未携带致病突变的突变体,这些突变体代表了系统性RNAi所需的未发现基因。
结论
Can-Seq提供了一种准确、经济高效的方法,可将新突变体分类为已知基因和未知基因。与目前用于正向遗传学筛选以发现基因的现有遗传和DNA测序方法相比,它具有多个优势。将Can-Seq与基于图谱的基因克隆结合使用,是鉴定影响目标性状的完整基因互补的经济有效方法。
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