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。     

群居型和散居型东亚飞蝗雌成虫飞行肌的超微结构

应用电子显微镜对群居型和散居型东亚飞蝗Locusta migratoria manilensis（Meyen）雌成虫背纵肌进行了比较观察。结果表明：群居型和散居型成虫背纵肌具有类似的亚细胞结构,飞行肌的肌原纤维具有1∶3粗细丝比例,每根粗丝由6根细丝环绕排列成六角形结构。飞行肌的发育和线粒体的形成均是渐进的过程,在不同日龄成虫间存在差异。肌节长度为2.1～3.4 μm;7和10日龄时群居型成虫肌节长度小于散居型;7日龄群居型肌原纤维直径显著大于散居型。背纵肌内线粒体含量约占肌纤维的20%～43%,两型飞蝗之间存在着显著的差异,7日龄时群居型线粒体占肌原纤维的比例高达42.96%,而散居型的只有22.45%;10日龄群居型线粒体含量为41.32%,散居型线粒体29.98%。上述差异可能是东亚飞蝗群居型成虫飞行能力显著强于散居型成虫的重要原因之一。     

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。     

蜜蜂间接飞翔肌粗肌丝的微丝结构

用能溶解肌球蛋白但不溶解副肌球蛋白的溶液(300 mM KCI,pH6.0)处理分离的蜜蜂间接飞翔肌粗肌丝,经数分钟后可以看到粗肌丝端头散开成为多根微丝,微丝数最多为7根。延长处理时间,可以见到粗肌丝中央部分只剩下直径约为5 nm的徽丝。实验结果支持我们以前提出的蜜蜂间接飞翔肌粗肌丝的结构模式,并指示贯穿肌小节、两端都和Z线相连的内芯至少部分由副肌球蛋白组成。只存在于A带的,由6根微丝形成的外套是由肌球蛋白分子组成。     

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。     

蜜蜂飞翔肌收缩蛋白的电子显微镜鉴定

自五十年代肌丝滑行模型建立以来,关于脊椎动物骨胳肌的蛋白质成分,肌丝排列以及肌肉收缩时结构变化的研究取得了很大的进展。骨胳肌肌原纤维由粗、细肌丝有规律地排列所组成。对于肌肉收缩蛋白的选择性抽提,专一性抗体标记以及重组肌丝的研究,证实肌球蛋白存在于粗肌丝;肌动蛋白、原肌球蛋白和原宁蛋白存在于细肌丝(Huxley,A.F.,1957;Huxley,H.E;,1972)。昆虫间接飞翔肌的结构和生理特性有许多不同于脊椎动物骨胳肌的特点。蜜蜂飞翔肌肌原纤维虽然也包含有粗、细两     

副肌球蛋白在意大利蜜蜂间接飞翔肌中的定位

肌肉收缩是由于肌原纤维中粗、细肌丝相互滑行的结果(Huxley,1988;Huxley,1983;Squire,1986)。许多无脊椎动物肌肉粗肌丝中除含有肌球蛋白外,还存在着含量不同的副肌球蛋白(陈明等,1984、1985)。我们曾经进行过一系列关于意大利蜜蜂(Apis mellifera ligustica Spin)间接飞翔肌原纤维排列及其粗肌丝亚丝结构的研究。间接飞翔肌的粗肌丝从Z-线延伸至另一Z-线(范世藩等,1966),分离的天然粗肌丝经变性剂(脲、胍)处理,可以散开成直径约为5nm的数根亚丝,在一些亚丝上     

