再生季稻与同期抽穗主季稻干物质分配特性及机制研究

doi:10.3724/SP.J.1006.2023.22016

作物学报 ›› 2023, Vol. 49 ›› Issue (3): 755-771.doi: 10.3724/SP.J.1006.2023.22016

再生季稻与同期抽穗主季稻干物质分配特性及机制研究

吴冬青¹(), 李洲², 郭春林³, 邹京南¹, 庞孜钦³, 林非凡¹, 何海斌¹, 林文雄¹^,³^,^*()

¹福建农林大学生命科学学院 / 农业生态过程与安全监测福建省重点实验室, 福建福州 350002
²福建省农业科学院亚热带农业研究所, 福建漳州 363005
³福建农林大学作物遗传育种与综合利用教育部重点实验室, 福建福州 350002

收稿日期:2022-03-18 接受日期:2022-07-21 出版日期:2023-03-12 网络出版日期:2022-08-24
通讯作者: 林文雄
作者简介:E-mail: wudq606@163.com
基金资助:
国家重点研发计划项目(2016YFD0300508);国家重点研发计划项目(2017YFD0301602);国家重点研发计划项目(2018YFD0301105);闽台种植资源创制与绿色栽培协调创新中心项目(福建2011项目);闽台种植资源创制与绿色栽培协调创新中心项目(2015-75);福建农林大学科技发展基金项目(KF2015043)

Dry matter partitioning properties and mechanism of ratooning rice and main crop (late season) synchronized in rice heading time

WU Dong-Qing¹(), LI Zhou², GUO Chun-Lin³, ZOU Jing-Nan¹, PANG Zi-Qin³, LIN Fei-Fan¹, HE Hai-Bin¹, LIN Wen-Xiong¹^,³^,^*()

¹College of Life Sciences, Fujian Agriculture and Forestry University / Fujian Province Key Laboratory of Agro-Ecological Process and Safety Monitoring, Fuzhou 350002, Fujian, China
²Subtropical Agriculture Research Institute, Fujian Academy of Agricultural Sciences, Zhangzhou 363005, Fujian, China
³Key Laboratory of Crop Genetics and Integrated Utilization, Ministry of Education, Fujian Agriculture and Forestry University, Fuzhou 350002, Fujian, China

Received:2022-03-18 Accepted:2022-07-21 Published:2023-03-12 Published online:2022-08-24
Contact: LIN Wen-Xiong
Supported by:
National Key Research and Development Program of China(2016YFD0300508);National Key Research and Development Program of China(2017YFD0301602);National Key Research and Development Program of China(2018YFD0301105);Fujian-Taiwan Coordination Innovation Center for Plant Germplasm Creation and Green Cultivation(Fujian 2011 Project);Fujian-Taiwan Coordination Innovation Center for Plant Germplasm Creation and Green Cultivation(2015-75);Fujian Agriculture and Forestry University Science and Technology Development Fund Project(KF2015043)

摘要/Abstract

摘要：

研究再生稻干物质积累与转运特性对深入理解再生稻产量形成的生理机制及进一步挖掘增产潜力有重要的理论与实际意义。本研究以华东南稻区推广的常规籼稻佳辐占和籼粳杂交稻甬优2640两个再生稻品种作为供试材料, 在确保2个供试水稻品种的再生季稻和主季稻在籽粒灌浆阶段处于同一晚秋气温条件下抽穗成熟, 比较再生季稻及其同期抽穗的主季晚稻的光合生理、激素含量、干物质生产、非结构性碳水化合物(NSC)、¹³C同化物在植株地上部和地下部的干物质积累与分配差异。结果表明, 相比同期抽穗的同基因型主季晚稻, 2个供试品种的再生季稻生育期缩短50%, 但有效穗数和收获指数分别增加50%和10%, 最终产量可达到对照产量的55%~65%; 再生季稻在籽粒灌浆前期叶片光合速率和SPAD值均明显增高, 但齐穗后20 d至成熟期其光合速率和SPAD值则明显降低; 再生季稻株体内的ZR、IAA含量在齐穗期较高, 之后相比较低, 再生季稻株内的ABA含量在齐穗期至齐穗后10 d或20 d较高, 达到10%~20%, 而其GA₃含量普遍较低; 再生季稻稻桩、叶片和茎鞘的NSC转运率高达67%~78%、59%~67%和52%~61%, 因此其NSC转运对产量贡献率也分别高达10%~18%; ¹³C光合同化物分配在穗部占比大, 成熟期再生季稻穗部的分配率高20.83%, 同时, 减少了再生季稻¹³C同化物向地下部的转移量达5%, 因而有效穗多, 收获指数高。再生季稻减少了光合同化物向根际土壤的转移与分配, 既能提高其收获指数, 又有利于减少水稻的CH₄等温室气体排放量, 是一种经济高效益和环境友好型的稻作模式。

