抗寒类蛋白与冷驯化诱发昆虫耐寒性研究进展

昆虫是变温动物,温度对其生长发育、基本行为及进化途径都会产生很大的影响,种群的繁衍面临如何安全度过漫长而寒冷的冬季的挑战。通过长时间的进化,昆虫获得一系列完整的耐寒策略。绝大多数的昆虫都是耐寒昆虫,在陆地寒冷温度刺激下,昆虫受抗寒基因的调控,体内产生大量抗寒物质,如海藻糖、甘油、山梨醇、抗冻蛋白、热激蛋白等,提高昆虫的耐寒能力,使其得以在低温寒冷的条件下成功越冬。同样,经过冷驯化后的昆虫能显著提高昆虫的耐寒力。近年来,关于昆虫耐寒性、抗寒类蛋白的研究不断开展,研究内容涉及昆虫的耐寒性、抗寒基因HSPs和AFPs的调控、冷驯化诱导抗寒等方面。本文综述了昆虫耐寒性、主要耐寒策略及冷驯化诱发昆虫耐寒性增强等研究内容。有助于全面认识昆虫耐寒性及其作用机制,为天敌昆虫低温储存和提高生物防治等应用打下坚实的基础。     

昆虫耐寒性研究

昆虫是变温动物,气候变化是造成种群季节消长的基本原因之一。尤其在不良的低温环境中,昆虫耐寒力的高低是其种群存在与发展的种要前提,昆虫对低温的适应能力及其机理也因而成为昆虫生态学和生物进化研究中的一个深受重视的问题,本文论述了与耐寒性直接相关的过冷却点昆虫的抗寒对策,明确了昆虫耐寒性的一些基本概念,一方面从环境影响昆虫的角度对耐寒性的一般规律,如季节性变化,地理变异快速冷驯化的作用等做了简要的概念括,另一方面阐述了昆虫适应环境的生理生化机制,包括低分子量的抗冻物质的产生,冰核剂的作用及抗冻蛋白的功能等做了简要的概括,另一方面简单述了昆虫适应环境的生理生化机制,包括低分子量的抗冻物质的产生,冰核剂的作用及抗冻蛋白的功能等。强调昆虫与环境相互作用过程中的生态生理适应,并指出昆虫耐寒性应当与生活史中别的因素联系起来,这样才能对耐寒性有一个更加全面的理解。     

昆虫病原线虫的耐寒性

昆虫病原线虫可开发成生物农药,广泛应用于多种地下及钻蛀害虫的安全防治。但昆虫病原线虫货架期较短,对寒冷等极端环境的耐受性较差,影响了其在生物防治方面的商业开发。本文介绍了寒区的昆虫病原线虫资源,总结了昆虫病原线虫耐寒性的测定方法及增强方法、耐寒性差异的研究进展,并对其耐寒的生理生化机制及分子机理进行了综述。研究昆虫病原线虫的耐寒性,对于解释种群动态,指导昆虫病原线虫的低温保存,以及拓展其在生物防治方面的应用具有重要意义。     

线虫耐寒性研究进展

对于分布在温带和寒带的线虫,它们只有战胜冬季寒冷的挑战,才能有利于种群的存在与发展。因此,耐寒性是线虫生物学研究中不可忽视的内容。综述了关于线虫在低温胁迫下的耐寒性测定方法、耐寒对策及耐寒机制等方面的研究进展。线虫的耐寒性和昆虫一样,可通过过冷却点和低温存活率两种指标进行评价,但在具体的实验方法上,线虫耐寒性研究有其不同之处。线虫的耐寒对策和耐寒机制具有多样化。耐寒对策主要有耐冻和避冻,二者能共同渗透于线虫的耐寒过程中。耐寒机制包括特殊发育阶段的形成、低温驯化作用、低分子量抗冻物质的聚集、以及高分子量抗冻蛋白和热休克蛋白的产生,等等。此外,还强调应从多个角度研究线虫的耐寒性,如寒冷敏感型线虫的研究、寄生线虫的耐寒对策研究以及交叉胁迫的研究。     

昆虫耐寒性的测定与评价方法

昆虫耐寒性因其重要的理论和实践意义成为当前生态学研究中一个热点领域。近年来 ,大量的文献从不同的角度报道了昆虫耐寒性及其生态学意义。该文根据近期昆虫耐寒性研究的文献并结合作者的实验结果 ,从研究方法的角度概述昆虫耐寒性实验研究中应注意的几个问题 ,包括持续低温和瞬间低温 ,恒定低温和变化的低温 ,以及冷却速率对昆虫耐寒性的影响。同时介绍评价昆虫耐寒性的几个参数和模型 ,并对耐寒性的定量表达和评价方法进行讨论。     

