了解水稻对不同农业生态系统的适应性：性状相互作用和数量性状基因座。

Understanding rice adaptation to varying agro-ecosystems: trait interactions and quantitative trait loci.

作者信息

Dixit Shalabh, Grondin Alexandre, Lee Cheng-Ruei, Henry Amelia, Olds Thomas-Mitchell, Kumar Arvind

机构信息

International Rice Research Institute, DAPO Box 7777, Metro Manila, Philippines.

Present address: Department of Agronomy and Horticulture, University of Nebraska-Lincoln, Lincoln, NE, 68583, USA.

出版信息

BMC Genet. 2015 Aug 5;16:86. doi: 10.1186/s12863-015-0249-1.

DOI:10.1186/s12863-015-0249-1

PMID:26243626

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4526302/

Abstract

BACKGROUND

Interaction and genetic control for traits influencing the adaptation of the rice crop to varying environments was studied in a mapping population derived from parents (Moroberekan and Swarna) contrasting for drought tolerance, yield potential, lodging resistance, and adaptation to dry direct seeding. A BC2F3-derived mapping population for traits related to these four trait groups was phenotyped to understand the interactions among traits and to map and align QTLs using composite interval mapping (CIM). The study also aimed to identify QTLs for the four trait groups as composite traits using multivariate least square interval mapping (MLSIM) to further understand the genetic control of these traits.

RESULTS

Significant correlations between drought- and yield-related traits at seedling and reproductive stages respectively with traits for adaptation to dry direct-seeded conditions were observed. CIM and MLSIM methods were applied to identify QTLs for univariate and composite traits. QTL clusters showing alignment of QTLs for several traits within and across trait groups were detected at chromosomes 3, 4, and 7 through CIM. The largest number of QTLs related to traits belonging to all four trait groups were identified on chromosome 3 close to the qDTY 3.2 locus. These included QTLs for traits such as bleeding rate, shoot biomass, stem strength, and spikelet fertility. Multivariate QTLs were identified at loci supported by univariate QTLs such as on chromosomes 3 and 4 as well as at distinctly different loci on chromosome 8 which were undetected through CIM.

CONCLUSION

Rice requires better adaptation across a wide range of environments and cultivation practices to adjust to climate change. Understanding the genetics and trade-offs related to each of these environments and cultivation practices thus becomes highly important to develop varieties with stability of yield across them. This study provides a wider picture of the genetics and physiology of adaptation of rice to wide range of environments. With a complete understanding of the processes and relationships between traits and trait groups, marker-assisted breeding can be used more efficiently to develop plant types that can combine all or most of the beneficial traits and show high stability across environments, ecosystems, and cultivation practices.

摘要

背景

在一个由（莫罗贝雷坎和斯瓦纳）亲本衍生的作图群体中，研究了影响水稻作物适应不同环境的性状的相互作用和遗传控制，这两个亲本在耐旱性、产量潜力、抗倒伏性以及对旱直播的适应性方面存在差异。对一个由BC2F3衍生的与这四个性状组相关性状的作图群体进行了表型分析，以了解性状间的相互作用，并使用复合区间作图（CIM）对数量性状基因座（QTL）进行定位和比对。该研究还旨在使用多元最小二乘区间作图（MLSIM）将这四个性状组的QTL鉴定为复合性状，以进一步了解这些性状的遗传控制。

结果

分别在幼苗期和生殖期观察到与干旱相关性状和产量相关性状与适应旱直播条件的性状之间存在显著相关性。应用CIM和MLSIM方法鉴定单变量和复合性状的QTL。通过CIM在第3、4和7号染色体上检测到QTL簇，这些QTL簇显示了性状组内和性状组间几个性状的QTL的比对。在靠近qDTY 3.2位点的第3号染色体上，鉴定出与所有四个性状组的性状相关的QTL数量最多。这些包括与伤流速率、地上部生物量、茎强度和小穗育性等性状相关的QTL。在单变量QTL支持的位点上鉴定出多变量QTL，如在第3和4号染色体上，以及在第8号染色体上明显不同的位点上，这些位点通过CIM未检测到。

结论

水稻需要更好地适应广泛的环境和栽培方式，以应对气候变化。因此，了解与每种环境和栽培方式相关的遗传学和权衡对于培育在这些环境中产量稳定的品种变得非常重要。本研究提供了水稻适应广泛环境的遗传学和生理学的更全面图景。全面了解性状和性状组之间的过程和关系后，标记辅助育种可以更有效地用于培育能够结合所有或大多数有益性状并在不同环境、生态系统和栽培方式下表现出高稳定性的植物类型。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9ff7/4526302/ab88af41edb9/12863_2015_249_Fig1_HTML.jpg

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了解水稻对不同农业生态系统的适应性：性状相互作用和数量性状基因座。

Understanding rice adaptation to varying agro-ecosystems: trait interactions and quantitative trait loci.

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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