棉花生境面积及其破碎化对烟粉虱种群的影响 *

doi:10.7679/j.issn.2095-1353.2020.01.011

应用昆虫学报 ›› 2020, Vol. 57 ›› Issue (1): 99-104.doi: 10.7679/j.issn.2095-1353.2020.01.011

棉花生境面积及其破碎化对烟粉虱种群的影响 ^*

宋海燕¹(), 李丽莉¹, 李超¹, 欧阳芳³, 于毅¹, 卢增斌²^,^***(), 门兴元¹^,^***()

1. 山东省农业科学院植物保护研究所,济南 250100
2. 山东省农业科学院玉米研究所,小麦玉米国家工程实验室,农业农村部黄淮海北部玉米生物学与遗传育种重点实验室,济南 250100
3. 中国科学院动物研究所,北京 100101

收稿日期:2019-12-20 接受日期:2020-01-10 出版日期:2020-01-31 发布日期:2020-07-03
通讯作者: 卢增斌,门兴元 E-mail:shy_810903@126.com;luzengbin12345@163.com;menxy2000@hotmail.com
基金资助:
国家重点研发计划(2017YFD0201900);国家自然科学基金项目(31800349);山东省农业科学院农业科技创新工程(CXGC2019G01)

Effects of varying the proportion of cotton habitat area and their fragmentation on the abundance of Bemisia tabaci

Hai-Yan SONG¹(), Li-Li LI¹, Chao LI¹, Fang OUYANG³, Yi YU¹, Zeng-Bin LU²^,^***(), Xing-Yuan MEN¹^,^***()

1. Institute of Plant Protection, Shandong Academy of Agricultural Sciences, Jinan 250100, China
2. Maize Research Institute, Shandong Academy of Agricultural Sciences, National Engineering Laboratory of Wheat and Maize, Key Laboratory of Biology and Genetic Improvement of Maize in Northern Yellow-Huai River Plain, Ministry of Agriculture and Rural Affairs, China, Jinan 250100, China
3. Institute of Zoology, Chinese Academy of Sciences, Beijing 100101, China

Received:2019-12-20 Accepted:2020-01-10 Online:2020-01-31 Published:2020-07-03
Contact: Zeng-Bin LU,Xing-Yuan MEN E-mail:shy_810903@126.com;luzengbin12345@163.com;menxy2000@hotmail.com

摘要/Abstract

摘要：

【目的】 阐明棉花生境面积变化及其破碎化对烟粉虱Bemisia tabaci 种群的作用规律,为合理利用作物布局进行害虫生态调控提供理论支撑。【方法】 采用国际流行的微景观试验模型系统（Experimental model landscape system,EMLS）进行试验设计,田间条件下连续两年研究了棉花生境面积变化（20%、40%、60%、80%和100%;其他为玉米生境面积）及2种极端破碎化（完全连通C clumped：H=1.0;完全破碎F fragmented：H=0.0）下烟粉虱种群数量变化,采用广义线性模型（GLM）分析各因素对烟粉虱种群数量的影响。【结果】 棉花生境面积及其破碎化单独作用时均对烟粉虱种群数量无显著影响,而取样时间则有显著影响。烟粉虱种群数量也没有受到取样时间与棉花生境面积、取样时间与破碎化以及三者交互作用的显著影响。但是,棉花生境面积与破碎化的互作效应则存在年度变化,2014年无显著作用,2015年显著影响烟粉虱种群。当棉花生境面积较小（20%）或较大（80%）时,破碎化程度高,烟粉虱种群数量少;棉花生境面积中等（40%和60%）时,破碎化程度低,烟粉虱种群数量少。【结论】烟粉虱种群对棉花生境面积变化有较强的适应性,而生境破碎化只能在一定程度上产生影响。

关键词: 棉花生境面积, 破碎化, 烟粉虱, 生态调控

Abstract:

[Objectives] To determine the effects of varying the proportion of cotton habitat area and their fragmentation on Bemisia tabaci populations and thereby investigate the effectiveness of controlling insect pests by changing crop planting patterns. [Methods] The experimental model landscape system (EMLS) was adopted to assess the effects of varying the proportion of cotton habitat area (20%, 40%, 60%, 80%, 100%), and of two levels of fragmentation (C clumped: H = 1.0; F fragmented: H = 0.0), on B. tabaci populations in a 2-year field trial. A generalized linear model (GLM) was used to analyze the effects of various factors on B. tabaci populations. [Results] The proportion of cotton habitat area and the level of fragmentation had no significant effects on B. tabaci populations, whereas survey time had a significant effect. B. tabaci abundance was also not significantly affected by the interactions between survey time and cotton habitat area, survey time and fragmentation, and among these three variables. However, the significance of the interaction between cotton habitat area and fragmentation depended on the year, with no significant effects in 2014 and significant effects in 2015. When the area planted in cotton was 20% or 80%, B. tabaci abundance was lower if there was a high degree of fragmentation. However, when the area planted in cotton was 40% and 60%, B. tabaci abundance was lower with less fragmentation. [Conclusion] B. tabaci can adapt to different proportions of cotton habitat area and the effects of fragmentation were subtle.

Key words: cotton habitat area, fragmentation, Bemisia tabaci, ecology-control

宋海燕, 李丽莉, 李超, 欧阳芳, 于毅, 卢增斌, 门兴元. 棉花生境面积及其破碎化对烟粉虱种群的影响 ^*[J]. 应用昆虫学报, 2020, 57(1): 99-104.

Hai-Yan SONG, Li-Li LI, Chao LI, Fang OUYANG, Yi YU, Zeng-Bin LU, Xing-Yuan MEN. Effects of varying the proportion of cotton habitat area and their fragmentation on the abundance of Bemisia tabaci[J]. Chinese Journal of Applied Entomology, 2020, 57(1): 99-104.

图/表 4

图1 试验区棉花和玉米生境种植格局设计图中数字代表每小区内棉花生境面积种植比例（0、20%、40%、60%、80%和100%）,其余为玉米生境面积。C和F代表破碎化程度的2个极端,即完全连通（C clumped：H=1.0）和完全破碎（F fragmented：H=0.0）。

Fig. 1 Patch structre and pattern of cotton and maize crops in experimental fields The number in the Fig.1 represents the proportion of cotton planting area in each plot, and the rest is maize planting area. C and F mean two levels of extreme fragmentation (C clumped: H = 1.0; F fragmented: H = 0.0).

表1 各因素对烟粉虱种群影响的统计分析结果

Table 1 The statistical results of the effects of cotton habitat area, fragmentation and survey times on Bemisia tabaci population

因子Factor	2014			2015
因子Factor	χ²	df	P	χ²	df	P
棉花生境面积Cotton habitat area	3.85	4	0.43	5.13	4	0.28
破碎化Fragmentation	0.44	1	0.51	0.02	1	0.88
调查时间Survey times	581.24	5	0.00	331.91	4	0.00
棉花生境面积×破碎化 Cotton habitat area×Fragmentation	1.27	3	0.74	9.22	3	0.03
棉花生境面积×调查时间 Cotton habitat area×Survey times	24.78	20	0.21	13.94	16	0.60
破碎化×调查时间Fragmentation×Survey times	3.17	5	0.67	0.59	4	0.96
棉花生境面积×破碎化×调查时间 Cotton habitat area×Fragmentation×Survey times	3.16	15	0.99	17.90	12	0.12
截距Intercept	10 941.89	1	<0.000 1	20 140.15	1	<0.000 1

图2 2014年不同处理烟粉虱种群数量动态 A-F分别代表7月8日、7月26日、8月6日、8月19日、9月2日和9月24日。

Fig. 2 Population dynamics of Bemisia tabaci in different treatments in 2014 A-F mean 8 July, 26 July, 6 Aug., 19 Aug., 2 Sep. and 24 Sep., respectively.

图3 2015年不同处理烟粉虱种群数量动态 A-E分别代表7月16日、7月31日、8月10日、8月20日和9月8日。

Fig. 3 Population dynamics of Bemisia tabaci in different treatments in 2015 A-E mean16 July, 31 July, 10 Aug., 20 Aug., 8 Sep., respectively.

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棉花生境面积及其破碎化对烟粉虱种群的影响 ^*

Effects of varying the proportion of cotton habitat area and their fragmentation on the abundance of Bemisia tabaci

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