螨类耐寒性及其机理研究进展

耐寒性的高低极大程度上影响螨类的越冬存活以及分布扩散情况。螨类耐寒性评估的主要指标是过冷却点以及低温胁迫下的致死温度和致死时间。螨类耐寒性通常具有可塑性,不同发育时期、滞育、季节变化以及冷驯化均会影响耐寒性,而耐寒性的变化涉及复杂的分子水平以及生理生化物质的变化。本文简要介绍了目前评估螨类耐寒性的生物学指标以及影响螨类的耐寒性的因素,总结了螨类耐寒性变化所涉及的生理生化和分子机制,探讨了目前螨类耐寒性需要进一步研究的科学问题,并对螨类耐寒性研究的生态学意义进行了展望。以期对螨类耐寒性的深入研究提供参考,促进害螨的综合防治和天敌捕食螨的开发利用。     

昆虫迁飞的调控基础及展望

昆虫迁飞是在长期适应多变的环境过程中进化形成的一种行为对策,也是昆虫的种类和数量繁多,以及迁飞害虫经常暴发成灾的主要原因.昆虫迁飞行为的发生不仅受到外界环境因素的影响,而且受到本身生理因素的调控.目前,国内外对此类研究主要集中在生态环境、生理因素、行为学以及种群遗传学方面的调控机制.随着分子生物学技术的发展,昆虫迁飞行为发生的分子调控机制也越来越受到重视.在对国内外主要昆虫迁飞调控机制概述的基础上,对新的分子生物学技术在昆虫迁飞调控中的应用进行了探讨与展望.     

昆虫冷驯化机制研究进展

昆虫耐寒性强弱决定其种群的发生、扩散和分布,因此低温胁迫下昆虫的抗寒对策成为近期研究的热点领域。冷驯化作为一种非常有效的耐寒策略,可显著增强昆虫的耐寒性。本文论述了冷驯化的2种基本形式:快速冷驯化和长时冷驯化,明确了二者在提升昆虫耐寒性中的作用;并从宏观到微观的角度概述了冷驯化的作用机制,如组织和细胞水平的特异性,低分子量抗冻保护剂的产生,热休克蛋白的表达及功能,以及阻止细胞程序性死亡的潜在机理等;讨论了不同研究方法所引起的结果差异性,并强调了冷驯化作用机制的整体效益和综合效益。最后通过分析2种冷驯化形式的联系与区别,以期较为全面地阐明昆虫冷驯化的潜在机制。     

昆虫体色多型的分子调控机制

体色多型普遍存在于各昆虫类群,体色多型不仅是生物多样性的体现,而且多样的着色模式对于昆虫本身具有重要的生物学意义.研究体色多型对探讨昆虫遗传多态性、适应机制及生物进化等具有重要的意义.本文主要从昆虫体色多型的分子调控机制进行综述,以期为今后探讨昆虫多态性、适应机制及生物进化提供参考.     

滞育昆虫营养物质的积累、转化与调控

滞育是昆虫度过不良环境的一种生存适应策略,营养物质的利用、积累和转化影响昆虫的滞育。滞育期间,昆虫体内发生一系列生理生化变化,包括脂类、碳水化合物和氨基酸等内源营养物质呈特异性地积累或转化,保障了滞育个体在逆境中存活及滞育解除后发育的能量需求。外源营养物质对昆虫滞育的影响较复杂,其种类、丰度、质量能通过"食料-寄主-天敌"营养关系进行传递,影响昆虫体内营养物质的积累和转化,改变昆虫的耐寒性、滞育率等,制约昆虫的滞育深度、滞育存活率。滞育昆虫营养物质积累、利用机制复杂多样,胰岛素信号通路-叉头转录因子以及激脂激素的调控效应在滞育诱导及营养物质转化中起到了关键的调控作用,但滞育的系统性调控仍需进一步深入研究。     

Factors affecting the cold hardiness of the peach-potato aphid Myzus persicae

Supercooling point studies were used to investigate the factors influencing the cold hardiness of the peach-potato aphid Myzus persicae, a freezing-susceptible insect. Overwintering adults lost cold hardiness as winter progressed, with a variable proportion showing a marked reduction in supercooling ability. Cold hardiness increased in spring so that all individuals demonstrated extensive supercooling ability typical of aphids reared in the laboratory at 20°C with a long photoperiod; these levels of cold hardiness were maintained in the field during summer and early autumn. First instar nymphs demonstrated considerable cold hardiness all year. Surface moisture caused inoculative freezing in some first instar nymphs and adults when supercooled, but the majority were unaffected. In the laboratory, adults starved for 7 days at 5°C showed distinct losses of supercooling potential equivalent to those observed in the field during mid to late winter. No loss of cold hardiness was found in first instar nymphs starved under the same conditions. The results demonstrate that the cold hardiness characteristics of M. persicae are atypical of those observed in other freezing-susceptible insects and it is suggested that continued feeding during mild winter conditions allows maintenance of cold hardiness particularly in adult aphids, and provides a possible explanation for the successful anholocyclic overwintering of M. persicae during such winters.     

