基于SSR的光敏型饲草高粱分子辅助育种体系

doi:10.3864/j.issn.0578-1752.2020.14.004

Abstract

Abstract:

【Objective】 The aim of this study is to use molecular marker to construct a breeding system to improve the traditional breeding method,thereby reducing breeding costs and improving breeding efficiency. At the same time, it lays a theoretical foundation for the formation of a new breeding system. 【Method】 The F₂ population was constructed by crossing the photosensitive(non-heading) forage sorghum variety Jinguang 1R as female and the photo insensitive(heading) sorghum variety BMRC-3-2 as male. According to heading and non-heading phenotypes, F₂ population was divided into two groups. Thirty plants were selected from each group and DNA was extracted from leaves, SSR and BSA were used to map photosensitive genes in F₂ population of Jinguang 1R/BMRC-3-2 and screen for specific SSR primers. The specific primers were used to identify the photosensitivity trait in F₁generation（F₁Hybrids breeded from high generation stable restorer line with Jinguang 1R as parent and matched with other male sterile lines）, and the final target primers were determined by comparing with the phenotype in the field, so as to construct a new photosensitive breeding system for forage sorghum. 【Result】 After SNP index analysis, the region of about 250 Kb before and after the highest point of 99% threshold line was selected as the candidate region for trait correlation. The total length of the region was 500 kb, with 400 SNP loci, and six of them were non-synonymous mutations or stop gain or stop loss SNP loci. Finally, two candidate genes were identified to be related to photosensitivity, which were located on chromosome 7. A pair of specific primers 70.2-3 was developed by SSR. The primers can distinguish between heading and non-heading sorghum plants to a great extent. The results showed that according to the "single peak" at 251bp, the accuracy of primers 70.2-3 in the identification and selection of 50 non-photosensitive F₁hybrids reached 100%, and all the materials showed a peak value near 251bp. Based on the "double peaks" in the vicinity of 214 bp and 251 bp, the accuracy rate of the primer for the identification and selection of the other 50 photosensitive F₁ hybrid species reached 90%. Three materials, No. F₁-69, F₁-70 and F₁-71, showed "double peaks" near 214 bp and 262 bp. Material F₁-81 has a "single peak" at 251bp, while material No. 86 has a "double peak" near 251 bp and 232 bp.【Conclusion】 In this study, we revealed that the candidate genes controlling heading date of sorghum were LOC8068537 and LOC8068548, which were between 810000 and 1310000 bp on chromosome 7 of sorghum. The acquisition of specific primers 70.2-3 improved the traditional breeding methods. The primer validation in laboratory could replace the field crossing observation, saving the breeding cost and improving the breeding efficiency.

Key words: forage sorghum, photosensitive type, molecular markers

NIU Hao,PING JunAi,WANG YuBin,ZHANG FuYao,LÜ Xin,LI HuiMing,CHU JianQiang. Molecular Aided Breeding System of Photosensitive Forage Sorghum Based on SSR[J].Scientia Agricultura Sinica, 2020, 53(14): 2795-2803.

