Coding-Sequence Evolution Does Not Explain Divergence in Petal Anthocyanin Pigmentation Between Mimulus luteus Var luteus and M. l. variegatus

IF 2.6 3区生物学 Q2 DEVELOPMENTAL BIOLOGY

Evolution & Development Pub Date : 2024-11-26 DOI:10.1111/ede.12493

Walker E. Orr, Ji Yang Kim, Iker J. Sánchez Márquez, Caine J. Ryan, Tejas Raj, Ellen K. Hom, Ashley E. Person, Anne Vonada, John A. Stratton, Arielle M. Cooley

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引用次数: 0

Abstract

Biologists have long been interested in understanding genetic constraints on the evolution of development. For example, noncoding changes in a gene might be favored over coding changes if they are less constrained by pleiotropic effects. Here, we evaluate the importance of coding-sequence changes to the recent evolution of a novel anthocyanin pigmentation trait in the monkeyflower genus Mimulus. The magenta-flowered Mimulus luteus var. variegatus recently gained petal lobe anthocyanin pigmentation via a single-locus Mendelian difference from its sister taxon, the yellow-flowered M. l. luteus. Previous work showed that the differentially expressed transcription factor gene MYB5a/NEGAN is the single causal gene. However, it was not clear whether MYB5a coding-sequence evolution (in addition to the observed patterns of differential expression) might also have contributed to increased anthocyanin production in M. l. variegatus. Quantitative image analysis of tobacco leaves, transfected with MYB5a coding sequence from each taxon, revealed robust anthocyanin production driven by both alleles. Counter to expectations, significantly higher anthocyanin production was driven by the allele from the low-anthocyanin M. l. luteus, a result that was confirmed through both a replication of the initial study and analysis by an alternative method of spectrophotometry on extracted leaf anthocyanins. Together with previously published expression studies, our findings support the hypothesis that petal pigment in M. l. variegatus was not gained by protein-coding changes, but instead solely via noncoding cis-regulatory evolution. Finally, while constructing the transgenes needed for this experiment, we unexpectedly discovered two sites in MYB5a that appear to be post-transcriptionally edited—a phenomenon that has been rarely reported, and even less often explored, for nuclear-encoded plant mRNAs.

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编码-序列进化无法解释变叶含羞草和变叶含羞草花瓣花青素色素的差异。

长期以来，生物学家一直有兴趣了解基因对发育进化的限制。例如，如果基因中的非编码变化受多生物效应的限制较少，那么它们可能比编码变化更受青睐。在这里，我们评估了编码序列变化对猴花属含羞草（Mimulus）中一种新型花青素色素性状近期进化的重要性。最近，品红色花的Mimulus luteus var. variegatus通过与其姊妹类群--黄色花的M.之前的研究表明，差异表达的转录因子基因 MYB5a/NEGAN 是唯一的致病基因。然而，目前还不清楚 MYB5a 编码序列的进化（除了观察到的差异表达模式外）是否也会导致变种烟草花青素产量的增加。通过对转染了各分类群 MYB5a 编码序列的烟草叶片进行定量图像分析，发现两种等位基因都能产生大量花青素。与预期相反的是，低花青素 M. l. luteus 的等位基因驱动的花青素产量明显更高，这一结果通过重复最初的研究和对提取的叶花青素进行分光光度法分析得到了证实。结合之前发表的表达研究，我们的发现支持了这样一个假设，即变色龙花瓣色素不是通过蛋白质编码变化获得的，而是完全通过非编码顺式调控进化获得的。最后，在构建本实验所需的转基因时，我们意外地发现 MYB5a 中的两个位点似乎被转录后编辑了--这种现象很少被报道，而对于核编码的植物 mRNA 来说，这种现象更少被探索。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Evolution & Development 生物-发育生物学

CiteScore

6.30

自引率

3.40%

发文量

审稿时长

>12 weeks

期刊介绍： Evolution & Development serves as a voice for the rapidly growing research community at the interface of evolutionary and developmental biology. The exciting re-integration of these two fields, after almost a century''s separation, holds much promise as the focus of a broader synthesis of biological thought. Evolution & Development publishes works that address the evolution/development interface from a diversity of angles. The journal welcomes papers from paleontologists, population biologists, developmental biologists, and molecular biologists, but also encourages submissions from professionals in other fields where relevant research is being carried out, from mathematics to the history and philosophy of science.