光周期对内蒙古三种草原蝗虫高龄若虫发育、存活、羽化、生殖的影响

研究不同光周期(L8∶D16、L12∶D12及L16∶D8)对毛足棒角蝗Dasyhippus barbipes(F.-W.),亚洲小车蝗Oedaleus decorus asiaticus B.-Bidenko,小翅雏蝗Chorthippus fallax(Zub.)3种草原蝗虫高龄若虫的发育、存活、羽化、生殖的影响。结果表明:在白天温度(28±1)℃,黑夜温度(23±1)℃的恒定温度下,不同光周期对毛足棒角蝗和亚洲小车蝗高龄若虫的发育、羽化、产卵影响不大,但是对其存活率有极显著的影响:毛足棒角蝗和亚洲小车蝗高龄若虫到成虫的发育速度在中光照下(L12∶D12)最快。而在短光照(L8∶D16)下更有利于小翅雏蝗若虫发育,其次是中光照;毛足棒角蝗的羽化在中光照条件下最适宜,而长光照时数(L16∶D8)更有利于亚洲小车蝗和小翅雏蝗的羽化;光周期对亚洲小车蝗产卵影响最为明显,毛足棒角蝗和亚洲小车蝗在中光照和长光照时数条件下有利于它们产卵,而小翅雏蝗在短光照和中光照时数下有利于产卵。     

环境因素对长颚斗蟋翅型分化的影响

长颚斗蟋具有明显的翅二型现象。比较长颚斗蟋不同翅型成虫的形态差异,结果表明其短翅型成虫除翅已明显退化外,与长翅型成虫并无其他形态差异。为探究环境因素与长颚斗蟋翅型分化的关系,就光周期、温度及密度对其翅型分化的影响进行了研究。结果表明,短光周期会抑制其长翅型的形成,而LD16∶8h的长光周期则促进长翅个体的分化,但非自然条件的长光周期及全明或全暗条件与上述结论并不一致。变化光周期亦会影响其翅型分化,而随着改变光周期的时间及方向的不同,影响作用亦不相同。在孵化后第20天及40天经历光周期的趋长变化会促进其长翅化;而在孵化后第20天经历光周期的趋短变化则会抑制其长翅化,第30天转移却有促进作用。此外,低温(20℃)条件诱导长颚斗蟋短翅化,高温(25℃,30℃)则促进长翅型的分化。单独饲养时,LD12∶12h与LD16∶8h条件下的若虫均羽化为短翅型成虫,当密度增加至2或5头/容器时,成虫的长翅率均明显增加,说明高密度亦是长翅型个体出现的重要诱因。     

长颚斗蟋长翅和短翅型雌成虫飞行肌发育、生殖力及寿命的比较

为探讨长颚斗蟋Velarifictorus asperses (Walker)翅型分化的生态学意义, 对室内饲养获得的长翅和短翅型雌成虫飞行肌和卵巢的发育, 以及长、 短翅型雌成虫的生殖力和寿命进行了比较研究。结果表明： 羽化当日, 长翅型雌成虫飞行肌重38.68±9.15 mg, 显著高于短翅型的17.53±4.44 mg （P<0.05）; 而二者卵巢重量无显著差异（P>0.05）, 分别为4.69±1.04 mg和4.88±0.97 mg。羽化后8 d内, 长翅型雌成虫飞行肌重量增加了48.9%, 短翅型雌成虫飞行肌重量无明显增加; 而短翅型雌成虫卵巢的重量增加至93.5±11.7 mg, 约为长翅型雌成虫的4.5倍。短翅型雌成虫的产卵前期显著短于长翅型, 其早期产卵量及总产卵量亦显著高于长翅型; 而两翅型雌成虫中后期产卵量及寿命无显著差异（P>0.05）。此外, 长翅型雌成虫在羽化后12 d开始发生飞行肌的降解, 飞行肌降解个体的卵巢重量显著高于未降解个体, 与短翅型相似。结果提示, 飞行肌与生殖系统的发育之间存在资源分配的权衡关系（trade-off), 且这种资源分配的差异可能会导致长翅型与短翅型个体在生活史策略上出现分化, 即长翅型个体具有飞行能力, 而短翅型个体则在生殖方面获得更高的收益, 且飞行肌的降解可能是长翅型个体由飞行转向生殖发育的生理信号。     

