从生理特点浅析昆虫繁盛原因

昆虫成为地球上数量最多、最为成功的一类动物 ,要归功于它们在长期进化过程中所形成的特点。该文从生理学的角度 ,分析了躯体大小、外骨骼、飞行、气管系统、变态、生殖、神经系统、食性等因素对昆虫繁盛的作用。     

昆虫与寄主植物的适应性及协调进化

昆虫与寄主植物的适应性及协调进化钦俊德（中国科学院动物研究所北京１０００８０）昆虫和植物都是地球上起源很早的生物类群。从化石的证据来推断，它们至少在３亿多年前已生活在一起，在不同地域建立起密切关系的生物群落。它们中不同的种类为了自身的生存和发展，并根...     

昆虫趋光性研究的回顾

利用昆虫的趋光性开展农林卫生害虫诱杀,一直是害虫绿色防控的组成部分。本文综述了昆虫的多种趋光性行为,昆虫趋光性机制—罗盘理论、马赫带效应理论和开放空间理论,对在物理、生物环境条件、光和光源属性条件下昆虫趋光的生态适应性,以及对昆虫抵达光源的位置和移动轨迹进行了讨论。     

细胞色素P-450在昆虫的适应性和抗药性中的作用

<正> 前文介绍了细胞色素P-450的分子特性和光谱特性、P-450的多样性、诱导性及其分子机理。鉴于这些特性对药剂的代谢、选择毒性、对寄主植物的适应性以及抗药性的重要性,本文简要地介绍细胞色素p-450(简称P-450)是如何发挥其保护作用的,以及与昆虫化学防治的关系。 一、P-450对昆虫的保护作用     

铜污染对昆虫生长发育及繁殖影响的研究进展

铜(Cu)是生物体生长发育所必需的微量营养元素,参与或构成许多含铜酶及含铜生物活性蛋白质,但是过度摄入Cu会对生物体产生危害。Cu中毒由许多因素而定,如物种、遗传、年龄和食物等。在生态系统中昆虫种类多,数量大,分布广,往往会取食、转移和代谢环境中的Cu,从而对自身生长发育及繁殖造成影响。通常表现为发育历期延长,体重下降,体长变短,化蛹率、羽化率、产卵率、孵化率、存活率降低,种群数量减少等。本文以近几年Cu2+胁迫对昆虫生长发育及繁殖影响的研究进行综述。     

昆虫标本馆建设与昆虫系统学的未来

昆虫标本馆是昆虫标本的保藏、研究和科学教育的实体,代表国家或者区域水平,致力于研究昆虫多样性、揭示昆虫进化规律,为国民经济建设持续发展服务。昆虫系统学研究是昆虫标本馆研究人员的主要任务,它的发展与昆虫标本馆的建设唇齿相依。本文阐述了昆虫标本馆的功能与作用,建设昆虫标本馆的重要性和迫切性;展望了昆虫系统学的未来以及昆虫系统学发展的机遇。     

安徽农林昆虫地理区划探析

安徽地跨我国北亚热带与南温带。根据气候、地貌特点,划分为5个大区12个亚区：1．淮北滑淮南温带平原区,包括黄泛平原亚区、淮北平原亚区和沿洼低地平原亚区;2．江淮南温带—北亚热带丘陵台地区;3．沿扛北亚热带平原低山区,包括江北平原低山亚区和沿江江南平原亚区;4．皖南北亚热带丘陵山地区,包括北部低山丘陵亚区、中部中山低山亚区和南部中山低山亚区;5．皖西北亚热带丘陵山地区。包括南坡丘陵低山亚区、中部低山中山亚区和北坡丘陵低山亚区。     

独特的昆虫化石──琥珀昆虫

提到化石,通常是指那些从岩层里发掘出来的、坚硬如石的生物遗骸。通常情况下,生物死亡以后,其尸体的有机质部分一般都会在空气的氧化作用及微生物的分解作用下很快腐烂、消失,而躯体的坚硬部分（如贝壳,昆虫的鞘翅等）或生物体活动时遗留下来的孔洞、痕迹及排泄物等埋藏在地下,经过自然界亿万年复杂而缓慢的石化作用后,最终形成了我们通常意义上所说的化石［’］,这类岩石上形成的化石也就是古生物学家主要的研究材料。而对于古昆虫学家来说,还有一种特殊类型的化石具有极高的研究价值,那就是琥珀昆虫。１琥珀昆虫的形成及研究概…     

浅谈昆虫世界的求偶交配行为

在昆虫世界的大观园里,大部分昆虫的受精产卵、生殖繁育都需要经过两性交配的过程才能完成。昆虫种类齐全,求偶行为更是多种多样。本文介绍了几种具有代表性的昆虫的求偶行为。对于昆虫吸引异性,延续种群,繁育后代,并维持物种间的生殖隔离具有重要意义。     

昆虫以群体的方式生活是繁殖所需

爱登堡大学（University of Edinburgh）和牛津大学（University of Oxford）的研究人员通过其设计的数学模型研究了蚂蚁和蜜蜂此类昆虫群体的进化模式。该研究结果刊登在2009年《进化生物学期刊》（J．Evol．Biol．）的第22卷第4期上。人们一直认为蚂蚁和蜜蜂可以长期不知疲倦地工作,最近研究表明这些昆虫行为更像模范公民。     

Did insect pollination cause increased seed plant diversity?

