The complete mitochondrial genome of Castanopsis carlesii and Castanea henryi reveals the rearrangement and size differences of mitochondrial DNA molecules.

IF 5.4 3区 材料科学 Q2 CHEMISTRY, PHYSICAL
Xiong-De Tu, Ya-Xuan Xin, Hou-Hua Fu, Cheng-Yuan Zhou, Qing-Long Liu, Xing-Hao Tang, Long-Hai Zou, Zhong-Jian Liu, Shi-Pin Chen, Wen-Jun Lin, Ming-He Li
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Abstract

Background: Castanopsis carlesii is a dominant tree species in subtropical evergreen broad-leaved forests and holds significant ecological value. It serves as an excellent timber tree species and raw material for cultivating edible fungi. Henry Chinquapin (Castanea henryi) wood is known for its hardness and resistance to water and moisture, making it an exceptional timber species. Additionally, its fruit has a sweet and fruity taste, making it a valuable food source. However, the mitogenomes of these species have not been previously reported. To gain a better understanding of them, this study successfully assembled high-quality mitogenomes of C. carlesii and Ca. henryi for the first time.

Results: Our research reveals that the mitochondrial DNA (mtDNA) of C. carlesii exhibits a unique multi-branched conformation, while Ca. henryi primarily exists in the form of two independent molecules that can be further divided into three independent molecules through one pair of long repetitive sequences. The size of the mitogenomes of C. carlesii and Ca. henryi are 592,702 bp and 379,929 bp respectively, which are currently the largest and smallest Fagaceae mitogenomes recorded thus far. The primary factor influencing mitogenome size is dispersed repeats. Comparison with published mitogenomes from closely related species highlights differences in size, gene loss patterns, codon usage preferences, repetitive sequences, as well as mitochondrial plastid DNA segments (MTPTs).

Conclusions: Our study enhances the understanding of mitogenome structure and evolution in Fagaceae, laying a crucial foundation for future research on cell respiration, disease resistance, and other traits in this family.

Castanopsis carlesii 和 Castanea henryi 的完整线粒体基因组揭示了线粒体 DNA 分子的重新排列和大小差异。
背景:Castanopsis carlesii 是亚热带常绿阔叶林的主要树种,具有重要的生态价值。它既是优良的用材树种,也是栽培食用菌的原料。Henry Chinquapin(Castanea henryi)木材以坚硬和耐水湿而著称,是一种特殊的木材树种。此外,它的果实味道甜美,是一种珍贵的食物来源。然而,这些物种的有丝分裂基因组以前还没有报道过。为了更好地了解它们,本研究首次成功地组装了 C. carlesii 和 Ca. henryi 的高质量有丝分裂基因组:我们的研究发现,C. carlesii 的线粒体 DNA(mtDNA)呈现出独特的多分支构象,而 Ca. henryi 则主要以两个独立分子的形式存在,并可通过一对长重复序列进一步分为三个独立分子。C. carlesii和Ca. henryi的有丝分裂基因组大小分别为592,702 bp和379,929 bp,是目前记录到的最大和最小的法桐科有丝分裂基因组。影响有丝分裂基因组大小的主要因素是分散的重复序列。通过与已发表的近缘物种有丝分裂基因组比较,我们发现两者在大小、基因缺失模式、密码子使用偏好、重复序列以及线粒体质粒DNA片段(MTPTs)等方面存在差异:我们的研究加深了对法桐科植物有丝分裂基因组结构和进化的了解,为今后研究该科植物的细胞呼吸、抗病性和其他性状奠定了重要基础。
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
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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