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腔棘鱼的基因组复杂性在其适应性免疫系统中得以体现。

Genome complexity in the coelacanth is reflected in its adaptive immune system.

作者信息

Saha Nil Ratan, Ota Tatsuya, Litman Gary W, Hansen John, Parra Zuly, Hsu Ellen, Buonocore Francesco, Canapa Adriana, Cheng Jan-Fang, Amemiya Chris T

机构信息

Molecular Genetics Program, Benaroya Research Institute at Virginia Mason, Seattle, Washington.

出版信息

J Exp Zool B Mol Dev Evol. 2014 Sep;322(6):438-63. doi: 10.1002/jez.b.22558. Epub 2014 Jan 24.

DOI:10.1002/jez.b.22558
PMID:24464682
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4110200/
Abstract

We have analyzed the available genome and transcriptome resources from the coelacanth in order to characterize genes involved in adaptive immunity. Two highly distinctive IgW-encoding loci have been identified that exhibit a unique genomic organization, including a multiplicity of tandemly repeated constant region exons. The overall organization of the IgW loci precludes typical heavy chain class switching. A locus encoding IgM could not be identified either computationally or by using several different experimental strategies. Four distinct sets of genes encoding Ig light chains were identified. This includes a variant sigma-type Ig light chain previously identified only in cartilaginous fishes and which is now provisionally denoted sigma-2. Genes encoding α/β and γ/δ T-cell receptors, and CD3, CD4, and CD8 co-receptors also were characterized. Ig heavy chain variable region genes and TCR components are interspersed within the TCR α/δ locus; this organization previously was reported only in tetrapods and raises questions regarding evolution and functional cooption of genes encoding variable regions. The composition, organization and syntenic conservation of the major histocompatibility complex locus have been characterized. We also identified large numbers of genes encoding cytokines and their receptors, and other genes associated with adaptive immunity. In terms of sequence identity and organization, the adaptive immune genes of the coelacanth more closely resemble orthologous genes in tetrapods than those in teleost fishes, consistent with current phylogenomic interpretations. Overall, the work reported described herein highlights the complexity inherent in the coelacanth genome and provides a rich catalog of immune genes for future investigations.

摘要

我们分析了腔棘鱼现有的基因组和转录组资源,以鉴定参与适应性免疫的基因。已鉴定出两个高度独特的编码IgW的基因座,它们呈现出独特的基因组结构,包括多个串联重复的恒定区外显子。IgW基因座的整体结构排除了典型的重链类别转换。无论是通过计算还是使用几种不同的实验策略,都无法鉴定出编码IgM的基因座。鉴定出了四组不同的编码Ig轻链的基因。这包括一种先前仅在软骨鱼类中发现的变体sigma型Ig轻链,现在暂时命名为sigma-2。还对编码α/β和γ/δT细胞受体以及CD3、CD4和CD8共受体的基因进行了表征。Ig重链可变区基因和TCR组分散布在TCRα/δ基因座内;这种结构先前仅在四足动物中报道过,这引发了关于编码可变区的基因的进化和功能共用的问题。主要组织相容性复合体基因座的组成、结构和同线性保守性已得到表征。我们还鉴定出大量编码细胞因子及其受体的基因,以及其他与适应性免疫相关的基因。就序列同一性和结构而言,腔棘鱼的适应性免疫基因与四足动物的直系同源基因比与硬骨鱼类的直系同源基因更为相似,这与当前的系统发育基因组学解释一致。总体而言,本文报道的工作突出了腔棘鱼基因组固有的复杂性,并为未来的研究提供了丰富的免疫基因目录。

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3
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4
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5
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