Influence of different promoters compounded with DPC on the spatial and temporal distribution of cotton boll and yield

doi:10.6048/j.issn.1001-4330.2024.02.003

Xinjiang Agricultural Sciences ›› 2024, Vol. 61 ›› Issue (2): 279-287.DOI: 10.6048/j.issn.1001-4330.2024.02.003

• Crop Genetics and Breeding·Germplasm Resources·Molecular Genetics • Previous Articles Next Articles

Influence of different promoters compounded with DPC on the spatial and temporal distribution of cotton boll and yield

WU Gang(), TIAN Yangqing, ZHAO Qiang(), LI Xinxin, Munire Abudulaini, ZHANG Jiahao, WANG Wenqing, ZHAN Dongxia(), MA Chunmei

College of Agriculture,Xinjang Agricultaral University Engineering Research Center of the Ministry of Education for Cotton, Urumqi 830052, China

Received:2023-06-19 Online:2024-02-20 Published:2024-03-19
Correspondence author: ZHAN Dongxia (1984-), female, from Hubei, lecturer, doctor, main research direction of crop high-yield cultivation technology research,(E-mail)zhandongxia@sina.cn;ZHAO Qiang(1981-), male, from Lingbi, Anhui, professor, doctoral supervisor, mainly engaged in the research on the principle and technology of crop chemical control,(E-mail)qiangzhao99@163.com
Supported by:
Xinjiang Uygur Autonomous Region Major Science and Technology Special Machine Cotton Molding Capping and Leaf Removal Ripening Technology Research Demonstration(2020A01002-2);Development Fund of Crop Science of Xinjiang Agricultural University(NXCDKY2021021)

缩节胺复配不同促进剂对棉花棉铃时空分布和光合特性的影响

吴刚(), 田阳青, 赵强(), 李欣欣, 穆妮热·阿卜杜艾尼, 张家豪, 王文庆, 占东霞(), 马春梅

新疆农业大学农学院 /棉花教育部工程研究中心,乌鲁木齐 830052

通讯作者: 占东霞(1984-),女,湖北人,讲师,博士,研究方向为作物高产栽培,(E-mail)zhandongxia@sina.cn；赵强(1981-),男,安徽人,教授,博士,硕士生/博士生导师,研究方向为作物化控,(E-mail)qiangzhao99@163.com
作者简介:吴刚(1997-),男,新疆人,硕士研究生,研究方向为作物化控,(E-mail)977204062@qq.com
基金资助:
新疆维吾尔自治区重大科技专项“机采棉塑型封顶与脱叶催熟技术研究示范”(2020A01002-2);新疆农业大学作物学重点学科发展基金(NXCDKY2021021)

Abstract

Abstract:

【Objective】 This experiment conducted aims to investigate the effect of chemical topping on cotton boll formation and photosynthetic characteristics by using indirubicin compounded with different accelerators in the hope of providing some scientific and theoretical basis for the research application of indirubicin compounded with accelerators on cotton boll regulation and photosynthetic characteristics.【Methods】 The experiment was conducted in Shaya County, Aksu Region, Xinjiang, China, from April to October 2022.The cotton variety under test was Xinluzhong 84, and the test chemicals were mainly indurated with thiram and auxin, compounded with thiram(0.1%, T₁), sodium compounded phenol(98% of the original drug, T₂), aminoxate(8% of the preparation, T₃), 14-hydroxy brassin(0.01%, T₄)and naphthalene acetic acid(98% of the original drug, T₅), with conventional micronutrient capping as the control(CK), a total of six treatments were used to investigate the effects of micronutrient complex promoters on the spatial and temporal distribution and photosynthetic characteristics of cotton boll.【Results】 The maximum accumulation rate of dry matter was reached at about 20~30 d after the treatment, and the net photosynthetic rate reached its maximum at about 20 d after the treatment, so it could be inferred that cotton entered the critical period of reproductive growth at about 20~30 d after the treatment, and all the compound treatments could improve the sitting rate, net photosynthetic rate and dry matter accumulation rate of the upper middle and lower inner peripheral boll.【Conclusion】 The rapid accumulation period of T₅ treatment was prolonged by about 5 d compared with CK, and the sitting rate of inner and lower outer boll of cotton plant was significantly different from that of CK.The sitting rate of inner and lower outer boll increased by 15.00% and 20.00% respectively, and that of middle inner and outer boll increased by 24.00% and 25.00% respectively, and the number of cotyledons increased by 1.13, and the number of boll set per plant increased significantly by 0.84.Therefore, it is recommended to use T₅ combination type chemical topping agent for cotton chemical topping.

