不同基因组区域简单重复序列（SSR）的模式和变化及其对玉米进化和育种的影响。

Pattern and variation in simple sequence repeat (SSR) at different genomic regions and its implications to maize evolution and breeding.

机构信息

Zhengzhou University Graduate Student Training Base at Beijing Lantron Seed, Zhengzhou, 450001, China.

School of Agricultural Sciences, Zhengzhou University, Zhengzhou, 450001, China.

出版信息

BMC Genomics. 2023 Mar 21;24(1):136. doi: 10.1186/s12864-023-09156-0.

DOI:10.1186/s12864-023-09156-0

PMID:36944913

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10029318/

Abstract

BACKGROUND

Repetitive DNA sequences accounts for over 80% of maize genome. Although simple sequence repeats (SSRs) account for only 0.03% of the genome, they have been widely used in maize genetic research and breeding as highly informative codominant DNA markers. The genome-wide distribution and polymorphism of SSRs are not well studied due to the lack of high-quality genome DNA sequence data.

RESULTS

In this study, using data from high-quality de novo-sequenced maize genomes of five representative maize inbred lines, we revealed that SSRs were more densely present in telomeric region than centromeric region, and were more abundant in genic sequences than intergenic sequences. On genic sequences, tri- and hexanucleotide motifs were more abundant in CDS sequence and some mono- and dinucleotide motifs were more abundant in UTR sequences. Median length and chromosomal density of SSRs were both narrowly range-bound, with median length of 14-18 bp and genome-wide average density of 3355.77 bp/Mbp. LTR-RTs of < 0.4 Mya had higher SSR density (4498-4992 bp/Mbp). The genome-specific and motif-specific SSR polymorphism were studied. Their potential breeding applications were discussed.

CONCLUSIONS

We found that the median length of SSR sequences of different SSR motifs was nearly constant. SSR density in genic regions was much higher than intergenic regions. In addition, SSR density at LTR-RTs of different evolutionary ages varied in a narrow range. The SSRs and their LTR-RT carriers evolved at an equal rate. All these observations indicated that SSR length and density were under control of yet unknown evolutionary forces. The chromosome region-specific and motif-specific SSR polymorphisms we observed supported the notion that SSR polymorphism was invaluable genome resource for developing highly informative genome and gene markers in maize genetic research and molecular breeding.

摘要

背景

重复 DNA 序列占玉米基因组的 80%以上。尽管简单序列重复（SSR）仅占基因组的 0.03%，但它们作为高度信息丰富的共显性 DNA 标记已广泛应用于玉米遗传研究和育种。由于缺乏高质量的基因组 DNA 序列数据，SSR 的全基因组分布和多态性尚未得到很好的研究。

结果

在这项研究中，我们使用来自五个代表玉米自交系的高质量从头测序玉米基因组数据，揭示了 SSR 在端粒区域比着丝粒区域更为密集，在基因序列中比在基因间序列中更为丰富。在基因序列上，三核苷酸和六核苷酸基序在 CDS 序列中更为丰富，一些单核苷酸和二核苷酸基序在 UTR 序列中更为丰富。SSR 的中位数长度和染色体密度都在狭窄的范围内，中位数长度为 14-18 bp，全基因组平均密度为 3355.77 bp/Mbp。<0.4 Mya 的 LTR-RTs 具有更高的 SSR 密度（4498-4992 bp/Mbp）。研究了基因组特异性和基序特异性 SSR 多态性，并讨论了其潜在的育种应用。

结论

我们发现不同 SSR 基序的 SSR 序列中位数长度几乎保持不变。基因区域的 SSR 密度远高于基因间区域。此外，不同进化年龄 LTR-RTs 的 SSR 密度在一个狭窄的范围内变化。SSR 及其 LTR-RT 载体以相同的速度进化。所有这些观察结果表明，SSR 长度和密度受到未知进化力量的控制。我们观察到的染色体区域特异性和基序特异性 SSR 多态性支持这样一种观点，即 SSR 多态性是开发玉米遗传研究和分子育种中高度信息丰富的基因组和基因标记的宝贵基因组资源。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/004d/10029318/6222817836a6/12864_2023_9156_Fig1_HTML.jpg

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不同基因组区域简单重复序列（SSR）的模式和变化及其对玉米进化和育种的影响。

Pattern and variation in simple sequence repeat (SSR) at different genomic regions and its implications to maize evolution and breeding.

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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