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甘蓝的完整线粒体基因组序列及共存线粒体类型分析。

The complete mitochondrial genome sequence of Brassica oleracea and analysis of coexisting mitotypes.

作者信息

Tanaka Yoshiyuki, Tsuda Mizue, Yasumoto Keita, Terachi Toru, Yamagishi Hiroshi

机构信息

Faculty of Life Sciences, Kyoto Sangyo University, Motoyama, Kamigamo, Kita, Kyoto, 603-8555, Japan,

出版信息

Curr Genet. 2014 Nov;60(4):277-84. doi: 10.1007/s00294-014-0433-2. Epub 2014 Jun 12.

DOI:10.1007/s00294-014-0433-2
PMID:24916859
Abstract

The complete mitochondrial genome sequences of Brassica species have provided insight into inter- and intraspecific variation of plant mitochondrial genomes. However, the size of mitochondrial genome sequenced for Brassica oleracea hitherto does not match to its physical mapping data. This fact led us to investigate B. oleracea mitochondrial genome in detail. Here we report novel B. oleracea mitochondrial genome, derived from var. capitata, a cabbage cultivar ''Fujiwase''. The genome was assembled into a 219,952-bp circular sequence that is comparable to the mitochondrial genomes of other Brassica species (ca. 220-232 kb). This genome contained 34 protein-coding genes, 3 rRNA genes and 17 tRNA genes. Due to absence of a large repeat (140 kb), the mitochondrial genome of ''Fujiwase'' is clearly smaller than the previously reported mitochondrial genome of B. oleracea accession ''08C717'' (360 kb). In both mitotypes, all genes were identical, except cox2-2, which was present only in the Fujiwase type. At least two rearrangement events via large and small repeat sequences have contributed to the structural differences between the two mitotypes. PCR-based marker analysis revealed that the Fujiwase type is predominant, whereas the 08C717 type coexists at low frequency in all B. oleracea cultivars examined. Intraspecific variations in the mitochondrial genome in B. oleracea may occur because of heteroplasmy, coexistence of different mitotypes within an individual, and substoichiometric shifting. Our data indicate that the Fujiwase-type genome should be used as the representative genome of B. oleracea.

摘要

芸苔属物种的完整线粒体基因组序列为了解植物线粒体基因组的种间和种内变异提供了线索。然而,迄今为止测序的甘蓝线粒体基因组大小与其物理图谱数据不匹配。这一事实促使我们对甘蓝线粒体基因组进行详细研究。在此,我们报道了源自甘蓝变种“富士早生”(一种卷心菜品种)的新型甘蓝线粒体基因组。该基因组组装成一个219,952 bp的环状序列,与其他芸苔属物种的线粒体基因组(约220 - 232 kb)相当。这个基因组包含34个蛋白质编码基因、3个rRNA基因和17个tRNA基因。由于缺乏一个大的重复序列(140 kb),“富士早生”的线粒体基因组明显小于先前报道的甘蓝材料“08C717”的线粒体基因组(360 kb)。在两种线粒体类型中,除了仅存在于富士早生类型中的cox2 - 2基因外,所有基因都是相同的。至少两次通过大小重复序列的重排事件导致了两种线粒体类型之间的结构差异。基于PCR的标记分析表明,富士早生类型占主导地位,而08C717类型在所有检测的甘蓝品种中以低频率共存。甘蓝线粒体基因组的种内变异可能是由于异质性、个体内不同线粒体类型的共存以及亚化学计量转移引起的。我们的数据表明,富士早生类型的基因组应作为甘蓝的代表性基因组。

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