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Research Article

Phenotypic Characterization and Genetic Mapping of An Open-hull Sterile Mutant in Rice

Plant Breeding and Biotechnology 2013;1(1):24-32.
Published online: March 31, 2013

Department of Plant Science, Plant Genomics and Breeding Institute, and Research Institute of Agriculture and Life Sciences, Seoul National University, Seoul 151-921, Korea

*Corresponding author Hee-Jong Koh, heejkoh@snu.ac.kr, Tel: +82-2-880-4541, Fax: +82-2-873-2056
• Received: March 5, 2013   • Revised: March 18, 2013   • Accepted: March 19, 2013

Copyright © 2013 The Korean Society of Breeding Science

This is an Open-Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/3.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

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  • Fine Mapping and Candidate-Gene Analysis of an open glume multi-pistil 3 (mp3) in Rice (Oryza sativa L.)
    Yongshu Liang, Junyi Gong, Yuxin Yan, Tingshen Peng, Jinyu Xiao, Shuang Wang, Wenbin Nan, Xiaojian Qin, Hanma Zhang
    Agriculture.2022; 12(10): 1731.     CrossRef

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Phenotypic Characterization and Genetic Mapping of An Open-hull Sterile Mutant in Rice
Plant Breed. Biotech.. 2013;1(1):24-32.   Published online March 31, 2013
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Phenotypic Characterization and Genetic Mapping of An Open-hull Sterile Mutant in Rice
Plant Breed. Biotech.. 2013;1(1):24-32.   Published online March 31, 2013
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Phenotypic Characterization and Genetic Mapping of An Open-hull Sterile Mutant in Rice
Image Image Image Image
Fig. 1 Overall phenotypes of wild type and Open-hull sterile mutant. A. Spikelets and seeds phenotypes of the wild type (left) and the Open–hull sterile mutant (right). B. Various spikelets phenotype of the Open-hull sterile mutant. C. Plant of wild type (left) and Open-hull sterile mutant (right). D. Panicle shape of wild type (left) and Open-hull sterile mutant (right). E. Spikelet of wild type (left) and Open-hull sterile mutant (right) after at the ripening stage.
Fig. 2 A. Spikelet cross sections of the wild-type (left) and Open-hull sterile mutants (middle and right. pa;palea, le; lemma. B. I2-KI pollen fertility test of the wild type (left) and Open-hull sterile mutant (right). Pollen grains stained dark black and light yellow were considered to be fertile and sterile, respectively.
Fig. 3 Bulked segregant analysis (BSA) of wild-type and mutant bulks from F2 population. A~C. STS (sequence tagged site) markers linked to the Open-hull sterile mutant locus. 1: Milyang 23 (Tongil-type rice). 2: Sinsunchallbyeo(Japonica type) Wild-type. 3, 4: Mutant bulks. 5, 6: Wild-type bulks.
Fig. 4 Genetic and physical maps of the Open-hull sterile mutant. A. A Schematic genetic linkage map of Open-hull sterile mutant gene. The mutant gene was primarily mapped on the short arm of chromosome 3, based on the bulked segregant analysis (BSA) of F2 individuals. The genetic distances (centi Morgan [cM]) between flanking markers are indicated. B. Physical map of the mutant gene, which was made by genotyping of 1530 F2 individuals using STS markers. The physical distance between adjacent markers, 105732-3 and 104474 (pink letters), was 191Kb. C. The mutant gene was fine mapped to an interval of 30.6Kb by genotyping of 646 F3 individuals which derived from F2 plants using additional STS markers (b-j). BAC contigs covering the mutant gene which published by IRGSP are shown. a, 105732-2; b, 105732-3; c, 105732-4; d, 105732-5; e, 105732-6; f, 105732-7; g, 105732-8; h, 105732-9; i, 105732-10; j, 105732-11; k, 104474. (D) Three putative genes, which were annotated in RAP-DB database, LOC_Os03g11614.1, LOC_Os03g11630.1 and LOC_Os03g11640.1, existed in this 30.6Kb region.
Phenotypic Characterization and Genetic Mapping of An Open-hull Sterile Mutant in Rice

The PCR-based molecular markers used in F2 genetic mapping of the Open-hull sterile mutant.

