Mechanism of Sterility and Breeding Strategies for Photoperiod/Thermo- Sensitive Genic Male Sterile Rice

doi:10.1016/S1672-6308(09)60012-3

Abstract

Abstract: To understand the male sterility mechanism of photoperiod/thermo-sensitive genic male sterile [P(T)GMS] lines in rice, the research progress on genetics of photoperiod and/or temperature sensitive genic male sterility in rice was reviewed. A new idea was proposed to explain the sterility mechanism of P(T)GMS rice. The fertility transition from sterile to fertile is the result of cooperative regulation of major-effect sterile genes with photoperiod and/or temperature sensitive genes, but not the so-called pgms gene in P(T)GMS rice. The minor-effect genes, which exhibit accumulative effect on sterility, are the important factors for the critical temperature of sterility transition. The more minor-effect genes the sterile line holds, the lower the critical temperature of sterility transition is. The critical temperature of sterility transition will be invariable if all the minor-effect genes are homozygous. The strategies for breeding P(T)GMS rice were also proposed. The selective indices of critical photoperiod and temperature for sterility transition should be set according to varietal type and ecological region. Imposing selection pressure is a key technology for breeding P(T)GMS rice with lower critical temperature for sterility, and improving the comprehensive performance of the whole traits and combining ability is vital for breeding P(T)GMS rice lines.

Key words: rice, photoperiod/thermo-sensitive genic male sterility, mechanism of sterility, breeding strategy

CHEN Li-yun, XIAO Ying-hui, LEI Dong-yang. Mechanism of Sterility and Breeding Strategies for Photoperiod/Thermo- Sensitive Genic Male Sterile Rice[J]. RICE SCIENCE, 2010, 17(3): 161-167 .

