Genetic dissection of grain traits and their corresponding heterosis in an elite hybrid

Genetic dissection of grain traits and their corresponding heterosis in an elite hybrid

Rice productivity has considerably improved due to the effective employment of heterosis, but the genetic basis of heterosis for grain shape and weight remains uncertain. For studying the genetic dissection of heterosis for grain shape/weight and their relationship with grain yield in rice, quantita...

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Published in:Frontiers in plant science Vol. 13; p. 977349
Main Authors: Zafar, Sundus, You, Hui, Zhang, Fan, Zhu, Shuang Bin, Chen, Kai, Shen, Congcong, Wu, Hezhou, Zhu, Fangjin, Zhang, Conghe, Xu, Jianlong
Format: Journal Article
Language:English
Published: Switzerland Frontiers Media S.A 05-10-2022
Subjects:
grain shape
grain weight
grain yield
heterosis
Plant Science
pyramiding breeding
quantitative trait locus/loci (QTL)
heterosis
quantitative trait locus/loci (QTL)
grain shape
pyramiding breeding
grain yield
grain weight
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Abstract Rice productivity has considerably improved due to the effective employment of heterosis, but the genetic basis of heterosis for grain shape and weight remains uncertain. For studying the genetic dissection of heterosis for grain shape/weight and their relationship with grain yield in rice, quantitative trait locus (QTL) mapping was performed on 1,061 recombinant inbred lines (RILs), which was developed by crossing / rice Quan9311B (Q9311B) and Wu-shan-si-miao (WSSM). Whereas, BC F (a backcross F ) was developed by crossing RILs with Quan9311A (Q9311A) combined with phenotyping in Hefei (HF) and Nanning (NN) environments. Overall, 114 (main-effect, mQTL) and 359 (epistatic QTL, eQTL) were identified in all populations (RIL, BC F , and mid-parent heterosis, H s) for 1000-grain weight (TGW), grain yield per plant (GYP) and grain shape traits including grain length (GL), grain width (GW), and grain length to width ratio (GLWR). Differential QTL detection revealed that all additive loci in RILs population do not show heterotic effects, and few of them affect the performance of BC F . However, 25 mQTL not only contributed to BC F 's performance but also contributed to heterosis. A total of seven QTL regions was identified, which simultaneously affected multiple grain traits (grain yield, weight, shape) in the same environment, including five regions with opposite directions and two regions with same directions of favorable allele effects, indicating that partial genetic overlaps are existed between different grain traits. This study suggested different approaches for obtaining good grain quality with high yield by pyramiding or introgressing favorable alleles (FA) with the same direction of gene effect at the QTL regions affecting grain shape/weight and grain yield distributing on different chromosomes, or introgressing or pyramiding FA in the parents instead of fixing additive effects in hybrid as well as pyramiding the polymorphic overdominant/dominant loci between the parents and eliminating underdominant loci from the parents. These outcomes offer valuable information and strategy to develop hybrid rice with suitable grain type and weight.