关键词: 再生季稻, ¹³C脉冲标记, 非结构碳水化合物, 干物质积累与分配

Abstract:

It is of great theoretical and practical significance to study the dry matter accumulation and translocation properties of ratoon rice for further understanding the physiological mechanism of yield formation and exploring the potential of yield increase. In this study, two rice varieties, Jiafuzhan (conventional indica rice) and Yongyou 2640 (indica-japonica hybrid rice), popularly planted in Southeast China, were used as the test materials. The ratooning and main rice crops of the two cultivars were regulated to be heading and ripening in the similar temperature condition of late autumn. Differences of photosynthetic physiology, hormone content, dry matter production, NSC translocation, and ¹³C assimilate in aboveground and underground parts of ratooning rice and its main crop synchronized heading in late season were compared. The results showed that, compared with main crop (late season) synchronized in rice heading time, the growth period of ratooning rice of the two varieties was 50% shorter, but they had 50% increase of effective panicles and 10% increase of harvest indexes, so the final yield could still reach 55%-65% of the control yield; the photosynthetic rate and SPAD value of the ratooning rice at the early stage of grain filling were significantly higher, but they turned to be significantly lower from 20 days after full heading to maturity; the content of ZR and IAA in ratooning rice were higher at the full heading stage, but lower later; the content of ABA in ratooning rice was 10%-20% higher from full heading stage to 10 days or 20 days after full heading, while the content of GA₃in ratooning rice was generally lower; NSC translocation rates of stubble, leaf and stem-sheath of the two tested varieties were as high as 67%-78%, 59%-67%, and 52%-61%, respectively, and the contribution rate of NSC translocation to yield was also as high as 10%-18%, respectively. The distribution rate of ¹³C photochemical compounds in panicle of ratooning rice at maturity stage was up to 20.83%, and the translocation of ¹³C assimilates to underground part of ratooning rice was reduced by 5%, resulting in more effective panicles and higher harvest index. Therefore, ratooning rice can reduce translocation and allocation of photoassimilates to rhizosphere soil, improve harvest index, lessen CH_4, and other greenhouse gas emissions, which is a high-benefit and environment-friendly rice cropping pattern.

Key words: ratooning season rice, ¹³C pulse labeling, non-structural carbohydrate, dry matter accumulation and translocation

吴冬青, 李洲, 郭春林, 邹京南, 庞孜钦, 林非凡, 何海斌, 林文雄. 再生季稻与同期抽穗主季稻干物质分配特性及机制研究[J]. 作物学报, 2023, 49(3): 755-771.

WU Dong-Qing, LI Zhou, GUO Chun-Lin, ZOU Jing-Nan, PANG Zi-Qin, LIN Fei-Fan, HE Hai-Bin, LIN Wen-Xiong. Dry matter partitioning properties and mechanism of ratooning rice and main crop (late season) synchronized in rice heading time[J]. Acta Agronomica Sinica, 2023, 49(3): 755-771.

