饥饿和交配对小地老虎飞行肌发育的影响

小地老虎Agrotis ypsilon(Rottemburg)成虫飞行肌的发育常受一些因素影响而发生变化,为探讨饥饿和交配行为对飞行肌发育的影响,通过电子显微镜对雌虫飞行肌(背纵肌)的肌原纤维、线粒体结构进行观察,结果显示:4日龄饥饿雌虫,肌原纤维直径、肌节长度、肌原纤维体积均显著(P<0.05)小于取食的。7日龄饥饿雌虫肌原纤维直径、肌节长度、肌原纤维体积分数较4日龄的差异均不显著(P≥0.05),而7日龄饥饿的肌原纤维直径显著(P<0.05)大于7日龄取食的;羽化10 d后,饥饿雌虫肌节长度显著(P<0.05)大于取食雌虫的,而肌纤维体积分数和线粒体体积分数均却小于后者。7、10、13日龄交配雌虫肌原纤维横切直径分别显著(P<0.05)小于同日龄非交配的;7、10、13日龄交配雌虫肌原纤维体积分数显著(P<0.05)小于非交配的,线粒体体积分数虽然无差异(P≥0.05),但是交配雌虫的早在4日龄便已明显(P<0.05)减小。上述结果表明:正常取食的小地老虎飞行肌4日龄后会发生降解现象;饥饿抑制飞行肌前期发育和中期的降解,而促进成虫末期肌原纤维的分解;交配能促进飞行肌的降解。     

粘虫蛾飞行肌超微结构的研究

应用电子显微镜对粘虫雌蛾Mythimna separata(Walker)飞行(背纵)肌的研究结果表明,其肌原纤维由500-700根肌球蛋白丝(粗丝)组成,每根粗丝由6根肌动蛋白丝(细丝)环绕排列成六角形,每根细丝精确地位于两根粗丝间1/2处,从而使粗丝和细丝的比为1：3。肌节较短,长度约2.2-2.6μm。肌原纤维之间充满着线粒体和横管。每个肌节约有线粒体三个,横管二根。线粒体约占肌纤维体积的40%,而横管为7%。每根横管准确地位于肌节的1/4、3/4处,或Z线和中膈的中央,并与肌质网交接形成二位体(dyads)或三位体(triads)。肌质网相当不发达,约占肌纤维体积的2.5%。但其分布很有特色,即除了紧贴于肌原纤维周围的由单层液泡组成的肌质网以外,在中膈处还有一层横穿于肌原纤维的肌质网。和其它同步飞行肌的结构和功能分析比较的结果还表明,粘虫蛾飞行肌具有较善于飞行的结构。     

粘虫蛾飞行肌的发育：超微结构特征分析

应用电子显微镜对正常条件下饲养的0-16日龄粘虫Mythimna separata (Walker)雌蛾飞行肌超微结构的研究结果表明：肌原纤维直径。线粒体和横管的体积分量均随蛾龄的增加而增加,到7日龄达到最大值以后又随蛾龄的增加而下降;但是,肌节长度则随蛾龄的增加而缩短,到7日龄达到最短后又随蛾龄的增加而延长,从而使整条发育曲线呈“V”字形;肌原纤维和肌质网体积分量变化不大或无规律可寻;二位体在发育初期和未期的比例较高,而三位体在4和7口龄比例较高;肌丝排列从0～7日龄均是有序的,肌动蛋白丝(细丝)和肌球蛋白丝(粗丝)的数量比为3：1,粗丝的数量变化也不大,每根肌原纤维约有600根。但从10日龄开始肌丝排列出现紊乱,细丝全部消失,粗丝降解、数量减少了30%,从而使肌原纤维留下一片片的空白。根据这些结果,把7日龄前的飞行肌发育过程视为生长过程,而把10日龄后的视作降解过程。最后对粘虫蛾飞行肌与卵巢发育及其飞行能力变化的关系进行了讨论。     

东亚飞蝗行为和形态型变的判定指标

通过田间、室外罩笼、室内行为测试等一系列实验,研究了东亚飞蝗群居型和散居型之间的行为和形态差异。确立了东亚飞蝗不同生态型个体的形态和行为指标．结果表明,雌雄散居型蝗蝻每分钟的跳跃次数均在1．4以下,转向次数分别在1．3和1．4以下;雌雄群居型蝗蝻每分钟的跳跃次数均在1．6以上,转向次数分别在1．6和1．5以上．群居型蝗虫的跳跃次数、转向次数显著高于散居型蝗虫。所以跳跃次数、转向次数可作为东亚飞蝗行为型变判定指标．在同型不同性别的蝗虫之间行为型变指标没有显著差异．F／C值可作为4龄以上东亚飞蝗的形态型变判定指标。而E／F值可作为东亚飞蝗成虫的形态型变判定指标．两型的F／C值都随龄期的增长而增加,且同龄期雄虫F／C均大于雌虫F／C．F／C、E／F值在不同型态和同型不同性别间均存在极显著差异．因此,确定两型形态型变标准时应将雌、雄虫分开,即雌性和雄性散居型第4、5龄及成虫的F／C值分别大于2．5、2．8、3．3和2．6、2．9、3．5;雌性和雄性群居型第4、5龄及成虫的F／C值分别小于2．5、2．7、3．1和2．5、2．8、3．3．成虫的E／F值也可以作为成蝗形态型变的判断指标．     

