盐胁迫对水稻籽粒灌浆特性及产量形成的影响

doi:10.3724/SP.J.1006.2024.32021

作物学报 ›› 2024, Vol. 50 ›› Issue (3): 734-746.doi: 10.3724/SP.J.1006.2024.32021

盐胁迫对水稻籽粒灌浆特性及产量形成的影响

韦还和¹(), 张翔¹, 朱旺², 耿孝宇¹, 马唯一¹, 左博源¹, 孟天瑶², 高平磊¹, 陈英龙¹, 许轲¹, 戴其根¹^,^*()

¹江苏省作物遗传生理重点实验室 / 江苏省作物栽培生理重点实验室 / 江苏省粮食作物现代产业技术协同创新中心 / 扬州大学水稻产业工程技术研究院 / 农业农村部盐碱土改良与利用(滨海盐碱地)重点实验室 / 国家耐盐碱水稻技术创新中心华东中心, 扬州大学, 江苏扬州 225009
²扬州大学教育部农业与农产品安全国际合作联合实验室 / 扬州大学农业科技发展研究院, 扬州大学 225009

收稿日期:2023-05-23 接受日期:2023-09-13 出版日期:2024-03-12 网络出版日期:2023-10-07
通讯作者: *戴其根, E-mail: qgdai@yzu.edu.cn
作者简介:E-mail: hhwei@yzu.edu.cn
基金资助:
国家重点研发计划项目(2022YFE0113400);国家重点研发计划项目(2022YFD1500402);国家自然科学基金项目(32001466);江苏省农业科技自主创新资金项目(CX(23)1020);江苏省高等学校基础科学(自然科学)研究重大项目(23KJA210004);中国博士后科学基金项目(2020M671628);江苏省碳达峰碳中和科技创新专项资金(BE2022304);江苏省碳达峰碳中和科技创新专项资金(BE2022305);江苏省高校优势学科建设工程项目(PAPD)

Effects of salinity stress on grain-filling characteristics and yield of rice

WEI Huan-He¹(), ZHANG Xiang¹, ZHU Wang², GENG Xiao-Yu¹, MA Wei-Yi¹, ZUO Bo-Yuan¹, MENG Tian-Yao², GAO Ping-Lei¹, CHEN Ying-Long¹, XU Ke¹, DAI Qi-Gen¹^,^*()

¹Jiangsu Key Laboratory of Crop Genetics and Physiology / Jiangsu Key Laboratory of Crop Cultivation and Physiology Jiangsu / Co-Innovation Center for Modern Production Technology of Grain Crops / Research Institute of Rice Industrial Engineering Technology / Key Laboratory of Saline-Alkali Soil Reclamation and Utilization in Coastal Areas, the Ministry of Agriculture and Rural Affairs of China / East China Branch of National Center of Technology Innovation for Saline-Alkali Tolerant Rice, Yangzhou University, Yangzhou 225009, Jiangsu, China
²Joint International Research Laboratory of Agri-culture and Agro-product Safety, Ministry of Education / Institute of Agricultural Science and Technological Development, Yangzhou University, Yangzhou 225009, Jiangsu, China

Received:2023-05-23 Accepted:2023-09-13 Published:2024-03-12 Published online:2023-10-07
Contact: *E-mail: qgdai@yzu.edu.cn
Supported by:
National Key Research and Development Program of China(2022YFE0113400);National Key Research and Development Program of China(2022YFD1500402);National Natural Science Foundation of China(32001466);Jiangsu Agricultural Science and Technology Innovation Fund(CX(23)1020);Natural Science Foundation of the Jiangsu Higher Education Institutions of China(23KJA210004);China Postdoctoral Science Foundation(2020M671628);Scientific and Technological Innovation Fund of Carbon Emissions Peak and Neutrality of Jiangsu Provincial Department of Science and Technology(BE2022304);Scientific and Technological Innovation Fund of Carbon Emissions Peak and Neutrality of Jiangsu Provincial Department of Science and Technology(BE2022305);Priority Academic Program Development PAPD of Jiangsu Higher Education Institutions