The dominant paradigm for the disproportionate number of flowering plants is the unique coevolution that they underwent with pollinating insects. The theory underlying this biotic pollination hypothesis contradicts more generally accepted evolutionary theory. Furthermore, various lines of empirical evidence falsify the biotic pollination hypothesis: (a) several lineages of plants were insect pollinated – angiosperms, Gnetales, Bennettitales, Cheiro-lepidiaceae, Medullosales, and Cycadales - yet only the first four were ever diverse or underwent radiations; (b) the predicted rise in insect diversity, which was coupled with angiosperm radiation, does not appear in the fossil record; (c) the family Poaceae (grasses) are wind pollinated, yet are exceptionally diverse and species-rich; and (d) the family Formicidae (ants) were not pollinators, yet are exceptionally species-rich and ecologically dominant. I enumerate many alternate (and seldom investigated) hypotheses for these patterns of seed plant diversity, keeping in mind that although I show that insect pollination was neither a necessary nor sufficient condition for large numbers of species, it may have played a substantial role in both plant and insect speciation. Alternatively, existing theory regarding the biotic pollination hypothesis can be refined in an attempt to eliminate the aforementioned empirical anomalies and theoretical inconsistencies.     

Concurrent effects of cold and hyperkalaemia cause insect chilling injury

Chilling injury and death are the ultimate consequence of low temperature exposure for chill susceptible insects, and low temperature tolerance is considered one of the most important factors determining insect distribution patterns. The physiological mechanisms that cause chilling injury are unknown, but chronic cold exposure that causes injury is consistently associated with elevated extracellular [K⁺], and cold tolerant insects possess a greater capacity to maintain ion balance at low temperatures. Here, we use the muscle tissue of the migratory locust (Locusta migratoria) to examine whether chill injury occurs during cold exposure or following return to benign temperature and we specifically examine if elevated extracellular [K⁺], low temperature, or a combination thereof causes cell death. We find that in vivo chill injury occurs during the cold exposure (when extracellular [K⁺] is high) and that there is limited capacity for repair immediately following the cold stress. Further, we demonstrate that that high extracellular [K⁺] causes cell death in situ, but only when experienced at low temperatures. These findings strongly suggest that that the ability to maintain ion (particularly K⁺) balance is critical to insect low temperature survival, and highlight novel routes of study in the mechanisms regulating cell death in insects in the cold.     

Leaf miner-induced changes in leaf transmittance cause variations in insect respiration rates

Very little is known about alterations in microclimate when an herbivore feeds on host plant. Modifications of leaf transmittance properties induced by feeding activity of the leaf miner Phyllonorycter blancardella F. were measured using a spectrometer. Their effects on the herbivore's body temperature and respiration rate have been determined under controlled conditions and varying radiation level employing an infrared gas analyser. By feeding within leaf tissues, a miner induces the formation of feeding windows which transmit a large portion of incoming radiations within a mine. As a result, body temperature and respiration rate increase with radiation level when positioned below feeding windows. Therefore, the miner is not always protected from radiations despite living within plant tissues. The amount of CO(2) released by larvae below feeding windows at high radiation levels is about five-fold that recorded in the dark. By contrast, body temperature and respiration rate increase only slightly with radiation level when the insect is positioned below intact tissues through which radiation is only weakly transmitted. A mine offers its inhabitant a heterogeneous light environment that allows the insect larva to thermoregulate through behavioural modification. Our results highlight the importance of physical feedbacks induced by herbivory which alter significantly an insect's metabolism independently of its nutritional state.     

Modeling insect dispersal and estimating parameters when mark-release techniques may cause initial disturbances

We consider the problem of quantitatively modeling movements of marked flea beetles in cultivated arrays of the cole crop, collards (Brassica oleraceae). Methods for the estimation of temporally and spatially dependent parameters in general dispersal models are outlined and a summary of our findings using these methods with flea beetle data is given.This research was supported in part by the National Science Foundation under NSF # MCS-8205335 and by the U.S. Air Force Office of Scientific Research under contract AFOSR 81-0198. Part of the research was carried out while this author was a Visiting Professor in the Department of Mathematics at Southern Methodist UniversityThis research was supported in part by the National Science Foundation under NSF # DEB-8207117This research was supported in part by the National Science Foundation under NSF # MCS-8200883. Part of the research was carried out while the first and third authors were visitors at the Institute for Computer Applications in Science and Engineering (ICASE), NASA Langley Research Center, Hampton, Virginia which is operated under NASA contracts NAS1-15810 and NAS1-16394     

