梨小食心虫幼虫寄主选择性和主要感器

【目的】明确梨小食心虫Grapholithamolesta(Busck)幼虫的寄主选择能力和主要感器。【方法】在室内条件下,测定梨小食心虫幼虫在7种寄主果实、不同发育阶段果实及受损伤果实的上的数量,并测定3种感器单独、两两组合处理及3种感器全部处理后的幼虫在不同寄主果实上的数量。【结果】1龄时,选择丰白毛桃、红富士苹果和霞光油桃的幼虫数分别为12.00、8.67和9.00头,选择早酥梨、嘎啦苹果和皇冠梨的幼虫数为2.00、1.00、1.00头;5龄时,选择上述6种果实的幼虫数依次为8.67、7.00、6.00、5.33、4.00和3.67头。选择丰白毛桃、红富士苹果和霞光油桃成熟期果实的幼虫数均显著高于选择同种未成熟和成熟早期果实。选择受损伤丰白毛桃、红富士苹果和霞光油桃的幼虫数显著高于选择同种未受损伤果实。分别单独处理触角、下颚须+下唇须和胸足的幼虫,未选择寄主果实的幼虫数为7.33-10.00头;两两感器组合处理后,未选择的幼虫数与单独处理触角无显著差异;3种感器全部处理的幼虫无选择能力,未选择的幼虫数为17.67头。【结论】梨小食心虫幼虫可选择寄主,且对寄主的选择性随幼虫龄期增加而变化。梨小食心虫幼虫触角是其选择寄主果实的主要感器。     

桃小食心虫生物学的研究——果实对幼虫蛀果、成活、生长发育及滞育的影响

桃小食心虫(Carposina niponensis Wals)是我国苹果、梨上的重要害虫,初孵幼虫在果面爬行片刻,即蛀入果内。幼虫能否入果,除受捕食性天敌和风雨等外界条件影响之外,与果实表皮组织有关系,蛀入果内幼虫的成活数量和生长情况亦受果肉组织及果实内含物的直接影响。因此,研究食料条件与桃小食心虫发生数量的关系,对提高该虫现有     

湿度对梨小食心虫存活和繁殖的影响

【目的】本研究旨在明确湿度变化对梨小食心虫Grapholitha molesta(Busck)在果实外各阶段存活率和蛀果率的影响及湿度对害虫最终存活率产生影响的关键阶段。【方法】在室内相对湿度25%,40%,55%,70%和85%条件下,记录和分析梨小食心虫的产卵量、卵孵化率、幼虫蛀果率、老熟幼虫化蛹率、蛹羽化率以及产卵、化蛹和羽化时间。【结果】湿度高低对化蛹率没有影响,供试的5种相对湿度下,化蛹率均为100%;但湿度对产卵量、卵孵化率、幼虫蛀果率、蛹羽化率和世代存活率均有显著影响,湿度越高,各阶段存活率、幼虫蛀果率和世代存活率也越高。不同虫态存活对湿度要求从高到低依次为:幼虫蛀果期成虫期卵期蛹期老熟幼虫期。湿度对害虫世代存活率产生显著影响主要发生在幼虫蛀果期、成虫期和卵孵化期。同时,湿度提高利于成虫产卵、化蛹和羽化,反之发育延缓。【结论】湿度会显著影响梨小食心虫各阶段的存活率、幼虫蛀果率和繁殖,成虫盛发期、卵期和蛀果期的湿度影响害虫种群数量和蛀果率的关键阶段。     

梨小食心虫蛹重对成虫繁殖力和寿命及下一代幼虫发育的影响

【目的】本文旨在明确营养状况不同造成的梨小食心虫Grapholitha molesta(Busck)雌、雄蛹重量差异对其羽化的成虫产卵量、产卵期、寿命及下一代(F1)幼虫发育的影响。【方法】室内条件下,通过不同的饲养方法,获得个体重量不同的梨小食心虫雌、雄蛹,待其羽化交配后,记录其产卵量、产卵时间和成虫寿命;卵孵化前后,分别测量卵和初孵幼虫大小,计算卵孵化率,统计幼虫发育历期。【结果】雌蛹重量对梨小食心虫的成虫产卵量影响显著,其重量与产卵量呈正相关(y=15.505x-59.292);同一条件下,雌蛹与雄蛹重量也呈正相关(y=0.823x-0.538)。同时,雌蛹重量对成虫产卵期影响也较大,蛹重大的个体羽化的雌虫比蛹重小的个体羽化的雌虫产卵高峰期提前1 d;较重、中等和较轻蛹羽化出的雌虫个体每天产卵量高于10粒/雌的时间分别为9~10,7和5~6 d;产卵量高于5粒/雌的时间分别为12~13,9和6~7 d。而雄蛹重量对产卵量、雄成虫寿命影响没有明显影响。较轻的蛹羽化的雌成虫寿命比较重蛹羽化的雌成虫短2~3 d;而雄蛹重量对其羽化的雄成虫寿命影响没有明显规律。雌、雄蛹重量对其羽化成虫的卵孵化率、卵和初孵幼虫的大小影响均不显著,对F_1幼虫发育历期影响也不显著。【结论】梨小食心虫雌蛹重对羽化成虫的产卵量和产卵期等影响显著,田间防治时应注意在不同条件下完成发育的个体,尤其是雌虫,由于营养差异引起的个体大小对随后种群增长的影响。     