摘要/Abstract

摘要：

以江苏沿海滩涂主栽常规粳稻南粳9108和淮稻5号为试材, 研究不同盐胁迫处理包括对照(CK, 盐浓度0)、中盐(medium-salinity stress, MS, 盐浓度0.15%)和高盐(high-salinity stress, HS, 盐浓度0.3%)对水稻籽粒灌浆及产量形成生理特性的影响。结果表明: (1) 与对照相比, 中盐和高盐胁迫均显著降低水稻产量, 降幅分别为26.3%和57.7% (两品种平均); 盐胁迫处理下, 穗数、每穗粒数、结实率和千粒重均显著下降。(2) 盐胁迫显著降低穗长、每穗强势粒和弱势粒籽粒数、结实率和千粒重, 其中强势粒结实率和千粒重的降幅均低于弱势粒。(3) 盐胁迫下, 水稻植株抽穗期和成熟期干物重以及抽穗期至成熟期干物质积累量显著下降, 但收获指数明显增加。此外, 抽穗后15 d和30 d盐胁迫处理的叶片净光合速率和SPAD值均显著低于对照。(4) 盐胁迫降低籽粒最大灌浆速率和平均灌浆速率, 但达最大灌浆速率时间和有效灌浆天数有所增加; 盐胁迫提高了强势粒和弱势粒有效灌浆天数, 但平均灌浆速率显著下降, 其中强势粒灌浆量的降幅低于弱势粒。(5) 盐胁迫下, 籽粒腺苷二磷酸焦磷酸化酶(AGPase)、淀粉合成酶(SSS)、颗粒型淀粉合成酶(GBSS)和淀粉分支酶(SBE)活性显著下降, 其中弱势粒的降幅高于强势粒。综上所述, 盐胁迫下水稻强势粒和弱势粒灌浆天数有所增加, 但籽粒灌浆速率及其淀粉合成关键酶活性显著下降, 致使籽粒充实度、粒重和产量显著下降, 其中盐胁迫对弱势粒抑制作用大于强势粒。

关键词: 盐胁迫, 水稻, 籽粒灌浆, 产量

Abstract:

To investigate the effect of salinity stress on grain-filling and yield of rice, the conventional japonica rice Nanjing 9108 and Huaidao 5 which were widely planted in saline alkali soil of Jiangsu province were used as the experimental materials. The treatments including the control (CK, 0 salt concentration), medium-salinity (medium-salinity, MS, 0.15% salt concentration), and high salt (high salinity, 0.3% salt concentration) were set. The results showed that, compared with the CK: (1) MS and HS both significantly reduced rice grain yield by 26.3% and 57.7% (average of the two cultivars), respectively. The number of panicles, spikelets per panicle, filled-grain percentage, and 1000-grain weight were all significantly decreased under salinity stress. (2) Salinity stress significantly reduced rice panicle length, the number of superior and inferior grains per panicle, filled-grain percentage, and 1000-grain weight. The decreases in filled-grain percentage and 1000-grain weight of superior grains per panicle under salinity stress were lower than those of inferior grains. (3) Salinity stress significantly reduced the dry matter weight of plants at heading and maturity stages, and the dry matter accumulation from heading to maturity, while increased the harvest index. The net photosynthetic rate and SPAD value at 15 and 30 days after heading of rice leaves under salinity stress were significantly lower than CK. (4) Salinity stress reduced the maximum and mean grain-filling rates of grains during grain-filling period, while the time to achieve the maximum grain-filling rate and effective grain-filling duration of grains increased. Salinity stress increased the days at the first, middle, and late stages during grain-filling period for superior and inferior grains, while the mean grain-filling rate and grain filling amount significantly decreased at the first, middle, and late stages during grain-filling period. The decrease in grain filling amount of superior grains at the first, middle, and late stages during grain-filling period was lower than that of inferior grains. (5) Salinity stress significantly decreased activities of ADP-glucose pyrophosphorylase (AGPase), starch synthases (SSS), granule-bound starch synthase (GBSS), and starch branching enzymes (SBE), and the decrease was greater in inferior grains than superior grains. In conclusion, the grain-filling days for superior and inferior grains increased under salinity stress, but the decrease in grain filling rate and activities of key enzymes involved in starch synthesis was greater, resulting in a significant deterioration in grain filling traits and a significant decrease in grain weight and yield. The inhibitory effects of salinity stress on grain-filling rate and grain filling amount of inferior grains were higher than those of superior grains.

