智利小植绥螨密度对朱砂叶螨产卵能力的影响

智利小植绥螨是朱砂叶螨的专性捕食者。本研究在室内,研究了智利小植绥螨密度对朱砂叶螨存活及生殖的影响。智利小植绥螨对朱砂叶螨存活干扰结果表明:干扰后24 h各处理朱砂叶螨的死亡率均显著高于对照,且死亡率随干扰密度增大而提高,10头捕食螨/叶碟处理高达76.67%,为对照处理的14.38倍。但是干扰48 h后对叶螨存活影响不大。对朱砂叶螨产卵干扰结果表明:干扰后各时间段朱砂叶螨单雌产卵量均随智利小植绥螨干扰密度的增加而降低。干扰24 h后,除1头捕食螨/叶碟处理与对照差异不显著外,其他各处理均与对照有显著差异。干扰48 h后,10头捕食螨/叶碟处理的叶螨单头产卵量是2.80粒,仅为对照的28.5%。但是干扰96h后,除10头捕食螨/叶碟处理与对照差异显著外,其余各处理与对照均差异不显著。本研究还分析了干扰对96 h内朱砂叶螨单雌总产卵量影响,处理5头/叶碟和10头/叶碟均显著低于对照,并且10头/叶碟显著低于5头/叶碟;1头/叶碟和3头/叶碟与对照相当,但是均显著高于10头/叶碟。结果显示,智利小植绥螨密度对朱砂叶螨有较强的生殖干扰作用,并且捕食螨密度越大,干扰作用越强,后代增殖潜能越小。     

智利小植绥螨对茄子二斑叶螨控制效果研究

【目的】明确智利小植绥螨Phytoseiulus persimilis对茄子上二斑叶螨Tetranychus urticae的控制效果,探索智利小植绥螨控制茄子二斑叶螨的最优释放数量。【方法】在1︰10、1︰30和1︰50不同益害比及10、30和60头/叶二斑叶螨不同猎物密度下,研究了智利小植绥螨捕食二斑叶螨的效果以及智利小植绥螨的增殖率。【结果】随智利小植绥螨释放比例的提高,防治效率明显提高,益害比1︰10、1︰30和1︰50的防效分别在释放后第14、22和26天达100%;在不同猎物密度下,按益害比1︰30释放智利小植绥螨,防效均随时间延长而提高,且6 d后不同猎物密度下防效差异不明显,第20天时3种密度下的防效均达100%,表明其捕食作用受到益害比影响较大而受猎物密度影响不明显。随着捕食螨释放比例的降低和二斑叶螨密度的提高,智利小植绥螨的增殖率增加,在益害比为1︰50、二斑叶螨种群密为60头/叶时,智利小植绥螨的最高增殖率分别达643%和893%,表明智利小植绥螨具有较高的种群增殖力。【结论】智利小植绥螨对茄子二斑叶螨具有较好的防控效果,推荐在二斑叶螨发生早期时按益害比1︰10~1︰30释放智利小植绥螨,以保证较快的防控效果和较少的捕食螨释放量。     

联苯肼酯对智利小植绥螨的安全性及二者对二斑叶螨的联合控制作用

【目的】评价联苯肼酯对智利小植绥螨Phytoseiulus persimilis的安全性,以及该药剂与捕食性天敌智利小植绥螨联合使用的效果。【方法】采用室内生物测定与田间试验的方法测定了联苯肼酯对智利小植绥螨成螨和若螨致死率与繁殖能力的影响,以及二者联合使用对茄子上二斑叶螨的控制效果。【结果】结果表明143 mg/L联苯肼酯对智利小植绥螨成螨和若螨的存活和生殖能力均无显著影响,处理后96 h对若螨的最高致死率为2.30%,成螨为2.04%;处理组8 d的平均产卵量为15.08粒/雌,与对照平均产卵量15.45粒/雌无显著差异;处理组所产卵的平均孵化率为98.63%,与对照组平均孵化率98.13%无显著差异;联苯肼酯悬浮剂在143 mg/L浓度下对二斑叶螨的控制效果表现为速效性高于单独使用智利小植绥螨,但持效性低于智利小植绥螨,防效在第22天时开始下降。二者联合使用表现出较好的速效性与持效性,处理后第2天防效达97.35%,第18天时达100%。【结论】联苯肼酯对智利小植绥螨具有极高的安全性,该药剂与智利小植绥螨联合使用对二斑叶螨具有良好的控制效果。     