稻飞虱翅型纯系后代个体的翅型分化对光周期变化不敏感

【目的】为了明确光周期和遗传因子在稻飞虱翅型分化中的作用, 研究了3种稻飞虱（褐飞虱Nilaparvata lugens、白背飞虱Sogatella furcifera和灰飞虱Laodelphax striatellus）翅型纯系或近纯系在不同光照时数下的翅型分化比率。【方法】以经过5~45代连续翅型筛选后的褐飞虱、白背飞虱和灰飞虱的长翅型和短翅型纯系或近纯系为材料, 在室内分别测定了其在长光照（16和20 h）、短光照(4~12 h)和正常光照(14 h) 3类光周期条件下饲养后, 雌、雄成虫中长翅和短翅个体出现的比率及存活率。【结果】白背飞虱和灰飞虱的长翅型纯系M♂×M♀或短翅型纯系B♂×B♀在不同光周期下的翅型比率均无显著差异（P>0.05）。褐飞虱短翅型近纯系B♂×B♀的雌虫短翅率和成虫总短翅率在不同光周期下也无显著差异（P>0.05）, 但雄虫短翅率在正常光照14 h和短光照4 h下显著高于长光照20 h下的（P<0.05）。当褐飞虱短翅型达到纯系后, 其后代翅型在6~16 h光照条件下无显著差异。褐飞虱长翅型近纯系M♂×M♀的后代虽有短翅个体出现, 但是雌虫和雄虫的各自短翅率在不同光周期下无显著差异（P>0.05), 仅总体短翅率在12 h光照条件下的显著高于16 h下的（P<0.05）。褐飞虱长、短翅型杂交筛选品系M♂×B♀的雌虫短翅率随光照时数的延长而升高; 灰飞虱杂交筛选品系M♂×B♀的短翅雄虫随光照时数的缩短而增多（P<0.05）, 但当筛选代次达到45代时, 这种趋势不再显著。3种稻飞虱长翅型和短翅型纯系或近纯系若虫的存活率会稍低于长、短翅型杂交后代的存活率, 但长、短翅型品系的存活率在6~16 h光照条件下差异不显著(P>0.05)。【结论】稻飞虱翅型分化对光周期的反应受飞虱本身遗传背景的影响, 翅型纯系后代个体的翅型分化对光周期变化不敏感。     

褐飞虱五龄若虫翅芽长度与成虫翅型关系的研究

褐飞虱饲养于不同水稻品种、不同生育期以及不同种群密度条件下,5龄若虫翅芽长度与成虫翅型具有稳定的相关性：翅芽长于1．10mm羽化后为长翅型雌虫,介于0．96～1．09mm之间为长翅型雄虫或短翅型雌虫,小于0．95mm为短翅型雄虫。根据5龄若虫翅芽长度结合外生殖器特征,编制了成虫翅型检索表。由此,可在5龄若虫期预测成虫的翅型和种群盛衰的趋势。     

遗传和环境因素对曲脉姬蟋亚热带种群翅型分化的影响

曲脉姬蟋Modicogryllus confirmatus Walker具有明显的翅二型现象。为探究环境及遗传如何影响曲脉姬蟋亚热带种群的翅型分化,对饲养于不同光周期、温度和密度条件下若虫羽化后的翅型比进行了调查,并对长、短翅型蟋蟀进行了3代遗传筛选和杂交试验,研究了光周期、温度、种群密度和遗传对曲脉姬蟋广西种群翅型分化的影响。结果表明:光周期和种群密度对曲脉姬蟋的翅型分化均无影响,而温度对其翅型分化具有调控作用。正常范围内的温度变化(25℃、30℃)对其翅型分化无显著影响,而35℃的极高温则显著降低曲脉姬蟋的长翅率,说明其翅型分化并不是对季节变化的适应,而高温胁迫可引起短翅化。对不同翅型进行了3代筛选,结果表明,往短翅型选拔会引起雌、雄虫的短翅率都明显下降,而往长翅型选拔时,雌、雄虫的短翅率均维持在极低水平;不同亲本组合的后代间的长翅率有差异,说明曲脉姬蟋的翅型分化可能受多基因调控。     