Key words: salinity stress, rice, grain-filling, grain yield

韦还和, 张翔, 朱旺, 耿孝宇, 马唯一, 左博源, 孟天瑶, 高平磊, 陈英龙, 许轲, 戴其根. 盐胁迫对水稻籽粒灌浆特性及产量形成的影响[J]. 作物学报, 2024, 50(3): 734-746.

WEI Huan-He, ZHANG Xiang, ZHU Wang, GENG Xiao-Yu, MA Wei-Yi, ZUO Bo-Yuan, MENG Tian-Yao, GAO Ping-Lei, CHEN Ying-Long, XU Ke, DAI Qi-Gen. Effects of salinity stress on grain-filling characteristics and yield of rice[J]. Acta Agronomica Sinica, 2024, 50(3): 734-746.

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年份 Year	品种 Cultivar	处理 Treatment	穗数 Number of panicles (×10⁴ hm^-2)	每穗粒数 Spikelets per panicle	结实率 Percentage of filled grains (%)	千粒重 1000-grain weight (g)	实产 Actual yield (t hm^-2)	抽穗期至成熟期天数 Duration from heading to maturity (d)
2021	南粳9108 Nanjing 9108	对照 CK	347 a	139.1 a	88.9 a	24.3 a	9.69 a	54
		中盐 MS	327 b	120.4 b	86.2 b	23.6 ab	7.38 b	53
		高盐 HS	271 c	87.6 c	83.1 c	21.6 b	4.02 c	52
	淮稻5号 Huaidao 5	对照 CK	371 a	126.2 a	89.7 a	25.4 a	9.48 a	55
		中盐 MS	355 b	100.7 b	88.1 ab	24.8 ab	7.19 b	53
		高盐 HS	288 c	82.8 c	82.7 b	22.7 b	4.10 c	51
2022	南粳9108 Nanjing 9108	对照 CK	357 a	133.7 a	89.9 a	24.7 a	9.95 a	55
		中盐 MS	317 b	114.4 b	87.4 b	23.2 b	7.10 b	54
		高盐 HS	287 c	97.0 c	82.3 c	22.0 c	4.34 c	52
	淮稻5号 Huaidao 5	对照 CK	365 a	122.0 a	90.7 a	25.8 a	9.66 a	54
		中盐 MS	347 ab	106.3 b	87.1 b	24.2 b	6.97 b	53
		高盐 HS	304 b	74.4 c	83.5 c	23.1 c	3.97 c	52
显著性分析 P-value
年份 Year (Y)			NS	NS	NS	NS	NS	−
品种 Cultivar (C)			*	*	NS	**	**	−
处理 Treatment (T)			**	**	**	**	**	−
年份品种 Y × C			NS	NS	NS	NS	NS	−
年份处理 Y × T			NS	NS	NS	NS	NS	−
品种处理 C × T			*	NS	NS	*	**	−
年份品种处理 Y × C × T			NS	NS	NS	NS	NS	−

