共查询到20条相似文献,搜索用时 31 毫秒
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The evolution of wings is heralded as the most important event in the diversification of insects, yet flight-wing loss has occurred in nearly all pterygote insect orders. Flight loss is especially prevalent among taxa inhabiting historically stable habitats. Recent studies of wing-polymorphic species have revealed numerous selective trade-offs in the reproductive potentials of winged versus flightless forms. A diverse set of environmental factors, both biotic and abiotic, trigger flight loss in alary polyphenic taxa, presumably by influencing juvenile hormone titers. Phylogenetic comparisons promise to elucidate much about the historical contexts and consequences of flight loss. 相似文献
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Barbara Webb 《Philosophical transactions of the Royal Society of London. Series B, Biological sciences》2012,367(1603):2715-2722
A traditional view of cognition is that it involves an internal process that represents, tracks or predicts an external process. This is not a general characteristic of all complex neural processing or feedback control, but rather implies specific forms of processing giving rise to specific behavioural capabilities. In this paper, I will review the evidence for such capabilities in insect navigation and learning. Do insects know where they are, or do they only know what to do? Do they learn what stimuli mean, or do they only learn how to behave? 相似文献
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Corazonin in insects 总被引:1,自引:0,他引:1
Corazonin is a peptidergic neurohormone of insects that is expressed in neurosecretory neurons of the pars lateralis of the protocerebrum and transported via nervi corporis cardiaci to the storage lobes of the corpora cardiaca. This peptide occurs with a single isoform in all insects studied so far, with the exception of the Coleoptera in which no corazonin form could be detected. Very few modifications of [Arg(7)]-corazonin, originally isolated from cockroaches, are known, namely [His(7)]-corazonin which is expressed in certain locusts and the stick insect Carausius morosus, and [Thr(4), His(7)]-corazonin recently described from the honey bee Apis mellifera. In this study, we performed a comprehensive screening for corazonin in the different insect groups after detecting of a fourth isoform in a crane fly, Tipula sp. ([Gln(10)]-corazonin). [Arg(7)]-corazonin is distributed in most major lineages of insects, and is thus the ancient form which was present at the time the phylum Insecta evolved. The replacement of Arg with His at position 7 from the N-terminus occurred several times in the evolution of insects. The third isoform, [Thr(4), His(7)]-corazonin, seems to be restricted to bees (Apidae); whereas wasps (Vespidae) and a bumble bee (Apidae) express other corazonins, specifically [His(7)]-corazonin and [Tyr(3), Gln(7), Gln(10)]-corazonin, respectively. A novel corazonin form, [His(4), Gln(7)]-corazonin, was also detected in all South African members of the newly described insect order Mantophasmatodea. The [His(4), Gln(7)]-corazonin separates these species from the Namibian Mantophasmatodea which express [Arg(7)]-corazonin and can be used as a distinct character to distinguish these morphologically similar insects. 相似文献
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H Chino 《Tanpakushitsu kakusan koso. Protein, nucleic acid, enzyme》1987,32(12):1413-1421
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Polyphenism is the phenomenon where two or more distinct phenotypes are produced by the same genotype. Examples of polyphenism provide some of the most compelling systems for the study of epigenetics. Polyphenisms are a major reason for the success of the insects, allowing them to partition life history stages (with larvae dedicated to feeding and growth, and adults dedicated to reproduction and dispersal), to adopt different phenotypes that best suit predictable environmental changes (seasonal morphs), to cope with temporally heterogeneous environments (dispersal morphs), and to partition labour within social groups (the castes of eusocial insects). We survey the status of research on?some of the best known examples of insect polyphenism, in each case considering the environmental cues that trigger shifts in phenotype, the neurochemical and hormonal pathways that mediate the transformation, the molecular genetic and epigenetic mechanisms involved in initiating and maintaining the polyphenism, and the adaptive and life-history significance of the phenomenon. We conclude by highlighting some of the common features?of these examples and consider future avenues for research on polyphenism. 相似文献
