昆虫的夏滞育

夏滞育作为昆虫越夏的生态策略 ,已广泛引起昆虫学家的重视。本文就几十年来夏滞育研究的进展进行综述。着重讨论诱导、维持、终止夏滞育的主要环境因子 ,夏滞育的生态特征和它的生态适应意义。     

葱蝇非滞育、 冬滞育和夏滞育蛹发育和形态特征比较

昆虫非滞育、 冬滞育和夏滞育蛹具有不同的生理和发育过程。本研究以葱蝇Delia antiqua作为模式种, 以黑腹果蝇Drosophila melanogaster蛹的发育形态特征和命名为参照, 用解剖、 拍照、 长度测量和图像处理等方法系统地比较研究了非滞育、 冬滞育和夏滞育蛹的发育历期和形态变化, 重点在头外翻和滞育相关发育和形态特征, 目的在于弄清非滞育、 冬滞育和夏滞育蛹发育和形态特征差异, 为滞育发育阶段的识别、 滞育分子机理研究奠定形态学基础。冬滞育蛹的滞育前期、 滞育期和滞育后期分别为4, 85和27 d, 夏滞育蛹的滞育前期、 滞育期和滞育后期分别为2, 8和22 d。从化蛹至头外翻完成为滞育前期, 头外翻完成约10 h内复眼中央游离脂肪体可见。头外翻的完成是滞育发生的前提, 非滞育、 夏滞育和冬滞育蛹头外翻发生在化蛹后的48, 36和83 h, 在头外翻过程中发育形态没有差异。头外翻的过程为： 首先, 头囊和胸部附肢从胸腔外翻, 头部形态出现; 然后, 腹部肌肉继续收缩, 将血淋巴和脂肪体推进头部及胸部附肢。葱蝇蛹在完成蛹期有效积温约15%时进入冬滞育或夏滞育。在滞育期, 蛹的形态一直停留在复眼中央游离脂肪体可见这一形态时期, 且冬滞育和夏滞育的蛹在形态上没有区别。在体长、 体宽和体重上, 冬滞育蛹最大, 夏滞育蛹次之, 非滞育蛹最小。在滞育后期, 在黄色体出现期间, 非滞育蛹的马氏管清楚可见, 呈绿色, 而滞育蛹的马氏管几乎不可见。本研究为认知昆虫滞育生理、 从发育历期和形态上推断滞育发育进程提供了依据。     

葱蝇热激蛋白DaHSP23基因的克隆及在冬滞育和夏滞育蛹中的表达分析

[目的]低分子量(12 ～43 kDa)热激蛋白(sHSPs)具有抗逆应答的功能,滞育是昆虫抵抗不良环境的特殊发育形式,但sHSPs在昆虫滞育发育过程中的作用仍不清楚.本研究克隆和特征化葱蝇Delia antiqua sHSP基因,并研究它在夏滞育和冬滞育发育过程中的表达模式,为阐明sHSPs在滞育发育上的功能奠定基础.[方法]通过RACE-PCR方法克隆了葱蝇HSP23基因,通过相似性比较分析了其特征、结构域及与双翅目代表性同源基因的系统发育关系;采用实时荧光定量PCR研究了该基因在葱蝇冬滞育蛹和夏滞育蛹发育过程中的表达情况,通过表达的差异比较揭示了该基因与滞育发育的关系.[结果]克隆出了葱蝇HSP23基因,命名为DaHSP23(GenBank登录号:HQ392521.1),其cDNA全长序列为904 bp,编码186个氨基酸,推测蛋白分子量为20.9 kDa,等电点为6.42.该基因的编码蛋白与其他双翅目昆虫的sHSPs有超过66％的氨基酸序列一致性,与已报道的其他双翅目昆虫的滞育相关HSP23基因同源.基因组测序显示该基因无内含子.DaHSP23基因在葱蝇非滞育蛹的发育过程中一直保持在较低的水平,各发育阶段间的表达量不存在显著差异.但在冬滞育和夏滞育蛹中,该基因从滞育起始期开始逐渐显著升高表达,到滞育维持期的中后期达到峰值,在滞育终止期逐渐降到较低的水平.[结论]DaHSP23基因在葱蝇冬滞育和夏滞育发育过程中明显上调表达,但存在差异,它在滞育期的调控可能是种专化的.DaHSP23可能在葱蝇两种类型的滞育上起重要作用.     