高温对稻褐飞虱发育与生殖的影响

通过高温处理及交配产卵实验,探讨了高温对稻褐飞虱Nilaparvata lugens (Stal)发育与生殖的影响。研究了不同高温条件对褐飞虱若虫发育历期、产卵量、产卵前期、寿命等生物学特性的影响。34℃以上高温导致褐飞虱若虫发育历期延长。高温处理4龄若虫使羽化后的雌成虫产卵量减少。高温处理不同日龄雌成虫也致使其产卵量减少,其中以1日龄短翅型、3日龄长翅型的产卵量影响最大。高温处理后褐飞虱寿命缩短。高温恒温处理,对短翅型雌成虫的产卵前期影响不大,但能延长长翅型雌成虫的产卵前期;而高温变温处理致使短、长翅型雌成虫的产卵前期均延长。高温变温对褐飞虱生殖的影响程度大于高温恒温。高温处理组雌、雄成虫与对照组相应的成虫交配试验表明,高温对雌性的影响大于雄性。实验初步确定34℃为对褐飞虱发育与生殖产生影响的临界温度。     

白背飞虱生殖行为的研究

本文测定了白背飞虱羽化、交配、产卵等生殖行为。结果表明,雄成虫较雌成虫羽化早;羽化高峰雄虫在中午前后,雌虫为午夜前后和早晨;交配日节律高峰在下午和后半夜;产卵日节律高峰在中午前后;雌成虫一生只交配1次,雄成虫可交配1～3次;交配前期长翅型显著长于短翅型,交配成功率为41.33％(实验种群);交配持续时间平均为91.87～92.80秒;未交配雌成虫的产卵前期显著长于交配过的雌成虫;交配前期、交配持续时间、产卵前期的遗传力h~2分别为0.1581、0.2661和0.2421。     

丽斗蟋翅二型雌虫飞行肌和卵巢发育间的资源分配差异

丽斗蟋Velarifictorus ornatus具有明显的翅二型现象, 长翅型与短翅型雌虫的卵巢和飞行肌存在着生理权衡。本研究分别应用蒽酮比色法、 硫代磷酸香草醛法、 考马斯亮蓝染液对羽化后10 d内两型雌虫飞行肌与卵巢内糖原、 总脂及蛋白质含量进行了定量分析。结果表明： 成虫羽化后10 d内, 两型雌虫体重无明显差异(P>0.05), 但短翅型雌虫怀卵量明显多于长翅型雌虫, 而人工脱翅能够促进长翅型雌虫怀卵量增加(P<0.05)。短翅型雌虫飞行肌内蛋白质、 糖原及总脂含量在成虫羽化后10 d内无明显变化, 但长翅型雌虫飞行肌内蛋白质在成虫羽化后3 d时达到最大值564.4±87.5 μg/♀, 糖原与总脂含量分别于羽化后第5天达到最大值85.2±21.7 μg/♀和5 284.7±1 267.4 μg/♀。然后开始下降, 各实验处理天数内, 长翅型雌虫飞行肌内蛋白质、 糖原及总脂含量都显著多于短翅型雌虫(P<0.05)。相反, 各处理天数内, 短翅型雌虫卵巢内蛋白质、 糖原及总脂含量则明显多于长翅型雌虫(P<0.05), 同时虫龄对蛋白质、 糖原及总脂在两型雌虫飞行肌与卵巢内分配也产生明显影响(P<0.05)。人工脱翅能够促进长翅型雌虫卵巢内蛋白质、 糖原及总脂含量增加, 同时诱导飞行肌内蛋白质、 糖原及总脂含量降低, 其中总脂含量在脱翅后10 d时降为2 394.9±1 461.8 μg/♀, 只有最大值的一半, 而与短翅型雌虫相似(P>0.05), 表明总脂为丽斗蟋飞行的主要能源物质。外用保幼激素Ⅲ能够促进长翅型雌虫卵巢内蛋白质、 糖原及总脂含量增加(P<0.05), 但对飞行肌内三者含量无明显影响(P>0.05), 外用早熟素Ⅰ对短翅型雌虫卵巢内蛋白质、 糖原及总脂含量亦无明显影响(P>0.05)。上述结果表明, 丽斗蟋长翅型雌虫首先将获得的资源用于发育飞行所需的飞行肌, 短翅型雌虫则首先将所获得的资源用于发育繁殖所需的卵巢, 但长翅型雌虫飞行肌与卵巢间的资源分配方式受保幼激素的影响。     