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品种 Cultivar name		种植模式Cropping pattern	有效穗数 Effective panicles (m^-2)	每穗粒数 No. of grains per panicles	结实率 Seed setting percentage (%)	千粒重 1000-grain weight (g)	产量 Grain yield (t hm^-2)	收获指数Harvest index (%)
2018	JFZ	RCR	442.0±4.9 a	51.0±2.0 a	90.1±1.08 a	23.5±0.24 a	4.77±0.15 Aa	56.9±0.4 a
	JFZ	STLR	276.0±7.8 c	112.0±5.3 b	86.0±1.79 b	27.5±0.30 b	7.31±0.26 Bb	42.7±0.2 b
	YY2640	RCR	336.0±10.6 b	112.7±4.4 b	63.7±2.49 c	22.3±0.17 c	5.38±0.10 Cc	53.5±0.2 c
	YY2640	STLR	224.0±7.3 c	293.7±7.5 c	70.6±1.73 c	22.6±0.56 c	10.50 Dd	49.5±0.1 d
2019	JFZ	RCR	441.7±8.8 a	49.5±1.2 a	90.3±2.39 a	23.4±0.28 a	4.62±0.13 Aa	55.3±0.1 a
	JFZ	STLR	275.4±3.3 c	111.2±3.1 b	85.6±2.54 b	27.0±0.28 b	7.08±0.20 Bb	50.2±0.2 b
	YY2640	RCR	307.0±7.7 b	115.1±6.9 b	82.6±1.31 b	22.6±0.40 c	6.58±0.30 Cc	54.3±0.4 c
	YY2640	STLR	209.1±5.1 c	284.3±10.6 c	80.3±2.42 b	22.2±0.32 c	10.6±0.24 Dd	49.4±0.1 d
		自由度DF	F-value
年度Year (Y)		1	NS	NS	NS	NS	NS	NS
品种Cultivar (C)		159.6	8.64^**	18.101^***	16.725^***	7.649^***	6.971^*	NS
种植模式 Cropping system (S)		1	39.661^***	16.891^***	NS	7.316^*	24.08^***	16.055^**
年度×品种Y×C		3	NS	5.49^**	13.304^***	NS	NS	NS
年度×种植模式Y×S		3	12.274^***	5.127^**	NS	NS	7.448^**	6.181^**
品种×种植模式C×S		3	151.952^***	476.76^***	5.68^**	9.79^***	31.023^***	6.62^**
年度×品种×种植模式 Y×C×S		7	67.566^***	173.042^***	5.838^**	3.437^*	11.746^***	3.917^*

测定指标 Determination index	品种及稻作模式 Cultivar and cropping pattern	孕穗期 Booting stage	抽穗期 Heading stage	乳熟期 Milk stage	成熟期 Maturity stage
叶面积指数 Leaf area index	JFZ-RCR	1.0±0.10 a	2.10±0.20 a	2.20±0.20 a	2.30±0.40
	JFZ-STLR	5.2±0.70 b	4.90±0.02 b	5.80±0.30 b	5.30±0.90
	YY2640-RCR	2.4±0.50 a	2.40±0.50 a	2.40±0.50 a	2.40±0.50
	YY2640-STLR	4.7±0.80 b	5.30±0.30 b	5.80±0.70 b	6.20±0.90
剑叶SPAD衰减率(降低值/d) Decay rate of blade SPAD	JFZ-RCR	0.1±0.10 a	0.25±0.08 a	1.16±0.30 a	1.19±0.09
	JFZ-STLR	0.1±0.04 a	0.16±0.03 b	0.70±0.07 b	0.87±0.12
	YY2640-RCR	0.22±0.08 a	0.24±0.09 a	1.02±0.26 a	1.40±0.11
	YY2640-STLR	0.05±0.01 b	0.10±0.08 b	0.59±0.12 b	0.95±0.04
单株叶重 Leaf weight per plant (g plants^-1)	JFZ-RCR		10.00±1.77 a		5.30±1.15 a
	JFZ-STLR		25.50±1.25 b		14.90±0.56 b
	YY2640-RCR		15.10±1.87 a		7.90±1.85 a
	YY2640-STLR		26.10±0.65 b		20.9±0.75 b

项目 Item	单株穗重 Panicle weight per plant (g plant^-1)	玉米素核苷 ZR (μg g^-1 FW)	赤霉素 GA₃ (μg g^-1 FW)	脱落酸 ABA (μg g^-1 FW)	生长素 IAA (μg g^-1 FW)	叶绿素SPAD值 SPAD value	转运量 Translocation amount (g plant^-1)	运转率 Translocation rate (%)
单株穗重 Panicle weight per plant (g plant^-1)	1	-0.401	-0.667	0.612	-0.412	-0.411	0.800^*	0.402
玉米素核苷 ZR (μg g^-1 FW)		1	0.821^*	-0.711^*	0.970^**	0.990^**	-0.760^*	-1.000^**
赤霉素GA₃ (μg g^-1 FW)			1	-0.975^**	0.821^*	0.821^*	-0.975^**	-0.821
脱落酸ABA (μg g^-1 FW)				1	-0.700^*	-0.890^*	1.000^**	0.760^*
生长素IAA (μg g^-1 FW)					1	1.000^**	-0.770^*	-1.000^**
叶绿素SPAD值 SPAD value						1	-0.760^*	-1.000^**
转运量 Translocation amount (g plant^-1)							1	0.788^*
运转率 Translocation rate (%)								1