中国植绥螨规模化饲养及保护利用研究进展

根据植绥螨食性的不同 ,可以采用叶螨、花粉和人工饲料等食物来培养植绥螨。规模化饲养植绥螨多用叶螨等害螨的寄主植物先繁殖害螨 ,然后在害螨中加入一些补充食物来大量生产植绥螨。张艳璇设计的袋栽法就是这样一套新的大量繁殖植绥螨的工艺方法。植绥螨的贮存目前都采用降低发育来实现 ,一般在 5～ 1 0℃的温度下能保存 5 0d以上。在田间按一定的比例释放抗药性的植绥螨 ,能够有效的控制二斑叶螨TetranychusurticaeKoch等害螨的发生。并且在地面鼓励种植覆盖作物、允许少量杂草生长或实行生草栽培 ,能够为植绥螨提供交替食物 ,从而更好地发挥生态控制功能的作用。     

拟小食螨瓢虫捕食六点始叶螨的初步观察

在室内以六点始叶螨Eotetranychus sexmaculatus(Riley)为猎物观察了拟小食螨瓢虫Stethorusparapauperculus Pang的发育历期、捕食量、捕食作用及干扰效应。研究结果表明:拟小食螨瓢虫取食六点始叶螨时完成一个世代需23.2 d,幼虫1～4龄的捕食量分别为9.5、14.5、19.5、64.2头六点始叶螨成螨;成虫期对六点始叶螨成螨的捕食量高达880.4头,拟小食螨瓢虫对六点始叶螨的捕食作用符合HollingⅡ方程,拟合的模型方程为Na=1.3843 N/(1+0.0231N),日均最大捕食量为43.29头;拟小食螨瓢虫的捕食率与个体间的干扰效应用Hassell-Varley(1959)模型拟合为E=0.4690P-0.5470。     

广东伊绥螨属一新种（蜱螨亚纲：植绥螨科）

本文记述了植绥螨科伊绥螨属一个新种广东伊绥螨Iphiseius guangdongensis sp.nov.,对该种的形态作了详细的描述,并与它的近似种进行了比较。     

中国植绥螨的研究应用

植绥螨是农业生产中极具价值的生防作用物.本文综述了四十年来我国在植绥螨种类调查、饲养繁殖、保护及释放利用等方面取得的成果及存在的一些问题,并展望了植绥螨研究应用的发展前景.     

尼氏钝绥螨对柑桔始叶螨捕食作用研究

尼氏钝梁螨AmblyseiusnicholsiEharaetLee是贵州省桔园叶螨天敌优势种,对抑制叶螨种群有一定作用。关于保护利用该螨综合防治柑桔全爪螨已有报道[1,2],但对柑桔上男一重要叶螨──柑桔始叶螨的捕食作用、控制能力等方面报道较少。本文研究了尼氏纯绥螨对柑桔给叶螨捕食作用,为柑桔始叶螨综合治理提供理论依据。王材料和方法1．1虫源：尼氏钝绥做雄成螨和柑桔始叶绒成螨采自桔园。卵、幼螨、若螨均在室内饲养而得。1．2反应皿设置：在直径为12cm的培养皿内置一层浸水的泡沫,上面平铺1张滤纸,其上放1张平展的柑桔叶片,叶片四周用浸过…     

