Suhas K. Kadam, Jin-Suk Youn, Asif S. Tamboli, JiYoung Yang, Jae Hong Pak, Yeon-Sik Choo
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Notably, the chloroplast genome of <i>A. littoricola</i> spans 150,985 bp, consistent with other <i>Artemisia</i> species, and comprises 131 genes, including 86 protein-coding, 37 tRNA, and 8 rRNA genes. Among these genes, 16 possess a single intron, while <i>clp</i>P and <i>ycf</i>3 exhibit two introns each. Furthermore, 18 genes display duplicated copies within the IR regions. Moreover, the genome possesses 42 Simple Sequence Repeats (SSRs), predominantly abundant in A/T content and located within intergenic spacer regions. The analysis of codon usage revealed that the codons for leucine were the most frequent, with a preference for ending with A/U. While the chloroplast genome exhibited conservation overall, non-coding regions showed lower conservation compared to coding regions, with the Inverted Repeat (IR) region displaying higher conservation than single-copy regions. Phylogenetic analyses position <i>A. littoricola</i> within subgenus <i>Dracunculus</i>, indicating a close relationship with <i>A. scoparia</i> and <i>A. desertorum</i>. Additionally, biogeographic reconstructions suggest ancestral origins in East Asia, emphasizing Mongolia, China (North East and North Central and South Central China), and Korea. This study underscores the importance of chloroplast genomics in understanding <i>Artemisia</i> diversity and evolution, offering valuable insights into taxonomy, evolutionary patterns, and biogeographic history. 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引用次数: 0
摘要
菊科植物,尤其是蒿属植物,由于形态特征有限和频繁的自然杂交,给分类学带来了挑战。叶绿体基因组分析等分子工具为准确的物种鉴定提供了解决方案。在这项研究中,我们对来自独岛的蒿属植物(Artemisia littoricola)的叶绿体基因组进行了测序和注释,并对六个不同的蒿属植物物种进行了比较分析。我们的研究结果表明,基因组结构是一致的,但重复序列和连接边界存在差异。值得注意的是,A. littoricola的叶绿体基因组跨度为150,985 bp,与其他蒿属植物一致,由131个基因组成,包括86个编码蛋白质的基因、37个tRNA基因和8个rRNA基因。在这些基因中,16 个基因有一个内含子,而 clpP 和 ycf3 则各有两个内含子。此外,18 个基因在内含子区域内有重复拷贝。此外,基因组中还有 42 个简单序列重复序列(SSR),主要以 A/T 含量为主,位于基因间间隔区。对密码子使用情况的分析表明,亮氨酸的密码子使用频率最高,且偏好以 A/U 结尾。虽然叶绿体基因组总体上表现出保护性,但与编码区相比,非编码区的保护性较低,其中反向重复区(IR)的保护性高于单拷贝区。系统发育分析将 A. littoricola 定位于龙舌兰亚属,表明它与 A. scoparia 和 A. desertorum 关系密切。此外,生物地理重建表明其祖先起源于东亚,重点是蒙古、中国(东北、华北中南)和韩国。这项研究强调了叶绿体基因组学在了解青蒿多样性和进化方面的重要性,为分类学、进化模式和生物地理历史提供了宝贵的见解。这些发现不仅加深了我们对青蒿错综复杂的生物学特性的了解,而且有助于保护工作,并促进了分子标记的开发,为进一步的研究以及在医药和农业领域的应用提供了便利。
Complete chloroplast genome sequence of Artemisia littoricola (Asteraceae) from Dokdo Island Korea: genome structure, phylogenetic analysis, and biogeography study
The Asteraceae family, particularly the Artemisia genus, presents taxonomic challenges due to limited morphological characteristics and frequent natural hybridization. Molecular tools, such as chloroplast genome analysis, offer solutions for accurate species identification. In this study, we sequenced and annotated the chloroplast genome of Artemisia littoricola sourced from Dokdo Island, employing comparative analyses across six diverse Artemisia species. Our findings reveal conserved genome structures with variations in repeat sequences and junction boundaries. Notably, the chloroplast genome of A. littoricola spans 150,985 bp, consistent with other Artemisia species, and comprises 131 genes, including 86 protein-coding, 37 tRNA, and 8 rRNA genes. Among these genes, 16 possess a single intron, while clpP and ycf3 exhibit two introns each. Furthermore, 18 genes display duplicated copies within the IR regions. Moreover, the genome possesses 42 Simple Sequence Repeats (SSRs), predominantly abundant in A/T content and located within intergenic spacer regions. The analysis of codon usage revealed that the codons for leucine were the most frequent, with a preference for ending with A/U. While the chloroplast genome exhibited conservation overall, non-coding regions showed lower conservation compared to coding regions, with the Inverted Repeat (IR) region displaying higher conservation than single-copy regions. Phylogenetic analyses position A. littoricola within subgenus Dracunculus, indicating a close relationship with A. scoparia and A. desertorum. Additionally, biogeographic reconstructions suggest ancestral origins in East Asia, emphasizing Mongolia, China (North East and North Central and South Central China), and Korea. This study underscores the importance of chloroplast genomics in understanding Artemisia diversity and evolution, offering valuable insights into taxonomy, evolutionary patterns, and biogeographic history. These findings not only enhance our understanding of Artemisia’s intricate biology but also contribute to conservation efforts and facilitate the development of molecular markers for further research and applications in medicine and agriculture.
期刊介绍:
Functional & Integrative Genomics is devoted to large-scale studies of genomes and their functions, including systems analyses of biological processes. The journal will provide the research community an integrated platform where researchers can share, review and discuss their findings on important biological questions that will ultimately enable us to answer the fundamental question: How do genomes work?