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蔷薇科自交不亲和位点的分子进化综合研究

A Comprehensive Study of Molecular Evolution at the Self-Incompatibility Locus of Rosaceae.

作者信息

Ashkani Jahanshah, Rees D J G

机构信息

Biotechnology Department, University of the Western Cape, Private Bag X17, Bellville, 7535, South Africa.

Biotechnology Platform, Agricultural Research Council, Private Bag X5, Onderstepoort, 0110, South Africa.

出版信息

J Mol Evol. 2016 Mar;82(2-3):128-45. doi: 10.1007/s00239-015-9726-4. Epub 2015 Dec 29.

DOI:10.1007/s00239-015-9726-4
PMID:26714486
Abstract

The family Rosaceae includes a range of important fruit trees, most of which have the S-RNase-based self-incompatibility (SI). Several models have been developed to explain how pollen (SLF) and pistil (S-RNase) components of the S-locus interact. It was discovered in 2010 that additional SLF proteins are involved in pollen specificity, and a Collaborative Non-Self Recognition model has been proposed for SI in Solanaceae; however, the validity of such model remains to be elucidated for other species. The results of this study support the divergent evolution of the S-locus genes from two Rosaceae subfamilies, Prunoideae/Amygdaloideae and Maloideae, The difference identified in the selective pressures between the two lineages provides evidence for positive selection at specific sites in both the S-RNase and the SLF proteins. The evolutionary findings of this study support the role of multiple SLF proteins leading to a Collaborative Non-Self Recognition model for SI in the Maloideae. Furthermore, the identification of the sites responsible for SI specificity determination and the mapping of these sites onto the modelled tertiary structure of ancestor proteins provide useful information for rational functional redesign and protein engineering for the future engineering of new functional alleles providing increased diversity in the SI system in the Maloideae.

摘要

蔷薇科包含一系列重要的果树,其中大多数具有基于S-RNase的自交不亲和性(SI)。已经开发了几种模型来解释S位点的花粉(SLF)和雌蕊(S-RNase)成分如何相互作用。2010年发现额外的SLF蛋白参与花粉特异性,并且已经提出了茄科SI的协作非自我识别模型;然而,这种模型在其他物种中的有效性仍有待阐明。本研究结果支持蔷薇科两个亚科(李亚科/扁桃亚科和苹果亚科)S位点基因的趋异进化。两个谱系之间在选择压力上的差异为S-RNase和SLF蛋白特定位点的正选择提供了证据。本研究的进化结果支持多种SLF蛋白在苹果亚科SI的协作非自我识别模型中的作用。此外,确定负责SI特异性决定的位点并将这些位点映射到祖先蛋白的模拟三级结构上,为未来设计新的功能等位基因以增加苹果亚科SI系统的多样性进行合理的功能重新设计和蛋白质工程提供了有用信息。

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