Phylogenomics and plastome evolution of Lithospermeae (Boraginaceae).

IF 5.4 3区 材料科学 Q2 CHEMISTRY, PHYSICAL ACS Applied Energy Materials Pub Date : 2024-10-14 DOI:10.1186/s12870-024-05665-6
Maryam Noroozi, Farrokh Ghahremaninejad, Mehrshid Riahi, James I Cohen
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Abstract

Background: Lithospermeae is the largest tribe within Boraginaceae. The tribe has been the focus of multiple phylogenetic studies over the last 15 years, with most focused on one genus or a few genera. In the present study, we newly sequenced 69 species of Lithospermeae and relatives to analyze the phylogenomic relationships among its members as well as the evolution of the plastid genome.

Results: The phylogeny of Lithospermeae resolved from the plastid genome and nrDNA cistron is generally congruent with prior studies, but is better resolved and supported. Increasing character sampling across the plastid genome results in gradually more similar trees to that from the entire plastid genome. Overall, plastid genome structure was quite consistent across Lithospermeae. Codon Usage Bias (CUB) analyses demonstrate that across Lithospermeae plastid genomes were rich in AT and poor in GC. Mutation may play a greater role than selection across the plastid genome of Lithospermeae. The present study is the first to highlight the CUB characteristics of Lithospermeae species, which can help elucidate the mechanisms underlying patterns of molecular evolution and improve the expression levels of exogenous genes by codon optimization.

Conclusions: This study provides a comprehensive phylogenomic analysis of Lithospermeae, significantly enhancing our understanding of the phylogenetic relationships and plastid genome evolution within this largest tribe of Boraginaceae. By utilizing an expanded genomic sampling approach, we have achieved increased resolution and support among the evolutionary relationships of the tribe, in line with but improving upon previous studies. The analyses of plastid genome structure revealed consistency across Lithospermeae, with a notable CUB. This study marks the first investigation into the CUB of Lithospermeae species and sets the stage for further research on the molecular evolution of plastid genomes across Boraginaceae.

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石蒜科(紫草科)的系统发生组学和质体进化。
背景介绍石蒜科(Lithospermeae)是婆婆纳科(Boraginaceae)中最大的一个科。在过去的 15 年中,该族一直是多项系统发育研究的重点,其中大多数研究集中于一个属或几个属。在本研究中,我们对 Lithospermeae 的 69 个种及其近缘种进行了新的测序,以分析其成员之间的系统发生关系以及质体基因组的进化:结果:从质体基因组和 nrDNA 单列子集解析的石蒜科系统发生与之前的研究基本一致,但得到了更好的解析和支持。对整个质体基因组的特征取样增加,会逐渐形成与整个质体基因组更相似的树。总体而言,Lithospermeae 的质体基因组结构相当一致。密码子使用偏差(CUB)分析表明,在整个石蒜科植物的质体基因组中,AT含量丰富,而GC含量较低。在整个石蒜科植物的质体基因组中,突变的作用可能大于选择的作用。本研究首次强调了石蒜科物种的 CUB 特征,有助于阐明分子进化模式的内在机制,并通过密码子优化提高外源基因的表达水平:本研究对石蒜科植物进行了全面的系统发生组分析,极大地增强了我们对这一婆婆纳科最大分支的系统发生关系和质体基因组进化的了解。通过采用扩大的基因组取样方法,我们提高了该族进化关系的分辨率和支持度,与之前的研究保持一致,并在此基础上有所改进。对质体基因组结构的分析表明,石蒜科植物的质体基因组结构具有一致性,并有一个显著的 CUB。该研究首次对石蒜科物种的 CUB 进行了研究,为进一步研究石蒜科质体基因组的分子进化奠定了基础。
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来源期刊
ACS Applied Energy Materials
ACS Applied Energy Materials Materials Science-Materials Chemistry
CiteScore
10.30
自引率
6.20%
发文量
1368
期刊介绍: ACS Applied Energy Materials is an interdisciplinary journal publishing original research covering all aspects of materials, engineering, chemistry, physics and biology relevant to energy conversion and storage. The journal is devoted to reports of new and original experimental and theoretical research of an applied nature that integrate knowledge in the areas of materials, engineering, physics, bioscience, and chemistry into important energy applications.
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