加州新小绥螨在不同温度下对 六点始叶螨的捕食效能

为明确加州新小绥螨对橡胶六点始叶螨的控害潜能,系统研究了21℃、24℃、27℃、30℃、33℃5个不同温度条件下加州新小绥螨对六点始叶螨各螨态的捕食效能和自身密度干扰效应。结果表明:加州新小绥螨对六点始叶螨若螨、幼螨和卵的选择系数分别为0.71、1.75和0.54。在21℃～33℃条件下,加州新小绥螨对不同螨态六点始叶螨的功能反应均能很好地拟合Holling-II型圆盘方程,其对六点始叶螨雌成螨、若螨、幼螨的捕食效能(a/Th)在30℃时最强,分别达19.91、44.90、189.45头/d,对叶螨卵的捕食能力在不同温度间差异不显著。在同一温度条件下,加州新小绥螨对不同螨态六点始叶螨的捕食量大小依次为:幼螨若螨成螨卵。在相同的猎物密度条件下,加州新小绥螨的捕食作用率随其自身密度的增加而逐渐降低,说明加州新小绥螨存在种内竞争和自我干扰作用,自身干扰系数为0.349。     

不同猎物及密度对巴氏新小绥螨和拉戈钝绥螨同类相残和集团内捕食作用的影响

明确不同猎物及密度下巴氏新小绥螨Neoseiulus barkeri与拉戈钝绥螨Amblyseius largoensis(Muma)的同类相残和集团内捕食作用,为其协同应用控制橡胶树害螨提供依据.在室温27±1℃、湿度75％±5％、光周期12 L∶12D 条件下,以六点始叶螨 Eotetranvchus sexmaculatus(Riley)、比哈小爪螨Oligonychus biharen(Hirst)和东方真叶螨Eutetranychus orientalis(klein)为集团外猎物,观察巴氏新小绥螨和拉戈钝绥螨对集团内和集团外猎物的捕食选择行为,以及不同集团外猎物密度下两种捕食螨对同种和异种捕食螨的捕食作用.巴氏新小绥螨和拉戈钝绥螨对异种个体及集团外不同猎物的捕食偏好性及捕食时间存在明显差异.巴氏新小绥螨偏好取食集团外猎物,异种捕食螨拉戈钝绥螨残存率达到80.00％以上;拉戈钝绥螨偏好取食集团外猎物六点始叶螨和比哈小爪螨,而当东方真叶螨存在时,其更偏好取食异种捕食螨巴氏新小绥螨(残存率为26.67％);发生集团内捕食时,拉戈钝绥螨为集团内捕食者,而巴氏新小绥螨为集团内猎物.集团外猎物密度可显著影响巴氏新小绥螨和拉戈钝绥螨相残作用,尤以猎物六点始叶螨对巴氏新小绥螨和东方真叶螨对拉戈钝绥螨影响最为明显,其充足时比无猎物时捕食量分别下降了 68.85％和62.90％.巴氏新小绥螨和拉戈钝绥螨的集团内捕食分别以比哈小爪螨和六点始叶螨的影响最大,猎物充足时比无猎物时捕食量下降了 80.00％和69.44％,但拉戈钝绥螨在以东方真叶螨为猎物时集团内捕食受猎物密度影响较小,猎物充足时取食量与猎物不足时接近,比无猎物时捕食量只下降20.83％.集团外猎物六点始叶螨、比哈小爪螨存在时,巴氏新小绥螨和拉戈钝绥螨表现为偏好选择集团外猎物,密度增加对两种植绥螨的同类相残和集团内捕食作用有明显抑制作用,但东方真叶螨充足与否,拉戈钝绥螨对巴氏新小绥螨的集团内捕食作用影响差异不显著.     

Beat sampling accuracy in estimating spruce spider mite (Acari: Tetranychidae) populations and injury on juniper

