利用公共数据库与其他植物遗传相似性分析绿紫苏(Perilla frutescens)品种的转录组分析

Q3 Agricultural and Biological Sciences
Yusuke Tanigaki, Takanobu Higashi, A. Nagano, M. Honjo, H. Fukuda
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引用次数: 5

摘要

确保和提高作物产量是农业中的重要问题。在许多情况下,对作物栽培的研究有着悠久的历史;然而,很少有研究关注作物在遗传水平上发生的变化。体内基因表达谱被认为有助于了解植物状况,从而稳定和提高产量。近年来,基因组学、蛋白质组学、代谢组学等综合分析提高了对体内信息的认识,并通过一次性分析提供了大量信息。RNA-seq转录组分析是一种组学分析技术,广泛应用于动物、植物和昆虫的研究(Scherf et al., 2000;Rifkin et al., 2003;Lister et al., 2008)。生物信息学方法用于阐明生物学含义。拟南芥(Arabidopsis thaliana)等模式植物有丰富的遗传信息,以及一个支持高度精确分析的参考序列(RefSeq) (Fiehn et al., 2001)。用于可视化分析数据和遗传信息的软件应用程序已建立在公共数据库中,提供了评估大量数据的能力。然而,关于品种的信息很少。另一方面,参与植物过程的基本机制和基因,如参与生长代谢的基因,在许多物种中是保守的。因此,利用数据库信息对建立和改善品种栽培环境有很大的帮助。在栽培品种中使用模式植物遗传分析技术具有提高产量和改善作物品质的强大潜力。尽管物种不同,但基因的功能往往相似,因为它们在进化上是保守的(Tanigaki et al., 2014)。在植物中,核酮糖-1,5-二磷酸羧化酶/加氧酶(RuBisCO)的氨基酸或核苷酸序列是进化保守的(Tabita et al., 2007)。在某些情况下,由于分子进化速率的差异,这种相似性很低(Xiang et al., 2004)。然而,物种特异性基因很难通过表达估计和定位代谢途径来分析。通过遗传功能分析使用组学数据来分析物种特异性基因是非常耗时的。此外,特定品种特有的基因可以促进物种特异性从头遗传分析(Hong et al., 2015)。寻求提高作物生长方法的传统农民需要快速(在单一种植海洋内)的数据
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Transcriptome Analysis of a Cultivar of Green Perilla (Perilla frutescens) Using Genetic Similarity with Other Plants via Public Databases
Ensuring stable and increasing crop yields are important problems within agriculture. In many cases, studies on the cultivation of crops have a long history; however, few studies have focused on the changes occurring in crops at the genetic level. Gene expression profiles in vivo are thought to assist in understanding plant conditions, so as to stabilize and increase yield. Recently, comprehensive analyses such as genomics, proteomics, and metabolomics have advanced the understanding of information in vivo and provided a lot of information through one-time analysis. Transcriptome analysis by RNA-seq, an omics analysis technique, is widely used in studies of animals, plants, and insects (Scherf et al., 2000; Rifkin et al., 2003; Lister et al., 2008). Bioinformatics approaches are used to elucidate biological implications. There is abundant genetic information available for model plants such as Arabidopsis thaliana, as well as a reference sequence (RefSeq) supporting highly accurate analysis (Fiehn et al., 2001). Software applications for visualizing the analyzed data and genetic information have been built into public databases, offering the ability to assess large quantities of data. However, there is little information for cultivars. On the other hand, basic mechanisms and genes involved in plant processes, such as those involved in growth metabolism, are conserved in many species. Therefore, the use of information available in databases is very helpful in building and improving the cultivation environment of cultivars. The use of model-plant genetic analysis techniques within cultivars has a strong potential to increase yield and improve crop quality. Although species differ, the functions of genes tend to be similar as they are evolutionarily conserved (Tanigaki et al., 2014). In plants, the amino acid or nucleotide sequences of ribulose-1,5-bisphosphate carboxylase/ oxygenase (RuBisCO) are evolutionarily conserved (Tabita et al., 2007). In some cases, this similarity is low because of differences in rates of molecular evolution (Xiang et al., 2004). However, species-specific genes are difficult to analyze by expression estimation and mapping to metabolic pathways. Using omics data for species-specific genes via genetic functional analysis is time-consuming. Moreover, genes specific to a particular cultivar can facilitate speciesspecific de novo genetic analysis (Hong et al., 2015). Conventional farmers seeking methods to improve crop growth require data rapidly (within a single planting sea-
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来源期刊
Environmental Control in Biology
Environmental Control in Biology Agricultural and Biological Sciences-Agronomy and Crop Science
CiteScore
2.00
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