Saponins do not affect the ecdysteroid receptor complex but cause membrane permeation in insect culture cell lines

This project studied the effects of four saponins with a triterpenoid (Quillajasaponaria saponin and aescin) or steroid structure (digitonin and diosgenin which is the deglycosylated form of dioscin) on insect cells, namely Schneider S2 cells of Drosophila melanogaster (Diptera). A series of different experiments were performed to investigate potential mechanisms of action by saponins with regard to ecdysteroid receptor (EcR) responsiveness, cell viability, cell membrane permeation, and induction of apoptosis with DNA fragmentation and caspase-3 like activity. Major results were that (1) exposure of S2 cells containing an EcR-based reporter construct to a concentration series of each saponin scored no EcR activation, while (2) a loss of ecdysteroid signaling was observed with median inhibitory concentrations (IC(50)'s) of 3-50 μM, and in parallel (3) a concentration-dependent change in loss of cell numbers in an cell viability assay with median effective concentrations (EC(50)'s) of 8-699 μM. In continuation, it was of interest that (4) a trypan blue assay with Q. saponaria saponin confirmed the cell membrane permeation effect leading to cell toxicity with a median lethal concentration (LC(50)) value of 44 μM, and interestingly this effect was very rapid. Another three interesting observations were that (5) exposure to 20E at 500 nM as used in the EcR-based report assay induced caspase-3 like activities which may help to explain the discrepancies between loss of EcR-responsiveness and cell viability, (6) low concentrations of saponins induced DNA fragmentation and caspase-3 like activities, confirming their potential to induce apoptosis, and (7) the saponin effects were counteracted with addition of cholesterol to the culture medium. In general the data obtained provide evidence that the anti-ecdysteroid action by saponins is not based on a true antagonistic interaction with EcR signaling, but can be explained by a cytotoxic action due to permeation of the insect cell membrane.     

On the paradox of thriving cold-water coral reefs in the food-limited deep sea

The deep sea is amongst the most food-limited habitats on Earth, as only a small fraction (<4%) of the surface primary production is exported below 200 m water depth. Here, cold-water coral (CWC) reefs form oases of life: their biodiversity compares with tropical coral reefs, their biomass and metabolic activity exceed other deep-sea ecosystems by far. We critically assess the paradox of thriving CWC reefs in the food-limited deep sea, by reviewing the literature and open-access data on CWC habitats. This review shows firstly that CWCs typically occur in areas where the food supply is not constantly low, but undergoes pronounced temporal variation. High currents, downwelling and/or vertically migrating zooplankton temporally boost the export of surface organic matter to the seabed, creating ‘feast’ conditions, interspersed with ‘famine’ periods during the non-productive season. Secondly, CWCs, particularly the most common reef-builder Desmophyllum pertusum (formerly known as Lophelia pertusa), are well adapted to these fluctuations in food availability. Laboratory and in situ measurements revealed their dietary flexibility, tissue reserves, and temporal variation in growth and energy allocation. Thirdly, the high structural and functional diversity of CWC reefs increases resource retention: acting as giant filters and sustaining complex food webs with diverse recycling pathways, the reefs optimise resource gains over losses. Anthropogenic pressures, including climate change and ocean acidification, threaten this fragile equilibrium through decreased resource supply, increased energy costs, and dissolution of the calcium-carbonate reef framework. Based on this review, we suggest additional criteria to judge the health of CWC reefs and their chance to persist in the future.     

Effect of the insect pathogenic bacterium Photorhabdus on insect phagocytes

Photorhabdus are insect pathogenic bacteria that replicate within the insect haemocoel following release from their entomopathogenic nematode symbionts. To investigate how they escape the cellular immune response we examined the effects of two strains of Photorhabdus, W14 and K122, on Manduca sexta phagocytes (haemocytes), in vitro and in vivo. Following injection of Esherichia coli into Manduca larvae, these non-pathogenic bacteria are rapidly cleared from the haemolymph and the number of free haemocytes transiently increases. In contrast, following injection of either strain of pathogenic Photorhabdus, the bacteria grow rapidly while the number of haemocytes decreases dramatically. In vitro incubation of haemocytes with either Photorhabdus supernatant reduced haemocyte viability, and the W14 supernatant caused distinct changes in the actin cytoskeleton morphology of different haemocyte cell types. In phagocytosis assays both Photorhabdus strains can inhibit their own phagocytosis whether the bacterial cells are alive or dead. Further, the supernatant of W14 also contains a factor capable of inhibiting the phagocytosis of labelled E. coli. Together these results suggest that Photorhabdus evades the cellular immune response by killing haemocytes and suppressing phagocytosis by mechanisms that differ between strains.