Seasonal adaptations in arctic insects

Many insect species live in the arctic and show a wide rangeof adaptations to its extreme severity and seasonality. Long,cold winters are met, for example, by cold hardiness and choiceof protected sites. Cold hardiness includes both widespreadtolerance to freezing and extreme supercooling ability, as wellas unusual responses in a few species, such as lack of typicalcryoprotectants. Adaptations to short, cool summers includeactivity at low temperatures, selection of warm habitats andmicrohabitats, melanism and hairiness coupled with basking behaviour,and prolonged or abbreviated life cycles. Diapause ensures thatmany species emerge early in summer, with brief synchronizedreproduction that maximizes the time for offspring developmentbefore winter returns. Some species overwinter in sites thatthaw earliest in spring, even if they are relatively exposedin winter. Other adaptations respond to year-to-year variability:for example, prolonged diapause can provide insurance againstunsuitable summers. All of these adaptations are co-ordinated.For example, cold hardiness relies on physiological and biochemicaladaptations but also on habitat choice and timing. Because theadaptations are complex, predicted climatic warming probablywill have unexpected effects. In particular, an increase intemperature that increases summer cloud when sea ice melts wouldlikely reduce temperatures for insect development and activity,because sunshine provides critical warmth to insects and theirmicrohabitats. Changes in moisture will also be important. Moreover,responses differ among species, depending especially on theirmicrohabitats. The complexity of the responses of insects toarctic conditions reinforces the need for research that is sufficientlydetailed.     

Changes in chemical components in the freshwater apple snail, Pomacea canaliculata (Gastropoda: Ampullariidae), in relation to the development of its cold hardiness

The apple snail, Pomacea canaliculata, is an invasive freshwater snail. It increases its cold hardiness before winter. However, the physiological mechanism of cold hardiness in molluscs is poorly understood, especially in freshwater molluscs. In this study, we examined the changes in low molecular weight compounds, glycogen and lipids, in the body of P. canaliculata in association with the development of cold hardiness. When snails without cold hardiness were experimentally cold-acclimated, the amount of glycerol, glutamine, and carnosine increased, while glycogen and phenylalanine decreased. Overwintering cold-tolerant snails collected from a drained paddy field in November also showed increased glycerol in their bodies with decreasing glycogen concentration, compared to summer snails collected from a submerged field. Water content also decreased during the cold acclimation, although the water loss was minimal. These results indicate that the freshwater snail, P. canaliculata enhances cold hardiness by accumulation of some kinds of low molecular weight compounds in its body as some insects do. However, the actual function of each low molecular compound is still unknown.     

Suppression of Na+K+ -ATPase activity by reversible phosphorylation over the winter in a freeze-tolerant insect

Larvae of the gall fly, Eurosta solidaginis, use the cold hardiness strategy of freeze tolerance as well as entry into a hypometabolic state (diapause) to survive the winter. Cold hardiness strategies have been extensively explored in this species, but the metabolic features of winter hypometabolism have received little attention. A primary consumer of energy in cells is the ATP-dependent sodium-potassium ion pump (Na(+)K(+)-ATPase) so inhibitory controls over transmembrane ion movements could contribute substantially to energy savings over the winter months. Na(+)K(+)-ATPase activity was quantified in larvae sampled between October and April. Activity was high in October (0.56+/-0.13nmol/min/mg) but fell by 85% in November, remained low through midwinter, and then increased strongly in April. To determine whether the seasonal change in Na(+)K(+)-ATPase activity was linked with posttranslational modification of the enzyme, extracts from 15 degrees C-acclimated larvae were incubated under conditions that stimulated protein kinases A, G, or C. The action of all three kinases suppressed Na(+)K(+)-ATPase activity to levels just 3-8% of control values whereas the opposite treatment with alkaline phosphatase had no effect. Hence, the seasonal suppression of Na(+)K(+)-ATPase activity may be linked to enzyme phosphorylation. Furthermore, acute cold (3 degrees C) or hypoxia exposures of 15 degrees C-acclimated larvae did not alter enzyme activity, and freezing at -16 degrees C increased activity, so environmental factors do not appear to directly influence enzyme activity. Rather, it appears that winter suppression of ion motive ATPase activity may be part of a program of winter metabolic suppression.     

