大豆耐荫性评价体系的建立与中国南方大豆资源耐荫性变异

doi:10.3864/j.issn.0578-1752.2017.05.002

中国农业科学 ›› 2017, Vol. 50 ›› Issue (5): 792-801.doi: 10.3864/j.issn.0578-1752.2017.05.002

• 作物遗传育种·种质资源·分子遗传学 • 上一篇下一篇

大豆耐荫性评价体系的建立与中国南方大豆资源耐荫性变异

孙祖东¹，张志鹏²，蔡昭艳¹，曾维英¹，赖振光¹，陈怀珠¹，杨守臻¹，唐向民¹，苏燕竹²，盖钧镒²

¹广西农业科学院经济作物研究所/农业部西南玉米大豆间套作区农业科学观测实验站，南宁530007；²南京农业大学大豆研究所/农业部大豆生物学与遗传育种重点实验室，南京210095

收稿日期:2016-09-02 出版日期:2017-03-01 发布日期:2017-03-01
通讯作者: 盖钧镒，Tel：025-84395405；E-mail：sri@njau.edu.cn
作者简介:孙祖东，E-mail：sunzudong639@163.com；张志鹏，Tel：18260085782；E-mail：2014201026@njau.edu.cn。孙祖东和张志鹏为同等贡献作者。
基金资助:
农业部国家大豆产业技术体系CARS-04项目、广西科学研究与技术开发计划（桂科合14125008-2-16）、广西农业科学院科技发展基金（桂农科2013YQ14）

Establishment of an Evaluation System of Shade Tolerance in Soybean and Its Variation in Southern China Germplasm Population

SUN ZuDong¹, ZHANG ZhiPeng², CAI ZhaoYan¹, ZENG WeiYing¹, LAI ZhenGuang¹, CHEN HuaiZhu¹, YANG ShouZhen¹, TANG XiangMin¹, SU YanZhu², GAI JunYi²

¹Institute of Economic Crops, Guangxi Academy of Agricultural Sciences/Ministry of Agriculture Southwest Experimental Station of Maize-Soybean Intercrop, Nanning 530007; ² Soybean Research Institute of Nanjing Agricultural University/Ministry of Agriculture Key Laboratory for Soybean Biology, Genetics and Breeding, Nanjing 210095

Received:2016-09-02 Online:2017-03-01 Published:2017-03-01

摘要/Abstract

摘要： 【目的】耐荫性是影响间套作大豆产量的重要因素，影响大豆间套作模式的应用与推广。建立高效、通用、稳定的耐荫性鉴定体系，以利于发掘耐荫种质，开展耐荫性育种。【方法】以60份不同耐荫性类型的大豆品种为材料，首先对15%、30%和60% 3个遮光度下倒伏品种比例等进行比较，确定遮光处理条件；其次对遮光后的株高、平均节间长、叶柄长和茎叶鲜重等17个性状进行筛选，选定耐荫鉴定指标；再比较播种后第40、50和60天3个时期耐荫指标的误差变异系数和表型变异系数等，明确鉴定时期，最后建立由遮光度、耐荫鉴定指标和鉴定时期构成的耐荫性评价体系；利用该体系对中国南方十二省区453份材料进行耐荫性鉴定和资源筛选。【结果】30%遮光度相对其他遮光梯度较优，表现为倒伏品种有而不太多（22%）、表型变异系数较高（25%）、品种间区分度较好。株高和平均节间长构成的耐荫指标相对其他指标具有以下优点：①较准确，误差变异系数低（9.36%），遗传率高（95.43%）；②较稳定，环境间相关系数高（0.92）；③品种间区分度较好，表型变异系数（31.25%）和遗传变异系数（30.52%）较大；④与田间目测耐荫级别相关性较高（0.73），较能反映田间实际情况。播种后50 d时相对其他时期耐荫指标各参数均最优，如环境间相关系数最大（0.87），误差变异系数最小（7.75%）。据此将30%遮光度条件下，播种后50 d株高和平均节间长相对值的平均数定为耐荫指数，指数越小则越耐荫。中国南方453份大豆耐荫指数的变幅为1.11—2.61，平均1.55，材料个体间差异极显著，且遗传率较高（91.13%），说明表型选择具有较高的准确性。Ⅲ、Ⅳ、Ⅴ和Ⅵ生态区内耐荫指数变幅分别为1.19—2.08、1.17—2.61、1.27—2.37和1.11—2.54，均存在大量的耐荫性变异，各生态区均有耐荫性材料。地方品种和育成品种耐荫指数变幅分别为1.11—2.61和1.17—2.54，都存在较丰富的耐荫性变异，在筛选出的11份耐荫资源中，有8份是育成品种，说明大豆育种过程中耐荫性已得到改良。【结论】由30%遮光度，播种后50 d的株高和平均节间长构成的耐荫指数是相对准确、稳定、灵敏、实用的耐荫性评价体系。中国南方大豆耐荫性存在较为丰富的变异，从453份南方材料中筛选到11份耐荫性强的种质资源。

