红米水稻抗氧化活性成分的遗传效应与环境互作

doi:10.16819/j.1001-7216.2024.221206

中国水稻科学 ›› 2024, Vol. 38 ›› Issue (1): 25-32.DOI: 10.16819/j.1001-7216.2024.221206

红米水稻抗氧化活性成分的遗传效应与环境互作

程祖锌¹^,², 肖长春³, 张玉婷¹^,², 黄昕颖¹^,², 史夏蕾¹^,², 凌波¹^,², 王泓超¹^,², 陈小玲¹^,², 林荔辉¹^,²^,^*()

¹福建农林大学农学院/福建省特种作物育种与利用工程技术研究中心, 福州 350002
²福建农林大学农学院/作物遗传育种与综合利用教育部重点实验室, 福州 350002
³福建省（山区）作物遗传改良与创新利用重点实验室, 福建三明 365500

收稿日期:2022-12-14 修回日期:2023-05-30 出版日期:2024-01-10 发布日期:2024-01-16
通讯作者: * email: lihui9027@163.com
基金资助:
福建省高校产学合作项目(2022N5011);福建省(山区)作物遗传改良与创新利用重点实验室开放课题资助项目(2022SKF02);福建省科技计划引导性项目(2022N0005);福建农林大学2019年度乡村振兴服务团队资助项目(11899170122)

Genetic Effects of Antioxidant Components in Red Rice and Its Interactions with Environment

CHENG Zuxin¹^,², XIAO Changchun³, ZHANG Yuting¹^,², HUANG Xinying¹^,², SHI Xialei¹^,², LING Bo¹^,², WANG Hongchao¹^,², CHEN Xiaoling¹^,², LIN Lihui¹^,²^,^*()

¹Fujian Engineering Technology Research Center of Breeding and Utilization for Special Crops/College of Agriculture, Fujian Agriculture and Forestry University, Fuzhou 350002, China
²Key Laboratory of Ministry of Education for Genetics, Breeding and Multiple Utilization of Crops/College of Agriculture, Fujian Agriculture and Forestry University, Fuzhou 350002, China
³Fujian Key Laboratory of Crop Genetic Improvement and Innovative Utilization for Mountain Area, Sanming 365500, China

Received:2022-12-14 Revised:2023-05-30 Online:2024-01-10 Published:2024-01-16
Contact: * email: lihui9027@163.com

摘要/Abstract

摘要：

【目的】剖析红米水稻总酚、总黄酮、原花青素和花色苷的遗传效应，为高营养价值红米杂交稻的培育提供参考。【方法】以8个红米恢复系为父本，6个不育系为母本，配制48个杂交组合为遗传材料，利用加性-显性遗传模型(AD模型)及统计方法，分析在不同环境下红米水稻抗氧化活性成分的遗传效应、杂种优势、遗传相关及其与环境互作。【结果】花色苷、原花青素、总酚和总黄酮主要受遗传主效应控制，其中原花青素、总酚和总黄酮总狭义遗传率高，以基因加性效应为主，低代选择有效；花色苷以显性效应为主，适宜中、高世代选择。这4种抗氧化活性成分的表型、遗传、加性、显性、加性×环境互作和显性×环境互作均呈正向相关，相关系数大；原花青素的基因型×环境互作效应小，稳定性好，以此为选择指标可有效提高其他3种成分，减轻工作量，提高育种效率。高温有利红米水稻杂种后代抗氧化活性成分的积累，提高群体杂种优势。此外，提高不育系抗氧化活性成分含量，有利于培育高抗氧化活性成分含量的杂交后代；恢复系18Rr174、18Rr175可有效提高后代总酚、总黄酮、原花青素含量，且受环境影响小。【结论】采用植物数量性状的加性-显性遗传模型，可有效预测亲本抗氧化活性成分的遗传效应，18Rr174、18Rr175在高抗氧化活性成分红米杂交稻的选育上具有较高应用价值。

关键词: 红米水稻, 抗氧化成分, 遗传效应, 基因型×环境互作效应

Abstract:

【Objective】 This study aims to dissect the genetic effects of total phenols, total flavonoids, procyanidins, and anthocyanins in red rice, to offer insights for cultivating high-nutrition red hybrid rice. 【Methods】 Forty-eight hybrid combinations were generated using eight red rice restorer lines as male parents and six sterile lines as female parents. Employing the additive-dominance genetic model (AD model) and statistical methods, the study analyzed the genetic effects, heterosis, genetic correlation of antioxidant components in red rice across diverse environmental conditions, and their interactions with the environment. 【Results】 Genetic main effects primarily control anthocyanins, procyanidins, total phenols, and total flavonoids. Procyanidins, total phenols, and total flavonoids exhibit high narrow-sense heritability, mainly governed by gene additive effects, enabling effective early-generation selection. Anthocyanins are predominantly influenced by dominant effects, suitable for medium and high generation selection. All four antioxidant components display positive correlations among phenotype, genetics, additive and dominance effects, as well as additive × environment and dominance × environment interactions, with high correlation coefficients. Procyanidins exhibit a small genotype × environment interaction effect, indicating good stability. Using procyanidins as a selection indicator effectively enhances the other three components, reduces workload, and improves breeding efficiency. Higher temperatures contribute to increased accumulation of antioxidant components in red rice hybrid offspring, enhancing population heterosis. Elevating the content of antioxidant components in sterile lines benefits the cultivation of offspring with higher antioxidant content. Restorer lines 18Rr174 and 18Rr175 effectively increase the contents of total phenols, total flavonoids, and procyanidins in offspring and are less influenced by the environment. 【Conclusion】 Utilizing the additive-dominance genetic model for quantitative traits could effectively predict parental genetic effects on antioxidant components. 18Rr174 and 18Rr175 can be used to breed red rice with high antioxidant activity components.

Key words: red rice, antioxidant composition, genetic effect, genotype ×, environmental interaction effect

程祖锌, 肖长春, 张玉婷, 黄昕颖, 史夏蕾, 凌波, 王泓超, 陈小玲, 林荔辉. 红米水稻抗氧化活性成分的遗传效应与环境互作[J]. 中国水稻科学, 2024, 38(1): 25-32.

CHENG Zuxin, XIAO Changchun, ZHANG Yuting, HUANG Xinying, SHI Xialei, LING Bo, WANG Hongchao, CHEN Xiaoling, LIN Lihui. Genetic Effects of Antioxidant Components in Red Rice and Its Interactions with Environment[J]. Chinese Journal OF Rice Science, 2024, 38(1): 25-32.

图/表 6

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种植季节 Planting season	性状 Trait	变幅 Range	平均值 Mean	标准差 SD	变异系数 CV/%
中稻 Middle season	总酚含量Total phenols/(g·kg⁻¹)	2.36~5.56	3.23	0.53	16.44
	总黄酮含量Total flavonoids/(g·kg⁻¹)	1.34~3.21	1.98	0.39	20.06
	原花青素含量Procyanidins/(g·kg⁻¹)	0.96~2.62	1.44	0.30	20.85
	花色苷含量Anthocyanins/(U·g⁻¹)	2.71~5.30	3.75	0.60	16.03
晚季 Late season	总酚含量Total phenols/(g·kg⁻¹)	0.98~3.81	2.27	0.63	27.71
	总黄酮含量Total flavonoids/(g·kg⁻¹)	0.57~2.13	1.08	0.32	29.31
	原花青素含量Procyanidins/(g·kg⁻¹)	0.24~1.59	0.81	0.31	38.05
	花色苷含量Anthocyanins/(U·g⁻¹)	1.88~3.56	2.58	0.33	12.68

种植季节 Planting season	性状 Trait	变幅 Range	平均值 Mean	标准差 SD	变异系数 CV/%
中稻 Middle season	总酚含量Total phenols/(g·kg⁻¹)	2.36~5.56	3.23	0.53	16.44
	总黄酮含量Total flavonoids/(g·kg⁻¹)	1.34~3.21	1.98	0.39	20.06
	原花青素含量Procyanidins/(g·kg⁻¹)	0.96~2.62	1.44	0.30	20.85
	花色苷含量Anthocyanins/(U·g⁻¹)	2.71~5.30	3.75	0.60	16.03
晚季 Late season	总酚含量Total phenols/(g·kg⁻¹)	0.98~3.81	2.27	0.63	27.71
	总黄酮含量Total flavonoids/(g·kg⁻¹)	0.57~2.13	1.08	0.32	29.31
	原花青素含量Procyanidins/(g·kg⁻¹)	0.24~1.59	0.81	0.31	38.05
	花色苷含量Anthocyanins/(U·g⁻¹)	1.88~3.56	2.58	0.33	12.68