References

Chen L Y. 2001. Theory and Technology of Two-Line Hybrid Rice. Shanghai: Shanghai Science and Technology Press: 102–105. (in Chinese)
Chen L Y, Xiao Y H, Tang W B, Lei D Y. 2007. Practices and prospects of super hybrid rice breeding. Rice Sci, 14(2): 71–77.
He Q, Chen L Y, Deng H F, Tang W B, Xiao Y H, Yuan L P. 2007. Fertility photo-thermo characteristics in PTGMS rice C815S and its homologous plant lines. Acta Agron Sin, 33(2): 262–268. (in Chinese with English abstract)
Li X H, Lu Q, Wang F L, Xu C G, Zhang Q. 2001. Separation of the two-locus inheritance of photoperiod sensitive genic male sterility in rice and precise mapping the pms3 locus. Euphytica, 119: 343–348.
Li X H, Wang F L, Lu Q, Xu C G. 2002. Fine mapping of PSGMS gene pms3 in rice (Oryza sativa L.). Acta Agron Sin, 28(3): 310– 314. (in Chinese with English abstract)
Li Z Y, Lin X H, Xie Y F, Zhang D P. 1999. Tagging of a photoperiod-sensitive genic male sterile gene in Nongken 58S via molecular markers. Acta Bot Sin, 41(7): 731–735. (in Chinese with English abstract)
Lin X H, Yu G X, Zhang D P, Xie Y F, Qin F L. 1996. Location of one PGMS gene in Nongken 58S on chromosome 5 of rice. J Huazhong Agric Univ, 15(1): 1–5. (in Chinese with English abstract)
Lu Q, Li X H, Guo D, Xu C G, Zhang Q. 2005. Localization of pms3, a gene for photoperiod-sensitive genic male sterility, to a 28.4-kb DNA fragment. Mol Genet Gen, 273: 507–511.
Mei M H, Dai X K, Xu C G, Zhang Q. 1999. Mapping and genetic analysis of the genes for photoperiod-sensitive genic male sterility in rice using the original mutant Nongken 58S. Crop Sci, 39: 1711–1715.
Mei M H, Xu C G, Chen L, Wang W, Cui H. 2000. Identification of AFLP-RFLP makers linked to the photoperiod-sensitive male sterile gene pms3 in rice. J Xiamen Univ: Nat Sci, 39(4): 421–425. (in Chinese with English abstract)
Qian Q, Zhu X D, Zeng D L, Xiong Z M, Min S K. 1995. Linkage analysis of Hubei photoperiod-senstive genic male sterile locus in rice. Acta Agric Zhejiang, 7(6): 429–433. (in Chinese with English abstract)
Shi M S. 1985. Study on the photoperiod sensitive genic male sterile lines in rice. Sci Agric Sin, 18(2): 44–48. (in Chinese with English abstract)
Shi M S, Deng J Y. 1986. The discovery, identification and utilization of Hubei photoperiodic sensitive nuclear male sterile rice. Acta Genet Sin, 13(2): 107–112. (in Chinese with English abstract)
Tang W B, He Q, Xiao Y H, Deng H B, Chen L Y. 2004. Heterosis analysis of the combinations with dual-purpose genic male sterile rice C815S. J Hunan Agric Univ: Nat Sci, 30(6): 499–502. (in Chinese with English abstract)
Wang B, Xu W W, Wang J Z, Wu W, Zheng H G, Yang Z Y, Ray J D, Nguyen H T. 1995. Tagging and mapping the thermo- sensitive genic male-sterile gene in rice (Oryza sativa L.) with molecular markers. Theor Appl Genet, 91: 1111–1114.
Wang F P, Mei M H, Xu C G, Zhang Q F. 1997. Pms1 is not the locus of relevant to fertility difference between the photoperiod-sensitive male sterile rice Nongken 58S and normal rice ‘Nongken 58S’. Acta Bot Sin, 39(10): 922–925. (in Chinese with English abstract)
Wang J Z, Wang B, Xu Q F, Yang D C, Zhu Y G. 1995. Tagging rice photoperiod-sensitive genic male sterile gene by RAPD analysis. Acta Genet Sin, 22(1): 53–58. (in Chinese with English abstract)
Wu X Y, Wan B H. 1991. Study on the genetic relationships between photoperiod-temperature sensitive genic male sterility genes and isozyme genes and its linkage measurement in rice. J South China Agric Univ, 12(1): 1–9. (in Chinese with English abstract)
Xie G S, Zhang D P, Xie Y F. 2000. Study of the number and allelism of restoring genes in photoperiod sensitive genic male sterile rice. J Wuhan Bot Res, 18(6): 449–453. (in Chinese with English abstract)
Xue G X, Deng J Y. 1991. Studies on the Hubei photoperiodic sensitive nuclear male sterile rice (Oryza sativa L. subsp. japonica): modification of minor genes on the phenotypic values of progenies of photoperiodic sensitive male sterile rice. Acta Genet Sin, 18(1): 59–66. (in Chinese with English abstract)
Xue G X, Deng J Y, Zhao J Z, Chen P, Shen Y Z. 1995. Genetical studies on photo-sensitive genic male sterility (PGMS) of rice: polymorphism of fertility distribution among different F2 segregated populations. Sci Agric Sin, 28(1): 33–41. (in Chinese with English abstract)
Yang Z P. 1997. Inheritance of photoperiod sensitive genic male sterility and breeding of photoperiod sensitive genic male-sterile lines in rice (Oryza sativa L.) through anther culture. Euphytica, 94: 93–99.
Yuan L P. 1987. Prospects of hybrid rice breeding. Hybrid Rice, (1): 1–3. (in Chinese)
Yuan S C, Zhang Z G, Xu C Z. 1988. Studies on the critical stage of fertility change induced by light and its phase development in HPGMR. Acta Agron Sin, 14(1): 8–9. (in Chinese with English abstract)
Zhang D P, Deng X A, Yu G X, Lin X H, Xie Y F, Li Z B. 1990. Chromosomal location of the photoperiod sensitive male genic sterile gene in Nongken 58S. J Huazhong Agric Univ, 9(4): 407–419. (in Chinese with English abstract)
Zhang Q F, Shen B Z, Dai X K, Mei M H, Saghai Maroof M A, Li Z B. 1994. Using bulked extremes and recessive class to map gene for photoperiod-sensitive genic male sterility in rice. Proc Natl Acad Sci USA, 99(8): 8875–8679.
Zhang X G, Zhu Y G. 1991. Genetic analysis of the sterility of Hubei PGMS. Hereditas, 13(3): 1–3. (in Chinese)

