寄主植物-甜菜夜蛾-寄生蜂三级营养关系的研究进展

综述了近年来甜菜夜蛾Spodoptera exigua (Hübner)、寄主植物和寄生蜂互作关系方面的研究进展。介绍了甜菜夜蛾取食诱导的植物抗虫性产生的原因和机制;阐述了诱导植物产生抗性的甜菜夜蛾激发子volicitin的合成途径和功能,以及虫害诱导的植物挥发物和蛋白酶抑制剂对甜菜夜蛾及其寄生蜂的生态学功能;展望了植物诱导抗虫性在甜菜夜蛾的生物防治和新型抗虫品种开发等领域的应用前景。     

实夜蛾属和铃夜蛾属昆虫性信息素通讯系统的研究进展

实夜蛾属Heliothis和铃夜蛾属Helicoverpa昆虫的性信息素通讯系统主要包括雌蛾的性信息素合成和雄蛾对性信息素接收两个方面,每方面都有分子、细胞、系统水平上进行协同作用的生物过程。性信息素生物合成激活肽（PBAN）与其受体作用,启动信号转导系统,从而激活合成性信息素的酶系统来合成性信息素,利用化学和生物测定的方法鉴定出具有诱蛾活性的性信息素腺体组分及行为功能;性信息素分子与性信息素结合蛋白（PBP）的复合体同受体相互作用,启动信号转导系统,诱导产生神经信号,从而引起一系列性行为反应。这些生物过程受到各种内部和外部因素的影响。     

植物与昆虫的协同进化

据统计地球上的植物约30万种,而以植物为食的昆虫约48万种,几乎没有一种植物能免受昆虫的危害。也许人们很容易认为,植物不能运动,对取食者毫无招架之功,只能充当随时光顾的昆虫的美餐。事实上植食性昆虫可谓冒着“杀身之祸”顶着巨大的选择压力、和植物共同经历了上亿年的发展进化才“保住”了今日的饭     

虫媒植物与传粉昆虫的协同进化

虫媒植物与传粉昆虫的协同进化史刚荣（甘肃省陇西师范学校,７４８１００）地球上大约在３５亿年前就开始出现生物。目前,已经过鉴定的全球生存的生物约在１７０多万种以上（世界资源报告,１９８６）,其中被子植物就有２０万种以上,在这些开花的被子植物中,有８０％...     

论昆虫与植物的相互作用和进化的关系

昆虫与植物是陆地生物群落中最为重要的组成部分,二者间的相互作用是多方面的,其中最为重要的是昆虫选择植物作为食物和生长场所、昆虫为植物传授花粉两方面。该文集中讨论这两方面的相互作用有哪些因素与进化有密切的关系。植食性昆虫根据其寄主植物范围,通常分为专食性（寄主范围窄）和广食性（寄主范围广）。从生态关系来看,广食性的取食行为比专食性的更为有利,但实际情况却与此相反,统观植食性昆虫的取食行为,有向专食性演化更为普遍的倾向。专食性发展有利于提高昆虫对寄主植物的选择效率,还可缓和天敌作用所造成的压力。根据昆虫与植物相互作用的特点,目前已提出很多昆虫与植物的进化理论,包括成对的协同进化、弥散的协同进化、群落的协同进化以及顺序进化。在昆虫对寄主植物的选择中,以植物对昆虫的影响较昆虫对植物的影响更为重要,称为顺序进化是适宜的;昆虫为被子植物传授花粉造成互惠共生,其中的进化关系应称为协同进化。     

铃夜蛾属昆虫性信息素生物合成及内分泌调控

综述了铃夜蛾属Helicoverpa昆虫性信息素生物合成途径及内分泌因子的调控作用 ,包括信息素生物合成激活神经肽 (PBAN)和信息素生物合成抑制肽 (PSP)等的来源、结构和作用机制及一些种中保幼激素 (JH)和章鱼胺 (OA)对性信息素生物合成的作用 ,并展望了未来的研究方向。     