参数 Parameter	总酚 Total phenols	总黄酮 Total flavonoids	原花青素 Procyanidins	花色苷 Anthocyanins
加性方差V_A	3615.82**	1136.360**	1042.660**	0.331**
显性方差V_D	1627.27**	426.295**	430.593**	0.383**
加性×环境互作方差V_AE	332.866**	259.891**	37.015**	0.133**
显性×环境互作方差V_DE	1901.300**	686.902**	499.270**	0.144**
剩余方差Ve	34.064*	19.048*	16.236⁺	0.001*
表型方差V_P	7511.320**	2528.490**	2025.770**	0.992**
普通狭义遗传率H²_N	0.4813**	0.4494**	0.5147**	0.3341**
互作狭义遗传率H²_NE	0.0443**	0.1027**	0.0183**	0.1337**

参数 Parameter	总酚 Total phenols	总黄酮 Total flavonoids	原花青素 Procyanidins	花色苷 Anthocyanins
加性方差V_A	3615.82**	1136.360**	1042.660**	0.331**
显性方差V_D	1627.27**	426.295**	430.593**	0.383**
加性×环境互作方差V_AE	332.866**	259.891**	37.015**	0.133**
显性×环境互作方差V_DE	1901.300**	686.902**	499.270**	0.144**
剩余方差Ve	34.064*	19.048*	16.236⁺	0.001*
表型方差V_P	7511.320**	2528.490**	2025.770**	0.992**
普通狭义遗传率H²_N	0.4813**	0.4494**	0.5147**	0.3341**
互作狭义遗传率H²_NE	0.0443**	0.1027**	0.0183**	0.1337**

性状Trait	A₁	A₂	A₃	A₄	A₅	A₆	R₁	R₂	R₃	R₄	R₅	R₆	R₇	R₈
总酚 Total phenols
AE	−12.223**	−12.751**	−47.137**	−24.149**	−74.921**	−71.062**	30.514**	64.783**	45.099**	38.880**	20.360**	11.929**	12.088**	18.575**
DE	−13.256*	−49.771**	−106.710**	−150.011**	−65.114**	−61.668**	8.361*	−62.213**	−8.860 **	−16.516**	−40.500**	−25.527**	−40.278**	−27.718**
AEE1	−2.863**	−12.704**	−16.556**	12.623**	−5.621**	−17.764**	10.888**	12.301**	0.509	23.071**	6.712**	−0.596	−4.545**	19.791**
AEE2	−2.894**	6.698**	−5.645**	1.249*	−29.667**	−15.705**	3.484**	18.211**	20.732**	−4.756**	2.882*	6.215**	10.238**	−11.043**
DEE1	28.073**	−38.691**	−78.770**	−102.736**	−129.319**	−77.881**	−35.867**	−69.401**	−2.646	−9.626*	−22.850*	−11.41	−65.362**	−15.136**
DEE2	−43.967**	−20.982**	−49.170**	−77.120**	51.251**	3.944**	45.892**	−5.189	7.977*	−10.175*	−25.698**	−19.195**	17.070**	−18.097**
总黄酮Total flavonoids
AE	−5.755**	−1.522**	−23.404**	−10.766**	−37.700**	−39.012**	24.535**	48.086**	23.501**	12.113**	2.884**	−2.353**	−1.332	10.726**
DE	−0.537	−9.562**	−55.269**	−75.530**	−29.001**	−28.920**	5.210*	−27.794**	−8.584**	3.210*	−17.930**	−13.941**	−23.709**	−6.223**
AEE1	−5.191**	−8.394**	−15.724**	−13.885**	−14.144**	−23.695**	14.919**	21.075**	15.925**	16.253**	−3.551**	0.587*	−3.976**	19.801**
AEE2	1.423**	7.397**	0.403	6.838**	−10.535**	−1.844*	1.143	10.404**	−0.541⁺	−8.324**	5.439**	−2.127**	3.104**	−12.779**
DEE1	−15.194**	−33.328**	−70.638**	−72.226**	−68.362**	−42.277**	−11.690**	−29.124**	−26.555**	11.238 **	−17.982**	−31.794**	−42.331**	−3.670*
DEE2	14.489**	20.764**	−1.983	−27.017*	30.256**	4.277⁺	18.536**	−7.396	15.276**	−7.020**	−5.577⁺	13.476**	11.178**	−4.507
原花青素Procyanidins
AE	−9.522**	−6.799**	−24.564**	−10.681**	−38.126**	−37.935**	18.440**	37.269**	28.156**	15.717**	13.103**	3.127**	8.153**	3.662**
DE	−9.739**	−21.556**	−54.262**	−77.806**	−30.605**	−31.484**	7.326**	−31.482**	−16.737**	−5.056**	−20.910**	−7.699**	−21.825**	−8.278**
AEE1	−1.949**	−3.555**	−6.856**	−4.542**	−3.004**	−8.140**	3.330**	5.507**	3.062**	5.848**	1.453**	0.782**	1.860**	6.215**
AEE2	−1.034*	1.425*	−0.839*	1.196**	−8.939**	−3.735**	2.447**	6.169**	5.759**	−0.924*	2.651**	0.197	0.695	−5.067**
DEE1	2.254*	−17.841**	−51.733**	−66.410**	−68.983**	−42.786**	−8.472**	−35.069**	−24.059**	−5.884**	−6.326⁺	−14.572**	−45.560**	−4.147*
DEE2	−13.907**	−7.948*	−13.186*	26.676**	32.367**	5.119**	17.237**	−2.596	4.035*	−0.165	−18.690**	5.361**	19.449**	−5.757*
花色苷Anthocyanins
AE	0.146**	0.126**	−0.570**	−0.414**	−0.680**	−0.631**	0.272**	0.403**	0.266**	0.428**	0.378**	0.139**	0.073**	0.318**
DE	0.702**	0.499**	−1.849**	−2.200**	−1.603**	−1.735**	−0.278**	−0.647**	−0.169**	−0.375**	−0.507**	−0.555**	−0.217**	−0.602**
AEE1	0.182**	−0.159**	−0.380**	−0.311**	−0.318**	−0.413**	0.061**	0.155**	−0.208**	0.443**	0.456**	0.185**	0.164**	0.473**
AEE2	−0.061**	0.055**	−0.091**	−0.032**	−0.244**	−0.110**	0.164**	0.179**	0.428**	−0.089**	−0.143**	−0.070**	0.225**	−0.211**
DEE1	0.505**	0.056	−1.138**	−1.309**	−1.244**	−1.076**	−0.314**	−0.482**	0.208**	−0.211**	−0.360**	−0.583**	−0.032	−0.595**
DEE2	0.107	0.380**	−0.473**	−0.608**	−0.153	−0.436**	0.072**	−0.082	−0.355**	−0.116*	−0.082	0.100**	−0.157**	0.071**

