Corazonin and corazonin-like substances in the central nervous system of the Pterygote and Apterygote insects

Antisera against corazonin were used to investigate distribution of immunoreactive cells in the central nervous system (CNS) of representatives of six insect orders: Ctenolepisma lineata (Zygentoma), Locusta migratoria (Orthoptera), Oxya yezoensis (Orthoptera), Gryllus bimaculatus (Orthoptera), Pyrrhocoris apterus (Hemiptera), Arge nigrinodosa (Hymenoptera), Athalia rosae (Hymenoptera), Bombyx mori (Lepidoptera) and Anomala cuprea (Coleoptera). Corazonin-like immunoreactive (CLI) cells were detected in the brain and ventral ganglia of all insects studied except for the albino strain of L. migratoria and the beetle A. cuprea. Implantation of the brain or different ganglia from insects with detected immunoreactivity induced dark coloration in the albino locust, providing further evidence for the presence of authentic corazonins [His(7)- and Arg(7)-isoforms] in these insects. The protocerebral lateral neurosecretory cells projecting into the ipsilateral retrocerebral neurohemal organs and bilateral longitudinal tracts extending and branching throughout the entire CNS seem to be a well-conserved part of the corazonin system in insects. The bilateral longitudinal tracts were formed by species-specific numbers of bilateral interneurons segmentally distributed in the ventral ganglia. Additional immunoreactive somata, mostly interneurons, were detected in the CNS of various insects. The distribution of corazonin in the cephalic neurosecretory system and in the bilateral interneurons suggests that corazonin acts as a hormone as well as a neurotransmitter or a neuromodulator. An ancient origin of corazonin is suggested by the presence of a corazonin-like substance in the primitive insect, C. lineata. These results support previous findings on the common occurrence of corazonin among insects, except for the albino strain of L. migratoria and the Coleoptera.     

Corazonin promotes tegumentary pigment migration in the crayfish Procambarus clarkii

The undecapeptide corazonin (pGlu-Thr-Phe-Gln-Tyr-Ser-His-Gly-Trp-Thr-AsnNH(2)) elicits a retraction of erythrophore pigment granules and dispersion of leucophore pigment granules in the crayfish Procambarus clarkii. The effects are dose-dependent from 10(-10) to 10(-5)M. Influence on erythrophores is lower than that of Red Pigment Concentrating Hormone (RPCH), which is inactive on leucophores. Corazonin effects are partly blocked by an anti-corazonin antibody, and even less by an anti-RPCH antibody. Corazonin effects are completely suppressed by the calcium chelator BAPTA. Immunoreactive somata and fibers were identified in various regions of the eyestalk (medulla terminalis, medulla interna and medulla externa) with the anti-corazonin antibody. These results suggest the possible existence of a corazonin-like peptide in crustaceans.     

Corazonin reduces the spinning rate in the silkworm,Bombyx mori

The insect neuropeptide, [Arg⁷]-corazonin was injected into larvae of the silkworm, Bombyx mori to investigate its influence on development and behavior. A single injection of 50 pmol of corazonin into the fourth and fifth instar larvae induced prolongation of the spinning period in all experimental groups except for those injected on day 10 of the fifth instar. The injection also caused a prolongation of the pupal period in some experimental groups, while it had no effect on the timing of larval ecdysis and the length of feeding period of the fifth instar. The spinning period was significantly prolonged even at a low dose of 1 pmol. Both the spinning rate and the rate of increase in hemolymph ecdysteroid level during the spinning stage were reduced by injection of corazonin. However, corazonin injection during days 5-7 of the fifth instar reduced the spinning rate without influencing the ecdysteroid level until the end of day 8, thereafter the rate of increase in hemolymph ecdysteroid level was slower in the corazonin-injected larvae than in the control larvae. Therefore, the suppressed ecdysteroid level observed in the corazonin-injected larvae appears to be a result rather than a cause of the reduced spinning rate. This study is the first published report for the corazonin effect on the behavior in insects.     

Flightlessness in insects

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.     

Polyphenism in insects

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.     

昆虫的雌雄嵌合现象

探讨了昆虫雌雄嵌合体的类型、类群、发生机制、对昆虫生物学的影响 ,以及其在胚胎发育学、比较形态学、神经系统调控机理上的应用。并对 1 980～ 2 0 0 0年《动物学记录》中收入的雌雄嵌合体记录进了行整理 ,共发现 1 3目 69科昆虫有雌雄嵌合体记载。文中还整理了中国现有的雌雄嵌合体记录     

昆虫的微孢子虫病

介绍了昆虫微孢子虫病的病理学、传播途径、寄主特异性、病害管理以及利用昆虫微孢子虫作为生物杀虫剂的应用等方面的研究进展 ,以期为益虫微孢子虫病害的防治和昆虫微孢子虫杀虫剂的研制提参考。     

昆虫的肢体自残现象

该文主要就昆虫的肢体自残现象发生的种类和虫态、被残器官和部位、自残发生的原因、自残对昆虫个体的有利及不利影响进行了综述，并简单地讨论了肢体自残现象在进化上的意义。     

Cognition in insects

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?     

Cognition in insects

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?     

黑化诱导激素对白薯天蛾的发育影响

黑化诱导激素是一种神经肽,它像激素一样调控昆虫的生长发育。给五龄白薯天蛾注射较高浓度的黑化诱导激素时,它们的吐丝期明显延长,蛹重也明显增加。给五龄各天白薯天蛾注射136pmol每克体重的黑化诱导激素,它们的添食期、吐丝期延长,蛹重增加。因此,黑化诱导激素会延长天蛾幼虫的添食期和吐丝期,影响天蛾幼虫的发育。     

Infraspecific categories in insects

Infraspecific categories are widely used for Lepidoptera, probably because of the attention from collectors that this order has received, but in other groups of insects their use is more restricted. The terms subspecies, race, form, variety, aberration, phase and caste are all employed by entomologists but with no great consistency. This is unfortunate because the phenomena which they are intended to describe are easily categorized; it should be possible to achieve a more standardized usage.
Since genetic isolation is necessary to permit the divergence of a population to a state on which it may be appropriate to bestow an infraspecific label, factors contributing towards a state of isolation in insect populations are discussed.     

植食性昆虫的学习行为

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     

Dehydration in dormant insects

Many of the mechanisms used by active insects to maintain water balance are not available to dormant individuals. Physiological and biochemical mechanisms of dehydration tolerance and resistance in dormant insects and some other invertebrates are reviewed, as well as linkages of dehydration with energy use and metabolism, with cold hardiness, and with diapause. Many dormant insects combine several striking adaptations to maintain water balance that-in addition to habitat choice-may include especially reduction of body water content, decreased cuticular permeability, absorption of water vapour, and tolerance of low body water levels. Many such features require energy and hence that metabolism, albeit much reduced, continues during dormancy. Four types of progressively dehydrated states are recognized: water is managed internally by solute or ion transport; relatively high concentrations of solutes modify the behaviour of water in solutions; still higher concentrations of certain carbohydrates lead to plasticized rubbers or glasses with very slow molecular kinetics; and anhydrobiosis eliminates metabolism.