Key words: cotton; DPC; space-time distribution of cotton bells; yield; photosynthetic characteristics

摘要：

【目的】运用缩节胺复配不同促进剂对棉花进行化学封顶试验,研究其对棉花成铃及光合特性的影响,为缩节胺复配促进剂对棉花棉铃调控和光合特性的研究应用提供科学依据。【方法】试验于2022年4~10月在新疆阿克苏地区沙雅县进行,供试棉花品种为新陆中84号,试验药剂以缩节胺和助剂为主,分别复配噻苯隆(0.1%,T₁)、复硝酚钠(98%原药,T₂)、胺鲜酯(8%制剂,T₃)、14-羟基芸苔素(0.01%,T₄)和萘乙酸(98%原药,T₅),以常规缩节胺封顶为对照(CK),共6个处理,分析缩节胺复配促进剂对棉花棉铃时空分布和光合特性的影响。【结果】各处理干物质积累达到最大积累速率的时间在药后20~30 d,净光合速率在药后20 d左右达到最大值,在药后20~30 d棉花进入生殖生长的关键时期,且各复配处理均能提高棉株上中下部内外围铃的坐桃率、净光合速率和干物质积累速率。【结论】T₅处理快速积累持续期较CK延长了5 d左右,且棉株中下部内外围铃坐桃率较CK差异显著,下部内外围铃坐桃率分别提高了15.00%和20.00%,中部内外围铃分别提高了24.00%和25.00%,伏桃增加了1.13个,单株结铃数显著增加了0.84个,较CK处理皮棉产量提高了15.48%,T₅复配类型化学封顶剂效果好。

关键词: 棉花, 缩节胺, 棉铃时空分布, 产量, 光合特性

CLC Number:

S562

WU Gang, TIAN Yangqing, ZHAO Qiang, LI Xinxin, Munire Abudulaini, ZHANG Jiahao, WANG Wenqing, ZHAN Dongxia, MA Chunmei. Influence of different promoters compounded with DPC on the spatial and temporal distribution of cotton boll and yield[J]. Xinjiang Agricultural Sciences, 2024, 61(2): 279-287.

吴刚, 田阳青, 赵强, 李欣欣, 穆妮热·阿卜杜艾尼, 张家豪, 王文庆, 占东霞, 马春梅. 缩节胺复配不同促进剂对棉花棉铃时空分布和光合特性的影响[J]. 新疆农业科学, 2024, 61(2): 279-287.

Figures/Tables 7

Tab.1 Experiment treatments and dosage

试验编号 Experi- mental number	试验处理 Experimental treatments	用药剂量 Dosage (g/hm²)
T₁	缩节胺+噻苯隆 (0.1%)+助剂	225+150+150
T₂	缩节胺+复硝酚钠 (98%原药)+助剂	225+15+150
T₃	缩节胺+胺鲜酯 (8%制剂)+助剂	225+150+150
T₄	缩节胺+14-羟基芸苔素 (0.01%)+助剂	225+150+150
T₅	缩节胺+萘乙酸 (98%原药)+助剂	225+15+150
CK	缩节胺+助剂	225+150

Fig.1 The change of the number of cotton buds capped with different promoters Note:Different small letters mean significant differences(P<0.05),the same as below

Tab.2 Changes in the proportion of three peaches with different promoters

处理 Treatments	伏前桃 Fore boll (个/株)	伏前桃占比 Prevolt boll proportion (%)	伏桃 Volt boll (个/株)	伏桃占比 Volt boll proportion (%)	秋桃 Autumn boll (个/株)	秋桃占比 Autumn boll proportion (%)
T₁	2.69^a	28	4.40^b	45	2.68^ab	27
T₂	2.89^a	29	4.30^b	42	2.94^a	29
T₃	3.57^a	34	4.33^b	42	2.53^ab	24
T₄	3.49^a	31	4.87^ab	43	2.94^a	26
T₅	2.70^a	27	5.50^a	54	1.90^b	19
CK	3.23^a	34	4.37^b	46	1.83^b	19

