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1.
云南六库桔小实蝇成虫种群数量变动及其影响因子分析 总被引:11,自引:0,他引:11
应用诱蝇谜引诱剂诱捕法于2003-2005年调查了云南六库桔小实蝇成虫种群动态,系统分析了气候因子及寄主植物对该种群变动的影响。研究结果表明:云南六库桔小实蝇种群发生呈季节性,仅出现于3-12月,成虫消长基本为单峰型,高峰出现在7月。六库桔小实蝇种群数量与气温、降雨量和月雨日数等气象因子有密切关系。决定系数和通径分析结果显示,月降雨量是影响六库桔小实蝇种群动态的主要决策因素;月平均气温和月平均最低气温是影响种群数量变动的主要限制因素,其中,月平均最低温度是间接影响种群数量变动的重要指标。主成分分析筛选出低温条件主成分,其累积方差贡献率达77.65%。逐步回归分析也证实,影响六库桔小实蝇种群月变动的主要气象因子是月平均气温和月平均最低气温。综合分析认为,低温是导致六库桔小实蝇季节性发生的关键因素。 相似文献
2.
Annual monitoring of the population dynamics of the oriental fruit fly, Bactrocera dorsalis (Hendel) (Diptera: Tephritidae) using methyl eugenol-baited traps was conducted throughout the year during 1997, 2000, 2003 and 2004 in Ruili, Yunnan Province, China. Temperature, rainfall and host-plant species were analyzed with respect to population fluctuation of the fly. During the study periods the fruit fly occurred throughout the year. Its population remained low from November to January and increased steadily from February until it reached a peak in June. Afterwards, the population declined until October. The results of stepwise regression analysis indicated that monthly mean temperature, monthly mean maximum temperature, monthly mean minimum temperature, monthly extreme maximum temperature, monthly extreme minimum temperature, and monthly raining days were the major climatic factors influencing populations. Path and decision coefficient analyses indicated that the monthly mean temperature was the crucial factor influencing population fluctuation, the monthly mean minimum temperature was the crucial limiting factor indirectly influencing increase in population, and the comprehensive factors influencing fly population dynamics, namely, the monthly raining days were the strongest of all the other factors. Generally, the monthly mean temperatures fell within the ranges of temperatures suitable for development and reproduction of the fly. But the monthly mean minimum temperatures from November to January seemed to be lower and were suggested to be responsible for the low populations in this period. Monthly rainfall and rainy days steadily increased from February through June, and this explained the increase in population observed during this period. During periods of continuous heavy rain from July through August, the fruit fly population showed a remarkable decrease. Host plant species was another essential factor influencing the population fluctuations. Abundant fruit and melon species formed the food and breeding materials for the fly during the study periods. 相似文献
3.
分别于1997、2000、2003和2004年通过诱蝇谜对云南瑞丽桔小实蝇种群动态进行了全年监测,并就气候因子及寄主植物对该种群变动的影响进行了系统分析.结果表明,桔小实蝇在瑞丽常年发生,当年11月至翌年1月份,桔小实蝇种群处于较低水平,2月份以后种群数量逐渐上升,至6月份形成种群的年增长高峰,此后至10月份种群数量迅速下降.经逐步回归分析表明,月均温、月平均最高温、月平均最低温、月极端最高温、月极端最低温和月雨日数是影响瑞丽桔小实蝇种群月变动的主要气候因子.通径分析和决策系统分析表明,月均温对种群数量变动具有正效应,是直接影响桔小实蝇种群变动的重要指标,月均最低温是影响种群增长的最主要的限制因素,月雨日数对种群动态的综合影响力最大.瑞丽各月平均温度位于桔小实蝇各虫态生长发育温度范围内,但11~翌年1月份的月均最低温低于桔小实蝇的适温范围,对桔小实蝇种群数量有一定抑制作用.2~5月份雨日数逐渐增多,雨量逐渐增大,有利于种群数量增长;7~8月份持续的强降雨过程被认为是桔小实蝇在该时期种群数量下降的主要原因.而瑞丽的多种瓜果成熟期的交替出现保证了桔小实蝇的食物供应. 相似文献
4.