东亚飞蝗Locusta migratoria manilensis(Meyen)二型生物学特性的初步研究

本文是研究东亚飞蝗二型生物学特性的一部分报导,目的在于通过二型生物学特性的比较,阐明二型在种群数量变动上的某些特点。实验结果指出:1.散居型飞蝗的发育速度大于群居型。低密度虫群的成活率亦高于高密度虫群。2.散居型成虫产卵量高于群居型,其卵小管数目也比后者稍多。3.若以食物吸收量与取食量的干重比例为指标,则散居型食物利用系数低于群居型。4.群居型体内水分含量比散居型低,但脂肪含量则比散居型高,实测结果前者的耐寒性比后者略强。此外,本文还简单讨论了二型的上述特性差异在飞蝗猖獗学上的意义。     

棉铃虫飞翔肌的超微结构

利用电子显微镜观测表明,棉铃虫Helicoverpa rmigera (Hubner)飞翔肌的肌原纤维由400～800根肌球蛋白丝组成,每根肌球蛋白由6根肌动蛋白丝环绕排列成六角形,肌节长度2.0～3.5μm,线粒体占飞翔肌的体积达42.38%～48.57%,微气管组织较为发达。初羽化棉铃虫肌原纤维和线粒体的发育基本完成,横管系统的发育相对较慢,羽化3日后趋于成熟,至5日龄占飞翔肌的体积达3.31%～3.54%。表明棉铃虫具有适宜飞行的飞翔肌结构。采自渤海海面距海岸线80km的迁飞蛾子飞翔肌基本结构和实验种群无明显的区别,但迁飞过程中的能量代谢导致线粒体内脊疏松而出现大量空洞。     

飞蝗抱对行为的进化意义及两型间相异的交配策略

飞蝗Locusta migratoriaL.不仅交配时间长,而且进行频繁的、长时间的交配前抱对。一般认为,交配前抱对行为是雄虫为了等待时机获取适时的交配。最近的研究表明,飞蝗的交配时间与P2值(最后交配雄虫子代的比例)、交配前抱对时间与交配时间存在显著的正相关关系,即飞蝗长时间的交配前抱对行为能延长其后续的交配时间,从而提高P2值。飞蝗具变型现象,散居型和群居型在形态特征、生理机能、行为及体色等方面存在明显差异。最近的研究结果显示,散居型较群居型具更高的P2值,较短的交配前抱对和较长的交配时间。冲绳和筑波种群散居型成虫的交配前抱对时间与交配时间存在显著的正相关关系,而群居型无此相关性。这些结果证实飞蝗散居型和群居型之间存在着繁殖策略的差异。     

螯虾腹屈肌的超微结构

用电子显微镜观察,发现螯虾(Procambarus clarkii)腹屈肌浅层(慢肌,tonic fiber)肌纤维和深层(快肌,twitch fiber)肌纤维的超微结构存在显著差异。浅层腹屈肌肌原纤维有相对长的肌节(5—10μm),肌原纤维直径较大,每根粗肌丝周围有9—12根细肌丝环绕,细肌丝与粗肌丝数量比约为6∶1;深层腹屈肌有相对短的肌节(3—4.5μm),肌原纤维直径较小,每根粗肌丝周围有6根细肌丝环绕,细肌丝与粗肌丝数量比为3∶1。以上结果提示,在决定螯虾腹屈肌收缩速度方面,可能肌原纤维直径大小比肌节长度更为重要。细、粗肌丝排列方式也可能与收缩速度有关。这与脊椎动物骨骼肌的情况是不同的。     

东亚飞蝗Locusta migratoria manilensis(Meyen)两型形态比较初步研究

本文对东亚飞蝗两型的卵、蝻及成虫的形态以及成虫的生殖、消化两系统各器官的长度进行了比较,试图明确两型在形态与解剖方面的差异。 研究方法 所用材料,除室内试验用卵系来自山东德州内涝蝗区(后经在北京室内饲养至第三代)外,其他省采自河南浚县蝗区。群居型蝻及成虫均系自野外采得一、二龄蝻,置于田间铁纱笼内(笼容积为33×33×33立方公分)饲养获得。每笼放幼蝻300头。散居型蝻     

