Effects of milkvetch （Astragalus sinicus） decomposition leachates on germination and seedling growth of goosegrass （Eleusine indica）

doi:10.11686/cyxb2021188

Abstract

Abstract:

This experiment investigated the allelopathic effects of leachate from milkvetch （Astragalus sinicus） decay on seed germination and seedling growth of goosegrass （Eleusine indica）. The experiment treatments comprised different decomposition durations and different milkvetch decomposition leachate concentrations applied to seeds of goosegrass， and six physiological indexes such as germination rate were determined. The activities of protective enzymes and the contents of proline （Pro） and malondialdehyde （MDA） in the leaves of goosegrass were determined after root irrigation with different concentrations （2%， 5%， 30% and 80%） of milkvetch decomposition leachates. It was found that for a given concentration of decomposition leachates， the inhibition effect was more pronounced with greater decomposition duration. At low concentrations of decomposition leachate， a hormesis effect was observed. When the decomposition duration exceeded 2 days and the decomposition leachate concentration was 80% or more， seed germination was completely inhibited. Superoxide dismutase activity was decreased with increased leachate concentration. Peroxidase activity was lower at leachate concentrations below 30%， and higher at concentrations greater than 30%. Catalase activity was increased with increasing leachate concentration up to 30% and was decreased as leachate concentrations reached 80%. When the concentration of decomposition leachate applied was greater than 2%， the content of MDA， Pro and H₂O₂ in goosegrass leaves increased with the increase of leachate concentration. In conclusion， the decomposition leachate of milkvetch has significant inhibitory effects on the seed germination and seedling growth of goosegrass. It is concluded that milkvetch decomposition leachate has the potential to inhibit weed growth. This study provides reference information for research into allelopathically active substances in milkvetch.

Key words: milkvetch, goosegrass, decomposition leachate, weed suppression

Si-lin LIU, Jun-xue CHEN, Yang YANG, Zhong-wen CHEN, Ling-ling LU, Ying-hui MU. Effects of milkvetch （Astragalus sinicus） decomposition leachates on germination and seedling growth of goosegrass （Eleusine indica）[J]. Acta Prataculturae Sinica, 2022, 31(7): 209-219.