STS marker Forward primer (5′-3′) Reverse primer (3′-5′) Product size (bp)
146619 TTTACAAGAGCGCATACATCTG TGCAACCTGAGTGGAGTTAATG 193
146619-2 ATTTTCTCTGCACCCTGTTCAC CTTTCCCAATGGAATATCAGGT 168
146619-3 TGTGTTCCCCTGTCTACTTTCA GAATCCACTCCCATGTATTCGT 182
105732 GATAAAATGTCTCAGCGCCACT GAGACAGGAATCGAACTCTTGC 198
105732-2 TCTGAGAAAATAGTTAGGAAATGATGA CAAGGTCCCTAACACCAAGAAA 197
134241 ACATGAGTCACGAAACGATGAA GGGTGAGATGTTTTGCTTTGTT 200
134241-2 GCCCTTTCCTCCTTTAAGAAAC CAGGAGAGGATAAATTGGGAGA 181
135158 TCTGTTCATGTGTCTCCGATCT CATGATCCTATGTTCGGTCGAT 171
104474 CTTCGCGTGGAGCAGTACTAT ACACACGAACAATCTCAAATGC 198
107226 TCATACAATTCGTTGCGTTTTC AAGTTCGTCTCGCAGTTACAGG 190
107226-2 AACAAACCCTAGCTACGAACCA GACCCACTAGCTCGGATAAATG 158
104473 AACCAATTAATCATGCCCTAATG ACTTCCAAAACCAGTTTCATCG 163

Descriptive statistics of agronomic traits of the Open-hull sterile mutant and wild-type.

Traits HDz) GL (mm) GW (mm) GT (mm) GS Brown rice 100-grain weight (g) Fertility rate (%)
Wild-type 8/14 5.54 2.89 2.16 1.92 2.01 83.1
Mutant 8/15 5.40 1.99 1.37 2.78 1.41 19.8
Difference nsy) * ** ** ** ** **

z)HD, is a the abbreviation of heading date; GL, for grain length; GW, for grain width; GT, for grain thickness; GS, for grain shape (length/width ratio).

y)Student’s t-test.

*0.01<P<0.05;

**p<0.01;

NS, reffered to not significantly different at the 0.05 level of significance.

Segregation of the normal and the Open-hull sterile mutant types in F1, F2 and F3 populations. X20.05(1)=3.841

Cross combination Generation No. of plant Total X2 (3:1) p

Wild-type Mutant
Mutant/Milyang 23 F1 35 0 35 - -
F2 1,250 280 1,530 36.267 > 0.05
F3 483 163 646 0.019 < 0.01

The PCR-based molecular markers used in F3 genetic mapping of the Open-hull sterile mutant.

STS marker Forward primer (5′-3′) Reverse primer (3′-5′) Product size (bp)
105732-3 GCATGGAGTATGTACCCCCTAT CTTGAACACATGACATATACTTTGC 155
105732-5 TATCGAAATGCTGCCGAAAT GCAGCTCTGTGTCCAGTTCA 137
105732-6 GGTCAAAGTGTTATCAACCCAGA GCGCATATATACCCCCATCA 116
105732-7 ATGTGGGACCACCTCGTAGT TCCAATGGCTGCTTTATTCc 139
105732-8 AGAACATCAACTGGGCTTTCA GCACACAAGATAAACCCAATCA 136
105732-9 TTTCTTGTCGTTTGGGCTTC CGCACAAGAGAAACAGGTGA 145
105732-10 TTTACCCTCGGCGATAGAGA GTCGCCATCACGATGAACT 124
105732-11 CCAGCAAAAACGTAACCTTGA TGCAGCTAGAGAATGGTCGAT 140
Table 1 The PCR-based molecular markers used in F2 genetic mapping of the Open-hull sterile mutant.
Table 2 Descriptive statistics of agronomic traits of the Open-hull sterile mutant and wild-type.

HD, is a the abbreviation of heading date; GL, for grain length; GW, for grain width; GT, for grain thickness; GS, for grain shape (length/width ratio).

Student’s t-test.

0.01<P<0.05;

p<0.01;

NS, reffered to not significantly different at the 0.05 level of significance.

Table 3 Segregation of the normal and the Open-hull sterile mutant types in F1, F2 and F3 populations. X20.05(1)=3.841
Table 4 The PCR-based molecular markers used in F3 genetic mapping of the Open-hull sterile mutant.