Tab.3 Changes in spatial distribution of cotton with different promoters

处理 Treatments	下部果枝坐桃率 Lower fruit branches sitting boll rate(%)		中部果枝坐桃率 Central fruit branch sitting boll rate(%)		上部果枝坐桃率 Upper fruit branch sitting boll rate(%)
处理 Treatments	内围铃 Entire the bell	外围铃 Peripheral bell	内围铃 Entire the bell	外围铃 Peripheral bell	内围铃 Entire the bell	外围铃 Peripheral bell
T₁	85.22^a	64.33^ab	77.78^bc	42.00^b	52.37^ab	21.00^a
T₂	88.89^a	67.00^a	77.78^bc	44.33^b	57.27^a	21.33^a
T₃	85.22^a	63.33^ab	74.69^c	40.33^b	51.33^ab	20.00^a
T₄	88.89^a	70.00^a	85.56^ab	46.33^b	59.41^a	21.33^a
T₅	92.56^a	75.00^a	89.67^a	64.67^a	64.78^a	25.33^a
CK	77.78^b	54.67^b	65.79^c	40.00^b	38.84^b	18.00^a

Tab.4 Logistic equation and characteristic values of dry matter accumulation in each treatment

处理 Treatments	逻辑斯蒂方程 Logic Stein's equation	t₀ (d)	t₁ (d)	t₂ (d)	t_m (d)	Δt/d	V_m (g/ (株·d))	GT (g/株)	R²
T₁	y=150.320 3/[1+e⁽⁴^.^{805 8-0}^.^{046 364}^t⁾]	103.57	75.19	131.96	33.83	56.77	1.74	98.99	0.995 $8^{^{* *}}$
T₂	y=154.070 1/[1+e⁽⁴^.^{873 1-0}^.^{046 212}^t⁾]	105.45	76.95	133.95	34.27	57.00	1.78	101.46	0.993 $8^{^{* *}}$
T₃	y=116.171 5/[1+e⁽⁵^.^{537 3-0}^.^{058 954}^t⁾]	93.93	71.59	116.27	29.03	44.68	1.71	76.50	0.994 $5^{^{* *}}$
T₄	y=132.960 3/[1+e⁽⁵^.^{623 6-0}^.^{057 143}^t⁾]	98.41	75.37	121.46	30.22	46.09	1.90	87.55	0.997 $1^{^{* *}}$
T₅	y=162.873 7/[1+e⁽⁴^.^{694 5-0}^.^{044 612}^t⁾]	105.23	75.71	134.75	34.66	59.04	1.82	107.25	0.997 $1^{^{* *}}$
CK	y=138.511 5/[1+e⁽⁵^.^{016 7-0}^.^{048 713}^t⁾]	102.98	75.95	130.02	33.11	54.07	1.69	91.21	0.990 $5^{^{* *}}$

Tab.4 Logistic equation and characteristic values of dry matter accumulation in each treatment

处理 Treatments	逻辑斯蒂方程 Logic Stein's equation	t₀ (d)	t₁ (d)	t₂ (d)	t_m (d)	Δt/d	V_m (g/ (株·d))	GT (g/株)	R²
T₁	y=150.320 3/[1+e⁽⁴^.^{805 8-0}^.^{046 364}^t⁾]	103.57	75.19	131.96	33.83	56.77	1.74	98.99	0.995 $8^{^{* *}}$
T₂	y=154.070 1/[1+e⁽⁴^.^{873 1-0}^.^{046 212}^t⁾]	105.45	76.95	133.95	34.27	57.00	1.78	101.46	0.993 $8^{^{* *}}$
T₃	y=116.171 5/[1+e⁽⁵^.^{537 3-0}^.^{058 954}^t⁾]	93.93	71.59	116.27	29.03	44.68	1.71	76.50	0.994 $5^{^{* *}}$
T₄	y=132.960 3/[1+e⁽⁵^.^{623 6-0}^.^{057 143}^t⁾]	98.41	75.37	121.46	30.22	46.09	1.90	87.55	0.997 $1^{^{* *}}$
T₅	y=162.873 7/[1+e⁽⁴^.^{694 5-0}^.^{044 612}^t⁾]	105.23	75.71	134.75	34.66	59.04	1.82	107.25	0.997 $1^{^{* *}}$
CK	y=138.511 5/[1+e⁽⁵^.^{016 7-0}^.^{048 713}^t⁾]	102.98	75.95	130.02	33.11	54.07	1.69	91.21	0.990 $5^{^{* *}}$

