利用大缺口读映射鉴定荷斯坦奶牛乳腺炎相关的新型可变剪接。

Identification of novel alternative splicing associated with mastitis disease in Holstein dairy cows using large gap read mapping.

机构信息

Centre for Genetic Improvement of Livestock, Department of Animal Biosciences, University of Guelph, 50 Stone Road East, Building #70, Guelph, ON, N1G 2W1, Canada.

Department of Animal Science, University of California - Davis, Davis, CA, 95616, USA.

出版信息

BMC Genomics. 2022 Mar 19;23(1):222. doi: 10.1186/s12864-022-08430-x.

DOI:10.1186/s12864-022-08430-x

PMID:35305573

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8934477/

Abstract

BACKGROUND

Mastitis is a very common disease in the dairy industry that producers encounter daily. Transcriptomics, using RNA-Sequencing (RNA - Seq) technology, can be used to study the functional aspect of mastitis resistance to identify animals that have a better immune response to mastitis. When the cow has mastitis, not only genes but also specific mRNA isoforms generated via alternative splicing (AS) could be differentially expressed (DE), leading to the phenotypic variation observed. Therefore, the objective of this study was to use large gap read mapping to identify mRNA isoforms DE between healthy and mastitic milk somatic cell samples (N = 12). These mRNA isoforms were then categorized based on being 1) annotated mRNA isoforms for gene name and length, 2) annotated mRNA isoforms with different transcript length and 3) novel mRNA isoforms of non - annotated genes.

RESULTS

Analysis identified 333 DE transcripts (with at least 2 mRNA isoforms annotated, with at least one being DE) between healthy and mastitic samples corresponding to 303 unique genes. Of these 333 DE transcripts between healthy and mastitic samples, 68 mRNA isoforms are annotated in the bovine genome reference (ARS.UCD.1.2), 249 mRNA isoforms had novel transcript lengths of known genes and 16 were novel transcript lengths of non - annotated genes in the bovine genome reference (ARS.UCD.1.2). Functional analysis including gene ontology, gene network and metabolic pathway analysis was performed on the list of 288 annotated and unique DE mRNA isoforms. In total, 67 significant metabolic pathways were identified including positive regulation of cytokine secretion and immune response. Additionally, numerous DE novel mRNA isoforms showed potential involvement with the immune system or mastitis. Lastly, QTL annotation analysis was performed on coding regions of the DE mRNA isoforms, identifying overlapping QTLs associated with clinical mastitis and somatic cell score.

CONCLUSION

This study identified novel mRNA isoforms generated via AS that could lead to differences in the immune response of Holstein dairy cows and be potentially implemented in future breeding programs.

摘要

背景

乳腺炎是奶牛养殖业中一种非常常见的疾病，生产者每天都会遇到。转录组学，使用 RNA 测序（RNA-Seq）技术，可用于研究乳腺炎抗性的功能方面，以识别对乳腺炎具有更好免疫反应的动物。当奶牛患有乳腺炎时，不仅基因，而且通过选择性剪接（AS）产生的特定 mRNA 异构体也可能差异表达（DE），导致观察到表型变异。因此，本研究的目的是使用大间隙读映射来识别健康和乳腺炎乳体细胞样品之间的 DE mRNA 异构体（N=12）。然后，根据以下标准对这些 mRNA 异构体进行分类：1）具有基因名称和长度注释的 mRNA 异构体，2）具有不同转录长度的注释 mRNA 异构体和 3）非注释基因的新 mRNA 异构体。

结果

分析确定了 333 个在健康和乳腺炎样本之间差异表达的转录本（至少有 2 个 mRNA 异构体注释，至少有一个是 DE），对应于 303 个独特的基因。在健康和乳腺炎样本之间的 333 个差异表达转录本中，68 个 mRNA 异构体在牛基因组参考（ARS.UCD.1.2）中注释，249 个 mRNA 异构体具有已知基因的新转录长度，16 个是牛基因组参考（ARS.UCD.1.2）中无注释基因的新转录长度。对 288 个注释和独特的 DE mRNA 异构体列表进行了包括基因本体论、基因网络和代谢途径分析在内的功能分析。总共鉴定出 67 个显著的代谢途径，包括细胞因子分泌和免疫反应的正调控。此外，许多差异表达的新 mRNA 异构体显示出与免疫系统或乳腺炎潜在的相关性。最后，对 DE mRNA 异构体的编码区进行了 QTL 注释分析，确定了与临床乳腺炎和体细胞评分相关的重叠 QTL。

结论

本研究鉴定了通过 AS 产生的新的 mRNA 异构体，这些异构体可能导致荷斯坦奶牛免疫反应的差异，并可能在未来的育种计划中得到实施。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8132/8934477/ff0b774c32f2/12864_2022_8430_Fig1_HTML.jpg

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利用大缺口读映射鉴定荷斯坦奶牛乳腺炎相关的新型可变剪接。

Identification of novel alternative splicing associated with mastitis disease in Holstein dairy cows using large gap read mapping.

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSION

背景

结果

结论

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