葱蝇热激蛋白DaHSP23基因的克隆及在冬滞育和夏滞育蛹中的表达分析（英文）

【目的】低分子量（12~43 kDa）热激蛋白(sHSPs)具有抗逆应答的功能,滞育是昆虫抵抗不良环境的特殊发育形式,但sHSPs在昆虫滞育发育过程中的作用仍不清楚。本研究克隆和特征化葱蝇Delia antiqua sHSP基因,并研究它在夏滞育和冬滞育发育过程中的表达模式,为阐明sHSPs在滞育发育上的功能奠定基础。【方法】通过RACE-PCR方法克隆了葱蝇HSP23基因,通过相似性比较分析了其特征、结构域及与双翅目代表性同源基因的系统发育关系;采用实时荧光定量PCR研究了该基因在葱蝇冬滞育蛹和夏滞育蛹发育过程中的表达情况,通过表达的差异比较揭示了该基因与滞育发育的关系。【结果】克隆出了葱蝇HSP23基因,命名为DaHSP23（GenBank登录号：HQ392521.1）,其cDNA全长序列为904 bp,编码186个氨基酸,推测蛋白分子量为20.9 kDa,等电点为6.42。该基因的编码蛋白与其他双翅目昆虫的sHSPs有超过66%的氨基酸序列一致性,与已报道的其他双翅目昆虫的滞育相关HSP23基因同源。基因组测序显示该基因无内含子。DaHSP23基因在葱蝇非滞育蛹的发育过程中一直保持在较低的水平,各发育阶段间的表达量不存在显著差异。但在冬滞育和夏滞育蛹中,该基因从滞育起始期开始逐渐显著升高表达,到滞育维持期的中后期达到峰值,在滞育终止期逐渐降到较低的水平。【结论】DaHSP23基因在葱蝇冬滞育和夏滞育发育过程中明显上调表达,但存在差异,它在滞育期的调控可能是种专化的。DaHSP23可能在葱蝇两种类型的滞育上起重要作用。     

葱蝇非滞育与夏滞育蛹蛋白的双向凝胶电泳比较分析

【目的】比较分析葱蝇Delia antiqua非滞育与夏滞育蛹的蛋白表达差异, 为进一步揭示昆虫滞育的分子调控机理和昆虫防治提供理论基础。【方法】以非滞育和夏滞育的蛹为材料, 提取总蛋白; 进行双向凝胶电泳和凝胶图像分析, 对并差异蛋白质进行MALDI-TOF MS质谱鉴定, 获得该点的质量指纹图谱; 利用MASCOT软件在NCBI和SWISS PORT蛋白质数据库中进行搜索鉴定。【结果】非滞育和夏滞育蛹的蛋白表达存在显著差异。通过质谱鉴定和生物信息学分析, 13个差异表达的蛋白质分别为胶原蛋白、 纺锤丝组装非正常蛋白6(SAS6)、 5,10-亚甲基四氢叶酸合成酶(MTHFS)、 Bnb蛋白(bangles and beads)及其他功能未知蛋白。【结论】葱蝇在夏滞育时期, 蛹体内的某些蛋白被上调或下调表达。本研究所鉴定的蛋白中, 部分可能是参与滞育相关的蛋白质网络中的成员, 它们可能在抗高温、 染色体分离、 叶酸代谢等生理过程中发挥重要作用。     