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References 32

[1]	平俊爱, 谢国强, 张福耀, 何余湧, 吴志勇, 王荣民, 吕鑫, 杜志宏, 李慧明, 牛皓, 王玉斌. 晋牧1号在南方红壤区的产草量: 营养价值及饲养效果研究. 安徽农业科学, 2018,46(35):94-96.
	PING J A, XIE G Q, ZHANG F Y, HE Y Y, WU Z Y, WANG R M, LÜ X, DU Z H, LI H M, NIU H, WANG Y B. Breeding and characteristic of Sorghum biclolr × S. sudanense ‘Jinmu1’. Journal of Anhui Agricultural Sciences, 2018,46(35):94-96. (in Chinese)
[2]	平俊爱, 张福耀, 牛皓, 杨慧勇, 吕鑫, 杜志宏, 李慧明, 王玉斌. 基于SSR标记的饲草高粱种质资源遗传多样性分析. 分子植物育种, 2018,16(14):4663-4670.
	PING J A, ZHANG F Y, NIU H, YANG H Y, LÜ X, DU Z H, LI H M, WANG Y B. Genetic diversity analysis of germplasm resources of forage sorghum based on SSR marker. Molecular Plant Breeding, 2018,16(14):4663-4670. (in Chinese)
[3]	BHOSALE S U, BENJAMIN S, RATTUNDE H F W, WELTZIEN E, HAUSSMANN B I, HAUSSMANN C T, RAMU P, CUEVAS H E, PATERSON A H, MELCHINGER A E, PARZIES H K. Association analysis of photoperiodic flowering time genes in west and central African sorghum [ Sorghum bicolor(L.) Moench]. BMC Plant Biology, 2012,12:32-41. pmid: 22394582
[4]	CASTO A L, MATTISON A J, OLSON S N, THAKRAN M, ROONEY W L, MULLET J E. Maturity2, a novel regulatorof flowering time in Sorghum bicolor, increases expression of SbPRR37 and SbCO in long days delaying flowering. PLoS ONE, 2019,14(4):e0212154. doi: 10.1371/journal.pone.0212154 pmid: 30969968
[5]	SUKUMARAN S, LI X, LI X R, ZHU C S, BAI G H, PERUMAL R, TUINSTRA M R, PRASAD P V V, MITCHELL S E, TESSO T T, YU J. QTL mapping for grain yield, flowering time, and stay-green traits in sorghum with genotyping-by-sequencing markers. Crop Science, 2016,56(4):1429-1442.
[6]	TUINSTRA M R, GROTE E M, GOLDSBROUGH P B, EJETA G. Genetic analysis of post-flowering drought tolerance and components of grain development in Sorghum bicolor(L.) Moench. Molecular Breeding, 1997,3(6):439-448.
[7]	SPINDEL J E, DAHLBERG J, COLGAN M, HOLLINGSWORTH J, SIEVERT J, STAGGENBORG S H, HUTMACHER R, JANSSON C, VOGEL J P. Association mapping by aerial drone reveals 213 genetic associations for Sorghum bicolor biomass traits under drought. BMC Genomics, 2018,19:679-696. pmid: 30223789
[8]	WANG Y H, UPADHYAYA H D, BURRELL A M, SAHRAEIAN S M, KLEIN R R, KLEIN P E. Genetic structure and linkage disequilibrium in a diverse, representative collection of the C4 model plant Sorghum bicolor. G3Genesgenetics, 2013,3(5):783-793.
[9]	HARPER M T, OH J, GIALLONGO F, LOPES J C, ROTH G W, HRISTOV A N. Using brown midrib 6 dwarf forage sorghum silage and fall-grown oat silage in lactating dairy cow rations. Journal of Dairy Science, 2017,100(7):5250-5265. doi: 10.3168/jds.2017-12552 pmid: 28527803
[10]	MULLET J E, ROONEY W L, KLEIN P E, BRYAN D M, BRYAN R M, BRADY J A. Discovery and utilization of sorghum genes(Ma₅/Ma₆). 13/744405[P] 2013-09-12.
[11]	MORGAN P W, FINLAYSON S A, LEE I J, CHILDS K L, HE C J, CREELMAN R A, DREW M C, MULLET J E. Regulation of circadianly rhythmic ethylene production by phytochrome b in sorghum. Biology and Biotechnology of the Plant Hormone Ethylene, 1997(1):105-111.
[12]	QUINBY J R, KARPER R E. The inheritance of three genes that influence time of floral initiation and maturity date in Milo1. Journal of the American Society of Agronomy, 1945(11):916-936.
[13]	QUINBY J R. Fourth maturity gene locus in sorghum. Crop Science, 1965(6):516-518.
[14]	QUINBY J R. The maturity genes of sorghum. Advances in Agronomy, 1967(19):267-305.
[15]	MAJOR D J, ROOD S B, MILLER F R. Temperature and photoperiod effects mediated by the sorghum maturity genes. Crop Science, 1990,30(2):305-310.
[16]	CHILDS K L, LU J L, MULLET J E, MORGAN P W. Genetic regulation of development in Sorghum bicolor: X. Greatly attenuated photoperiod sensitivity in a phytochrome-deficient sorghum possessing a biological clock but lacking a red light-high irradiance response. Plant Physiology, 1995,108(1):345-351. pmid: 12228479