梨树上桃小食心虫的生物学特性及防治试验

<正> 桃小食心虫是我国北方多种果树上钻蛀果实的一大害虫,尤以苹果、梨和枣的果实受害重,亟需积极防治。因其在不同守主上的发生、为害不完全一样。苹果、枣上为害的桃小食心虫已有较详细的研究,一年可发生1—2代,而在梨树上为害的桃小食心虫,迄今尚缺乏资料参考。以1978—1980年我们在辽宁省锦西县虹螺山梨区进行了此虫的生物学观察和药剂防治试验。现将结果报道于下,以供参考。     

室内饲养梨小食心虫幼虫脱果动态

为掌握不同果实室内饲养梨小食心虫Grapholita molesta(Busck)的效果及幼虫脱果的动态,以新红星苹果、富士苹果和大金星山楂饲养梨小食心虫,逐日记载幼虫脱果数量,并进行逻辑斯蒂(logistic equation)曲线拟合。结果显示,相同接卵数和相同饲料重量的情况下,3种饲料得到的幼虫数量高低次序为:新红星苹果>红富士苹果>大金星山楂。其中,新红星苹果每千克产虫量为27.7头,显著高于其它两种饲料。经逻辑斯蒂方程拟合可知,两种苹果幼虫脱果各时期及盛期历期相差较小;而以山楂饲喂的幼虫脱果各时期均比苹果饲喂的梨小食心虫提前4⁵ d,但盛期历期均为6 d左右。由此可知,梨小食心虫幼虫脱果动态可能与寄主水果种类关系较大,而与同种水果不同品种关系较小,这也可能是造成梨小食心虫各代发生重叠及混栽园受害严重的原因。因此,本研究不仅对在室内饲养梨小食心虫具有指导作用,且为测报防治田间脱果幼虫时间提供依据。     

苹果蠹蛾的蛀果与脱果特性

苹果蠹蛾Cydia pomonella(L.)是我国重大植物检疫性有害生物,对苹果属以及梨属的水果生产造成严重的危害。该虫以初孵化的1龄幼虫蛀入果肉,在果实内部取食为害并完成发育,老熟幼虫在黑暗中离开果实并寻找场所结茧化蛹。为掌握苹果蠹蛾幼虫进入及脱出果实时的行为特性,从而为实施有效的防治措施提供基础信息,本文在内蒙古格棱布楞滩对苹果蠹蛾幼虫的蛀果与脱果特性开展了详细研究。取得的主要研究结果如下:1)在苹果蠹蛾种群密度较高的情况下,单个果实平均蛀孔数可达5.25个,初期蛀入果实的幼虫在2～8头之间;2)苹果及梨蛀果中的幼虫数量与蛀孔数无关,虽然果实上的最高蛀孔数可达14个,但一般情况下受害果实中的幼虫数不超过3个;3)当果实表面蛀孔数较多时(苹果超过5个,梨超过2个),苹果蠹蛾幼虫向种室钻蛀的行为发生偏移,通常转入在果肉中为害;4)落果后5d内,落果内的幼虫近半数脱果(43.1%),落果后15d内,落果内的幼虫几乎全部脱果(99.9%);5)在脱果幼虫中,94%选择在夜间脱果,6%在日间脱果;6)至试验结束,蛀果中还有64%的幼虫滞留。以上研究结果表明,在种群密度较高的情况下,苹果蠹蛾幼虫存在激烈的种内竞争;及时清除苹果蠹蛾幼虫蛀果后造成的落果对未脱果幼虫有很好的防治效果。     