Figures/Tables 8

References 35

1	Jalaludin A， Ngim J， Bakar B H J， et al. Preliminary findings of potentially resistant goosegrass （Eleusine indica） to glufosinate-ammonium in Malaysia. Weed Biology and Management， 2010， 10（4）： 256-260.
2	Seng C T， VAN L L， San C T， et al. Initial report of glufosinate and paraquat multiple resistance that evolved in a biotype of goosegrass （Eleusine indica） in Malaysia. Weed Biology and Management， 2010， 10（4）： 229-233.
3	An J， Shen X F， Ma Q B， et al. Transcriptome profiling to discover putative genes associated with paraquat resistance in goosegrass （Eleusine indica L.）. Public Library of Science One， 2014， 9（6）： e99940.
4	Yang L. Effects of Chinese milk vetch planting and co-incorporation with rice straw on fertilizer reduction and their regulating mechanisms of biological nitrogen fixation. Beijing： Chinese Academy of Agricultural Sciences， 2019.
	杨璐. 紫云英种植及与稻草协同利用的减肥效应和紫云英固氮调控机制. 北京：中国农业科学院， 2019.
5	Deng L P. Effects of multiple cropping rotation on crop yield， soil fertility and farmland greenhouse gas emission. Jiangxi： Jiangxi Agricultural University， 2017.
	邓丽萍. 稻田复种轮作对作物产量、土壤肥力及农田温室气体排放的影响. 江西：江西农业大学， 2017.
6	Wang Y Q， Gao S J， Cao W D， et al. Fertility and nitrification characteristics of two typical paddy soils after application of milk vetch（Astragalus sinicus） for 8 years. Acta Prataculturae Sinica， 2017， 26（2）： 180-189.
	王艳秋，高嵩涓，曹卫东，等. 多年冬种紫云英对两种典型双季稻田土壤肥力及硝化特征的影响. 草业学报， 2017， 26（2）： 180-189.
7	Yang W Y， Wang Z， Li D， et al. Effects of different winter green fertilizers on soil organic matter and pH in paddy field. Journal of Zhejiang Agricultural Sciences， 2017， 58（2）： 239-240.
	杨文叶，王忠，李丹，等. 不同冬绿肥对水稻田土壤有机质及酸碱度的影响. 浙江农业科学， 2017， 58（2）： 239-240.
8	Gao G J， Li Z D， Han R H， et al. Effects of three south green manures on flooded soil nutrient and enzyme activities and their decomposition properties. Chinese Journal of Tropical Crops， 2016， 37（8）： 1476-1483.
	高桂娟，李志丹，韩瑞宏，等. 3种南方绿肥腐解特征及其对淹水土壤养分和酶活性的影响. 热带作物学报， 2016， 37（8）： 1476-1483.
9	Zhan P， Huang L， Li P G， et al. Effect of reducing amount of chemical fertilizer combined with Astragalus sinicus green fertilizer on planting efficiency of early rice and late rice. Modern Agricultural Science and Technology， 2020， 26（6）： 6-8.
	詹鹏，黄琳，李培根，等. 减量化肥配施紫云英绿肥对早稻种植效益及晚稻后效的影响. 现代农业科技， 2020， 26（6）： 6-8.
10	He Y M， Yang Q Z， He H X. Effects of green manure on improving cultivated land quality and rice yield. Agriculture and Technology， 2019， 39（14）： 36-38.
	何艳明，杨庆祝，何红喜. 绿肥对提升耕地质量与水稻产量作用的研究. 农业与技术， 2019， 39（14）： 36-38.
11	Choi J S， Kim M T， Ryu J H， et al. Effect of legume cover crops and nitrogen fertilization rates on yield and nitrogen use efficiency of waxy corn （Zea mays L.） in no-tillage system. Korean Journal of Soil Science and Fertilizer， 2016， 49（5）： 531-540.
12	Li M L， Hu X F， Dai H H， et al. Effects of Brassica chinensis intercropping leguminous green manure on vegetable quality and soil enzyme activities. Journal of Shanghai University （Natural Science Edition）， 2019， 25（2）： 275-281.
	李梦璐，胡雪峰，代会会，等. 豆科绿肥间作对小青菜品质和土壤酶活性的影响. 上海大学学报（自然科学版）， 2019， 25（2）： 275-281.
13	He C M， Zhong S J， Yan J H， et al. Effect of Chinese milk vetch （Astragalus sinicus L.） as a green manure on grape productivity and quality， nutrient contents， and microbiologic properties of vineyard soils. Fujian Journal of Agricultural Sciences， 2018， 33（11）： 1151-1157.
	何春梅，钟少杰，严建辉，等. 紫云英翻压对葡萄产量品质与果园土壤理化性状及微生物量的影响. 福建农业学报， 2018， 33（11）： 1151-1157.
14	Zhou Q， Zhang X D， Ma S M， et al. Effects of intercropping green manure on soil carbon， nitrogen and soil microbial in rapeseed rhizosphere. Acta Ecologica Sinica， 2017， 37（23）： 7965-7971.
	周泉，张小短，马淑敏，等. 间作绿肥对油菜根际土壤碳氮及根际微生物的影响. 生态学报， 2017， 37（23）： 7965-7971.
15	Liu X F， Liu C Z， Pan Z L， et al. Effect of reducing chemical fertilizer when the green manure applied on soil nutrients， water retention and supply capacities. Soil and Fertilizer Sciences in China， 2017（3）： 75-79.
	刘小粉，刘春增，潘兹亮，等. 施用绿肥条件下减施化肥对土壤养分及持水供水能力的影响. 中国土壤与肥料， 2017（3）： 75-79.
16	Yu Q G， Ye J， Ma J W， et al. Effects of green manure planting on nitrogen and phosphorus runoff losses in mountainous orchard. Journal of Soil and Water Conservation， 2012， 26（2）： 6-10.
	俞巧钢，叶静，马军伟，等. 山地果园套种绿肥对氮磷径流流失的影响. 水土保持学报， 2012， 26（2）： 6-10.
17	Uribe N， Corzo G， Quintero M， et al. Impact of conservation tillage on nitrogen and phosphorus runoff losses in a potato crop system in Fuquene watershed， Colombia. Agricultural Water Management， 2018， 209： 62-72.
18	Zhu H Q. Effect of reduced nitrogen fertilizer and intercropping green manure on ramie yield. Wuhan： Huazhong Agricultural University， 2019.
	朱惠群. 减施氮肥与间作绿肥对苎麻产量的影响. 武汉：华中农业大学， 2019.
19	Wan S X， Tang S， Jiang G Y， et al. Effects of Chinese milk vetch manure and fertilizer on soil microbial characteristics and yield of rice. Acta Prataculturae Sinica， 2016， 25（6）： 109-117.
	万水霞，唐杉，蒋光月，等. 紫云英与化肥配施对土壤微生物特征和作物产量的影响. 草业学报， 2016， 25（6）： 109-117.
20	Tan J A， Li B T， Pan X H， et al. Effects of different winter-green manure on occurrence of diseases， insect pests，weeds of early rice and its yield. Chinese Agricultural Science Bulletin， 2015， 31（4）： 179-184.
	谭景艾，李保同，潘晓华，等. 冬种绿肥对早稻病虫草发生及产量的影响. 中国农学通报， 2015， 31（4）： 179-184.
21	Cao J K， Jiang W B， Zhao Y M. Experimental instruction of physiology and biochemistry of postharvest fruits and vegetables. Beijing： China Light Industry Press， 2020.
	曹建康，姜微波，赵玉梅. 果蔬采后生理生化实验指导. 北京：中国轻工业出版社， 2020.
22	Han X. Study on allelopathy of garlic stalk decomposition and identification of allelochemicals. Xianyang： Northwest A&F University， 2013.
	韩旭. 大蒜秸秆腐解物化感作用研究及化感物质鉴定. 咸阳：西北农林科技大学， 2013.
23	Liu Z H. Study on the effect of rape roots on post-harvest maize. Beijing： Chinese Academy of Agricultural Sciences， 2017.
	刘哲辉. 油菜根茬对后作玉米的增产作用研究. 北京：中国农业科学院， 2017.
24	Cao A C， Liu X M， Guo M X， et al. Incidences of soil-borne diseases and control measures. Plant Protection， 2017， 43（2）： 6-16.
	曹坳程，刘晓漫，郭美霞，等. 作物土传病害的危害及防治技术. 植物保护， 2017， 43（2）： 6-16.
25	Xu L Y. Effects of intercropping tea plantation with green manure on the green leafhopper and main natural enemies of pests. Fuzhou： Fujian Agriculture and Forestry University， 2013.
	许丽艳. 茶园间作不同绿肥对假眼小绿叶蝉和主要茶虫天敌的影响. 福州：福建农林大学， 2013.
26	Su Y， He Z C， Yang Y H， et al. Study on ecological grass control of green manure-wheat intercropping. Journal of Zhejiang Agricultural Sciences， 2019， 60（8）： 1280-1282.
	苏瑶，何振超，杨艳华，等. 绿肥-小麦套作生态控草技术初探. 浙江农业科学， 2019， 60（8）： 1280-1282.
27	Qu Y， Feng B L. Weed biological control technology： Research progress. Chinese Agricultural Science Bulletin， 2019， 35（4）： 108-115.
	屈洋，冯佰利. 杂草生物控制技术研究进展. 中国农学通报， 2019， 35（4）： 108-115.
28	Yang Y H， Zhang S， Wang S， et al. Yield and nutrient concentration in common green manure crops and assessment of potential for nitrogen replacement in different regions of China. Acta Prataculturae Sinica， 2020， 29（6）： 39-55.
	杨叶华，张松，王帅，等. 中国不同区域常见绿肥产量和养分含量特征及替代氮肥潜力评估. 草业学报， 2020， 29（6）： 39-55.
29	Niu H H. Studies of Vicia villosa allelopathy on four common forage in the seedling stage. Changsha： Hunan Agricultural University， 2019.
	牛欢欢. 光叶紫花苕子对4种牧草的化感作用研究. 长沙：湖南农业大学， 2019.
30	Zhang J Y. The allelochemical in exocarp of pecan and its herbicidal activity improving. Urumchi： Xinjiang Agricultural University， 2017.
	张金云. 山核桃外果皮化感物质及其除草活性的改进. 乌鲁木齐：新疆农业大学， 2017.
31	Tang S， Wang Y Q， Zhang Z， et al. Effects of multi-year milk vetch application on weed seed bank density and biodiversity in paddy field. Chinese Journal of Ecology， 2016， 35（7）： 1730-1736.
	唐杉，王允青，张智，等. 多年紫云英还田对稻田杂草种子库密度及多样性的影响. 生态学杂志， 2016， 35（7）： 1730-1736.
32	Zhuang Y， Zhao D G， Zhao Y C. Effect of water extract of cotton roots on allelopathy in Citrullus lanatus and Glycine max. Seed， 2019， 38（9）： 24-29.
	庄宇，赵德刚，赵懿琛. 棉花水浸提液对西瓜、大豆的化感作用研究. 种子， 2019， 38（9）： 24-29.
33	Wang Z， Liu L T， Sun H C， et al. Effect of cotton seeding growth and development by main allelochemicals in cotton humus. Acta Agriculture Boreali-Sinica， 2013， 28（S1）： 192-195.
	王曌，刘连涛，孙红春，等. 棉花腐殖质中主要化感物质对棉花幼苗生长发育的影响. 华北农学报， 2013， 28（S1）： 192-195.
34	Zhu Y S， Qi J C， Li J， et al. Effects of seed priming on soluble substances content and antioxidant enzymes activities in aged barley grains. Seed， 2019， 38（11）： 29-33.
	朱迎树，齐军仓，李剑，等. 引发对老化大麦种子可溶性物质及抗氧化酶活性的影响. 种子， 2019， 38（11）： 29-33.
35	Gu L. Allelopathy of Chrysanthemum morifolium extract on two kinds of monocotyledonous weeds and Camellia oleifera. Changsha： Central South University of Forestry and Technology， 2020.
	古龙. 黄菊浸提液对2种单子叶杂草及油茶的化感作用. 长沙：中南林业科技大学， 2020.

