在具有相同DEEPER ROOTING 1功能等位基因的水稻品种中，根系生长角度自然变异的潜在数量性状基因座。

QTLs underlying natural variation of root growth angle among rice cultivars with the same functional allele of DEEPER ROOTING 1.

作者信息

Kitomi Yuka, Kanno Noriko, Kawai Sawako, Mizubayashi Tatsumi, Fukuoka Shuichi, Uga Yusaku

机构信息

National Institute of Agrobiological Sciences, 2-1-2 Kannondai, Tsukuba, Ibaraki 305-8602 Japan.

出版信息

Rice (N Y). 2015 Mar 21;8:16. doi: 10.1186/s12284-015-0049-2. eCollection 2015.

DOI:10.1186/s12284-015-0049-2

PMID:25844121

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4385264/

Abstract

BACKGROUND

The functional allele of the rice gene DEEPER ROOTING 1 (DRO1) increases the root growth angle (RGA). However, wide natural variation in RGA is observed among rice cultivars with the functional DRO1 allele. To elucidate genetic factors related to such variation, we quantitatively measured RGA using the basket method and analyzed quantitative trait loci (QTLs) for RGA in three F2 mapping populations derived from crosses between the large RGA-type cultivar Kinandang Patong and each of three accessions with varying RGA: Momiroman has small RGA and was used to produce the MoK-F2 population; Yumeaoba has intermediate RGA (YuK-F2 population); Tachisugata has large RGA (TaK-F2 population). All four accessions belong to the same haplotype group of functional DRO1 allele.

RESULTS

We detected the following statistically significant QTLs: one QTL on chromosome 4 in MoK-F2, three QTLs on chromosomes 2, 4, and 6 in YuK-F2, and one QTL on chromosome 2 in TaK-F2. Among them, the two QTLs on chromosome 4 were located near DRO2, which has been previously reported as a major QTL for RGA, whereas the two major QTLs for RGA on chromosomes 2 (DRO4) and 6 (DRO5) were novel. With the LOD threshold reduced to 3.0, several minor QTLs for RGA were also detected in each population.

CONCLUSION

Natural variation in RGA in rice cultivars carrying functional DRO1 alleles may be controlled by a few major QTLs and by several additional minor QTLs.

摘要

背景

水稻基因“更深扎根1”（DRO1）的功能等位基因可增大根生长角度（RGA）。然而，在具有功能性DRO1等位基因的水稻品种中，RGA存在广泛的自然变异。为了阐明与这种变异相关的遗传因素，我们使用篮式法对RGA进行了定量测量，并分析了来自大RGA型品种基南当巴通与三个RGA不同的种质杂交产生的三个F2作图群体中RGA的数量性状位点（QTL）：莫米罗曼的RGA较小，用于构建莫米罗曼-基南当巴通F2群体（MoK-F2群体）；梦肋八的RGA中等（梦肋八-基南当巴通F2群体，YuK-F2群体）；立菅形的RGA较大（立菅形-基南当巴通F2群体，TaK-F2群体）。所有四个种质都属于功能性DROI等位基因的同一单倍型组。

结果

我们检测到以下具有统计学意义的QTL：MoK-F2群体中位于4号染色体上的一个QTL，YuK-F2群体中位于2号、4号和6号染色体上的三个QTL，以及TaK-F2群体中位于2号染色体上的一个QTL。其中，4号染色体上的两个QTL位于DRO2附近，DRO2此前已被报道为RGA的一个主要QTL，而2号染色体（DRO4）和6号染色体（DRO5）上的两个RGA主要QTL是新发现的。将LOD阈值降至3.0时，在每个群体中还检测到了几个RGA的次要QTL。

结论

携带功能性DRO1等位基因水稻品种的RGA自然变异可能受少数主要QTL和一些其他次要QTL控制。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9bcc/4385264/adbaa2770f8f/12284_2015_49_Fig1_HTML.jpg

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在具有相同DEEPER ROOTING 1功能等位基因的水稻品种中，根系生长角度自然变异的潜在数量性状基因座。

QTLs underlying natural variation of root growth angle among rice cultivars with the same functional allele of DEEPER ROOTING 1.

作者信息

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSION

背景

结果

结论

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