AbstractList Rice productivity has considerably improved due to the effective employment of heterosis, but the genetic basis of heterosis for grain shape and weight remains uncertain. For studying the genetic dissection of heterosis for grain shape/weight and their relationship with grain yield in rice, quantitative trait locus (QTL) mapping was performed on 1,061 recombinant inbred lines (RILs), which was developed by crossing xian / indica rice Quan9311B (Q9311B) and Wu-shan-si-miao (WSSM). Whereas, BC 1 F 1 (a backcross F 1 ) was developed by crossing RILs with Quan9311A (Q9311A) combined with phenotyping in Hefei (HF) and Nanning (NN) environments. Overall, 114 (main-effect, mQTL) and 359 (epistatic QTL, eQTL) were identified in all populations (RIL, BC 1 F 1 , and mid-parent heterosis, H MP s) for 1000-grain weight (TGW), grain yield per plant (GYP) and grain shape traits including grain length (GL), grain width (GW), and grain length to width ratio (GLWR). Differential QTL detection revealed that all additive loci in RILs population do not show heterotic effects, and few of them affect the performance of BC 1 F 1 . However, 25 mQTL not only contributed to BC 1 F 1 ’s performance but also contributed to heterosis. A total of seven QTL regions was identified, which simultaneously affected multiple grain traits (grain yield, weight, shape) in the same environment, including five regions with opposite directions and two regions with same directions of favorable allele effects, indicating that partial genetic overlaps are existed between different grain traits. This study suggested different approaches for obtaining good grain quality with high yield by pyramiding or introgressing favorable alleles (FA) with the same direction of gene effect at the QTL regions affecting grain shape/weight and grain yield distributing on different chromosomes, or introgressing or pyramiding FA in the parents instead of fixing additive effects in hybrid as well as pyramiding the polymorphic overdominant/dominant loci between the parents and eliminating underdominant loci from the parents. These outcomes offer valuable information and strategy to develop hybrid rice with suitable grain type and weight.
Rice productivity has considerably improved due to the effective employment of heterosis, but the genetic basis of heterosis for grain shape and weight remains uncertain. For studying the genetic dissection of heterosis for grain shape/weight and their relationship with grain yield in rice, quantitative trait locus (QTL) mapping was performed on 1,061 recombinant inbred lines (RILs), which was developed by crossing xian/indica rice Quan9311B (Q9311B) and Wu-shan-si-miao (WSSM). Whereas, BC1F1 (a backcross F1) was developed by crossing RILs with Quan9311A (Q9311A) combined with phenotyping in Hefei (HF) and Nanning (NN) environments. Overall, 114 (main-effect, mQTL) and 359 (epistatic QTL, eQTL) were identified in all populations (RIL, BC1F1, and mid-parent heterosis, HMPs) for 1000-grain weight (TGW), grain yield per plant (GYP) and grain shape traits including grain length (GL), grain width (GW), and grain length to width ratio (GLWR). Differential QTL detection revealed that all additive loci in RILs population do not show heterotic effects, and few of them affect the performance of BC1F1. However, 25 mQTL not only contributed to BC1F1’s performance but also contributed to heterosis. A total of seven QTL regions was identified, which simultaneously affected multiple grain traits (grain yield, weight, shape) in the same environment, including five regions with opposite directions and two regions with same directions of favorable allele effects, indicating that partial genetic overlaps are existed between different grain traits. This study suggested different approaches for obtaining good grain quality with high yield by pyramiding or introgressing favorable alleles (FA) with the same direction of gene effect at the QTL regions affecting grain shape/weight and grain yield distributing on different chromosomes, or introgressing or pyramiding FA in the parents instead of fixing additive effects in hybrid as well as pyramiding the polymorphic overdominant/dominant loci between the parents and eliminating underdominant loci from the parents. These outcomes offer valuable information and strategy to develop hybrid rice with suitable grain type and weight.
Rice productivity has considerably improved due to the effective employment of heterosis, but the genetic basis of heterosis for grain shape and weight remains uncertain. For studying the genetic dissection of heterosis for grain shape/weight and their relationship with grain yield in rice, quantitative trait locus (QTL) mapping was performed on 1,061 recombinant inbred lines (RILs), which was developed by crossing / rice Quan9311B (Q9311B) and Wu-shan-si-miao (WSSM). Whereas, BC F (a backcross F ) was developed by crossing RILs with Quan9311A (Q9311A) combined with phenotyping in Hefei (HF) and Nanning (NN) environments. Overall, 114 (main-effect, mQTL) and 359 (epistatic QTL, eQTL) were identified in all populations (RIL, BC F , and mid-parent heterosis, H s) for 1000-grain weight (TGW), grain yield per plant (GYP) and grain shape traits including grain length (GL), grain width (GW), and grain length to width ratio (GLWR). Differential QTL detection revealed that all additive loci in RILs population do not show heterotic effects, and few of them affect the performance of BC F . However, 25 mQTL not only contributed to BC F 's performance but also contributed to heterosis. A total of seven QTL regions was identified, which simultaneously affected multiple grain traits (grain yield, weight, shape) in the same environment, including five regions with opposite directions and two regions with same directions of favorable allele effects, indicating that partial genetic overlaps are existed between different grain traits. This study suggested different approaches for obtaining good grain quality with high yield by pyramiding or introgressing favorable alleles (FA) with the same direction of gene effect at the QTL regions affecting grain shape/weight and grain yield distributing on different chromosomes, or introgressing or pyramiding FA in the parents instead of fixing additive effects in hybrid as well as pyramiding the polymorphic overdominant/dominant loci between the parents and eliminating underdominant loci from the parents. These outcomes offer valuable information and strategy to develop hybrid rice with suitable grain type and weight.