印楝素乳油对梨小食心虫的防控效果研究

【目的】探索0.3%印楝素乳油对梨小食心虫Grapholita molesta的控制效果。【方法】根据梨小食心虫的生物习性,采用浸渍法和浸虫法对梨小食心虫1日龄、3日龄、5日龄的卵和3龄、5龄幼虫进行了杀虫活性测定,采用药膜法对梨小食心虫初孵幼虫进行毒力测定,并通过田间试验测定0.3%印楝素乳油对梨小食心虫的控制效果。【结果】0.3%印楝素乳油对梨小食心虫1日龄、3日龄和5日龄卵的致死中量分别为6.5195、4.5789、6.6268 mg/L,对初孵幼虫的致死中量为6.0495 mg/L,效果较好,而对3龄和5龄幼虫几乎没有杀伤作用。使用有效成分为2.0 mg/kg~3.0 mg/L的印楝素乳油在田间进行梨小食心虫防治试验时,药后5 d和10 d的防治效果在63.18%~76.22%之间,至药后15 d时,防效则下降到27%以下,果实受害明显,表明该药剂已失去控制作用。【结论】印楝素乳油不能作为防治梨小食心虫的专用药剂,仅可在其发生危害的初期,防治其他害虫时,作为兼治的药剂来使用。     

不同成熟度的寄主果实对梨小食心虫生长发育及繁殖的影响

[目的]为探索不同成熟度的苹果、桃、梨果实对梨小食心虫Grapholitha molesta生长发育和繁殖的影响。[方法]在寄主果实不同发育阶段采果,并在室温(26±0.5)℃,L:D=15:9,RH=70%±10%条件下,测定了梨小食心虫在不同成熟度的桃、梨、苹果果实上的发育历期、存活率和繁殖力,并组建了其生命表。[结果]梨小食心虫在不同成熟度的苹果、桃、梨果实上的生长和繁殖有显著差异。幼虫发育历期在幼果期的寄主果实上无显著性差异,果实膨大期和成熟期以桃最短(10.44 d,9.42 d)。总存活率在幼果期和膨大前期、膨大后期为苹果最高(3.47%,13.04%,25.35%),果实成熟期为梨最高(39.70%)。单雌产卵量在幼果期和果实膨大前期为苹果最高(138.33粒/雌,145.33粒/雌),果实膨大后期为桃最高(151.90粒/雌),成熟期为梨最高(182.12粒/雌)。生命表分析结果表明,净生殖率幼果期为苹果最高(8.60),果实膨大期为桃最高(19.42),果实成熟期为梨最高(47.44)。内禀增长率幼果期苹果最高(0.0632),果实膨大前期为桃最高(0.0210),果实膨大后期为桃最高(0.0999)成熟期为梨最高(0.1117)。[结论]幼果期最适宜的寄主为苹果,果实膨大期最适宜寄主为桃,果实成熟期最适宜寄主为梨,这为揭示梨小食心虫在不同寄主间转移为害规律和田间防治提供了科学依据和参考。     

沙雷氏杆菌S3菌株产几丁质酶对棉铃虫不同虫龄幼虫的后致死作用

研究了粘质沙雷氏杆菌（Serratia marcesens）S3菌株产几丁质酶（Chitinase）对棉铃虫(Helicoverpa armigera)的后致死作用。生物测定表明,沙雷氏杆菌S3菌株产几丁质酶对棉铃虫幼虫48h的毒力不高,其中几丁质酶浓度为50μg/mL对初孵幼虫的毒杀力仅为8.3%,对高龄幼虫48h不表现毒力。但几丁质酶对棉铃虫幼虫特别是低龄幼虫生长发育如10d龄虫重、蛹重、化蛹历期、蜕皮、羽化等影响较大,造成棉铃虫幼虫化蛹历期延长,死蛹率和不正常羽化率增加。其中经几丁质酶处理后的初孵、1d龄、2d龄、3d龄、4d龄幼虫蛹重分别是对照组的51.0%、77.1%、81.4%、86.0%、96.2%;化蛹率分别为74.5%、87.5%、93.7%、95.8%、95.8%,都低于对照组的97.9%;死蛹率分别为57.3%、18.8%、13.6%、7.8%、7.9%;初孵幼虫化蛹历期长达14d;初孵幼虫的正常羽化的蛹只有40.8%。几丁质酶对棉铃虫的后致死作用明显。     

Seasonal and cultivar-associated variation in oviposition preference of Oriental fruit moth (Lepidoptera: Tortricidae) adults and feeding behavior of neonate larvae in apples