[17]	ROONEY W L, JÜRG B, BEAN B, MULLET J E. Designing sorghum as a dedicated bioenergy feedstock. Biofuels, Bioprod Bioref, 2007,1(2):147-157.
[18]	ROONEY W L, AYDIN S. Genetic control of a photoperiod-sensitive response inSorghum bicolor(L.) Moench. Crop Science, 1999,39(2):397-400.
[19]	MORGAN P W, FINLAYSON S A, CHILDS K L, MULLET J E, ROONEY W L. Opportunities to improve adaptability and yield in grasses. Crop Science, 2002,42(6):1791-1799. doi: 10.2135/cropsci2002.1791
[20]	MURPHY R L, KLEIN R R, MORISHIGE D T, BRADY J A, ROONEY W L, MILLER F R, DUGAS D V, KLEIN P E, MULLET J E. Coincident light and clock regulation of pseudo response regulator protein 37 (PRR37) controls photoperiodic flowering in sorghum. Proceedings of the National Academy of Sciences of the USA, 2011,108(39):16469-16474. doi: 10.1073/pnas.1106212108 pmid: 21930910
[21]	YANG S S, WEERS B D, MORISHIGE D T, MULLET J E. CONSTANS is a photoperiod regulated activator of flowering in sorghum. BMC Plant Biology, 2014,14(1):148-162.
[22]	YANG S S, MURPHY R L, MORISHIGE D T, KLEIN P E, ROONEY W L, MULLET J E. Sorghum phytochrome B inhibits flowering in long days by activating expression of SbPRR37 and SbGHD7, repressors of SbEHD1, SbCN8 and SbCN12. PLoS ONE, 2014,9(8):e105352. doi: 10.1371/journal.pone.0105352 pmid: 25122453
[23]	WANG Y, TAN L B, FU Y C, ZHU Z F, LIU F X, SUN C, CAI H W. Molecular evolution of the sorghum maturity gene Ma₃. PLoS ONE, 2015,10(5):e0124435. pmid: 25961888
[24]	WOLABU T W, TADEGE M. Photoperiod response and floral transition in sorghum. Plant Signaling & Behavior, 2016,11(12):e1261232. doi: 10.1080/15592324.2016.1261232 pmid: 27854155
[25]	WOLABU T W, ZHANG F, NIU L F, KALVE S, MATHUR P B, MUSZYNSKI M G, TADEGE M. Three FLOWERING LOCUS T-like genes function as potential florigens and mediate photoperiod response in sorghum. New Phytologist, 2016,210(3):946-959. pmid: 26765652
[26]	MULLET J E, ROONEY W L. Method for production of sorghum hybrids with selected flowering times. 13/886130[P]. 2016-08-30.
[27]	CHILDS K L, MILLER F R, CORDONNIER PRATT M M, PRATT L H, MORGAN P W, MULLET J E. The sorghum photoperiod sensitivity gene, Ma₃ encodes a phytochrome B. Plant Physiology, 1997,113(2):611-619. doi: 10.1104/pp.113.2.611
[28]	CHILDS K L, CORDONNIER PRATT M M, PRATT L H, MORGAN P W. Genetic regulation of development in Sorghum bicolor: VII. Ma₃ ^R flowering mutant lacks a phytochrome that predominates in green tissue . Plant Physiology, 1992,99(2):765-770. pmid: 16668953
[29]	CHILDS K L, PRATT L H, MORGAN P W. Genetic regulation of development in Sorghum bicolor: VI. The Ma₃^R allele results in abnormal phytochrome physiology. Plant Physiology, 1991,97(2):714-719. doi: 10.1104/pp.97.2.714 pmid: 16668457
[30]	HART G E, SCHERTZ K F, PENG Y, SYED N H. Genetic mapping ofSorghum bicolor(L.) moench QTLs that control variation in tillering and other morphological characters. Theoretical and Applied Genetics, 2001,103(8):1232-1242.
[31]	CHANTEREAU J, TROUCHE G, RAMI J F, DEU M, BARRO C, GRIVET L. RFLP mapping of QTLs for photoperiod response in tropical sorghum. Euphytica, 2001,120(2):183-194. doi: 10.1023/A:1017513608309
[32]	牛皓, 平俊爱, 张福耀, 吕鑫, 杜志宏, 李慧明, 王玉斌. 基于SSR的高粱光敏特性分析. 安徽农业科学, 2018,46(35):103-105.
	NIU H, PING J A, ZHANG F Y, LÜ X, DU Z H, LI H M, WANG Y B. Analysis on the photosensitivity of sorghum based on SSR. Journal of Anhui Agricultural Sciences, 2018,46(35):103-105. (in Chinese)

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性状Traits	实际值Actual value	理论值Theoretical value	分离比Separation ratio	χ²
不抽穗Photosensitive	251	236	9﹕7	1.1
抽穗Photo-insensitive	169	184	9﹕7	1.1

Molecular Aided Breeding System of Photosensitive Forage Sorghum Based on SSR

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