食虫蝙蝠与昆虫之间的相互作用和协同进化关系

食虫蝙蝠与昆虫之间是捕食和被捕食的关系,夜行性昆虫是食虫蝙蝠主要的食物来源。在漫长的协同进化中,蝙蝠施加的捕食压力导致夜行性昆虫一系列特征的进化,其中一部分昆虫进化出能听到蝙蝠的超声波信号并采取逃跑行为或者能通过其它方式躲避蝙蝠,同时昆虫的适应性特征同样影响着蝙蝠的回声定位和捕食策略。本文从蝙蝠捕食昆虫的种类、昆虫对蝙蝠捕食的反应和食虫性蝙蝠对昆虫防卫的适应对策等三个方面对食虫蝙蝠与昆虫之间的相互关系进行了概述。     

植物与草食动物之间的协同适应及进化

通常协同进化是指一个物种 (或种群 )的遗传结构由于回应于另一个物种 (或种群 )遗传结构的变化而发生的相应改变。广义的理解 ,协同进化是相互作用的物种之间的互惠进化。生物之间、特别是植物与草食动物之间的协同适应与进化 ,已经成为生物进化、生态、遗传等学科十分关注的问题 ,可能成为生物学中各学科研究的交汇点或结点。作者具体阐述了 :(1)生物之间协同进化的研究意义 ,包括对生物学与生态学的价值 ;(2 )生物之间协同进化研究的限制或困难 ,诸如时间、研究对象、进化等级尺度和研究方法的限制 ;(3)植物与草食动物之间协同进化的主要研究对象 (系统 ) ,即昆虫传粉系统、昆虫诱导植物反应系统、种子散布系统、以及大型草食动物采食与植物反应系统 ;(4 )植物与草食动物之间协同进化的主要研究内容 ,包括适应特征 (性状 )——物种的可塑性 ,以及适应机制——物种适应过程与策略两个方面 ;(5 )植物与草食动物之间协同进化研究的存在问题及研究方向     

食果动物与被取食植物的相互关系:协同进化?

在种子传播过程中动植物是否存在协同进化关系一直是争论的焦点。有观点认为,植物通过食果动物对其种子的传播可能获得逃避种子捕食者、占据新的生境斑块和基因流动等好处,而动物通过消化果肉获得营养和能量作为回报,动植物彼此相互作用,进而可能建立协同进化关系。动植物之间还可能发生在种、属或科水平以上的多物种的多配协同进化,或者通过关键种的协同进化来带动其他食果动物和植物相关性状的进化。“果肉防御假说”则认为果肉原本是保护种子的防御组织,后来才进化成为吸引食果动物以促进种子传播的物质。然而,食果动物和植物一对一的协同进化的例证并不多见;适合种子萌发和生长的环境在时空上难以确定;食果动物和植物的进化速度不一致;植物与种子传播者的选择压力存在着高度的不对称和不平衡,加上环境因素的重要影响,这种选择压力受到极大的限制而有可能变得不显著。种子传播中动植物在进化意义上的关系尚需进一步研究。未来研究应对食果动物和植物关系的复杂性和多样性有足够的认识。通过对系统发育中相联系的不同种的动植物关系的比较研究来揭示动植物关系对物种分化的影响,有可能为检验食果动物和植物之间的协同进化关系提供新的证据。食果动物传播种子对植物群落动态变化的影响、动植物关系和生物多样性保护等仍将是该领域研究的热点。     

Fossil oak galls preserve ancient multitrophic interactions

Trace fossils of insect feeding have contributed substantially to our understanding of the evolution of insect-plant interactions. The most complex phenotypes of herbivory are galls, whose diagnostic morphologies often allow the identification of the gall inducer. Although fossil insect-induced galls over 300Myr old are known, most are two-dimensional impressions lacking adequate morphological detail either for the precise identification of the causer or for detection of the communities of specialist parasitoids and inquilines inhabiting modern plant galls. Here, we describe the first evidence for such multitrophic associations in Pleistocene fossil galls from the Eemian interglacial (130000-115000 years ago) of The Netherlands. The exceptionally well-preserved fossils can be attributed to extant species of Andricus gallwasps (Hymenoptera: Cynipidae) galling oaks (Quercus), and provide the first fossil evidence of gall attack by herbivorous inquiline gallwasps. Furthermore, phylogenetic placement of one fossil in a lineage showing obligate host plant alternation implies the presence of a second oak species, Quercus cerris, currently unknown from Eemian fossils in northwestern Europe. This contrasts with the southern European native range of Q. cerris in the current interglacial and suggests that gallwasp invasions following human planting of Q. cerris in northern Europe may represent a return to preglacial distribution limits.     