飞蝗变型及体色多型的内分泌控制机理

飞蝗具变型现象,散居型和群居型在形态特征、生理机能、行为及体色等方面存在明显差异。保幼激素已被证实能诱导飞蝗散居型绿色的出现。近年,从飞蝗心侧体成功地分离了一种神经肽——黑化诱导激素([His^7]-corazonin),并用白化型进行检测,证实了其对体色黑化作用的活性。不同时间对飞蝗若虫注射不同剂量的[His^7]-corazonin,能诱导出现除绿色以外的散居型体色,如浅褐色、褐色、赤褐色、黑色等;也能诱导出现群居型的体色,即黑色配以橘黄色的底色。而且,对散居型若虫注射[His^7]-corazonin能诱导其形态向群居型转换。这些研究证实[His^7]-corazonin对飞蝗的变型有着重要的控制作用,但又不是唯一的。     

昆虫神经毒素BjαIT的表达及杀虫活性

根据毕赤酵母Pichia pastoris密码子偏爱性,不改变毒素蛋白质一级结构,设计合成了昆虫神经毒素BjαIT基因,并分别克隆至大肠杆菌Escherichia coli融合表达载体pPET30-a(+)和毕赤酵母分泌表达载体pPIC9K。在IPTG的诱导下,神经毒素在大肠杆菌中融合表达,表达产物利用镍亲和层析柱纯化,纯化产物用于制备抗血清和活性测试。采用斑点杂交,筛选得到了较高水平分泌表达重组BjαIT的酵母转化子,摇瓶条件下,毒素表达量最大可达约20 mg/L。大肠杆菌BjαIT表达产物对东亚飞蝗Locusta migratoria manilensis和德国小蠊Blattela germanica没有活性,但酵母表达产物经注射东亚飞蝗和德国小蠊表现出杀虫活性。     

Neural correlates to flight‐related density‐dependent phase characteristics in locusts

Locust phase polymorphism is an extreme example of behavioral plasticity; in response to changes in population density, locusts dramatically alter their behavior. These changes in behavior facilitate the appearance of various morphological and physiological phase characteristics. One of the principal behavioral changes is the more intense flight behavior and improved flight performance of gregarious locusts compared to solitary ones. Surprisingly, the neurophysiological basis of the behavioral phase characteristics has received little attention. Here we present density‐dependent differences in flight‐related sensory and central neural elements in the desert locust. Using techniques already established for gregarious locusts, we compared the response of locusts of both phases to controlled wind stimuli. Gregarious locusts demonstrated a lower threshold for wind‐induced flight initiation. Wind‐induced spiking activity in the locust tritocerebral commissure giants (TCG, a pair of identified interneurons that relay input from head hair receptors to thoracic motor centers) was found to be weaker in solitary locusts compared to gregarious ones. The solitary locusts' TCG also demonstrated much stronger spike frequency adaptation in response to wind stimuli. Although the number of forehead wind sensitive hairs was found to be larger in solitary locusts, the stimuli conveyed to their flight motor centers were weaker. The tritocerebral commissure dwarf (TCD) is an inhibitory flight‐related interneuron in the locust that responds to light stimuli. An increase in TCD spontaneous activity in dark conditions was significantly stronger in gregarious locusts than in solitary ones. Thus, phase‐dependent differences in the activity of flight‐related interneurons reflect behavioral phase characteristics. © 2003 Wiley Periodicals, Inc. J Neurobiol 57: 152–162, 2003     

A role for ecdysteroids in the phase polymorphism of the desert locust

Abstract. Locusts show density-dependent continuous phase polymorphism; they appear in two forms or phases, gregarious and solitary, and there is a continuous range of intermediates between the extreme phases. Although earlier studies showed that there are no major phase-dependent differences in the titres of ecdysteroid in the haemolymph of desert locusts, Schistocerca gregaria , recent studies showed some minor differences in the timing of the main peak of ecdysteroids. In crowded penultimate- and last-instar hoppers, peak titres were lower but longer-lasting, whereas in isolated hoppers they were higher but of shorter duration. The major component of the haemolymph peak of ecdysteroid was 20-hydroxyecdysone in both isolated and crowded hoppers, but differences were found in the relative amounts of two minor components (makisterone A-like compound and highly polar products). In S. gregaria adults, the regression of the prothoracic glands was irregular and subject to high individual variations, but phase-dependent differences in the rate of regression were significant, and the adult glands did not produce physiologically significant amounts of ecdysteroids. Peak titres of ecdysteroid in the haemolymph were higher in isolated than in crowded adults. Similar to larvae, adults of the solitary phase contain more ecdysone in the haemolymph than those of the gregarious phase. Moreover, the phase characteristic titres of ecdysteroid in the adult stage can be shifted from one phase to another phase in response to appropriate changes in density. In contrast, the maximum amount of ecdysteroids in both ovaries and eggs was significantly higher in the gregarious than in the solitary phase. The amounts, and to some extent the types of ecdysteroids, were the only difference between ovaries and eggs from solitary and gregarious locusts. In addition, in newly hatched larvae, the amount of ecdysteroid was more than five times higher in gregarious than in solitary phase.     