小蜂滞育的研究进展

滞育现象在多种小蜂类天敌昆虫中存在,通过研究小蜂滞育技术,可实现蜂种的长期贮存、延长防控作用时间、提高产品的抗逆性,对小蜂工厂化生产及应用具有重要意义。本文在分析国内外小蜂总科昆虫滞育文献的基础上,总结了已开展滞育研究的69种小蜂类昆虫的滞育虫态、滞育持续期、主要诱导因子以及亲代效应等,分属小蜂科、赤眼蜂科、姬小蜂科、跳小蜂科、金小蜂科、蚜小蜂科、旋小蜂、长尾小蜂科、广肩小蜂、四节小蜂科10科。小蜂多以幼虫或预蛹滞育,其滞育敏感阶段因种不同而异。滞育持续期相对较长,大多可维持数月。一种寄生麦红吸浆虫的金小蜂Macroglenes penetrans在2.5℃的土壤中,其滞育持续期可达16个月。低温、短日照和寄主是影响多数小蜂滞育的主要因子;但也有少数小蜂进行夏滞育,如普金姬小蜂Chrysocharis pubicornis、Aphelinus flavus、车轴草广肩小蜂Bruchophagus platypterus等。另外,亲代也可对小蜂滞育产生一定影响。目前,对小蜂滞育后发育生物学评价的研究报道较少,尚待进一步探索研究。     

昆虫滞育的研究进展

对于大多数昆虫种群,滞育是一个生长发育过程中的选择,生物体具有识别周围环境改变的能力,通过调节昆虫自身内分泌机制,进而决定是否进入滞育状态。滞育可以发生在昆虫生命过程中的任何时期,其中卵期是最适昆虫滞育的时期之一。本文综述昆虫滞育,特别是卵滞育的研究,主要集中在以下方面：个体生态学、环境生理学、内分泌学、生物化学和分子生物学。     

昆虫滞育关联热休克蛋白的研究进展

滞育是昆虫逃避不利环境条件的基本方式之一, 益虫的合理利用和害虫的综合治理, 都离不开对滞育调控机理的研究。滞育可以诱导一些基因表达模式的改变, 如热休克蛋白基因的差异表达, 导致昆虫抗逆性增强。本文综述了与昆虫滞育关联的热休克蛋白的研究概况, 从热休克蛋白与滞育的关联、 不同虫态滞育期间热休克蛋白基因的差异表达和滞育相关的蛋白质组学研究几个方面进行了概述。与其他的胁迫反应均诱导热休克蛋白同步上调表达不同, 热休克蛋白在不同种类昆虫以及同种昆虫的不同滞育生理阶段的表达模式差别很大。热休克蛋白在滞育期间的表达是决定越冬抗逆性和存活的重要因子之一。本文可为昆虫滞育如何应答环境条件刺激的研究提供参考信息。     

35℃下烟青虫夏滞育率、蛹重及代谢速率的变化

【目的】本文旨在研究烟青虫Helicoverpa assulta在高温下的滞育的发生和生理的变化。【方法】高温可以诱导不同龄期的烟青虫进入夏滞育,本实验在35℃,L︰D=16︰8条件诱导3龄、4龄、6龄、预蛹期的烟青虫夏滞育,并比较研究了滞育蛹和非滞育蛹代谢水平的差异。【结果】研究结果发现,在35℃下,烟青虫的3龄、4龄、6龄幼虫与预蛹期的夏滞育率分别为25.96%、25.71%、22.76%、11.31%,3个幼虫期的滞育率显著高于预蛹期滞育率。不同龄期的滞育诱导中,雄性的夏滞育率都明显高于雌性夏滞育率。并且,滞育蛹显著比未滞育蛹重。对滞育蛹和未滞育蛹的失重动态与呼吸代谢速率比较研究,结果发现:夏滞育虫蛹的失重曲线平缓,显著低于未滞育蛹;并且呼吸代谢速率曲线平缓且显著低于未滞育蛹。【结论】研究表明,高温能诱导烟青虫能进入夏滞育,并且夏滞育蛹能通过维持低的代谢水平来度过不利环境,具有一定的生态适应意义。     