Fig.2 Changes in the photosynthetic properties of cotton capped with different promoters

Tab.5 Changes in cotton production of different promoters

处理 Treat- ments	单位面积株数 The number of hectares (10⁴株/ hm²)	单铃重 Single bell heavy (g)	单株铃数 Number of single bells (个)	皮棉产量 Cotton yield (kg/hm²)
T₁	14.20^a	6.05^a	8.06^ab	3 002.23^c
T₂	14.30^a	6.03^a	7.97^ab	3 028.55^bc
T₃	14.10^a	6.00^a	8.02^ab	2 962.85^c
T₄	14.00^a	6.01^a	8.48^ab	3 261.07^ab
T₅	13.90^a	5.96^a	8.62^a	3 333.60^a
CK	14.30^a	6.01^a	7.78^b	2 886.75^c

References 31

[1]	麦丹别克·安尼瓦尔. 新疆2021年棉花生产剖析及未来种业发展方向[J]. 棉花科学, 2022, 44(1):11-14.
	Maidanbieke Anniwaer. Anatomy of cotton production in Xinjiang in 2021 and future direction of seed industry development[J]. Cotton Sciences, 2022, 44(1):11-14.
[2]	刘嘉嘉. 新疆棉花生产现状和存在问题及对策[J]. 棉花科学, 2022, 44(5):15-19.
	LIU Jiajia. Current situation and problems of cotton production in Xinjiang and countermeasures[J]. Cotton Sciences, 2022, 44(5):15-19.
[3]	张洪浩. 新疆棉花生产问题探讨与建议[J]. 农业科技通讯, 2021,(11):18-20.
	ZHANG Honghao. Discussion and suggestions on cotton production in Xinjiang[J]. Agricultural Science and Technology Newsletter, 2021,(11):18-20.
[4]	王刚. 化学打顶剂在新疆棉花生产中的研究与应用[J]. 中国棉花, 2015, 42(10):8-10. DOI
	WANG Gang. Research and application of chemical topping agents in cotton production in Xinjiang[J]. China Cotton, 2015, 42(10):8-10.
[5]	傅腾腾. 植物生长调节剂在作物上的应用研究进展[J]. 长江大学学报(自然科学版), 2011, 8(10):233-235.
	FU Tengteng. Advances in the application of plant growth regulators on crops[J]. Journal of Changjiang University(Natural Science Edition), 2011, 8(10):233-235.
[6]	陶龙兴. 植物生长调节剂在农业中的应用及发展趋势[J]. 浙江农业学报, 2001, 13(5):84-88.
	TAO Longxing. Application and development trend of plant growth regulators in agriculture[J]. Acta Agriculturae Zhejiangensis, 2001, 13(5):84-88.
[7]	顾万荣. 中国作物化控栽培工程技术研究进展及展望[J]. 中国农学通报, 2005, 21(7):400-405.
	GU Wanrong. Progress and prospects of chemically controlled cultivation engineering technology in China[J]. China Agricultural Science Bulletin, 2005, 21(7):400-405.
[8]	Bandara P M S, Tanino K K. Paclobutrazol enhances minituber production in Norland potatoes[J]. Journal of Plant Growth Regulation, 1995, 14(3):151-155. DOI URL
[9]	杨秀荣, 刘亦学, 刘水芳, 等. 植物生长调节剂及其研究与应用[J]. 天津农业科学, 2007, 13(1):23-25.
	YANG Xiurong, LIU Yixue, LIU Shuifang, et al. Plant growth regulators and their research and application[J]. Tianjin Agricultural Sciences, 2007, 13(1):23-25.
[10]	张小冰. 新型植物激素—油菜素内酯在农业上的应用[J]. 生物学教学, 2009, 34(1):4-6.
	ZHANG Xiaobing. Application of a new plant hormone, oleuropein lactone, in agriculture[J]. Biology Teaching, 2009, 34(1):4-6.
[11]	冯璐. 植物生长物质对新品种马铃薯试管苗生长及微型薯诱导的影响[D]. 太原: 山西农业大学, 2017.