Protein co-evolution, co-adaptation and interactions

Co-evolution has an important function in the evolution of species and it is clearly manifested in certain scenarios such as host–parasite and predator–prey interactions, symbiosis and mutualism. The extrapolation of the concepts and methodologies developed for the study of species co-evolution at the molecular level has prompted the development of a variety of computational methods able to predict protein interactions through the characteristics of co-evolution. Particularly successful have been those methods that predict interactions at the genomic level based on the detection of pairs of protein families with similar evolutionary histories (similarity of phylogenetic trees: mirrortree). Future advances in this field will require a better understanding of the molecular basis of the co-evolution of protein families. Thus, it will be important to decipher the molecular mechanisms underlying the similarity observed in phylogenetic trees of interacting proteins, distinguishing direct specific molecular interactions from other general functional constraints. In particular, it will be important to separate the effects of physical interactions within protein complexes (‘co-adaptation') from other forces that, in a less specific way, can also create general patterns of co-evolution.     

Evolutionary and plastic rescue in multitrophic model communities

Under changing environmental conditions, intraspecific variation can potentially rescue populations from extinction. There are two principal sources of variation that may ultimately lead to population rescue: genetic diversity and phenotypic plasticity. We compared the potential for evolutionary rescue (through genetic diversity) and plastic rescue (through phenotypic plasticity) by analysing their differential ability to produce dynamical stability and persistence in model food webs. We also evaluated how rescue is affected by the trophic location of variation. We tested the following hypotheses: (i) plastic communities are more likely to exhibit stability and persistence than communities in which genetic diversity provides the same range of traits. (ii) Variation at the lowest trophic level promotes stability and persistence more than variation at higher levels. (iii) Communities with variation at two levels have greater probabilities of stability and persistence than communities with variation at only one level. We found that (i) plasticity promotes stability and persistence more than genetic diversity; (ii) variation at the second highest trophic level promotes stability and persistence more than variation at the autotroph level; and (iii) more than variation at two trophic levels. Our study shows that proper evaluation of the rescue potential of intraspecific variation critically depends on its origin and trophic location.     

Ant attendance of the cotton aphid is beneficial for okra plants: deciphering multitrophic interactions

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Chemically mediated multitrophic interactions in a plant–insect vector‐phytoplasma system compared with a partially nonvector species

• 1 We elucidated the life cycles of two jumping plant lice species (Hemiptera: Psyllidae): Cacopsylla picta, a vector of the apple proliferation phytoplasma (Candidatus Phytoplasma mali), and Cacopsylla melanoneura, a nonvectoring species in Germany and some neighbouring countries, which may transmit the phytoplasma in one region in Italy.
• 2 The adults of C. picta reproduce exclusively on apple and migrate soon after emergence (emigrants) to conifers in mountainous regions, and return to apple plants in early spring (remigrants). Cacopsylla melanoneura also uses conifers as overwintering host plants but prefers to reproduce on hawthorn, despite its ability to reproduce on apple.
• 3 Both psyllid species used chemical cues for the identification of their alternate host plants during migration. Remigrants of C. melanoneura preferred the odour of their main reproduction host plant hawthorn to apple but preferred the odour of apple when experienced by feeding and oviposition. Although emigrants of C. picta reportedly prefer the odour of apple trees infected by Ca. P. mali, the remigrants of both species did not distinguish between the odours of infected or uninfected apple plants.
• 4 Investigating the distribution of Ca. P. mali in plant species involved in psyllid life cycle revealed that the phytoplasma is specialized on apple.
• 5 Infection of apple by Ca. P. mali increased mortality and resulted in decreased body size of C. picta offspring.
• 6 Gravid females of C. picta preferred to oviposit on non‐infected plants.
• 7 It is concluded that Ca. P. mali indirectly promotes its acquisition from infected plants and transmission to non‐infected plants by behavioural manipulation of its vector C. picta.