葱蝇海藻糖-6-磷酸合成酶基因的克隆、序列分析及滞育相关表达

海藻糖-6-磷酸合成酶（trehalose-6-phosphate synthase, TPS）是昆虫海藻糖合成途径中的关键酶之一。本研究通过对葱蝇Delia antiqua海藻糖-6-磷酸合成酶基因的克隆、 序列分析及滞育相关表达的分析, 旨在证明该基因在能源合成以及抵御高温和低温环境方面发挥重要作用, 为进一步弄清葱蝇滞育分子机制提供理论依据。根据葱蝇抑制消减杂交文库中的EST序列信息, 设计特异性引物, 并通过RACE技术克隆了葱蝇海藻糖-6-磷酸合成酶基因全长cDNA, 命名为DaTPS1 （GenBank登录号： JX681124）, 其全长为2 904 bp, 开放阅读框2 448 bp, 编码815个氨基酸, 推测其相对分子质量为91.2 kD, 等电点为5.96。生物信息学分析表明, 该基因编码的氨基酸序列具有两个保守结构域, 与其他物种TPS具有较高的同源性, 其中和黑腹果蝇Drosophila melanogaster亲缘关系最近, 氨基酸序列一致性为92.1%; 其蛋白质三维结构有15条大的α螺旋和11股反向平行的β链折叠。RT-PCR分析表明, DaTPS1在葱蝇非滞育、 夏滞育和冬滞育期蛹中都有表达, 但是非滞育期各时期表达量基本没有变化, 而在夏滞育和冬滞育蛹的滞育前期表达量较高, 滞育保持期表达量较低, 滞育期后期表达量又有所升高。推断在葱蝇蛹夏滞育和冬滞育期前期, TPS1开始催化合成较多的海藻糖以提高滞育期抵御不良环境的能力, 滞育保持期蛹的新陈代谢降低, 所需能量较少, 所以TPS1处于低水平表达状态, 而滞育期结束后, 蛹生长发育逐渐恢复, 所需能量有所增加, TPS1的表达量再次升高。本研究对揭示昆虫TPS在能量代谢通路中的作用及昆虫滞育的分子机理具有一定的科学意义。     

Physiological and molecular biological mechanisms underlying diapause in aquatic invertebrates

The review considers the published data, as well as its own, which demonstrate the abundance and evolutionary conservation of the mechanism of diapause in invertebrates. The ecological reasons for the emergence of diapause in life cycles of hydrobionts are analyzed. The specific physiological features of invertebrate diapausing organisms and the hormonal control of diapause are briefed. The molecular genetic mechanism of diapause is demonstrated by the example of a model species, Caenorhabditis elegans. Recent fundamental discoveries in molecular genetics related to the joint effect of genes and environmental factors on the basic metabolism, choice between the development-diapause alternative, and many other seasonal adaptations in multicellular organisms are discussed. The near discovery of the functional role of daf genes in hydrobionts is postulated. These studies will lead to a deeper understanding of the fine mechanism that underlies photoperiodism and the wider application of diapause phenomenon in theory and practice.     

Demarcation of diapause development by cold and its relation to time-interval activation of TIME-ATPase in eggs of the silkworm, Bombyx mori

We investigated the mode of action of winter cold in the termination of diapause by investigating Time-Interval-Measuring Enzyme (TIME). First, we determined the period of cold required for the completion of diapause development. Synchronously developing egg batches of a pure strain (C108 Bombyx mori silkworm) were used to minimize variations in hatching time. Hatching occurred with only 18 days chilling at 5 degrees C when the incubation at 25 degrees C after the chilling was elongated. The 18-day period was much shorter than we expected; diapause in B. mori is known to terminate completely with about 100 days of chilling. Even in such a short period of chilling, no sporadic hatching occurred. Moreover, we determined that a temperature-insensitive stage, which we called "Neboke", followed the short cold-requiring stage. Thus, the stage of diapause development was demarcated from other stages of diapause. While the length of diapause development was elongated when chilling was delayed after oviposition, the Neboke stage length was invariant. Cold evidently exerts its effect only on diapause development. When TIME was purified from eggs and chilled in test tubes, a transitory burst of its ATPase activity occurred at a time equivalent to shortly before the completion of diapause development; this was an interval-timer activation. The mechanism by which cold activates TIME to measure the time interval may help explain in biochemical terms the insect's adaptation to its seasonal environments.     