	FENG Lu. Effect of plant growth substances on the growth of test tube seedlings and micro potato induction of new potato varieties[D]. Taiyuan: Shanxi Agricultural University, 2017.
[12]	周欣欣, 张宏军, 白孟卿, 等. 植物生长调节剂产业发展现状及前景[J]. 农药科学与管理, 2017, 38(11):14-19.
	ZHOU Xinxin, ZHANG Hongjun, BAI Mengqing, et al. Current status and prospects of the development of plant growth regulator industry[J]. Pesticide Science and Management, 2017, 38(11):14-19.
[13]	刘海涛, 海成伟, 江建设. 油菜素内酯对抗虫棉经济性状的影响[J]. 中国棉花, 2009, 36(8):15-16. DOI
	LIU Haitao, HAI Chengwei, JIANG Jianshe. Effect of oleuropein lactones on economic traits of insect-resistant cotton[J]. China Cotton, 2009, 36(8):15-16. DOI
[14]	Fang S, Gao K, Hu W, et al. Foliar and seed application of plant growth regulators affects cotton yield by altering leaf physiology and floral bud carbohydrate accumulation[J]. Field Crops Research, 2019, 231:105-114. DOI URL
[15]	王为, 赵强, 吴雪琴. 苯肽胺酸复配不同外源物质对棉花生长发育的调控效应研究[J]. 新疆农业大学学报, 2022, 45(1):1-8.
	WANG Wei, ZHAO Qiang, WU Xueqin. Study on the regulatory effects of phenylpropanoid acid compounded with different exogenous substances on cotton growth and development[J]. Journal of Xinjiang Agricultural University, 2022, 45(1):1-8.
[16]	马春梅, 田阳青, 赵强, 等. 植物生长调节剂复配对棉花产量的影响[J]. 作物杂志, 2022,(6):181-185.
	MA Chunmei, TIAN Yangqing, ZHAO Qiang, et al. Effect of plant growth regulator compounding on cotton yield[J]. Crops, 2022,(6):181-185.
[17]	金嵘, 李进, 梁晶, 等. 4种植物生长调节剂对棉花生长发育、光合特性及产量的影响[J]. 新疆农业科学, 2021, 58(11):2035-2042. DOI
	JIN Rong, LI Jin, LIANG Jing, et al. Effects of four plant growth regulators on growth and development, photosynthetic characteristics and yield of cotton[J]. Xinjiang Agricultural Sciences, 2021, 58(11):2035-2042. DOI
[18]	高艾兰, 宋贤利. 50%噻苯隆可湿性粉剂对棉花脱叶及防止烂铃的药效试验[J]. 农药, 2003,(1):35.
	GAO Ailan, SONG Xianli. The efficacy of 50% thiabenduron wettable powder on defoliation and prevention of rotten boll in cotton[J]. Agrochemicals, 2003,(1):35.
[19]	刘京涛, 王秀芳, 王滨杰, 等. 噻苯敌草隆脱叶剂对棉花脱叶、吐絮效果试验[J]. 作物杂志, 2012,(4):141-143.
	LIU Jingtao, WANG Xiufang, WANG Binjie, et al. Effect of thiram defoliants on cotton defoliation and flocculation[J]. Crops, 2012,(4):141-143.
[20]	Campoy J A, Ruiz D, Egea J. Effects of shading and thidiazuron+ oil treatment on dormancy breaking, blooming and fruit set in apricot in a warm-winter climate[J]. Scientia Horticulturae, 2010, 125(3):203-210. DOI URL
[21]	杨国强. 噻苯隆在草莓的残留分析及其对草莓相关酶活性水平的影响研究[D]. 贵阳: 贵州大学, 2019.
	YANG Guoqiang. Residue analysis of thiabenduron in strawberry and its effect on the level of strawberry-related enzyme activity[D]. Guiyang: Guizhou University, 2019.
[22]	樊翠芹, 张丽, 于翠红, 等. 0.1%噻苯隆可溶性液剂在巨峰葡萄上的应用效果[J]. 河北农业科学, 2016, 20(6):40-45.
	FAN Cuiqin, ZHANG Li, YU Cuihong, et al. Effectiveness of 0.1% thiabenduron soluble liquid solution on Giant Peak grapes[J]. Journal of Hebei Agricultural Sciences, 2016, 20(6):40-45.