桔小实蝇Bactrocera dorsalis是芒果生产中的一种毁灭性害虫。本研究对2020-2022年云南元江县桔小实蝇的周年发生动态进行了监测,并分析了气象因子与该虫数量的相关性。结果表明,元江芒果园中桔小实蝇周年发生,总体呈现出种群数量冬季低、夏季高的规律。该地区桔小实蝇种群每年有2个快速增长期,3月种群数量快速增长,4-5月发生下降或增幅变缓,6月后种群数量再次快速增长,至7月达到发生高峰,后开始下降,到12月和次年1月为发生低谷。相关性分析表明,元江芒果园中桔小实蝇发生量与月均气温、月平均最高气温和平均最低气温呈正相关关系,月降水量、月日照时数、月平均相对湿度和月最小相对湿度对桔小实蝇的发生影响小。经逐步回归分析发现,月平均气温是影响桔小实蝇种群数量变化的最关键气象因子,这为元江县或相同气候区蔬菜瓜果等重要经济作物的桔小实蝇防控提供了理论依据。 相似文献
5.
云南元江干热河谷桔小实蝇种群动态及其影响因子分析 总被引:23,自引:3,他引:23
分别于1992、1998、2003和2004年在云南元江干热河谷通过性诱剂诱捕,对桔小实蝇雄性成虫数量变化进行了全年监测,并就气候因子及寄主植物对数量变动的影响进行了综合分析。桔小实蝇在元江干热河谷常年发生,当年12月至次年2月,桔小实蝇种群较低,3月以后逐渐上升,于6~8月形成增长高峰,9~11月种群迅速下降。近两年桔小实蝇种群数量较上世纪90年代明显增大。月均温、月均降雨量和寄主植物是影响元江桔小实蝇种群变动的主要因子。元江干热河谷各月均温在桔小实蝇适温区内,为其常年发生提供了温度条件。但12~2月的月平均最低温度低于桔小实蝇的适温下限,而5月的月平均最高温超过桔小实蝇的适温上限,这两方面对桔小实蝇种群均有一定抑制作用。元江夏季6至8月的月降雨量为100~150 mm,有助于桔小实蝇种群增长。芒果和甜橙是元江桔小实蝇最喜好的寄主水果,其种面积、挂果期是影响桔小实蝇种群变动的重要因素。气温、降雨和寄主植物通过各自的作用方式和发生时间综合影响着元江干热河谷地区桔小实蝇种群变动。 相似文献
6.
2002~2005年期间,在广东广州利用性引诱剂对桔小实蝇进行了全年种群动态监测,调查可知桔小实蝇可在广州全年发生.该虫数量从5月开始迅速上升,6~9月份是发生盛期;10月份虫口密度逐渐下降,11月到翌年3月份种群数量很低.对桔小实蝇发生数量和气象因子进行主成分分析和相关分析,结果表明温雨因子作用最大,其中月平均降雨量是影响桔小实蝇种群变动的关键因子;日照因子作用次之,但月总日照时数对该虫的发生数量没有显著影响. 相似文献
7.
桔小实蝇在中国云南省的分布(英文) 总被引:9,自引:0,他引:9
叶辉 《Entomologia Sinica》2001,(2)
在云南 1 2个县的诱捕试验表明 ,桔小实蝇在云南的分布可以划分为 3个区域。广南、元江和瑞丽以南的地区为该虫常年发生区。在该区域内 ,桔小实蝇年发生 4- 5代 ,可对瓜果形成周年危害。位于六库、大姚和曲靖以北的地区为该虫的非分布区。本试验未能在该地区诱捕到桔小实蝇或桔小实蝇受害果。位于上述两区域之间的区域为桔小实蝇季节性分布区。桔小实蝇在该地区年发生 2 - 3代 ,出现于 5- 1 1月。桔小实蝇在分布区内不同地区的发生高峰期 ,由南向北逐渐推移 ,如在景洪为 6月而在姚安为 1 0月。在地理垂直分布上 ,该虫主要分布于海拔 50 0 - 2 30 0m范围内 ,而其在 50 0 - 1 0 0 0m范围内发生量最大。研究认为 ,桔小实蝇在上述经度和海拔范围的发生与分布 ,主要与当地气候条件与寄主植物有关。 相似文献
8.