Upregulation of a desaturase is associated with the enhancement of cold hardiness in the onion maggot, Delia antiqua

Cold-acclimated non-diapause pupae, and summer- and winter-diapause pupae of the onion maggot, Delia antiqua (Diptera: Anthomyiidae), show marked cold hardiness as compared with intact non-diapause pupae. Homeoviscous adaptation of cellular membranes is crucial to enhance the cold hardiness of organisms, and Delta9-acyl-CoA desaturases have been assumed, albeit without experimental evidence in insects, to play a key role in the adaptation. We cloned the cDNA of a desaturase gene (Dadesat) from D. antiqua, which is most likely to encode Delta9-acyl-CoA desaturase. Expression of Dadesat mRNA in the brain, midgut, and Malpighian tubules of cold-acclimated and diapause pupae was upregulated 2-10 fold, correlating well with the increase in cold hardiness. In the pupae with enhanced cold hardiness, palmitoleic and oleic acids, the presumed products of Dadesat, in the phospholipids were significantly increased. These findings suggest that the increase in the expression of Dadesat contributes to enhanced cold hardiness in D. antiqua through the production of these unsaturated fatty acids.     

Adult diapause and cold hardiness in Aulacophora nigripennis (Coleoptera: Chrysomelidae)

We investigated the control of diapause termination and seasonal changes of cold hardiness and polyol content in Aulacophora nigripennis. Adults were ready to start post-diapause development upon transfer to high temperature by late February irrespective of photoperiod. Photoperiod probably functions to maintain diapause before winter because adults resume reproductive development at a long photoperiod in autumn. Adults showed a decreased supercooling point (SCP), increased chill tolerance and high myo-inositol content during winter. Chill tolerance at 0 degrees C appears to be a more suitable indicator of their cold hardiness than SCP because they die at 0 degrees C without freezing and they normally have no chance of being exposed to low subzero temperatures close to their SCP. The temporal pattern for changes in chill tolerance was synchronized with that for fluctuations in myo-inositol content, indicating a possible causal relationship between the two phenomena.     

桔小实蝇自然种群蛹和越冬成虫的耐寒性

本文通过过冷却点和低温耐寒能力的测定,研究了我国桔小实蝇Boctrocera dorsalis (Hendel)不同季节种群和地理种群蛹的耐寒性规律。结果表明：桔小实蝇自然种群蛹的低温存活力有明显的季节规律,冬前种群的耐寒性显著强于夏季种群。如在0℃低温下暴露2天,夏季种群基本全部死亡,而冬前种群存活率仍为61.4%。2005-2006年不同月份桔小实蝇1日龄蛹过冷却点差异明显,以2月份均值最高,为-9.26℃,8月份最低,为-15.20℃;且2月份桔小实蝇蛹个体过冷却点值出现明显的分化现象,分别在-15℃左右和-6℃左右出现两个明显的聚集区。所研究的5个桔小实蝇地理区域种群没有出现明显的耐寒性分化。结合本文结果,文中还就桔小实蝇自然种群耐寒性影响因素进行了讨论。     

Long-term reduction of cold hardiness following ingestion of ice-nucleating bacteria in the Colorado potato beetle,Leptinotarsa decemlineata

We investigated the effect of ingestion of ice-nucleating bacteria on the supercooling capacity and cold hardiness of the Colorado potato beetle (Leptinotarsa decemlineata Say), a freeze-intolerant species that overwinters as adults in shallow, terrestrial burrows. Ingestion of ice-nucleating bacteria (Enterobacter agglomerans, Pseudomonas fluorescens, Pseudomonas putida, Pseudomonas syringae), fed on slices of potato tuber, caused an abrupt decrease in supercooling capacity. No change occurred in the supercooling capacity of beetles fed Escherichia coli, as this species lacks ice-nucleating activity. Ingestion rates showed that tubers treated with different species were equally palatable. During diapause induction beetles evacuated food from their guts, but nevertheless retained sufficient ice-nucleating bacteria to diminish supercooling. Beetles fed P. fluorescens and P. putida exhibited reduced supercooling even after an 8-wk exposure to simulated winter conditions. Furthermore, P. fluorescens was isolated 10-wk post-ingestion from diapausing beetles. Our data suggest that ingested bacteria may be retained by insects during entry into diapause and that the cold hardiness of candidate crop pests, such as L. decemlineata, may be reduced by feeding them ice-nucleating bacteria prior to winter diapause.