品种 Cultivar	处理 Treatment	穗长 Panicle length (cm)	强势粒 Superior grains			弱势粒 Inferior grains
品种 Cultivar	处理 Treatment	穗长 Panicle length (cm)	籽粒数 Number of grains	结实率 Percentage of filled grains (%)	千粒重 1000-grain weight (g)	籽粒数 Number of grains	结实率 Percentage of filled grains (%)	千粒重 1000-grain weight (g)
南粳9108 Nanjing 9108	对照 CK	13.6 a	15.1 a	93.7 a	26.4 a	29.0 a	84.5 a	22.9 a
南粳9108 Nanjing 9108	中盐 MS	12.3 b	12.5 b	90.8 b	25.0 b	24.6 b	81.7 b	21.1 b
	高盐 HS	11.9 b	11.5 c	87.3 c	23.9 c	16.7 c	77.9 c	20.1 c
淮稻5号 Huaidao 5	对照 CK	12.9 a	14.2 a	94.2 a	27.8 a	26.5 a	83.8 a	23.8 a
	中盐 MS	11.7 b	11.6 b	92.1 ab	26.5 b	20.9 b	81.3 ab	22.2 b
	高盐 HS	11.3 b	10.9 c	88.5 b	24.9 c	13.7 c	76.7 b	20.5 c

品种 Cultivar	处理 Treatment	干物重 Dry matter weight (t hm^-2)			干物重积累量 Dry matter accumulation (t hm^-2)		收获指数 Harvest index
		拔节期	抽穗期	成熟期	拔节期-抽穗期	抽穗期-成熟期
		Jointing	Heading	Maturity	Jointing to heading	Heading to maturity
南粳9108	对照 CK	4.7 a	10.8 a	17.1 a	6.05 a	6.37 a	0.495 c
Nanjing 9108	中盐 MS	3.2 b	7.9 b	12.0 b	4.65 b	4.19 b	0.517 b
	高盐 HS	2.4 c	4.6 c	6.8 c	2.17 c	2.23 c	0.534 a
淮稻5号	对照 CK	4.5 a	10.5 a	16.6 a	5.95 a	6.19 a	0.499 c
Huaidao 5	中盐 MS	3.3 b	7.7 b	11.8 b	4.39 b	4.10 b	0.521 b
	高盐 HS	2.1 c	4.3 c	6.4 c	2.20 c	2.10 c	0.541 a

品种 Cultivar	处理 Treatment	净光合速率Leaf net photosynthetic rate (µmol m^-2 s^-1)		相对叶绿素含量SPAD values
品种 Cultivar	处理 Treatment	抽穗后15 d 15 days after heading	抽穗后30 d 30 days after heading	抽穗后15 d 15 days after heading	抽穗后30 d 30 days after heading
南粳9108 Nanjing 9108	对照 CK	23.4 a	17.7 a	44.2 a	36.5 a
南粳9108 Nanjing 9108	中盐 MS	21.8 ab	16.6 b	41.6 b	33.4 b
	高盐 HS	19.2 b	14.2 c	35.6 c	28.6 c
淮稻5号 Huaidao 5	对照 CK	22.8 a	16.8 a	43.6 a	35.1 a
淮稻5号 Huaidao 5	中盐 MS	21.1 b	15.7 b	40.5 b	32.4 b
	高盐 HS	18.7 c	13.4 c	34.5 c	26.7 c