Author Shen, Congcong
Zafar, Sundus
You, Hui
Chen, Kai
Zhang, Conghe
Xu, Jianlong
Zhu, Shuang Bin
Zhang, Fan
Zhu, Fangjin
Wu, Hezhou
AuthorAffiliation 4 Win-All Hi-Tech Seed Co., Ltd. , Hefei , China
2 The National Key Facility for Crop Gene Resources and Genetic Improvement, Institute of Crop Sciences, Chinese Academy of Agricultural Sciences , Beijing , China
1 Shenzhen Branch, Guangdong Laboratory for Lingnan Modern Agriculture, Agricultural Genomics Institute at Shenzhen, Chinese Academy of Agricultural Sciences , Shenzhen , China
3 Hunan Tao-Hua-Yuan Agricultural Technologies Co., LTD. , Hunan , China
5 Hainan Yazhou Bay Seed Lab/National Nanfan Research Institute (Sanya), Chinese Academy of Agricultural Sciences , Sanya , China
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– name: 5 Hainan Yazhou Bay Seed Lab/National Nanfan Research Institute (Sanya), Chinese Academy of Agricultural Sciences , Sanya , China
– name: 2 The National Key Facility for Crop Gene Resources and Genetic Improvement, Institute of Crop Sciences, Chinese Academy of Agricultural Sciences , Beijing , China
– name: 4 Win-All Hi-Tech Seed Co., Ltd. , Hefei , China
– name: 3 Hunan Tao-Hua-Yuan Agricultural Technologies Co., LTD. , Hunan , China
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Keywords heterosis
quantitative trait locus/loci (QTL)
grain shape
pyramiding breeding
grain yield
grain weight
Language English
License Copyright © 2022 Zafar, You, Zhang, Zhu, Chen, Shen, Wu, Zhu, Zhang and Xu.
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Edited by: Hanwei Mei, Shanghai Agrobiological Gene Center, China
Reviewed by: Jieyun Zhuang, Zhejiang University, China; Guiquan Zhang, South China Agricultural University, China
These authors have contributed equally to this work
This article was submitted to Plant Breeding, a section of the journal Frontiers in Plant Science
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  article-title: Heterosis and combining ability analysis for yield and related-yield traits in hybrid rice
  publication-title: Int. J. Biol.
  doi: 10.5539/ijb.v2n2p222
  contributor:
    fullname: Bagheri
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Snippet Rice productivity has considerably improved due to the effective employment of heterosis, but the genetic basis of heterosis for grain shape and weight remains...
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StartPage 977349
SubjectTerms grain shape
grain weight
grain yield
heterosis
Plant Science
pyramiding breeding
quantitative trait locus/loci (QTL)
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  priority: 102
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Title Genetic dissection of grain traits and their corresponding heterosis in an elite hybrid
URI https://www.ncbi.nlm.nih.gov/pubmed/36275576
https://search.proquest.com/docview/2728146019
https://pubmed.ncbi.nlm.nih.gov/PMC9581170
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