Environmental Cues, Endocrine Factors, and Reproductive Diapause in Male Insects

Environmental cues, mostly photoperiod and temperature, mediated by effects on the neuroendocrine system, control reproductive diapause in female insects. Arrest of oocyte development characterizes female reproductive diapause, which has two major adaptive functions: It improves chances of survival during unfavorable season(s), and/or it confines oviposition to that period of the year that is optimal for survival of the eggs and progeny. Although reproductive diapause is less well studied in male insects, there may be no sex-dependent differences in regard to the first of these functions. The second one, however, is not valid for the male; instead, selection pressure directs the male's reproductive strategy toward maximum chances of fertilization of the female's eggs with minimum waste of energy. Therefore, in species with female reproductive diapause, the males may or may not exhibit diapause, but if they do, their diapause must be adapted to that existing in conspecific females. Male reproductive diapause is defined as a reversible state of inability of the male to inseminate receptive females. In relation to reproductive diapause, there are several patterns of coadaptations between male reproductive strategy and timing of female receptivity, (a) In some insects, the females are receptive in the early part of their diapause; mating occurs during this period and there is no diapause in the male. The male dies shortly after copulation and the female stores the sperms to fertilize the eggs that develop after termination of the female's diapause, (b) In some species, as in the grasshopper Anacridium aegyptium, females are receptive during diapause; though oocyte development is arrested, copulation occurs and the stored sperms fertilize the eggs when the female's diapause ends. Males were claimed to have no diapause, but recent studies have revealed the presence of a reproductive diapause in a proportion of the males. This and other cases show that female receptivity during reproductive diapause may or may not be accompanied by male reproductive diapause. If there is a reproductive diapause in the male, it is controlled by the same endocrine mechanism, the corpora allata (CA), as in the females, (c) In many species females are refractory during their diapause. In these cases, males exhibit reproductive diapause, which may be light, as in the beetle Oulema melanopus, or well established, as in certain grasshoppers, butterflies, and beetles. In the latter cases, male diapause is controlled by similar environmental cues (photoperiod, temperature) and by the same intrinsic mechanism (neuroendocrine system, especially CA) as female diapause. Nevertheless, male diapause is less intense; the environmental cues leading to its termination are less complex and/or less extreme, so male diapause terminates before that of the females. Presumably, male diapause is under two antagonistic selection pressures: A male should not waste energy by courting dia-pausing refractory females, but he should be ready to copulate as soon as the females become receptive, otherwise he may lose in the competition between males for females. Some further strategies, which do not seem to fit the above patterns, are also outlined.     

Metabolic reserves associated with pupal diapause in the flesh fly, Sarcophaga crassipalpis

Larvae of Sarcophaga crassipalpis destined for pupal diapause (light:dark 12:12, 20°C) contain nearly twice as much lipid and twice the haemolymph protein concentration as larvae that will not enter diapause (light:dark 15:9, 20°C). This conspicuous difference in metabolic reserves provides the earliest indication of the developmental fate of the larva. Lipid reserves are utilized rapidly during the first half of diapause and then remain stable until adult eclosion. In contrast, residual dry weight changes very little early in diapause but drops sharply late in diapause, thus implying a transition from lipid utilization to protein or carbohydrate utilization in mid-diapause. We suggest that this metabolic transition marks the end of the “fixed latency period”: pupae readily respond to environmental or hormonal stimulation after this point. Diapause-destined larvae did not accumulate more glycogen than nondiapause-destined larvae, but an 80% decrease in glycogen at the onset of diapause and its elevation at the end of diapause suggests the utilization of glycerol or related compounds as cryoprotectants during diapause. Profiles of water content are very similar in short-day and long-day flies, thus suggesting that dehydration is not a mechanism exploited by the flesh fly to achieve cold hardiness. Adult flies that have experienced pupal diapause emerge from the puparium with lipid, glycogen, and water content nearly identical to flies that have not experienced diapause, but the residual dry weight is much lower. The severe depletion of protein may account for the reduced fecundity of flies that have experienced diapause.     