品种 Cultivar	处理 Treatment	粒位 Grain position	方程参数 Parameter				方程拟合 Simulated equation
品种 Cultivar	处理 Treatment	粒位 Grain position	A	B	K	N	方程拟合 Simulated equation
南粳9108 Nanjing 9108	对照 CK	强势粒 SG	21.97	7222.25	0.4987	4.5520	$Y=21.97{{\left( 1+7222.25{{\text{e}}^{-0.4987X}} \right)}^{-\ \frac{1}{4.5520}}}$	R²=0.976
		弱势粒 IG	18.47	10,231.27	0.2951	3.7955	$Y=18.47{{\left( 1+10231.27{{\text{e}}^{-0.2951X}} \right)}^{-\ \frac{1}{3.7955}}}$	R²=0.985
	中盐 MS	强势粒 SG	20.86	4853.81	0.4083	3.5638	$Y=20.86{{\left( 1+4853.81{{\text{e}}^{-0.4083X}} \right)}^{-\ \frac{1}{3.5638}}}$	R²=0.985
		弱势粒 IG	17.42	8217.82	0.2699	3.3456	$Y=17.42{{\left( 1+8217.82{{\text{e}}^{-0.2699X}} \right)}^{-\ \frac{1}{3.3456}}}$	R²=0.987
	高盐 HS	强势粒 SG	19.70	4417.23	0.3846	3.1275	$Y=19.70{{\left( 1+4417.23{{\text{e}}^{-0.3846X}} \right)}^{-\ \frac{1}{3.1275}}}$	R²=0.988
		弱势粒 IG	16.53	11,967.81	0.2696	3.2366	$Y=16.53{{\left( 1+11967.81{{\text{e}}^{-0.2696X}} \right)}^{-\ \frac{1}{3.2366}}}$	R²=0.986
淮稻5号 Huaidao 5	对照 CK	强势粒 SG	23.01	7682.64	0.4864	4.5317	$Y=23.01{{\left( 1+7682.64{{\text{e}}^{-0.4864X}} \right)}^{-\ \frac{1}{4.5317}}}$	R²=0.988
		弱势粒 IG	19.24	11,824.47	0.2907	3.9182	$Y=19.24{{\left( 1+11824.47{{\text{e}}^{-0.2907X}} \right)}^{-\ \frac{1}{3.9182}}}$	R²=0.978
	中盐 MS	强势粒 SG	21.65	4853.82	0.4021	3.4138	$Y=21.65{{\left( 1+4853.82{{\text{e}}^{-0.4021X}} \right)}^{-\ \frac{1}{3.4138}}}$	R²=0.983
		弱势粒 IG	18.44	11,416.20	0.2736	3.6728	$Y=18.44{{\left( 1+11416.20{{\text{e}}^{-0.2736X}} \right)}^{-\ \frac{1}{3.6728}}}$	R²=0.989
	高盐 HS	强势粒 SG	20.22	4417.29	0.3847	3.1275	$Y=20.22{{\left( 1+4417.29{{\text{e}}^{-0.3847X}} \right)}^{-\ \frac{1}{3.1275}}}$	R²=0.990
		弱势粒 IG	16.71	11,967.81	0.2662	3.2366	$Y=16.71{{\left( 1+11967.81{{\text{e}}^{-0.2662X}} \right)}^{-\ \frac{1}{3.2366}}}$	R²=0.986

盐胁迫对水稻籽粒灌浆特性及产量形成的影响

Effects of salinity stress on grain-filling characteristics and yield of rice

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品种 Cultivar	处理 Treatment	粒位 Grain position	前期 Early stage			中期 Middle stage			后期 Late stage
品种 Cultivar	处理 Treatment	粒位 Grain position	天数 Days (d)	平均灌浆速率MGR (mg grain^-1 d^-1)	灌浆量 GFA (mg)	天数 Days (d)	平均灌浆速率 MGR (mg grain^-1 d^-1)	灌浆量 GFA (mg)	天数 Days (d)	平均灌浆速率 MGR (mg grain^-1 d^-1)	灌浆量 GFA (mg)
南粳9108 Nanjing 9108	对照 CK	强势粒 SG	10.8	0.94	152.1	8.0	1.21	146.5	5.2	0.38	29.8
		弱势粒 IG	20.4	0.38	226.5	12.8	0.67	249.0	9.1	0.21	54.8
	中盐 MS	强势粒 SG	13.1	0.65	107.1	9.1	1.08	123.2	6.7	0.33	27.8
		弱势粒 IG	22.2	0.31	170.9	13.5	0.62	205.8	10.2	0.19	47.7
	高盐 HS	强势粒 SG	14.2	0.53	87.4	9.3	1.04	110.5	7.3	0.31	26.3
		弱势粒 IG	23.8	0.27	108.3	13.4	0.60	133.6	10.3	0.18	31.4
淮稻5号 Huaidao 5	对照 CK	强势粒 SG	11.2	0.94	149.6	8.2	1.24	144.5	5.3	0.39	29.4
		弱势粒 IG	21.0	0.39	218.8	13.2	0.67	235.0	9.2	0.21	51.0
	中盐 MS	强势粒 SG	13.5	0.65	101.1	9.1	1.13	120.0	6.8	0.35	27.6
		弱势粒 IG	22.5	0.34	160.5	13.7	0.63	180.7	9.9	0.19	40.3
	高盐 HS	强势粒 SG	14.2	0.55	85.0	9.3	1.06	107.5	7.3	0.32	25.6
		弱势粒 IG	24.1	0.27	89.8	13.6	0.60	110.8	10.4	0.18	26.0