The Oriental fruit moth, Grapholita molesta (Busck) (Lepidoptera: Tortricidae) has become a pest of tree fruits since its introduction to the United States in the early twentieth century. Oriental fruit moth has historically been a major pest problem in peach production, and outbreaks in commercial apple (Malus spp.) orchards in the eastern United States were rare until the late 1990s. Recent outbreaks in Mid-Atlantic apple orchards have lead researchers to investigate host-associated effects on oriental fruit moth biology, behavior, and population dynamics. Studies were designed to assess cultivar level effects in apples on oviposition and larval feeding behavior of oriental fruit moth. In a mixed cultivar apple orchard, total oriental fruit moth oviposition and oviposition site preferences varied between cultivars. These preferences also varied over time, when sampling was repeated at various times of the growing season. Although most adult female oriental fruit moth preferentially oviposited in the calyx and stem areas of apple fruit, noticeable numbers of eggs also were laid on the sides of fruit, contradicting some previous reports. Oriental fruit moth females exhibited a strong ovipositional preference for fruit that were previously damaged by oriental fruit moth or codling moth, Cydia ponmonella (L.). The majority of newly hatched oriental fruit moth larvae were observed to spend <24 h on the surface of apple fruit before entry, and this behavior was observed on several apple cultivars. Neonate larvae exhibited a preference for entering fruit at either the stem or calyx ends, regardless of their initial site of placement. Our findings underscore the importance of adequate spray coverage and accurate timing of insecticide applications targeting oriental fruit moth.     

Comparative survival rates of oriental fruit moth (Lepidoptera: Tortricidae) larvae on shoots and fruit of apple and peach

Studies were designed to examine the effects of host plants on oriental fruit moth, Grapholita molesta (Busck) (Lepidoptera: Tortricidae), survival. G. molesta larval survival in the orchard was comparable between apple (Malus spp.) and peach (Prunus spp.) shoots, indicating that both host species can harbor large larval populations during the early season. G. molesta larvae used multiple shoots for feeding and development on peaches but usually only damaged single shoots in apple. Survival differences were present between peach and apple fruit, but this survival was affected by fruit maturity level. Generally, larval survival higher was in ripening peach fruit than in green, immature apple fruit. Larval survival varied among several apple cultivars, indicating that cultivar-level variability needs to be considered. These host-associated effects may impact efforts to predictively model G. molesta populations in commercial orchards where multiple host plant species, or different cultivars of the same species are often grown in proximity. Thus, host-associated dynamics should be included into future population models that underlie management programs.     

Effects of orchard host plants on the oviposition preference of the oriental fruit moth (Lepidoptera: Tortricidae)

Recently, the oriental fruit moth, Grapholita molesta (Busck) (Lepidoptera: Tortricidae), has emerged as a major problem on apples (Malus spp.) grown in the mid-Atlantic and midwestern United States, despite its historically important and frequent occurrence as a peach (Prunus spp.) pest. It is possible that host-driven biological phenomena may be contributing to changes in G. molesta population dynamics resulting in outbreaks in apple. Studies were designed to examine the effects of host plants on oviposition behavior, in an effort to clarify the host association status of eastern U.S. populations and also to gain insight into how pest modeling and management efforts may be altered to take into account various host-associated effects. G. molesta adults exhibited ovipositional preference for nonbearing peach trees over nonbearing apple trees in close-range choice tests conducted in the field, regardless of the larval host origin. A significant preference for peach shoots over apple shoots was observed on six of 12 sampling dates with a wild G. molesta population at the interface of adjacent peach and apple blocks. Numbers of eggs found on apple fruit were higher after peach fruit were harvested and apple fruit began to approach maturity (during the flight period for third and fourth brood adults). Possible implications for population modeling and integrated management of G. molesta are discussed.     

梨小食心虫的产卵选择性

为了准确掌握梨小食心虫的产卵特性,研究模拟室外条件下该虫在不同寄主果树的叶片、桃枝不同部位及不同品种桃果上的产卵偏好.结果表明: 梨小食心虫成虫对7种寄主果树叶片的产卵偏好由高至低依次为:桃＞樱桃＞苹果＞李＞梨＞海棠＞杏.在桃树叶片上的产卵量占总产卵量的33.5%,平均单叶卵量达8.3粒;虫卵在不同寄主叶片正、反两面的分布有所差异,苹果和海棠叶片正面卵量多于背面,桃、李、梨、杏叶背面卵量多于正面,桃叶背面卵量是正面的3.3倍,樱桃叶两面卵量差异不明显;该虫在桃枝上产卵部位选择顺序为:叶片＞托叶＞叶柄＞枝条,叶片是其主要产卵部位,占总产卵量的88.7%;梨小食心虫在桃枝上主要选择靠近顶端未展叶的前10片桃叶背面产卵,前10叶卵量占总产卵量的725%,其中第3片叶上产卵最多,占9.3%;第25叶以后仅占总产卵量的1.1%;在不同类型桃果上的产卵偏好次序为:油桃＞蟠桃＞毛桃;绒毛疏密及其特点是影响梨小食心虫在寄主果树叶片和果实上产卵选择的首要因素.     