Annual monitoring of the population dynamics of the oriental fruit fly, Bactrocera dorsalis (Hendel) (Diptera: Tephritidae) using methyl eugenol-baited traps was conducted throughout the year during 1997, 2000, 2003 and 2004 in Ruili, Yunnan Province, China. Temperature, rainfall and host-plant species were analyzed with respect to population fluctuation of the fly. During the study periods the fruit fly occurred throughout the year. Its population remained low from November to January and increased steadily from February until it reached a peak in June. Afterwards, the population declined until October. The results of stepwise regression analysis indicated that monthly mean temperature, monthly mean maximum temperature, monthly mean minimum temperature, monthly extreme maximum temperature, monthly extreme minimum temperature, and monthly raining days were the major climatic factors influencing populations. Path and decision coefficient analyses indicated that the monthly mean temperature was the crucial factor influencing population fluctuation, the monthly mean minimum temperature was the crucial limiting factor indirectly influencing increase in population, and the comprehensive factors influencing fly population dynamics, namely, the monthly raining days were the strongest of all the other factors. Generally, the monthly mean temperatures fell within the ranges of temperatures suitable for development and reproduction of the fly. But the monthly mean minimum temperatures from November to January seemed to be lower and were suggested to be responsible for the low populations in this period. Monthly rainfall and rainy days steadily increased from February through June, and this explained the increase in population observed during this period. During periods of continuous heavy rain from July through August, the fruit fly population showed a remarkable decrease. Host plant species was another essential factor influencing the population fluctuations. Abundant fruit and melon species formed the food and breeding materials for the fly during the study periods. 相似文献
9.
YE Hui 《Insect Science》2001,8(2):175-182
Abstract The Oriental fruit fly, Bactrocera dorsalis Hendel (Diptera: Tephritidae), is a serious pest inaect for vegetables and fruits in Yunnan Province. The trap experiments located in 12 counties of Yunnan indicated that, the geographical distribution of Oriental fruit fly there could be plotted as three distribution zones. To the south of Guannan, Yuanjiang and Rulin is the annual distribution zone. In this region, the Oriental fruit fly completed 4–5 generations per year, and infested the local vegetables and fruits all the year around. To the north of Luku, Dayiao and Qujing is the zone without the insect, where the Oriental fruit fly was not trapped and no fruits infested by the fly were found during the present study. The region between the above two zones was the seasonal distribution zone for the insect. The fruit fly occurred only during May to December in this area, and completed 2–3 generations in this period. The peak abundance of the oriental fruit fly took place from June in Jinghong to October in Yiaoan, along the altitude graduates from the south to the north. In elevation, the Oriental fruit fly was trapped at altitude of 500–2300 m above sea level, in which high trap catches appeared between 500–1000 m. It is proposed that the variations of the fruit fly distribution in altitude and latitude are principally correlated with local temperatures and host plants. 相似文献
10.
光照、温度和湿度对桔小实蝇飞翔活动的影响 总被引:15,自引:1,他引:15
于2004年6月在云南元江芒果园内通过性诱剂诱捕,对桔小实蝇Bactrocera dorsalis(Hendel)的飞翔活动日节律进行了全天24h的监测,并就光照、温度和相对湿度3个环境因子的影响进行了测试和综合分析。研究表明,桔小实蝇雄成虫仅在白天有光照的情况下进行飞翔活动,夜晚停止飞翔。在1d内有2个飞翔活动高峰期,分别发生在上午8∶00~9∶00和下午18∶00~20∶00,且前者进行飞翔活动的虫量相对后者要大。在下午2∶00左右进入白天飞翔活动的低谷。光刺激是桔小实蝇飞翔活动的基本条件,其趋光性因芒果园内树荫下的光照强度变化而异,在100~200lux之间对桔小实蝇飞翔活动明显有利,而当光照强度低于100lux或高于200lux,飞翔活动也相应减小。气温总体上位于桔小实蝇飞翔活动的适宜范围,而下午低于60%的相对湿度对其飞翔活动有一定的抑制作用。气温、湿度和光照对桔小实蝇飞翔活动的作用机理各不相同并且各因子之间也相互作用,最终对桔小实蝇的飞翔活动产生综合效应。 相似文献
11.