Adipokinetic Hormone and Flight Fuel Related Characteristics of Density-Dependent Locust Phase Polymorphism: A Review

Recent findings on differences between the gregarious and solitary phases of locusts are reviewed in relation to flight fuel utilization, adipokinetic responses, and adipokinetic hormones. Laboratory results obtained with Locusta migratoria migratorioides show that the amount of lipid reserves, resting levels of haemolymph lipids, and hyperlipaemic responses to flight and to injection of corpus cardiacum extract or of synthetic adipokinetic hormones, are higher in crowded than in isolated locusts. No major phase-dependent differences seem to exist in flight-related carbohydrate metabolism. The adipokinetic hormone content of the corpora cardiaca is higher in younger isolated locusts than in crowded ones. Adipokinetic hormone precursor-related peptide content of the corpora cardiaca is also higher in isolated than in crowded locusts. Crowded locusts have higher lipid reserves and higher hyperlipaemic responses to flight than isolated locusts also in Schistocerca gregaria and, following injection of synthetic adipokinetic hormone, the formation of low density lipophorin is higher in crowded than in isolated locusts of this species. The laboratory results obtained with isolated and crowded locusts are extrapolated to understand the ecophysiology of the migrations of solitary and gregarious field populations of L.m. migratorioides according to available information on the differences in the migration of the two phases. It is inferred that in this species solitary locusts have a rather coarse adipokinetic strategy focused on a single prereproductive long-distance migratory flight, whereas gregarious locusts possess a fine adipokinetic balance for reiterative, sometimes unpredictably long-distance, migrations in the prereproductive, as well as reproductive, periods. The differences between the adipokinetic strategies of solitary and gregarious S. gregaria seem to be less dramatic, nevertheless, they indicate a better adaptation of the gregarious phase to prolonged flights.     

群居型、散居型意大利蝗形态特征的数量分析

意大利蝗Calliptamus italicus(L.)是新疆草原的主要危害害虫之一,为了从形态上精确区分群居型和散居型意大利蝗,本文用数值分类学的方法对两型成虫的10个形态指标和5个形态指标比值进行了数量分析.方差分析结果表明:两型成虫在所测量的10个形态指标上都存在着显著性差异(P＜0.05);形态指标比值中前翅长...     

蝗虫多型现象的神经内分泌调控

蝗虫有两种型,即散居型和群居型。蝗灾通常由群居型蝗虫所引发。多年来人们试图找到控制蝗虫由散居型向群居型转变的关键因子,以期控制蝗虫危害。该文主要从神经内分泌的角度概述了蝗虫多型性的生理机制,重点介绍了保幼激素、蜕皮激素和脑神经肽［His7］-corazonin在蝗虫多型性中的主要作用和机制。     

Neural correlates to flight-related density-dependent phase characteristics in locusts

Locust phase polymorphism is an extreme example of behavioral plasticity; in response to changes in population density, locusts dramatically alter their behavior. These changes in behavior facilitate the appearance of various morphological and physiological phase characteristics. One of the principal behavioral changes is the more intense flight behavior and improved flight performance of gregarious locusts compared to solitary ones. Surprisingly, the neurophysiological basis of the behavioral phase characteristics has received little attention. Here we present density-dependent differences in flight-related sensory and central neural elements in the desert locust. Using techniques already established for gregarious locusts, we compared the response of locusts of both phases to controlled wind stimuli. Gregarious locusts demonstrated a lower threshold for wind-induced flight initiation. Wind-induced spiking activity in the locust tritocerebral commissure giants (TCG, a pair of identified interneurons that relay input from head hair receptors to thoracic motor centers) was found to be weaker in solitary locusts compared to gregarious ones. The solitary locusts' TCG also demonstrated much stronger spike frequency adaptation in response to wind stimuli. Although the number of forehead wind sensitive hairs was found to be larger in solitary locusts, the stimuli conveyed to their flight motor centers were weaker. The tritocerebral commissure dwarf (TCD) is an inhibitory flight-related interneuron in the locust that responds to light stimuli. An increase in TCD spontaneous activity in dark conditions was significantly stronger in gregarious locusts than in solitary ones. Thus, phase-dependent differences in the activity of flight-related interneurons reflect behavioral phase characteristics.