梨小食心虫的产卵选择性

为了准确掌握梨小食心虫的产卵特性,研究模拟室外条件下该虫在不同寄主果树的叶片、桃枝不同部位及不同品种桃果上的产卵偏好.结果表明: 梨小食心虫成虫对7种寄主果树叶片的产卵偏好由高至低依次为:桃＞樱桃＞苹果＞李＞梨＞海棠＞杏.在桃树叶片上的产卵量占总产卵量的33.5%,平均单叶卵量达8.3粒;虫卵在不同寄主叶片正、反两面的分布有所差异,苹果和海棠叶片正面卵量多于背面,桃、李、梨、杏叶背面卵量多于正面,桃叶背面卵量是正面的3.3倍,樱桃叶两面卵量差异不明显;该虫在桃枝上产卵部位选择顺序为:叶片＞托叶＞叶柄＞枝条,叶片是其主要产卵部位,占总产卵量的88.7%;梨小食心虫在桃枝上主要选择靠近顶端未展叶的前10片桃叶背面产卵,前10叶卵量占总产卵量的725%,其中第3片叶上产卵最多,占9.3%;第25叶以后仅占总产卵量的1.1%;在不同类型桃果上的产卵偏好次序为:油桃＞蟠桃＞毛桃;绒毛疏密及其特点是影响梨小食心虫在寄主果树叶片和果实上产卵选择的首要因素.     

Interactions between extrafloral nectaries, ants (Hymenoptera: Formicidae), and other natural enemies affect biological control of Grapholita molesta (Lepidoptera: Tortricidae) on peach (Rosales: Rosaceae)

Extrafloral nectaries (EFNs) are reported to benefit some plants when ants (Hymenoptera: Formicidae) use their secretions and fend off herbivores, but in some cases resulting competitive interactions may reduce biological control of specific herbivores. This research examined the interactions between ants and other natural enemies associated with the EFNs of peach [Prunus persica (L.) Batcsh] and the implications for biological control of a key pest, the oriental fruit moth [Grapholita molesta (Busck)]. Studies using sentinel G. molesta placed on peach trees ('Lovell' cultivar) with EFNs present and absent revealed that several natural enemy groups associated with the EFNs contribute to reductions in G. molesta eggs, larvae, and pupae in peach orchards. Ants on trees with EFNs antagonized the G. molesta egg parasitoid Trichogramma minutum (Riley), but the ants were crucial in reducing G. molesta in both the larval and pupal stages. Overall, individual trees with EFNs experienced higher ant and other (nonant) natural enemy densities and subsequent pest reductions, as compared with trees without EFNs. However, the implications of EFN-natural enemy-pest interactions to orchard-level biological control will likely depend on local G. molesta population dynamics.     

Stimuli affecting selection of oviposition sites by female peach twig borer, Anarsia lineatella Zeller (Lepidoptera: Gelechiidae)

In laboratory and field experiments, stimuli were tested that might affect oviposition decisions by female peach twig borer moths, Anarsia lineatella Zeller (Lepidoptera: Gelechiidae). When given a choice between immature green peach fruits, green mature peach fruits and soft-ripe peach fruits, the latter received the fewest eggs. Fuzzy halves of peach fruits received ten times more eggs then shaved hairless halves. Volatiles from both almond and peach shoots induced more oviposition by females than by control stimuli. Similarly, volatiles from immature green peach fruits, mature green or mature hard-ripe peach fruits induced more oviposition than their respective control stimuli. In a choice experiment, volatiles from immature peach fruit stimulated three times more oviposition than those from soft-ripe peach fruit. Discrimination against mature soft-ripe peach fruits as potential oviposition sites may lie in the phenology of A. lineatella and host peach fruits. Larval development to the pupal stage takes 15–27 days. Therefore, any eggs laid on a ripe fruit 14 days before it falls from the tree will not likely develop into adult insects because developing larvae will only reach third or fourth instar before the fruit is decomposed, and only first and second instar larvae can overwinter.