腐解天数 Decay days （d）	浓度 Concentration	发芽势 Germination potential	发芽率 Germination rate	发芽指数 Germination index	活力指数 Vital index	株高 Plant height	鲜重 Fresh weight	化感隶属累加值 RI accumulate value
2	CK	0.00	0.00	0.00	0.00	0.00	0.00	0.00
	2%	0.42	0.36	0.41	0.43	0.05	0.31	1.98
	5%	0.40	0.33	0.35	0.39	0.06	0.21	1.74
	30%	-0.55	-0.21	-0.49	-0.47	0.03	0.10	-1.57
	80%	-1.00	-0.94	-0.98	-0.99	-0.26	-0.64	-4.80
3	CK	0.00	0.00	0.00	0.00	0.00	0.00	0.00
	2%	0.20	0.19	0.20	0.34	0.18	0.30	1.39
	5%	-0.37	-0.32	-0.37	-0.22	0.19	0.28	-0.81
	30%	-0.91	-0.86	-0.91	-0.87	0.30	0.21	-3.03
	80%	-1.00	-1.00	-1.00	-1.00	-1.00	-1.00	-6.00
7	CK	0.00	0.00	0.00	0.00	0.00	0.00	0.00
	2%	0.00	-0.07	-0.10	0.08	0.17	0.38	0.46
	5%	-0.81	-0.19	-0.49	-0.38	0.18	0.07	-1.61
	30%	-1.00	-0.99	-1.00	-1.00	-1.00	-1.00	-5.99
	80%	-1.00	-1.00	-1.00	-1.00	-1.00	-1.00	-6.00
15	CK	0.00	0.00	0.00	0.00	0.00	0.00	0.00
	2%	-0.98	-0.48	-0.79	-0.77	0.09	0.01	-2.91
	5%	-1.00	-0.91	-0.99	-0.99	-0.02	-1.00	-4.91
	30%	-1.00	-1.00	-1.00	-1.00	-1.00	-1.00	-6.00
	80%	-1.00	-1.00	-1.00	-1.00	-1.00	-1.00	-6.00

