Zachary Kileeg, Aparna Haldar, Hasna Khan, Arooj Qamar, G Adam Mott
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引用次数: 0
Abstract
To maximize overall fitness, plants must accurately respond to a host of growth, developmental, and environmental signals throughout their life. Many of these internal and external signals are perceived by the leucine-rich repeat receptor-like kinases, which play roles in regulating growth, development, and immunity. This largest family of receptor kinases in plants can be divided into subfamilies based on the conservation of the kinase domain, which demonstrates that shared evolutionary history often indicates shared molecular function. Here we investigate the evolutionary history of this family across the evolution of 112 plant species. We identify lineage-specific expansions of the malectin-domain containing subfamily LRR subfamily I primarily in the Brassicales and bryophytes. Most other plant lineages instead show a large expansion in LRR subfamily XII, which in Arabidopsis is known to contain key receptors in pathogen perception. This striking asymmetric expansion may reveal a dichotomy in the evolutionary history and adaptation strategies employed by plants. A greater understanding of the evolutionary pressures and adaptation strategies acting on members of this receptor family offers a way to improve functional predictions for orphan receptors and simplify the identification of novel stress-related receptors.
为了最大限度地提高整体健康水平,植物必须在整个生命过程中对一系列生长、发育和环境信号做出准确的反应。富亮氨酸重复受体样激酶能感知许多这些内部和外部信号,在调节生长、发育和免疫方面发挥作用。这个植物中最大的受体激酶家族可根据激酶结构域的保守性分为多个亚家族,这表明共同的进化历史往往预示着共同的分子功能。在这里,我们研究了该家族在 112 个植物物种进化过程中的进化历史。我们发现含麦拉宁结构域的亚家族 LRR 亚家族 I 主要在芸苔目和裸子植物中出现了特定世系的扩展。而大多数其他植物品系中的 LRR 亚家族 XII 则出现了大幅扩展,拟南芥中的 LRR 亚家族 XII 包含病原体感知中的关键受体。这种惊人的非对称扩展可能揭示了植物进化史和适应策略的两极分化。更深入地了解作用于该受体家族成员的进化压力和适应策略,将有助于改进孤儿受体的功能预测,并简化新型胁迫相关受体的鉴定工作。