12.
Toshinori Okuyama 《Ecological Entomology》2020,45(3):493-497
1. Variation in parasitism risk among hosts is a key factor influencing host–parasitoid interactions; however, within-patch variation (as opposed to between-patch variation) in parasitism risk has hardly been studied. This study investigated the mechanisms of within-patch variation in parasitism risk in the oriental fruit fly, Bactrocera dorsalis (Hendel) (Diptera: Tephritidae). 2. Bactrocera dorsalis pupates underground. Previous studies have shown that pupae at greater depths have a reduced risk of parasitism by a pupal parasitoid Dirhinus giffardii (Silvestri) (Hymenoptera: Chalcididae). When a pupa near the ground surface is parasitised, the victim may decrease the risk of parasitism risk for pupae located at deeper depths. It was hypothesised that larvae will pupate at greater depths when they perceive the presence of conspecifics because of the benefit of pupating deeper than other individuals. 3. In a series of laboratory experiments, the effects of three factors on pupation depth were examined, including: (i) the density of larvae during development; (ii) the density of concurrently burrowing larvae; and (iii) the presence of pre-existing pupae in the pupation substrate. Only the density of concurrently burrowing larvae influenced pupation depth, which suggests that when a burrowing larva perceives the presence of other burrowing larvae, it aims to burrow deeper than them. 4. This study shows not only that parasitism risk is variable among pupae within a patch, but also that it is density-dependent. A commonly made assumption (i.e. the absence of within-patch variability in parasitism risk) needs to be re-evaluated in a wide range of host–parasitoid systems. 相似文献
13.
《昆虫学报》2025,68(1)
【目的】基于线粒体基因组数据;明晰云南省橘小实蝇Bactrocera dorsalis种群遗传多样性和遗传结构;揭示其在云南的扩散路径;为橘小实蝇防控策略的制定和规划提供理论依据。【方法】2022年7-9月收集云南省橘小实蝇15个地理种群;使用DNBSEQ-T7平台进行线粒体基因组测序、组装与注释;基于13个蛋白质编码基因(protein-coding genes, PCGs)序列使用MEGA-X 10.0.5, DnaSP 6.12和Arlequin 3.5.2软件分析种群遗传多样性与遗传分化;基于13个PCG和COI序列使用最大似然法构建系统发育树;使用PopART4.8.4软件构建单倍型网络;通过中性检验和错配分布分析种群历史动态。【结果】共获得云南橘小实蝇15个地理种群149条线粒体全基因组;包含共1 697个变异位点;总体表现出高水平的遗传多样性(Pi=0.00783; K=87.591; Hd=0.9994);种群间遗传距离为0.00702~0.00874;遗传分化指数为-0.02345~0.05203;系统发育树和单倍型网络均未呈现出明显的种群结构;橘小实蝇云南种群历史上发生过扩张;云南西部和南部为橘小实蝇最早入侵区域;北部地区橘小实蝇入侵时间较晚。【结论】云南省橘小实蝇不同组群均呈现出高水平遗传多样性和弱遗传结构;线粒体基因组变异位点丰富且广泛分布在所有种群中;不同地理种群间没有明显分化;推测橘小实蝇由云南西部及南部向北部地区扩散。 相似文献
14.