年度 Year	品种 Cultivar	种植模式 Cropping pattern	干物质转运量 Translocation amount of dry matter (kg hm^-2)			干物质转运率 Translocation rate of dry matter (%)			干物质贡献率 Contribution rate of dry matter (%)			齐穗后干物质贡献率 Contribution rate of dry matter after full heading stage (%)
年度 Year	品种 Cultivar	种植模式 Cropping pattern	稻桩 Stubble	茎鞘 Stem-sheath	叶片 Leaf	稻桩 Stubble	茎鞘 Stem-sheath	叶片 Leaf	稻桩 Stubble	茎鞘 Stem-sheath	叶片 Leaf
2018	JFZ	RCR	204.2	781.7 c	261.1 b	12.6	17.6 b	25.2 b	2.7	12.6 b	7.8 b	76.9 b
	JFZ	STLR	—	526.0 bc	254.8 b	—	7.9 c	9.6 d	—	8.5 c	4.1 c	87.4 a
	YY2640	RCR	245.6	703.0 a	446.3 a	20.0	21.3 a	26.8 a	5.1	14.6 a	9.3 a	71.0 c
	YY2640	STLR	—	584.8 b	437.4 a	—	6.6 c	12.5 c	—	6.3 d	4.7 c	89.0 a
2019	JFZ	RCR	246.3	819.4 ab	237.6 c	18.7	27.0 a	30.2 a	5.6	18.6 a	5.4 a	70.4 c
	JFZ	STLR	—	666.2 b	232.7 c	—	11.0 c	14.7 c	—	11.5 b	4.0 c	84.5 b
	YY2640	RCR	269.6	941.6 a	321.4 b	16.2	23.4 b	28.4 b	4.7	16.6 a	5.6 a	73.1 c
	YY2640	STLR	—	684.0 b	396.4 a	—	7.8 d	12.3 d	—	7.7 c	4.5 b	87.8 a

品种 Cultivar	稻作模式 Cropping pattern	可溶性糖含量 Content of soluble sugars (g plant^-1)					淀粉含量 Content of starches (g plant^-1)					NSC含量 Content of NSC (g plant^-1)
品种 Cultivar	稻作模式 Cropping pattern	根 Root	茎鞘 Stem-sheath	叶 Leaf	稻桩 Stubble	籽粒 Grain	根 Root	茎鞘 Stem-sheath	叶 Leaf	稻桩 Stubble	籽粒 Grain	根 Root	茎鞘 Stem-sheath	叶 Leaf	稻桩 Stubble	籽粒 Grain
齐穗期 Full heading stage
JFZ	RCR	0.57 c	2.14 b	0.44 d	0.43 a	0.25 c	0.67 b	2.38 d	0.32 c	0.52 b	0.02 d	1.24 c	4.52 c	0.76 d	0.95 a	0.27 c
JFZ	STLR	1.65 a	2.62 b	0.72 c		0.26 c	1.22 a	5.66 b	0.53 b		0.05 c	2.87 a	8.28 ab	1.25 c		0.31 c
YY2640	RCR	0.86 b	2.42 b	1.03 b	0.34 b	0.26 c	0.66 b	4.25 c	0.85 ab	0.82 a	0.02 d	1.52 c	6.67 bc	1.88 b	1.16 a	0.28 c
YY2640	STLR	1.35 ab	3.93 a	1.56 a		1.06 a	1.22 a	6.82 a	1.15 a		0.07 b	2.57 a	10.75 a	2.71 a		1.13 a
成熟期 Maturity stage
JFZ	RCR	0.27 c	0.98 d	0.16 d	0.09 b	1.02 a	0.18 cd	1.18 c	0.19 c	0.12 b	17.22 c	0.45 c	2.16 c	0.35 d	0.21 b	18.24 c
JFZ	STLR	1.08 a	3.22 a	0.64 c		0.58 b	0.67 a	2.59 a	0.33 b		28.51 b	1.75 a	5.81 a	0.97 b		29.09 b
YY2640	RCR	0.49 b	1.51 c	0.23 d	0.18 a	1.17 a	0.26 c	1.07 c	0.39 b	0.20 a	26.62 b	0.75 b	2.58 c	0.62 c	0.38 a	27.79 b
YY2640	STLR	1.13 a	3.18 a	1.07 b		0.80 ab	0.59 ab	2.88 a	0.75 a		41.58 a	1.72 a	6.06 a	1.82 a		42.38 a