斑翅食蚧蚜小蜂的生物学特性

斑翅食蚧蚜小蜂Coccophagus ceroplastae是橡副珠蜡蚧Parasaissetia nigra的重要内寄生蜂。对斑翅食蚧蚜小蜂的形态特征进行了描述,在实验室条件下观察了斑翅食蚧蚜小蜂的行为、发育、存活、繁殖等生物学特性。结果表明:斑翅食蚧蚜小蜂幼虫分3龄,完成一个世代需21-26d。卵巢左右成对,各由3条卵巢管组成,为发育成熟型,成虫期补充营养和发育时间对抱卵量的影响不明显。羽化后即可进行交配,交配时间2-3s,雄蜂有竞争交配行为,交配对雌蜂产卵有显著刺激作用。产卵行为有寻找、寄主检查、产卵器刺探、产卵、产卵针拔出等步骤,存在过寄生现象。羽化主要是在08:00-10:00,温度、相对湿度、光照对其羽化节律均有影响,温度升高羽化提前,且相对集中;相对湿度在20%-90%范围内,随湿度的升高成虫羽化高蜂延后;而光照时间过长或过短均可使斑翅食蚧蚜小蜂的羽化相对分散。随着温度的升高,雌成蜂的寿命逐渐缩短;补充营养能延长成虫寿命,取食10%蔗糖的寿命最长,清水和无补充营养寿命短。     

Ecological significance of the wing polymorphism of the oriental chinch bug,Cavelerius saccharivorus Okajima (Heteroptera: Lygaeidae)

The wing polymorphism of the oriental chinch bug, Cavelerius saccharivorus, was studied in relation to its reproductive strategy. The frequency distribution of wing form in terms of the relative wing length (R.W.L.) changed with increase in the population density from a single modality biased toward the brachypterous form to bimodality with both macropterous and more extreme brachypterous forms. Since some evidences in the field showed that fliers are limited to macropters, such a bimodality of wing form indicated that C. saccharivorus employs a mixed strategy with some portion of adults staying on in the same habitat, whereas the rest disperse. Moreover, macropters were larger in body size than brachypters emerging in high density populations, although smaller than brachypters emerging in low density populations. Larger body size as well as the delay of ovarian maturation in macropters was considered to be a beneficial trait for migratory behaviour.     

Reproductive cost of flight capability: a comparison of life history traits in wing dimorphic planthoppers

Abstract. 1. Reproductive costs associated with flight capability were evaluated in the wing dimorphic planthopper, Prokelisia dolus Wilson, by comparing the life history of traits of winged (macropterous) and flightless (brachypterous) females under controlled laboratory conditions.
2. Macropters with large thoraces and fully developed wings maintain a greater investment in flight apparatus than brachypters with small thoraces and reduced wings.
3. Associated with greater flight capability in the macropter of P.dolus are shorter adult life, decreased total fecundity, and delayed age at first reproduction compared to brachypterous females.
4. Under field conditions where mortality is high, the difference in realized fecundity between the two wing forms living on similar resources is further exaggerated with the brachypter having the greater advantage.
5. When the life history traits of the wing forms of P. dolus are compared with traits for nine other species of planthoppers, two similarities emerge. First, the preoviposition period of the macropterous wing form is always longer than that for the brachypter resulting in a reproductive delay. Second, most studies show that macropters are less fecund than brachypters.
6. There is no general tendency among planthopper species for macropterous adults to live fewer days or develop more slowly as nymphs compared to their flightless counterparts.
7. The reproductive delay and reduced fecundity of the volent wing form of planthoppers supports the notion that flight capability is costly and that phenotypic trade-offs between flight and reproduction exist.     

Wing structure and polymorphism in minute scavenger beetles (Coleoptera,Latridiidae)

The main structural elements of the hind wing in 56 species of the family Latridiidae (Coleoptera) are analyzed. In macropterous forms, wing venation is reduced to 3 modified veins. 10 areas of sclerotization of the wing membrane are distinguished. Three forms with different degrees of wing reduction are revealed: the brachypterous, the micropterous, and the apterous form. Among 56 species examined, 40 are represented only by the macropterous form; 2, 3, 5, and 6 species, by macropterous and brachypterous, macropterous and micropterous, micropterous, and apterous forms, respectively.     