     

An example of molecular co-evolution: reactive oxygen species (ROS) and ROS scavenger levels in Schistosoma mansoni/Biomphalaria glabrata interactions

The co-evolution between hosts and parasites involves huge reciprocal selective pressures on both protagonists. However, relatively few reports have evaluated the impact of these reciprocal pressures on the molecular determinants at the core of the relevant interaction, such as the factors influencing parasitic virulence and host resistance. Here, we address this question in a host-parasite model that allows co-evolution to be monitored in the field: the interaction between the mollusc, Biomphalaria glabrata, and its trematode parasite, Schistosoma mansoni. Reactive oxygen species (ROS) produced by the haemocytes of B. glabrata are known to play a crucial role in killing S. mansoni. Therefore, the parasite must defend itself against oxidative damage caused by ROS using ROS scavengers in order to survive. In this context, ROS and ROS scavengers are involved in a co-evolutionary arms race, and their respective production levels by sympatric host and parasite could be expected to be closely related. Here, we test this hypothesis by comparing host oxidant and parasite antioxidant capabilities between two S. mansoni/B. glabrata populations that have co-evolved independently. As expected, our findings show a clear link between the oxidant and antioxidant levels, presumably resulting from sympatric co-evolution. We believe this work provides the first supporting evidence of the Red Queen Hypothesis of reciprocal evolution for functional traits at the field-level in a model involving a host and a eukaryotic parasite.     

Asymmetric or diffusive co-evolution generates meta-populations in fig-fig wasp mutualisms

Co-evolutionary theory assumes co-adapted characteristics are a positive response to counter those of another species,whereby co-evolved species reach an evolutionarily stable interaction through bilateral adaptation.However,evidence from the fig-fig wasp mutualistic system implies very different co-evolutionary selection mechanisms,due to the inherent conflict among interacted partners.Fig plants appear to have discriminatively enforced fig wasps to evolve"adaptation characteristics"that provide greater benefit to the fig,and fig wasps appear to have diversified their evolutionary strategies in response to discriminative enforcement by figs and competition among different fig wasp species.In what appears to be an asymmetric interaction,the prosperity of cooperative pollinating wasps should inevitably lead to population increases of parasitic individuals,thus resulting in localized extinctions of pollinating wasps.In response,the sanctioning of parasitic wasps by the fig should lead to a reduction in the parasitic wasp population.The meta-populations created by such asymmetric interactions may result in each population of coevolved species chaotically oscillated,temporally or evolutionarily.     

Coping with multiple enemies: pairwise interactions do not predict evolutionary change in complex multitrophic communities

Predicting the ecological and evolutionary trajectories of populations in multispecies communities is one of the fundamental challenges in ecology. Many of these predictions are made by scaling patterns observed from pairwise interactions. Here, we show that the coupling of ecological and evolutionary outcomes is likely to be weaker in increasingly complex communities due to greater chance of life‐history trait correlations. Using model microbial communities comprising a focal bacterial species, Bacillus subtilis, a bacterial competitor, protist predator and phage parasite, we found that increasing the number of enemies in a community had an overall negative effect on B. subtilis population growth. However, only the competitor imposed direct selection for B. subtilis trait evolution in pairwise cultures and this effect was weakened in the presence of other antagonists that had a negative effect on the competitor. In contrast, adaptation to parasites was driven indirectly by correlated selection where competitors had a positive and predators a negative effect. For all measured traits, selection in pairwise communities was a poor predictor of B. subtilis evolution in more complex communities. Together, our results suggest that coupling of ecological and evolutionary outcomes is interaction‐specific and generally less evident in more complex communities where the increasing number of trait correlations could mask weak ecological signals.