腐解天数 Decay days （d）	浓度 Concentration	发芽势 Germination potential	发芽率 Germination rate	发芽指数 Germination index	活力指数 Vital index	株高 Plant height	鲜重 Fresh weight	化感隶属累加值 RI accumulate value
2	CK	0.00	0.00	0.00	0.00	0.00	0.00	0.00
	2%	0.42	0.36	0.41	0.43	0.05	0.31	1.98
	5%	0.40	0.33	0.35	0.39	0.06	0.21	1.74
	30%	-0.55	-0.21	-0.49	-0.47	0.03	0.10	-1.57
	80%	-1.00	-0.94	-0.98	-0.99	-0.26	-0.64	-4.80
3	CK	0.00	0.00	0.00	0.00	0.00	0.00	0.00
	2%	0.20	0.19	0.20	0.34	0.18	0.30	1.39
	5%	-0.37	-0.32	-0.37	-0.22	0.19	0.28	-0.81
	30%	-0.91	-0.86	-0.91	-0.87	0.30	0.21	-3.03
	80%	-1.00	-1.00	-1.00	-1.00	-1.00	-1.00	-6.00
7	CK	0.00	0.00	0.00	0.00	0.00	0.00	0.00
	2%	0.00	-0.07	-0.10	0.08	0.17	0.38	0.46
	5%	-0.81	-0.19	-0.49	-0.38	0.18	0.07	-1.61
	30%	-1.00	-0.99	-1.00	-1.00	-1.00	-1.00	-5.99
	80%	-1.00	-1.00	-1.00	-1.00	-1.00	-1.00	-6.00
15	CK	0.00	0.00	0.00	0.00	0.00	0.00	0.00
	2%	-0.98	-0.48	-0.79	-0.77	0.09	0.01	-2.91
	5%	-1.00	-0.91	-0.99	-0.99	-0.02	-1.00	-4.91
	30%	-1.00	-1.00	-1.00	-1.00	-1.00	-1.00	-6.00
	80%	-1.00	-1.00	-1.00	-1.00	-1.00	-1.00	-6.00