植物源引诱物质可显著提高橘小实蝇Bactrocera dorsalis(Hendel)蛋白饵剂的应用效果,本文测试了柑橘、番木瓜、芒果、番石榴、杨桃的叶片浸提物、果实以及已知植物次生物质对橘小实蝇的引诱效果。植物浸提物的生物测定结果表明,杨桃的二氯甲烷浸提物的引诱效果最佳,平均引诱率为20.83%,对于不同的萃取剂而言,二氯甲烷、乙醇浸提物效果明显优于石油醚,三者浸提的平均引诱率分别为15.67%、15.17%和10.50%;对于不同寄主植物而言,柑橘浸提物的效果最佳,3种有机溶剂浸提物的平均引诱率为18.33%,其中石油醚、二氯甲烷和乙醇浸提物的引诱率分别为20.00%、15.83%和19.17%,其他植物浸提物的引诱效果为杨桃>番木瓜>芒果>番石榴,3种有机溶剂浸提物的平均引诱率分别为17.22%、11.67%、11.11%和10.56%。寄主果实的生物测定结果表明,柑橘的平均引诱率为65.83%,其中雌虫和雄虫的引诱率分别为61.67%和70.00%,明显高于杨桃、番石榴和番木瓜,三者的引诱率分别为31.67%、31.67%和21.67%,与柑橘引诱率差异显著(P<0.05)。已知植物次生物质的生物测定结果表明,甲基丁香酚的引诱效果最佳,平均引诱率为45.00%,其中雄虫和雌虫的引诱率分别为86.67%和3.33%;乙酸乙酯和番石榴香精的引诱效果次之,平均引诱率分别为32.50%和28.33%,其中雌虫的引诱率均为36.67%;杨桃香精和柠檬酸的引诱效果较差,平均引诱率分别为25.00%和26.67%。 相似文献
15.
Population dynamics of the oriental fruit fly, Bactrocera dorsalis (Diptera: Tephritidae) in the Kunming area,southwestern China 总被引:5,自引:0,他引:5
HUI YE JIAN-HONG LIU 《Insect Science》2005,12(5):387-392
Population dynamics of Bactrocera dorsalis Hendel (Diptera: Tephritidae) were studied through pheromone trapping over 4 years (1997, 1999, 2000, 2003) in the Kunming region, a high plateau area in southwestern China. B. dorsalis immigrates from southern Yunnan to Kunming each year, and occurs during early May through November. Annual trap captures recorded an increase in the B. dorsalis populations from May to July, when they peaked in abundance, and a decline until November. No flies were detected from November to April. The fruit flies had two generations. There was considerable overlapping due to the continuous arrival of immigrating flies during the summer months. Annual capture rates were significantly related to numbers of flies caught in July when peak captures were recorded; whereas the peak captures, in turn, positively depended on numbers of flies recorded in May, the first month of fly appearance in the current year. It suggested that the annual population abundance was mainly dependent on the size of the initial emigrating population. A daily average temperature of 18℃ was probably the threshold temperature required for the flies to undertake long-range dispersal, which partially explained the start of the fly in May each year on this high plateau. Under field conditions, the fruit flies can withstand 13℃ as a daily average temperature. No flies were recorded in any of the study years at a daily temperature colder than 10 ℃. 相似文献
16.
Relationship among five populations of Bactrocera dorsalis based on mitochondrial DNA sequences in western Yunnan, China 总被引:2,自引:0,他引:2
Genetic variation in the Oriental fruit fly, Bactrocera dorsalis (Hendel), was analysed using five populations from western Yunnan, China, to elucidate the distribution and likely dispersal patterns of this fly. A 503-bp portion of the mitochondrial cytochrome oxidase gene was sequenced from a minimum of seven individuals from each of five fly populations; 25 haplotypes were observed among 57 individuals in these populations. High genetic diversity within populations was detected. Genetic distances between haplotypes reached 1.2%. Mantel tests did not indicate any isolation because of geographic distance. The Ruili (RL) population was significantly isolated from the others (pairwise Fst ranging from 0.10 to 0.21, and average genetic distances being higher than for all other four population comparisons). RL is geographically separated from the other sites by the Gaoligong Mountains. The Liuku (LK) population had a close genetic relationship with the Lujiangba (LJB) population, suggesting that the LK population probably originated from LJB that is located in the same valley to the south. The Baoshan (BS) and Dali (DL) populations were also geographically isolated from the others, not originating from LJB and RL, where the fly is present year-round. The north-south orientation of mountains and valleys in western Yunnan appears to prevent latitudinal gene exchange by dispersing flies and thus divides the five populations into four relatively independent zones, namely BS, DL, LK-LJB and RL. In addition, air currents that generally flow south to north appear to assist dispersing flies, especially in valleys between the mountain chains. 相似文献
17.