家蚕滞育卵与非滞育卵中几种关键酶活性的比较

家蚕Bombyx mori是卵滞育的昆虫, 在滞育期间无形态变化, 也不存在器官发育和组织分化, 然而其生理代谢过程仍在进行。为进一步研究家蚕滞育的机制, 本研究测定了家蚕滞育卵、 即时浸酸处理的滞育卵及非滞育卵在胚胎发育过程中的超氧化物歧化酶(superoxide dismutase, SOD, EC 1.15.1.1)、 过氧化氢酶(catalase, CAT, EC 1.11.1.6)、 丙酮酸激酶(pyruvate kinase, PK, EC 2.7.1.40)、 乙酰胆碱酯酶(acetylcholine esterase, AchE, EC 3.1.1.7)和乳酸脱氢酶(lactate dehydrogenase, LDH, EC 1.1.1.28) 的活性变化。结果表明： 处理后1-7 d, 即时浸酸处理的滞育卵, SOD活性由56 517.00 U/g提高到81 986.94 U/g, CAT活性由14.98 U/g提高到106.90 U/g, PK活性由25.19 U/g提高到181.70 U/g, AChE活性由17.88 U/g提高到287.86 U/g, 而LDH活性由169.96 U/g下降到122.82 U/g。 而在非滞育卵中, SOD活性由86 417.99 U/g下降到66 024.19 U/g, LDH活性由169.07 U/g下降到135.02 U/g; CAT活性由1.47 U/g提高到44.37 U/g, PK活性由20.56 U/g提高到92.09 U/g, AChE活性由21.40 U/g提高到99.17 U/g。在滞育卵中, SOD和AChE活性较稳定; CAT活性随发育上升, 而LDH活性随发育而下降; PK活性在胚胎发育的前 4 d呈上升趋势, 随后基本保持稳定。通过了解家蚕滞育卵、 非滞育卵与即时浸酸卵的相关酶活性在胚胎发育过程中存在的变化, 有助于进一步揭示家蚕滞育的机理。     

Evolution of overwintering strategies in Eurasian species of the Drosophila obscura species group

The phylogenetic relationship of Eurasian species of the Drosophila obscura species group remains ambiguous in spite of intensive analyses based on morphology, allozymes and DNA sequences. The present analysis based on sequence data for cytochrome oxidase subunit I (COI) and a-glycerophosphate dehydrogenase (Gpdh) suggests that the phylogenetic position of D. alpina is also ambiguous. These ambiguities have been considered to be attributable to rapid phyletic radiation in this group at an early stage of its evolution. Overwintering strategies are diversified among these species: D. alpina and D. subsihestris pass the winter in pupal diapause, D. bifasciata and D. obscura in reproductive diapause, and D. subobscura and D. guanche without entering diapause. This diversity may also suggest rapid radiation at an early phase of adaptations to temperate climates. On the other hand, adult tolerance of cold was closely related to overwintering strategy and distribution: D. obscura and D. bifasciata with reproductive diapause were very tolerant; D. alpina and D. subsilvestris which pass the winter in pupal diapause were less tolerant; D. subobscura having no diapause was moderately tolerant and D. guanche occurring in the Canary Islands was rather susceptible. Tolerance of high temperature at the preimaginal stages seemed to be also associated with overwintering strategy; i.e. lower in the species with pupal diapause than in those with reproductive diapause or without diapause mechanism.     