再生季稻与同期抽穗主季稻干物质分配特性及机制研究

Dry matter partitioning properties and mechanism of ratooning rice and main crop (late season) synchronized in rice heading time

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品种 Cultivar	稻作模式 Cropping Pattern	NSC转运量 Translocation amount of NSC (g plant^-1)				NSC转运率 Translocation rate of NSC (%)				NSC转运对产量贡献率 Contribution rate of NSC translocation to production (%)
品种 Cultivar	稻作模式 Cropping Pattern	根 Root	茎鞘 Stem-sheath	叶 Leaf	桩 Stubble	根 Root	茎鞘 Stem-sheath	叶 Leaf	桩 Stubble	茎鞘 Stem-sheath	叶 Leaf	桩 Stubble
JFZ	RCR	0.79 b	2.36 d	0.41 c	0.74 a	63.71 a	52.21 b	58.73 b	77.89 a	12.93 ab	2.24 b	4.05 a
JFZ	STLR	1.12 a	2.47 d	0.28 d		39.02 c	29.83 d	22.40 d		8.49 c	0.96 d
YY2640	RCR	0.77 bc	4.09 b	1.26 a	0.78 a	50.65 b	61.31 a	67.02 a	67.02 a	14.71 a	4.43 a	2.81 b
YY2640	STLR	0.85 b	4.69 a	0.89 b		33.07 d	43.62 c	32.84 c		11.06 b	2.10 b

品种 Cultivar	分配部位 Allocated part	齐穗期含量 Contents at full heading stage (mg pot^-1)		成熟期含量 Contents at maturity stage (mg pot^-1)		同品种成熟和齐穗期含量差异 The content difference of the same accessions at maturity and full heading stages (mg pot^-1)
品种 Cultivar	分配部位 Allocated part	RCR	STLR	RCR	STLR	RCR	STLR
JFZ	¹³C-土壤 ¹³C-soil	4.87 Ecd^*	0.40 d	3.02 Cbc	2.75 Cc	-1.84 Db	2.35 Db^*
	¹³C-根系 ¹³C-roots	1.54 Ed	2.66 Ed^*	0.44 Cc	4.33 Cc^*	-1.10 Db	1.67 Db^*
	¹³C-稻桩 ¹³C-stubbles	4.11 Ecd	—	1.30 Cc	—	-2.82 Db	—
	¹³C-茎鞘 ¹³C-stem-sheath	38.57 EAb^*	34.42 Ab	9.31 Bb	20.95 Ab^*	-29.25 Ac	-13.46 Ad^*
	¹³C-叶 ¹³C-leaves	6.30 Ec	7.73 Ec^*	3.33 Cc	5.36 Cc^*	-2.97 Db	-2.36 Dc
	¹³C-穗 ¹³C-panicles	70.25 Ba^*	48.35 Ba	102.26 Aa^*	60.97 Ba	32.01 Aa^*	12.62 Aa
YY2640	¹³C-土壤 ¹³C-soil	3.35 Ec^*	0.41 Ed	2.36 Cc^*	1.30 Cc	-0.99 Db	0.89 Db^*
	¹³C-根系 ¹³C-roots	0.97 Ec	1.41 Ed	0.30 Cc	2.74 Cc^*	-0.68 Db	1.34 Db^*
	¹³C-稻桩 ¹³C-stubbles	2.04 Ec	—	0.91 Cc	—	-1.13 Db	—
	¹³C-茎鞘 ¹³C-stem-sheath	19.12 Db	20.53 Db^*	9.13 Bb	16.39 Bb^*	-9.99 Cc	-4.13 Cc^*
	¹³C-叶 ¹³C-leaves	3.00 Ec	9.95 Ec^*	1.88 Cc	4.05 Cc^*	-1.12 Db^*	-5.89 Cd
	¹³C-穗 ¹³C-panicles	89.07 Ca^*	62.77 Ca	104.93 Aa^*	70.22 Ba	15.87 Ba^*	7.46 Ba

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