[23]	李钊阳, Shaukat Ali, 唐良德, 等. 0.2%噻苯隆可溶液剂对金桔产量和品质的影响[J]. 中国农学通报, 2021, 37(16):33-36. DOI
	LI Zhaoyang, Shaukat Ali, TANG Liangde, et al. Effect of 0.2% thiabenduron soluble solution on yield and quality of kumquat[J]. China Agricultural Science Bulletin, 2021, 37(16):33-36.
[24]	吴雪琴. 3种打(封)顶方式对南疆棉花株型及干物质积累的影响[J]. 西北农业学报, 2021, 30(12):1797-1803.
	WU Xueqin. Effects of three topping methods on cotton plant size and dry matter accumulation in South China[J]. Acta Agriculturae Boreali-occidentalis Sinica, 2021, 30(12):1797-1803.
[25]	徐宇强, 张静, 管利军, 等. 化学打顶对东疆棉花生长发育主要性状的影响[J]. 中国棉花, 2014, 41(2):30-31,38. DOI
	XU Yuqiang, ZHANG Jing, GUAN Lijun, et al. Effects of chemical topping on major traits of cotton growth and development in East China[J]. China Cotton, 2014, 41(2):30-31,38. DOI
[26]	叶春秀. 不同化学打顶剂对北疆早熟陆地棉农艺及经济性状的影响[J]. 西南农业学报, 2017, 30(4):762-766.
	YE Chunxiu. Effects of different chemical topping agents on agronomic and economic traits of early maturing land cotton in Northern Xinjiang[J]. Southwest China Journal of Agricultural Sciences, 2017, 30(4):762-766.
[27]	王国栋, 曾胜和, 梁飞, 等. 化学打顶剂对新疆早熟棉花农艺及产量性状的影响[J]. 江苏农业科学, 2022, 50(8):87-93.
	WANG Guodong, ZENG Shenghe, LIANG Fei, et al. Effect of chemical topping agents on agronomic and yield traits of early maturing cotton in Xinjiang[J]. Jiangsu Agricultural Sciences, 2022, 50(8):87-93.
[28]	胡宇凯, 赵书珍, 董红强, 等. 化学打顶对南疆棉花干物质积累与分配的影响[J]. 棉花学报, 2022, 34(3):247-255. DOI
	HU Yukai, ZHAO Shuzhen, DONG Hongqiang, et al. Effect of chemical topping on dry matter accumulation and distribution of cotton in Southern Xinjiang[J]. Cotton Science, 2022, 34(3):247-255.
[29]	杨成勋, 张旺锋, 徐守振, 等. 喷施化学打顶剂对棉花冠层结构及群体光合生产的影响[J]. 中国农业科学, 2016, 49(9):1672-1684. DOI
	YANG Chengxun, ZHANG Wangfeng, XU Shouzhen, et al. Effects of chemical topping sprays on canopy structure and population photosynthetic production in cotton[J]. Scientia Agricultura Sinica, 2016, 49(9):1672-1684. DOI
[30]	杨成勋. 化学打顶对棉花冠层结构指标及产量形成的影响[J]. 新疆农业科学, 2015, 52(7):1243-1250.
	YANG Chengxun. Effect of chemical topping on canopy structure index and yield formation of cotton[J]. Xinjiang Agricultural Sciences, 2015, 52(7):1243-1250.
[31]	李文姗, 张俊尧, 王家勇, 等. 不同滴施量艾氟迪对棉花光合特性及成铃规律的影响[J]. 河南农业科学, 2023, 52(1):53-60.
	LI Wenshan, ZHANG Junyao, WANG Jiayong, et al. Effects of different drip applications of Eflornithine on photosynthetic characteristics and boll formation pattern of cotton[J]. Henan Agricultural Sciences, 2023, 52(1):53-60.

Influence of different promoters compounded with DPC on the spatial and temporal distribution of cotton boll and yield

缩节胺复配不同促进剂对棉花棉铃时空分布和光合特性的影响

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