关键词: 大豆, 耐荫, 变异, 种质资源

Abstract: 【Objective】 Shade tolerance is an important factor that affects the yield of intercropped soybean, thus limiting the extension of intercropping patterns of soybean. It is necessary to establish an efficient, versatile and reliable shade tolerance identification system to be used in identifying the shade tolerant sources from germplasm populations, which can be used for shade tolerance breeding. 【Method】 Samples of 60 soybean varieties with different shade-tolerance levels were chosen from the germplasm storage in Guangxi Academy of Agricultural Sciences were used in this study. Firstly, the suitable shading treatment for shade tolerance evaluation was chosen among the three shading levels (i.e. 15%, 30% and 60%) according to a reasonable lodging rate of the tested varieties. Secondly, the suitable shade tolerance indicators were chosen from the 17 traits, including plant height, mean internode length, petiole length, shoot fresh weight and so forth. Then, the suitable measuring time was chosen among the three dates, i.e. on the 40th, 50th and 60th day after sowing according to the error coefficient of variation and phenotypic coefficient of variation of the selected shade tolerance indicator. Finally, the shade tolerance evaluation procedure was assembled to include the suitable shading level, shade tolerance indicator and measuring time. Using the designed procedure, the shade tolerance of 453 soybean varieties from southern China was evaluated, from which the tolerant sources were screened out. 【Result】 The 30% shading intension condition was better than other shading degrees. More specifically, there showed lower lodging rate of accessions (22%), higher phenotypic coefficient of variation (25%), and better distinction among accessions. The shade tolerance indicator which composed of the plant height and the average internode length is better than other indicators after comprehensive tradeoff, with advantages as follows: i) It is more accurate due to its smaller error coefficient of variation (9.36%) and higher heritability (95.43%); ii) It is more stable, as its correlation (0.92) between two environments is the largest; iii) It has a better distinction degree, because its phenotypic coefficient of variation (31.25%) and genotypic coefficient of variation (30.52%) are larger; iv) It is more consistent to the field shade tolerance situation with the highest correlation (0.73) between the indicator and visual shade tolerance level. Compared to other measuring times, the shade tolerance indicator on the 50th day after sowing is better, for example its correlation (0.87) between two environments is the highest and error coefficient of variation (7.75%) is the smallest. Therefore, the average of relative plant height and average length of internode was defined on the 50th day after sowing under 30% shading intension condition as the shade tolerance index (STI). The smaller STI, the more shade tolerance of the accession. The STI of 453 soybean varieties from southern China ranged from 1.11 to 2.61, with an average of 1.55 and there showed significant differences among the accessions. In addition, the heritability (91.13%) of these soybean varieties indicated that soybean shade tolerance had high accuracy from phenotypic selection. The STI in eco-region Ⅲ, Ⅳ ,Ⅴ and Ⅵ showed abundant variations with the range of 1.19-2.08, 1.17-2.61, 1.27-2.37, and 1.11-2.54, respectively, which provide materials for the improvement of shade tolerance. Furthermore, the released cultivars and landraces also have abundant variations with the range of 1.11-2.61 and 1.17-2.54, respectively. However, eight of the eleven accessions with high shade tolerance in two environments were released cultivars, which implies the achievement in shade tolerance breeding of soybeans. 【Conclusion】 The shade tolerance indicator which composed of plant height and average internode length on the 50th day after sowing was concluded to be accurate, stable, sensitive and authentic. Using this evaluation system, a number of shade tolerant soybean varieties were screened out from the southern China germplasm population.

Key words: soybean, shade tolerance, variation, germplasm

孙祖东，张志鹏，蔡昭艳，曾维英，赖振光，陈怀珠，杨守臻，唐向民，苏燕竹，盖钧镒. 大豆耐荫性评价体系的建立与中国南方大豆资源耐荫性变异[J]. 中国农业科学, 2017, 50(5): 792-801.

SUN ZuDong, ZHANG ZhiPeng, CAI ZhaoYan, ZENG WeiYing, LAI ZhenGuang, CHEN HuaiZhu, YANG ShouZhen, TANG XiangMin, SU YanZhu, GAI JunYi. Establishment of an Evaluation System of Shade Tolerance in Soybean and Its Variation in Southern China Germplasm Population[J]. Scientia Agricultura Sinica, 2017, 50(5): 792-801.

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大豆耐荫性评价体系的建立与中国南方大豆资源耐荫性变异

Establishment of an Evaluation System of Shade Tolerance in Soybean and Its Variation in Southern China Germplasm Population

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