The use of a standardized beat sampling method for estimating spruce spider mite, Oligonychus ununguis (Jacobi) (Acari: Tetranychidae), densities on a widely used evergreen ornamental plant species, Juniperus chinensis variety 'Sargentii' A. Henry (Cupressaceae), was examined. There was a significant positive relationship between total spruce spider mite densities and spider mite densities from beat sampling on juniper. The slope and intercept of the relationship may be used by pest managers to predict total spider mite densities on plants from beat sample counts. Beat sampling dramatically underestimates the total number of spider mites on a foliage sample. The relationships between spruce spider mite feeding injury and spider mite density estimates from beat sampling juniper foliage and total spider mite counts on foliage were also examined. There was a significant positive relationship between spruce spider mite density as estimated from beat sampling and injury to the plants. There was a similar positive relationship between the total number of spruce spider mites and injury to the plants, suggesting that a pest manager could use beat sampling counts to estimate plant injury and related thresholds. These findings have important implications to decision-making for spruce spider mite control, especially as it relates to threshold levels and determining rates of predator releases. Further assessment of the effectiveness of beat and other sampling methods across multiple spider mite- host plant associations needs to be examined to enable pest managers to select sampling plans that are feasible and reliable.     

Aesthetic damage thresholds for twospotted spider mites (Acari: Tetranychidae) on impatiens: effect of plant age and level of infestation

The effects of plant age and infestation level of twospotted spider mite, Tetranychus urticae Koch (Acari: Tetranychidae), on visible plant damage, and the effect of plant age on spider mite population growth on impatiens, Impatiens wallerana Hook.f. (Ericales: Balsaminaceae), were determined by inoculating impatiens plants of three different ages with two densities of spider mites. Each plant was inoculated with either one adult female mite per three leaves or six leaves based on the average number of leaves on plants of each of the three age classes. Subsequently, leaf damage was correlated with mite-days (cumulative spider mite density) per leaf. The results showed that older aged plants exhibited greater damage than younger plants. Regression models of damage thresholds for each plant age suggest that monitoring for spider mites must be done periodically throughout the entire plant production cycle, but that more attention should be given toward the end of the cycle. Measurements of visible leaf damage were correlated with plant marketability. Specifically, the level of damage (proportion of damaged leaves per plant) at which plant marketability changes from a "premium" to a "discounted" category was 0.04-0.06. Thus, regression equations of the damage threshold could be used to estimate a cumulative spider mite density or mite-days equivalent to the economic threshold. Based on these equations, 5% leaf damage corresponds to 2.1, 1.51, and 1.25 mite-days for youngest, intermediate, and oldest plants, respectively. Because the damage threshold on impatiens was shown to be very low, the action threshold for biological control is essentially zero, and predators would need to be released as soon as damage is observed.     

Euseiusfinlandicus (Acari: Phytoseiidae) as a potential biocontrol agent against Tetranychus urticae (Acari: Tetranychidae): life history and feeding habits on three different types of food

Life history and reproductive parameters of the generalist predatory mite Euseius (Amblyseius) finlandicus (Oudemans) were studied in the laboratory at 25 +/- 1 degrees C, with a 16L:8D photoperiod and 60 +/- 15% RH, to investigate its response to different food sources: an eriophyid mite Aceria sp., tulip pollen Tulipa gesnerana L., and two-spotted spider mite Tetranychus urticae Koch. Total developmental time of the immature stages was the shortest on eriophyid mites, followed by pollen, and then spider mites. Fecundity was highest on pollen (43.69 eggs; 1.63 eggs/female/day), then eriophyid mites (39.73 eggs; 1.37 eggs/female/day) and lowest on spider mites (18.16 eggs; 0.80 eggs/female/day). Intrinsic rate of increase (Rm), net reproductive rate (Ro) and finite rate of increase (lambda) followed the same pattern [pollen (0.168, 27.96 and 1.183, respectively), eriophyid mites (0.153, 20.81 and 1.167), spider mites (0.110, 9.44 and 1.119)]. Mean generation time (days) was the shortest on pollen (19.90), followed by eriophyid mites (20.02), and then spider mites (20.59). Average spider mite larvae consumed by E. finlandicus during immature stages were 9.18 for males and 11.85 for females. Adult E. finlandicus females consumed an average of 166.38 spider mite protonymphs during adult stage compared to an average of 66.55 by males. The number of prey protonymphs consumed per day by females was highest in the oviposition period, lower in the pre-oviposition period and the lowest in the post-oviposition period. The eriophyid mite as a prey recorded the shortest developmental time, while pollen as food recorded the highest oviposition rate in E. finlandicus. The potential of this predator as a biocontrol agent against T. urticae is discussed.     