粘虫(Mythimna separata Walker)迁飞行为研究

粘虫成虫期取食、飞翔、求偶或性反应交配和产卵一系列行为是各具相对独立性和顺序性的阶段.飞翔在取食、飞翔、求偶或性反应交配、产卵等期内都有发生,并有不同的飞翔特征,在迁飞中以飞翔期的飞翔最为重要.雌雄蛾的飞翔期在羽化后3～10日龄,因求偶、性反应前期变化而有变异.粘虫雌蛾求偶前期2～11d,平均为5.93d,雄蛾性反应前期3～11d,平均为7.14d.求偶、性反应与迁飞潜力有密切关系.随求偶、性反应前期加长,求偶、性反应前飞翔量呈"S"形曲线增长;求偶或性反应迟的个体有飞翔期,且有1～2个飞翔峰(日).根据有无飞翔期和求偶、性反应与飞翔量曲线确定雌蛾求偶前期大于5d,雄蛾性反应前期大于4d的个体为迁飞型个体.自然种群中雌蛾迁飞型个体占52.47%,雄蛾占97.14%;不同地理种群江苏、吉林、山东和广东1～4代粘虫,雌蛾迁飞个体依次占47.64%、49.29%、47.22%和68.22%,求偶前期平均依次为5.75、5.64、5.58和6.77d.影响求偶前期的生态因素主要是温度逐渐上升和食料不断老化,两者可能是引起粘虫迁飞的主要因素.讨论了粘虫成虫期行为、繁殖与迁飞潜力及迁飞过程的关系.     

棉铃虫飞翔的能源物质及消耗

研究结果表明棉铃虫Helicoverpa armigera(Hubner)初羽化个体的能源储备主要为甘油酯,1日龄成虫甘油酯和糖原的含量分别为每头3.6365mg和0.3658mg,通过成虫期的取食,二者的含量分别于羽化后4d和5d达到高峰(6.5707mg和2.3500mg)。对吊飞个体的测定表明甘油酯和糖原是棉铃虫飞翔的能源物质,蛋白质含量和飞行活动无明显的相关关系。4日龄成虫在飞行磨上吊飞66h,飞翔时间37.9943h,累积飞行216.8650km。累积消耗能量218.72J,其中甘油酯占85.87%,糖原占14.13%。     

营养和幼期密度对棉铃虫飞翔能力的影响

采自棉花、玉米、花生、绿豆和芝麻5种作物上的棉铃虫Helicoverpa armigera(Hubner),其飞翔能力依次为：棉花和玉米>花生>绿豆和芝麻。对室内利用人工饲料、棉铃、棉蕾和棉叶饲养的棉铃虫吊飞表明,取食人工饲料和棉铃的个体的飞翔能力数倍于取食棉叶者。成虫体重越大,飞翔能力越强。获得补充营养个体的飞翔距离是无补充营养者的2倍左右。本试验还研究了食物质量对棉铃虫卵巢发育的影响,结果显示成虫期的补充营养明显影响幼期营养较差个体的卵巢发育进程。对不同幼虫密度下发育个体的吊飞则表明成虫的飞翔能力和幼期密度关系不大。鉴于较差的营养条件和较高的幼期密度并不导致成虫飞翔能力的增加,本文认为,棉铃虫的远距离运动是成虫对羽化阶段不良环境的行为反应。     

粘虫飞行肌中与能量代谢有关的酶活性研究

该文报道粘虫Mythimna separata (Walker ) 蛹及不同日龄成虫飞行肌中与3 种代谢途径有关的5 种酶,即3-磷酸甘油醛脱氢酶(GAPDH)、3-磷酸甘油脱氢酶(GDH)、乳酸脱氢酶(LDH)、3-羟酰辅酶A 脱氢酶(HOAD)、柠檬酸合成酶(CS)活性的变化。成虫羽化后,这5 种酶的活性大多数都高于蛹期,表明成虫飞行肌与能量代谢有关的活动比蛹期高。不同日龄成虫飞行肌的能量代谢特点为：成虫羽化后糖酵解循环的活性增加;1 日龄进行糖酵解的能力较强,2 日龄即具备较强的脂肪代谢能力,2～5日龄糖及脂肪代谢的能力基本相当,但7日龄脂肪代谢的能力较强。1～7日龄粘虫蛾飞行肌具有较高的GDH 和LDH活性,这既是粘虫蛾飞行肌能进行高度有氧代谢的重要标志,也是其具有一定无氧代谢能力的最好说明,而飞行肌中较高的CS活性则是粘虫蛾具有较强飞行能力的重要保证。对成虫GAPDH∶HOAD 活性进行分析比较的结果还显示,粘虫蛾持续飞行的能源物质既有脂类也有糖类,而不仅仅只限于脂类。     