Diapause and seasonal life cycle strategy in the house spider, Achaearanea tepidariorum (Araneae, Theridiidae)

Abstract In order to elucidate the mechanism regulating its seasonal life cycle, the photoperiodic response of Achaearanea tepidariorum has been analysed. Nymphal development was faster in long-day and slower in short-day photoperiods. The combined action of low temperature, poor food supply and short daylength induced diapause at an earlier developmental stage than short days alone. Thus, photoperiod is a primary factor inducing nymphal diapause, but the diapausing instar is influenced by both temperature and food supply. Hibernating nymphs became unresponsive to photoperiod in late December. After hibernation, however, sensitivity was restored and the nymphs remained sensitive to photoperiod throughout their life. This spider could also enter an imaginal or reproductive diapause. Photoperiod was again a primary inducing factor and temperature modified the photoperiodic response to some extent. The induction of the reproductive diapause was almost temperature-compensated whereas development was not. So the involvement of a photoperiodic counter system was suggested. Irrespective of whether the nymph had experienced diapause or not, the imaginal diapause was induced in response to a short-day photoperiod after adult moult. Based on these observations, the seasonal life cycle and the adaptive significance of nymphal and imaginal diapause are discussed.     

Environmental Cues,Endocrine Factors,and Reproductive Diapause in Male Insects

Environmental cues, mostly photoperiod and temperature, mediated by effects on the neuroendocrine system, control reproductive diapause in female insects. Arrest of oocyte development characterizes female reproductive diapause, which has two major adaptive functions: It improves chances of survival during unfavorable season(s), and/or it confines oviposition to that period of the year that is optimal for survival of the eggs and progeny. Although reproductive diapause is less well studied in male insects, there may be no sex-dependent differences in regard to the first of these functions. The second one, however, is not valid for the male; instead, selection pressure directs the male's reproductive strategy toward maximum chances of fertilization of the female's eggs with minimum waste of energy. Therefore, in species with female reproductive diapause, the males may or may not exhibit diapause, but if they do, their diapause must be adapted to that existing in conspecific females. Male reproductive diapause is defined as a reversible state of inability of the male to inseminate receptive females. In relation to reproductive diapause, there are several patterns of coadaptations between male reproductive strategy and timing of female receptivity, (a) In some insects, the females are receptive in the early part of their diapause; mating occurs during this period and there is no diapause in the male. The male dies shortly after copulation and the female stores the sperms to fertilize the eggs that develop after termination of the female's diapause, (b) In some species, as in the grasshopper Anacridium aegyptium, females are receptive during diapause; though oocyte development is arrested, copulation occurs and the stored sperms fertilize the eggs when the female's diapause ends. Males were claimed to have no diapause, but recent studies have revealed the presence of a reproductive diapause in a proportion of the males. This and other cases show that female receptivity during reproductive diapause may or may not be accompanied by male reproductive diapause. If there is a reproductive diapause in the male, it is controlled by the same endocrine mechanism, the corpora allata (CA), as in the females, (c) In many species females are refractory during their diapause. In these cases, males exhibit reproductive diapause, which may be light, as in the beetle Oulema melanopus, or well established, as in certain grasshoppers, butterflies, and beetles. In the latter cases, male diapause is controlled by similar environmental cues (photoperiod, temperature) and by the same intrinsic mechanism (neuroendocrine system, especially CA) as female diapause. Nevertheless, male diapause is less intense; the environmental cues leading to its termination are less complex and/or less extreme, so male diapause terminates before that of the females. Presumably, male diapause is under two antagonistic selection pressures: A male should not waste energy by courting dia-pausing refractory females, but he should be ready to copulate as soon as the females become receptive, otherwise he may lose in the competition between males for females. Some further strategies, which do not seem to fit the above patterns, are also outlined.