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品种 Cultivar	处理 Treatment	粒位 Grain position	AGPase酶活性 AGPase activity (mol min^-1 mg^-1)			GBSS酶活性 GBSS activity (mol min^-1 mg^-1)			SSS酶活性 SSS activity (mol min^-1 mg^-1)			SBE酶活性 SBE activity (U g^-1)
品种 Cultivar	处理 Treatment	粒位 Grain position	15 DAH	30 DAH	45 DAH	15 DAH	30 DAH	45 DAH	15 DAH	30 DAH	45 DAH	15 DAH	30 DAH	45 DAH
南粳9108 Nanjing 9108	对照 CK	强势粒 SG	15.8 a	43.8 a	14.1 a	6.4 a	16.8 a	4.5 a	3.7 a	6.1 a	2.7 a	4.2 a	6.8 a	3.2 a
		弱势粒 IG	11.8 b	37.4 b	7.6 bc	5.6 b	14.8 b	3.3 b	3.2 b	4.8 b	1.9 b	3.8 b	5.8 b	2.7 b
	中盐 MS	强势粒 SG	10.3 c	28.7 c	8.6 b	5.1 c	13.2 c	3.2 b	2.9 b	4.8 b	2.1 b	3.2 c	5.2 c	2.6 b
		弱势粒 IG	7.3 d	23.9 d	4.3 d	3.9 d	10.3 d	2.0 cd	2.3 c	3.6 c	1.3 c	2.8 d	4.3 d	2.1 c
	高盐 HS	强势粒 SG	6.3 d	23.7 d	6.2 c	3.4 e	10.9 d	2.3 c	1.9 d	3.7 c	1.2 c	1.9 e	3.8 e	1.7 d
		弱势粒 IG	4.3 e	19.3 e	3.0 d	2.2 f	8.8 e	1.4 d	1.2 e	2.9 d	0.7 d	1.3 f	2.7 f	1.1 e
淮稻5号 Huaidao 5	对照 CK	强势粒 SG	15.7 a	42.7 a	13.5 a	6.8 a	17.0 a	4.7 a	3.6 a	5.9 a	2.9 a	4.4 a	6.6 a	3.1 a
		弱势粒 IG	12.8 b	36.5 b	7.3 b	5.5 b	15.1 b	3.4 bc	3.1 b	5.0 b	1.6 c	3.5 b	5.7 b	2.8 b
	中盐 MS	强势粒 SG	10.7 c	29.8 c	7.9 b	5.6 b	13.8 c	3.8 b	2.7 c	4.9 b	2.0 b	3.6 b	5.4 b	2.4 c
		弱势粒 IG	8.0 d	24.5 d	3.9 d	4.0 c	11.1 d	2.4 c	2.2 d	3.7 c	1.0 d	2.6 c	4.6 c	1.8 d
	高盐 HS	强势粒 SG	6.1 e	23.7 d	6.4 c	3.7 c	10.3 d	2.1 c	2.1 d	3.2 d	1.5 c	1.8 d	4.0 d	1.8 d
		弱势粒 IG	4.6 f	18.9 e	3.1 d	2.0 d	7.8 e	1.3 d	1.3 e	2.0 e	0.6 e	1.2 e	2.5 e	1.2 e