Mitochondrial genome diversity and evolution in Branchiopoda (Crustacea).

IF 1.7 3区生物学 Q2 ZOOLOGY

Zoological Letters Pub Date : 2019-05-27 eCollection Date: 2019-01-01 DOI:10.1186/s40851-019-0131-5

Andrea Luchetti, Giobbe Forni, Alyza M Skaist, Sarah J Wheelan, Barbara Mantovani

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引用次数: 15

Abstract

Background: The crustacean class Branchiopoda includes fairy shrimps, clam shrimps, tadpole shrimps, and water fleas. Branchiopods, which are well known for their great variety of reproductive strategies, date back to the Cambrian and extant taxa can be mainly found in freshwater habitats, also including ephemeral ponds. Mitochondrial genomes of the notostracan taxa Lepidurus apus lubbocki (Italy), L. arcticus (Iceland) and Triops cancriformis (an Italian and a Spanish population) are here characterized for the first time and analyzed together with available branchiopod mitogenomes.

Results: Overall, branchiopod mitogenomes share the basic structure congruent with the ancestral Pancrustacea model. On the other hand, rearrangements involving tRNAs and the control region are observed among analyzed taxa. Remarkably, an unassigned region in the L. apus lubbocki mitogenome showed a chimeric structure, likely resulting from a non-homologous recombination event between the two flanking trnC and trnY genes. Notably, Anostraca and Onychocaudata mitogenomes showed increased GC content compared to both Notostraca and the common ancestor, and a significantly higher substitution rate, which does not correlate with selective pressures, as suggested by dN/dS values.

Conclusions: Branchiopod mitogenomes appear rather well-conserved, although gene rearrangements have occurred. For the first time, it is reported a putative non-homologous recombination event involving a mitogenome, which produced a pseudogenic tRNA sequence. In addition, in line with data in the literature, we explain the higher substitution rate of Anostraca and Onychocaudata with the inferred GC substitution bias that occurred during their evolution.

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鳃足纲（甲壳纲）线粒体基因组多样性及其进化。

背景：鳃足纲甲壳动物包括神仙虾、蛤蜊虾、蝌蚪虾和水蚤。分支足类以其多样的繁殖策略而闻名，可以追溯到寒武纪，现存的分类群主要分布在淡水栖息地，也包括短暂的池塘。首次对脊索动物分类群Lepidurus apus lubbocki（意大利）、L.arcticus（冰岛）和Triops canciformis（意大利和西班牙种群）的线粒体基因组进行了表征，并与现有的鳃足类线粒体基因组一起进行了分析。结果：总的来说，鳃足有丝分裂基因组具有与祖先Pancrustacea模型一致的基本结构。另一方面，在分析的分类群中观察到涉及tRNA和控制区的重排。值得注意的是，L.apus lubbocki有丝分裂基因组中的一个未分配区域显示出嵌合结构，这可能是由两个侧翼trnC和trnY基因之间的非同源重组事件引起的。值得注意的是，与介形目和共同祖先相比，Anostraca和Onychocaudata的有丝分裂基因组显示出GC含量增加，并且具有显著更高的取代率，这与选择压力无关，如dN/dS值所示。结论：尽管发生了基因重排，但鳃足有丝分裂基因组看起来相当保守。首次报道了一个涉及有丝分裂基因组的假定非同源重组事件，该事件产生了假基因tRNA序列。此外，根据文献中的数据，我们解释了Anostraca和Onychocaudata较高的取代率，以及它们进化过程中发生的GC取代偏差。

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

Zoological Letters Agricultural and Biological Sciences-Animal Science and Zoology

CiteScore

3.60

自引率

0.00%

发文量

审稿时长

10 weeks

期刊介绍： Zoological Letters is an open access journal that publishes new and important findings in the zoological sciences. As a sister journal to Zoological Science, Zoological Letters covers a wide range of basic fields of zoology, from taxonomy to bioinformatics. We also welcome submissions of paleontology reports as part of our effort to contribute to the development of new perspectives in evolutionary zoology. Our goal is to serve as a global publishing forum for fundamental researchers in all fields of zoology.