[1]	Prathap V, Suresh KUMAR, Nand Lal MEENA, Chirag MAHESHWARI, Monika DALAL, Aruna TYAGI. Phosphorus Starvation Tolerance in Rice Through a Combined Physiological, Biochemical and Proteome Analysis [J]. Rice Science, 2023, 30(6): 8-.
[2]	Serena REGGI, Elisabetta ONELLI, Alessandra MOSCATELLI, Nadia STROPPA, Matteo Dell’ANNO, Kiril PERFANOV, Luciana ROSSI. Seed-Specific Expression of Apolipoprotein A-I_Milano Dimer in Rice Engineered Lines [J]. Rice Science, 2023, 30(6): 6-.
[3]	Sundus ZAFAR, XU Jianlong. Recent Advances to Enhance Nutritional Quality of Rice [J]. Rice Science, 2023, 30(6): 4-.
[4]	Kankunlanach KHAMPUANG, Nanthana CHAIWONG, Atilla YAZICI, Baris DEMIRER, Ismail CAKMAK, Chanakan PROM-U-THAI. Effect of Sulfur Fertilization on Productivity and Grain Zinc Yield of Rice Grown under Low and Adequate Soil Zinc Applications [J]. Rice Science, 2023, 30(6): 9-.
[5]	FAN Fengfeng, CAI Meng, LUO Xiong, LIU Manman, YUAN Huanran, CHENG Mingxing, Ayaz AHMAD, LI Nengwu, LI Shaoqing. Novel QTLs from Wild Rice Oryza longistaminata Confer Rice Strong Tolerance to High Temperature at Seedling Stage [J]. Rice Science, 2023, 30(6): 14-.
[6]	LIN Shaodan, YAO Yue, LI Jiayi, LI Xiaobin, MA Jie, WENG Haiyong, CHENG Zuxin, YE Dapeng. Application of UAV-Based Imaging and Deep Learning in Assessment of Rice Blast Resistance [J]. Rice Science, 2023, 30(6): 10-.
[7]	Md. Forshed DEWAN, Md. AHIDUZZAMAN, Md. Nahidul ISLAM, Habibul Bari SHOZIB. Potential Benefits of Bioactive Compounds of Traditional Rice Grown in South and South-East Asia: A Review [J]. Rice Science, 2023, 30(6): 5-.
[8]	Raja CHAKRABORTY, Pratap KALITA, Saikat SEN. Phenolic Profile, Antioxidant, Antihyperlipidemic and Cardiac Risk Preventive Effect of Chakhao Poireiton (A Pigmented Black Rice) in High-Fat High-Sugar induced Rats [J]. Rice Science, 2023, 30(6): 11-.
[9]	LI Qianlong, FENG Qi, WANG Heqin, KANG Yunhai, ZHANG Conghe, DU Ming, ZHANG Yunhu, WANG Hui, CHEN Jinjie, HAN Bin, FANG Yu, WANG Ahong. Genome-Wide Dissection of Quan 9311A Breeding Process and Application Advantages [J]. Rice Science, 2023, 30(6): 7-.
[10]	JI Dongling, XIAO Wenhui, SUN Zhiwei, LIU Lijun, GU Junfei, ZHANG Hao, Tom Matthew HARRISON, LIU Ke, WANG Zhiqin, WANG Weilu, YANG Jianchang. Translocation and Distribution of Carbon-Nitrogen in Relation to Rice Yield and Grain Quality as Affected by High Temperature at Early Panicle Initiation Stage [J]. Rice Science, 2023, 30(6): 12-.
[11]	Nazaratul Ashifa Abdullah Salim, Norlida Mat Daud, Julieta Griboff, Abdul Rahim Harun. Elemental Assessments in Paddy Soil for Geographical Traceability of Rice from Peninsular Malaysia [J]. Rice Science, 2023, 30(5): 486-498.
[12]	Monica Ruffini Castiglione, Stefania Bottega, Carlo Sorce, Carmelina SpanÒ. Effects of Zinc Oxide Particles with Different Sizes on Root Development in Oryza sativa [J]. Rice Science, 2023, 30(5): 449-458.
[13]	Tan Jingyi, Zhang Xiaobo, Shang Huihui, Li Panpan, Wang Zhonghao, Liao Xinwei, Xu Xia, Yang Shihua, Gong Junyi, Wu Jianli. ORYZA SATIVA SPOTTED-LEAF 41 (OsSPL41) Negatively Regulates Plant Immunity in Rice [J]. Rice Science, 2023, 30(5): 426-436.
[14]	Ammara Latif, Sun Ying, Pu Cuixia, Noman Ali. Rice Curled Its Leaves Either Adaxially or Abaxially to Combat Drought Stress [J]. Rice Science, 2023, 30(5): 405-416.
[15]	Liu Qiao, Qiu Linlin, Hua Yangguang, Li Jing, Pang Bo, Zhai Yufeng, Wang Dekai. LHD3 Encoding a J-Domain Protein Controls Heading Date in Rice [J]. Rice Science, 2023, 30(5): 437-448.