云南西双版纳桔小实蝇种群动态 总被引:26,自引:1,他引:26
于1997年、2000年和2003年在云南西双版纳通过性诱剂诱捕对桔小实蝇种群动态进行了全年监测,并就气候因子及寄主种类对该种群变动的影响进行了系统分析.结果表明,桔小实蝇在西双版纳常年发生.当年11月至次年2月,桔小实蝇种群处于较低水平,3月以后种群数量逐渐上升,至6~7月形成一个种群增长高峰,此后至10月种群数量迅速下降.分析表明,影响桔小实蝇种群变化的重要因子是温度、降雨量和寄主种类.西双版纳各月均温位于桔小实蝇适温范围内,但12~2月的月平均最低温度低于桔小实蝇的适温范围,对桔小实蝇种群数量有一定抑制作用.降雨量是影响桔小实蝇种群数量变动的另一重要因子.月降雨量低于50 mm以下对桔小实蝇种群不利,而100~200 mm的月降雨量有助于桔小实蝇种群的增长.月降雨量大于250 mm以上将导致桔小实蝇种群数量下降.6~7月强降雨过程被认为是桔小实蝇在该时期种群数量下降的主要原因.芒果、番石榴、桃、梨、柑桔、龙眼和荔枝是桔小实蝇在该地区的主要寄主水果.其中,芒果和龙眼是当地桔小实蝇最喜好的寄主水果,其种植面积、挂果期和产量对桔小实蝇种群数量变动影响较大,被认为是影响该地区桔小实蝇种群变动的又一主要因素. 相似文献
18.
研究外来入侵害虫橘小实蝇及其寄生蜂在不同湿度条件下的存活与发育能力,以预测其在福建的适生分布区。结果表明:在25℃条件下,不同相对湿度对切割潜蝇茧蜂成蜂种群寿命影响大小依次为75%>95%>55%>35%,其中75%相对湿度下种群平均寿命最长,采用二次曲线模型并求得最适相对湿度为75.2%;不同相对湿度对橘小实蝇种群寿命的影响大小依次为75%>55%>95%>35%,采用二次曲线模型并求得最适相对湿度为68.7%,二者可能具有相似的分布区域。同时,从存活曲线分布的情况来看,切割潜蝇茧蜂在不同湿度下的存活曲线分布较橘小实蝇更集中,表明橘小实蝇对湿度的变化表现出更强的敏感性。同时,湿度低于35%时,不能交配并繁殖后代;处于较高湿度时,对其后代体形大小没有显著影响。 相似文献
19.
布氏潜蝇茧蜂对橘小实蝇幼虫寄生作用的研究 总被引:4,自引:0,他引:4
在试验室条件下研究了布氏潜蝇茧蜂Fopius vandenboschi(Fullaway)的寄生习性。结果表明:该寄生蜂嗜好寄生低龄的橘小实蝇幼虫;橘小实蝇幼虫的密度对布氏潜蝇茧蜂的寄生有明显的影响;被寄生的幼虫数随寄主自身密度的增加而增加,当寄主幼虫密度达每果片30只以上时,寄生数量的增加幅度就趋于下降,用Holling圆盘方程模拟为Na=0.9051N/(1 0.0163N)。此外,布氏潜蝇茧蜂的自身密度对寄生作用也有影响,随着寄生蜂数量的增加,寄生蜂的发现域逐渐变小,用Hassell-Varley方程表示为α=0.4655P-0.5807。 相似文献