Molecular characterization of the flightin gene in the wing-dimorphic planthopper,Nilaparvata lugens,and its evolution in Pancrustacea

Flightin was initially identified in Drosophila melanogaster. Previous work has shown that Drosophila flightin plays a key role in indirect flight muscle (IFM) function and has limited expression in the IFM. In this study, we demonstrated that flightin is conserved across the Pancrustacea species, including winged insects, non-winged insects, non-insect hexapods and several crustaceans. The brown planthopper (BPH), Nilaparvata lugens (Stål) (Hemiptera: Delphacidae), a long-distance migration insect with wing dimorphism, is the most destructive rice pest in Asia. We showed that flightin was one of the most differentially expressed genes in macropterous and brachypterous BPH adults. In female BPHs, flightin was expressed in the IFM of macropterous adults, no expression was detected in brachypterous ones; while in male BPHs, flightin was not only expressed in the IFM of macropterous adults, but also in the dorsal longitudinal muscle (DLM) in the basal two abdominal segments of both macropterous and brachypterous ones. RNAi and transmission electron microscopy results showed that flightin played key roles in maintaining IFM and male DLM structure, which drive wing movements in macropterous adults and the vibration of the male-specific tymbal, respectively. Using Daphnia magna as an example of a crustacean species, we observed that flightin was expressed in juvenile instars and adults, and was localized in the antenna muscles. These results illustrate the functional variations of flightin in insects and other arthropod species and provide clues as to how insects with flight apparatuses evolved from ancient pancrustaceans.     

Temporal pattern of feeding activity in the firebug Pyrrhocoris apterus and its relation to sex, wing dimorphism and physiological state of adults

Abstract.  The present study tested whether the pattern of feeding activity in the firebug Pyrrhocoris apterus (L.) is sex- and wing morph-related, diurnal or nocturnal, as well as whether the feeding rhythm persists in constant darkness. Temporal patterns of feeding activity are analysed in macropterous and brachypterous adults reared under long-day (LD 18 : 6 h) and short-day (LD 12 : 12 h) photoperiods, and in adults transferred to constant darkness. In females, the total feeding activity is highest in long-day reproductively active brachypters, intermediate in short-day diapausing brachypters, and lowest in macropters; the differences among males are substantially smaller. Although the total feeding activity of macropterous males is higher than in macropterous females, no sex-related differences are found in feeding activity of diapausing and reproductively active brachypters. The frequency of feeding exhibits sex-related differences, with obviously higher values in males. Mean feeding periods of macropterous and reproductively active brachypterous males are shorter than in females of the same wing morph. Mean interfeeding periods are longest in macropters, intermediate in diapausing brachypters, and shortest in reproductively active brachypters, and always lower in males than in females. The study shows that the feeding activity of P. apterus adults is age-, sex- and wing morph-related, and exhibits a diurnal pattern, except in reproductively active brachypterous females. The latter do not express a clear diurnal rhythm of feeding, presumably because of interactions with cycles of egg development and oviposition. The persistence of diurnal rhythm of feeding activity in short-day brachypterous females transferred to constant darkness indicates an endogeneity of this rhythm in P. apterus .     

Differences in haemolymph proteins in relation to diapause and wing dimorphism inPyrrhocoris apterus (L.) (Heteroptera: Pyrrhocoridae)

Three different cultures of dimorphic bug,Pyrrhocoris apterus, were analyzed concerning diapause and its relation to wing morph pattern. The proportion of macropterous bugs was considerably higher (36%) in the Mediterranean culture from Israel than that (1.3%) in the temperate culture from the Czech Republic. The macropterous morph- and brachypterous morphrelated types of reproduction arrest, differing by the length of pre-oviposition period, were distinguished in cultures analyzed. The reproduction arrest with an average pre-oviposition period of 38.2 days in Mediterranean macropters and 18.5 days in macropters from selected macropterous strain, was found to be typical for macropterous morph. Two different photoperiodic conditions induced macropterous morph-related reproduction arrest, the long-day (18 h light-6 h dark) photoperiod in macropterous strain macropters and the short-day (12 h light-12 h dark) photoperiod in Mediterranean macropters. The brachypterous morph-related reproduction arrest, characterized by pre-oviposition period longer than 90 days, occurred predominantly in diapausing brachypterous bugs. While the hibernal diapause of brachypterous bugs was characterized by a very high level of the 78- and 82-kDa proteins in haemolymph, their content in haemolymph of macropters during macropterous morph-related reproduction arrest was almost as low as in the reproductive adults. The variation of reproduction arrest in relation to wing dimorphism represents an important feature in the life strategy ofP. apterus.