Allocating time between feeding, resting and moving by the two-spotted spider mite, Tetranychus urticae and its predator Phytoseiulus persimilis

This study characterizes the timing of feeding, moving and resting for the two-spotted spider mite, Tetranychus urticae Koch and a phytoseiid predator, Phytoseiulus persimilis Athias-Henriot. Feeding is the interaction between T. urticae and plants, and between P. persimilis and T. urticae. Movement plays a key role in locating new food resources. Both activities are closely related to survival and reproduction. We measured the time allocated to these behaviours at four ages of the spider mite (juveniles, adult females immediately after moult and adult females 1 and 3 days after moult) and two ages of the predatory mite (juveniles and adult females). We also examined the effect of previous spider mite-inflicted leaf damage on the spider mite behaviour. Juveniles of both the spider mite and the predatory mite moved around less than their adult counterparts. Newly emerged adult female spider mites spent most of their time moving, stopping only to feed. This represents the teneral phase, during which adult female spider mites are most likely to disperse. With the exception of this age group, spider mites moved more and fed less on previously damaged than on clean leaves. Because of this, the spider mite behaviour was initially more variable on damaged leaves. Phytoseiulus persimilis rested at all stages for a much larger percentage of the time and spent less time feeding than did T. urticae; the predators invariably rested in close proximity to the prey. Compared to adult predators, juveniles spent approximately four times as long handling a prey egg. The predator-prey interaction is dependent upon the local movement of both the predators and prey. These details of individual behaviours in a multispecies environment can provide an understanding of population dynamics.     

Population density and phenology of Tetranychus urticae (Acari: Tetranychidae) in hop is linked to the timing of sulfur applications

The twospotted spider mite, Tetranychus urticae Koch, is a worldwide pest of numerous agronomic and horticultural plants. Sulfur fungicides are known to induce outbreaks of this pest on several crops, although mechanisms associated with sulfur-induced mite outbreaks are largely unknown. Studies were conducted during 2007-2009 in Oregon and Washington hop yards to evaluate the effect of timing of sulfur applications on T. urticae and key predators. In both regions, applications of sulfur made relatively late in the growing season (mid-June to mid-July) were associated with the greatest exacerbation of spider mite outbreaks, particularly in the upper canopy of the crop. The severity of mite outbreaks was closely associated with sulfur applications made during a relatively narrow time period coincident with the early exponential phase of spider mite increase and rapid host growth. A nonlinear model relating mean cumulative mite days during the time of sulfur sprays to the percent increase in total cumulative mite days (standardized to a nontreated plot) explained 58% of the variability observed in increased spider mite severity related to sulfur spray timing. Spatial patterns of spider mites in the Oregon plots indicated similar dispersal of motile stages of spider mites among leaves treated with sulfur versus nontreated leaves; however, in two of three years, eggs were less aggregated on leaves of sulfur-treated plants, pointing to enhanced dispersal. Apart from one experiment in Washington, relatively few predatory mites were observed during the course of these studies, and sulfur-induced mite outbreaks generally occurred irrespective of predatory mite abundance. Collectively, these studies indicate sulfur induces mite outbreaks through direct or indirect effects on T. urticae, mostly independent of predatory mite abundance or toxicity to these predators. Avoidance of exacerbation of spider mite outbreaks by sulfur sprays was achieved by carefully timing applications to periods of low spider mite abundance and slower host development, which is generally early to mid-spring for hop.     