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B Webb 《Philosophical transactions of the Royal Society of London. Series B, Biological sciences》2012,367(1603):2715-2722
A traditional view of cognition is that it involves an internal process that represents, tracks or predicts an external process. This is not a general characteristic of all complex neural processing or feedback control, but rather implies specific forms of processing giving rise to specific behavioural capabilities. In this paper, I will review the evidence for such capabilities in insect navigation and learning. Do insects know where they are, or do they only know what to do? Do they learn what stimuli mean, or do they only learn how to behave? 相似文献
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Path integration in insects 总被引:6,自引:0,他引:6
The most notable advance in our knowledge of path integration in insects is a new understanding of how the honeybee measures the distance that it travels during its foraging trips. Data from two groups show that the bee's odometer records distance in terms of the net amount of image motion over the retina that is accumulated during a flight. Progress has also been made in clarifying the relation between path integration and other navigational strategies. On unfamiliar ground, path integration is the only available means of navigation. In familiar surroundings, however, guidance by landmarks may override guidance by path integration. Path integration then becomes a back-up strategy that is used primarily when landmarks fail. 相似文献
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植食性昆虫的学习行为 总被引:13,自引:2,他引:13
学习是指因经历不同而导致的行为变化。在植食性昆虫中,学习主要包含习惯性反应、厌恶性学习、联系性学习、敏感性反应和嗜好性诱导等类型。昆虫在幼虫和成虫期都具有学习能力,但幼虫期食料和取食经历不会对成虫行为产生直接影响。昆虫学习行为的表现受其本身食性、寄主刺激物的类别及寄主植物时空分布动态等因子的影响。学习能力有助于植食性昆虫应对复杂多变的植物环境,提高对寄主植物的利用效率,有利于其生存繁衍。对害虫学习行为的了解可为栖境调控、行为调控等害虫治理方法提供重要 相似文献
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昆虫的RNA干扰 总被引:2,自引:0,他引:2
RNA干扰(RNAi)是一种强有力的分子生物学技术, 在昆虫研究中得到了较多的应用。目前, RNAi技术主要应用于昆虫功能基因和功能基因组研究, 已在多个目的19种昆虫上实现了RNAi。在昆虫上实现RNAi的方法主要有注射、浸泡、喂食、转基因和病毒介导等方法, 这些方法各有特点, 其中喂食法因其简单而最有应用前景。昆虫RNAi的系统性较为复杂, 只有部分昆虫具有RNAi的系统性。昆虫中RNAi信号传导的基因可能是sid-1, 但昆虫RNAi的系统性机理还不是很清楚。转基因植物产生的dsRNA实现了对作物的保护, 证实了RNAi技术可用于害虫控制, 为害虫控制开辟了新领域。昆虫的RNAi研究处在起步阶段, 研究昆虫RNAi的机理, 特别是RNAi在昆虫体内的系统性扩散机理, 改进实现RNAi的方法, 提高RNAi技术在昆虫研究中的应用, 有利于昆虫基因功能鉴定和害虫控制, 促进昆虫学科的发展。 相似文献
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S.O. Andersen M.G. Peter P. Roepstorff 《Comparative biochemistry and physiology. Part B, Biochemistry & molecular biology》1996,113(4):689-705
The insect cuticle is an extracellular structure covering the total outer surface of the animal and providing protection against harmful influences from the environment. The mechanical properties of cuticles may vary considerably, and pronounced regional differences are generally observed. The properties may also change during development, and it can be assumed that the physical and chemical properties of all cuticular regions tend to be close to the optimal for proper physiological function during all developmental stages. Cuticular regions can be stabilized by the process of sclerotization, whereby o-diphenols are oxidatively incorporated into the material. Our current knowledge of the sclerotization process is reviewed, and it is suggested that the main features of the chemistry of sclerotization probably have been established, and that the major questions now remaining concern the precise regional and temporal control of the process. 相似文献
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