红米水稻抗氧化活性成分的遗传效应与环境互作

Genetic Effects of Antioxidant Components in Red Rice and Its Interactions with Environment

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Metrics

性状 Trait	表现型值 Phenotypic value		基因型值Genotypic value			群体杂种优势Population heterosis			群体超亲优势Over-parent heterosis
性状 Trait	表现型值 Phenotypic value		GE	GEE1	GEE2	GE	GEE1	GEE2	GE	GEE1	GEE2
总酚TP		269.570	273.221	10.320⁺	1.406	0.238**	0.226**	0.060⁺	−0.112**	0.060	−0.036
总黄酮TF		150.982	152.071	6.081⁺	−1.404	0.187**	0.292**	0.037	−0.120**	0.028	−0.112**
原花青素PR		109.685	111.244	6.947⁺	−0.385	0.294**	0.343**	0.025	−0.157**	0.143*	−0.077⁺
花色苷AN		3.034	3.138	0.079	0.016	0.304**	0.209**	0.056^*	−0.070**	−0.037	−0.043*

性状Trait	参数Parameter	总酚TP	总黄酮TF	原花青素PR
总黄酮TF	加性AE	1.000⁺
	显性DE	0.988⁺
	表型PE	0.889⁺
	遗传GE	0.894⁺
	加性×环境互作AEE	0.496
	显性×环境互作DEE	0.692
原花青素PR	加性AE	1.000⁺	0.993⁺
	显性DE	0.996⁺	1.000⁺
	表型PE	0.962⁺	0.932⁺
	遗传GE	0.968⁺	0.939⁺
	加性×环境互作AEE	0.861	0.794⁺
	显性×环境互作DEE	0.900	0.877
花色苷AN	加性AE	1.000⁺	0.957⁺	0.978⁺
	显性DE	0.851⁺	0.940⁺	0.845⁺
	表型PE	0.842⁺	0.769⁺	0.808⁺
	遗传GE	0.844⁺	0.772⁺	0.812⁺
	加性×环境互作AEE	0.847	0.429	0.901⁺
	显性×环境互作DEE	0.652	0.542	0.613

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