Genome-wide analysis of long terminal repeat retrotransposons from the cranberry Vaccinium macrocarpon

IF 1.5 4区农林科学 Q3 PLANT SCIENCES Journal of Berry Research Pub Date : 2021-11-14 DOI:10.3233/jbr-211515

Nusrat Sultana, Gerhard Menzel, Kathrin M. Seibt, Sònia Garcia, Beatrice Weber, Sedat Serçe, Tony Heitkam

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Abstract

BACKGROUND:Long terminal repeat (LTR) retrotransposons are widespread in plant genomes and play a large role in the generation of genomic variation. Despite this, their identification and characterization remains challenging, especially for non-model genomes. Hence, LTR retrotransposons remain undercharacterized in Vaccinium genomes, although they may be beneficial for current berry breeding efforts. OBJECTIVE:Exemplarily focusing on the genome of American cranberry (Vaccinium macrocarpon Aiton), we aim to generate an overview of the LTR retrotransposon landscape, highlighting the abundance, transcriptional activity, sequence, and structure of the major retrotransposon lineages. METHODS:Graph-based clustering of whole genome shotgun Illumina reads was performed to identify the most abundant LTR retrotransposons and to reconstruct representative in silico full-length elements. To generate insights into the LTR retrotransposon diversity in V. macrocarpon, we also queried the genome assembly for presence of reverse transcriptases (RTs), the key domain of LTR retrotransposons. Using transcriptomic data, transcriptional activity of retrotransposons corresponding to the consensuses was analyzed. RESULTS:We provide an in-depth characterization of the LTR retrotransposon landscape in the V. macrocarpon genome. Based on 475 RTs harvested from the genome assembly, we detect a high retrotransposon variety, with all major lineages present. To better understand their structural hallmarks, we reconstructed 26 Ty1-copia and 28 Ty3-gypsy in silico consensuses that capture the detected diversity. Accordingly, we frequently identify association with tandemly repeated motifs, extra open reading frames, and specialized, lineage-typical domains. Based on the overall high genomic abundance and transcriptional activity, we suggest that retrotransposons of the Ale and Athila lineages are most promising to monitor retrotransposon-derived polymorphisms across accessions. CONCLUSIONS:We conclude that LTR retrotransposons are major components of the V. macrocarpon genome. The representative consensuses provide an entry point for further Vaccinium genome analyses and may be applied to derive molecular markers for enhancing cranberry selection and breeding.

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蔓越莓长末端重复反转录转座子的全基因组分析

背景:长末端重复(LTR)逆转录转座子广泛存在于植物基因组中，并在基因组变异的产生中发挥重要作用。尽管如此，它们的鉴定和表征仍然具有挑战性，特别是对于非模式基因组。因此，尽管LTR逆转录转座子可能对当前的浆果育种工作有益，但它们在Vaccinium基因组中的特征仍然不充分。目的:以美国蔓越莓(Vaccinium macrocarpon Aiton)的基因组为例，我们旨在概述LTR反转录转座子的概况，重点介绍主要反转录转座子谱系的丰度、转录活性、序列和结构。方法:对全基因组的shotgun Illumina reads进行基于图的聚类，以鉴定最丰富的LTR反转录转座子，并重建具有代表性的硅全长元件。为了深入了解V. macrocarpon的LTR逆转录转座子多样性，我们还查询了基因组组装中是否存在逆转录酶(RTs)，这是LTR逆转录转座子的关键结构域。利用转录组学数据，分析了与共识对应的反转录转座子的转录活性。结果:我们提供了V. macrocarpon基因组中LTR反转录转座子景观的深入表征。基于从基因组组装中收集的475个RTs，我们检测到一个高反转录转座子品种，所有主要谱系都存在。为了更好地理解它们的结构特征，我们重建了26个Ty1-copia和28个Ty3-gypsy，以捕捉到检测到的多样性。因此，我们经常识别与串联重复的基序，额外开放的阅读框架和专门的，谱系典型域的关联。基于总体上较高的基因组丰度和转录活性，我们认为Ale和Athila谱系的反转录转座子最有希望监测跨群体的反转录转座子衍生多态性。结论:我们认为LTR逆转录转座子是V. macrocarpon基因组的主要组成部分。这些具有代表性的共识为进一步的蔓越莓基因组分析提供了一个切入点，并可用于推导分子标记，以增强蔓越莓的选择和育种。

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来源期刊

Journal of Berry Research Biochemistry, Genetics and Molecular Biology-Biochemistry

CiteScore

3.50

自引率

11.80%

发文量

期刊介绍： The main objective of the Journal of Berry Research is to improve the knowledge about quality and production of berries to benefit health of the consumers and maintain profitable production using sustainable systems. The objective will be achieved by focusing on four main areas of research and development: From genetics to variety evaluation Nursery production systems and plant quality control Plant physiology, biochemistry and molecular biology, as well as cultural management Health for the consumer: components and factors affecting berries'' nutritional value Specifically, the journal will cover berries (strawberry, raspberry, blackberry, blueberry, cranberry currants, etc.), as well as grapes and small soft fruit in general (e.g., kiwi fruit). It will publish research results covering all areas of plant breeding, including plant genetics, genomics, functional genomics, proteomics and metabolomics, plant physiology, plant pathology and plant development, as well as results dealing with the chemistry and biochemistry of bioactive compounds contained in such fruits and their possible role in human health. Contributions detailing possible pharmacological, medical or therapeutic use or dietary significance will be welcomed in addition to studies regarding biosafety issues of genetically modified plants.