An ecosystem analysis of spider mite outbreaks: physiological stimulation or natural enemy suppression

A simulation model was used to assess the role of several mechanisms proposed to be responsible for spider mite outbreaks on cotton that are typically observed following applications of insecticides. Simulation results were compared to an outbreak that occurred after two pyrethroid applications on cotton in a controlled experiment in the San Joaquin Valley of California. In the model, physiological effects were simulated by increasing spider mite fecundity and decreasing developmental duration, whereas loss of natural enemies was simulated by increasing spider mite age-specific survival. At the levels simulated, survival had the greatest impact on maximum spider mite density, degree days (^oD) to maximum density, and cumulative spider mite-^oD, whereas fecundity had the least, and developmental duration had an intermediate effect. There were substantial two-way interactions among all three life history parameters, with age-specific survival having the most influence. Survival had the greatest effect on spider mite population dynamics when in combination with short developmental duration. The influence of developmental duration on maximum spider mite density was greater than comparable percentage changes in fecundity, an effect that was more pronounced at high than at low survival. Changing fecundity, developmental duration, or age-specific survival individually did not result in a spider mite outbreak of the magnitude observed in the field. However, changing these three parameters simultaneously, resulted in a simulated maximum density of 8,000/m², which represents a 12-fold increase over the untreated control, and closely mimicked the previously observed field outbreak. It is proposed that spider mite outbreaks on cotton following insecticide applications are not solely the result of physiological stimulation, but are rather due to several life history parameters being affected simultaneously, with natural enemy-mediated survival having the greatest individual impact. Implications of chemically-induced phenomena affecting spider mite management on cotton are discussed. A copy of the crop and herbivore simulation models can be obtained by sending an IBM compatible disk to L. T. Wilson.     

The microbiota in spider mite feces potentially reflects intestinal bacterial communities in the host

Microorganisms provide many physiological functions to herbivorous hosts. Spider mites (genus Tetranychus) are important agricultural pests throughout the world; however, the composition of the spider mite microbial community, especially gut microbiome, remains unclear. Here, we investigated the bacterial community in five spider mite species and their associated feces by deep sequencing of the 16S rRNA gene. The composition of the bacterial community was significantly different among the five prevalent spider mite species, and some bacterial symbionts showed host‐species specificity. Moreover, the abundance of the bacterial community in spider mite feces was significantly higher than that in the corresponding spider mite samples. However, Flavobacterium was detected in all samples, and represent a “core microbiome”. Remarkably, the maternally inherited endosymbiont Wolbachia was detected in both spider mite and feces. Overall, these results offer insight into the complex community of symbionts in spider mites, and give a new direction for future studies.     

酢浆草如叶螨研究概述

酢浆草如叶螨Tetranychina harti(Ewing)是一种世界性分布的叶螨,在国内18个省市区也有分布。它取食酢浆草属植物,尤以危害红花酢浆草和酢浆草为甚,严重影响园林景观,是重要的园林和草坪害虫。文章根据国内外全面的资料,详细地介绍该螨的分类、形态特征、分布、遗传学、生物学、生态学和综合治理等方面的最新研究进展,旨在帮助国内昆虫工作者清楚地了解和有效地防治该螨。     

Effects of soil moisture and temperature on reproduction and development of twospotted spider mite (Acari: Tetranychidae) in strawberries

The effects of soil moisture and temperature on the reproduction of twospotted spider mite, Tetranychus urticae Koch (Acari: Tetranychidae), were examined in laboratory and field tests in strawberries, Fragaria x ananassa Duchesne, in Florida. Different soil moisture levels (low, moderate, and high) were compared to determine how soil moisture affects the reproduction and development of twospotted spider mite. In addition to soil moisture, different irrigation techniques (drip versus drip/overhead) were compared to determine their effects on twospotted spider mite reproduction as well as the incidence of angular leaf spot, Xanthomonas fragaria Kennedy & King disease. Similar studies were conducted to determine how different temperatures (18, 27, and 35 degrees C) affect the reproduction and development of twospotted spider mites. In the laboratory, low soil moisture as well as temperatures >27 degrees C promoted twospotted spider mite development. A similar trend was observed in a field study with low soil moisture promoting twospotted spider mite reproduction during the early season (11 November--8 December). Irrespective of moisture levels, a significantly higher incidence of X. fragaria was recorded in treatments with drip/overhead irrigation systems compared with drip irrigation. Implications for management of soil moisture levels are discussed with respect to the abundance of twospotted spider mite and X. fragaria in strawberries.