粘虫飞行对生殖及寿命的影响

该文报道了粘虫Mythimna separata（Walker）成虫飞行后产卵、交配及寿命的研究结果。1日龄成虫飞行6 h、12 h、18 h、24 h后的产卵前期均显著短于对照的,其中飞行6 h、12 h的比对照的短2天以上,产卵量均比对照的高。对1～5日龄成虫分别飞行23.5 h后的研究结果表明,1日龄飞行的产卵前期和上述结果相一致。2～4日龄飞行的与对照的没有显著差异,但产卵量则随飞行日龄的延迟而逐渐减少。5日龄飞行的产卵前期显著延长,产卵量已不到对照的一半。所有经过飞行的成虫产卵高峰日比对照的早1天。不同日龄成虫飞行时间、距离与成虫产卵量的关系为：1～3日龄飞行时间、距离长的个体产卵量也高;但4～5日龄的成虫飞行时间与距离越长,其产卵量越少,表现出明显的卵子发生飞行拮抗症(oogenesis-flight syndrome)。除了5日龄飞行的成虫交配率有所下降以外,所有经过飞行的成虫产卵历期、交配率及寿命与对照的没有显著差异。最后,根据这些结果,对粘虫迁飞的起飞时期,迁飞在粘虫生殖、种群动态及成灾规律中的作用进行了讨论。     

Structure of the cross-striated adductor muscle of the scallop

The structure of the cross-striated adductor muscle of the scallop has been studied by electron microscopy and X-ray diffraction using living relaxed, glycerol-extracted (rigor), fixed and dried muscles. The thick filaments are arranged in a hexagonal lattice whose size varies with sarcomere length so as to maintain a constant lattice volume. In the overlap region there are approximately 12 thin filaments about each thick filament and these are arranged in a partially disordered lattice similar to that found in other invertebrate muscles, giving a thin-to-thick filament ratio in this region of 6:1.The thin filaments, which contain actin and tropomyosin, are about 1 μm long and the actin subunits are arranged on a helix of pitch 2 × 38.5 nm. The thick filaments, which contain myosin and paramyosin, are about 1.76 μm long and have a backbone diameter of about 21 nm. We propose that these filaments have a core of paramyosin about 6 nm in diameter, around which the myosin molecules pack. In living relaxed muscle, the projecting myosin heads are symmetrically arranged. The data are consistent with a six-stranded helix, each strand having a pitch of 290 nm. The projections along the strands each correspond to the heads of one or two myosin molecules and occur at alternating intervals of 13 and 16 nm. In rigor muscle these projections move away from the backbone and attach to the thin filaments.In both living and dried muscle, alternate planes of thick filaments are staggered longitudinally relative to each other by about 7.2 nm. This gives rise to a body-centred orthorhombic lattice with a unit cell twice the volume of the basic filament lattice.     

Oblique section 3-D reconstruction of relaxed insect flight muscle reveals the cross-bridge lattice in helical registration.

In this work we examined the arrangement of cross-bridges on the surface of myosin filaments in the A-band of Lethocerus flight muscle. Muscle fibers were fixed using the tannic-acid-uranyl-acetate, ("TAURAC") procedure. This new procedure provides remarkably good preservation of native features in relaxed insect flight muscle. We computed 3-D reconstructions from single images of oblique transverse sections. The reconstructions reveal a square profile of the averaged myosin filaments in cross section view, resulting from the symmetrical arrangement of four pairs of myosin heads in each 14.5-nm repeat along the filament. The square profiles form a very regular right-handed helical arrangement along the surface of the myosin filament. Furthermore, TAURAC fixation traps a near complete 38.7 nm labeling of the thin filaments in relaxed muscle marking the left-handed helix of actin targets surrounding the thick filaments. These features observed in an averaged reconstruction encompassing nearly an entire myofibril indicate that the myosin heads, even in relaxed muscle, are in excellent helical register in the A-band.     

Flight muscle differentiation in nymphs of a dragonfly Anax imperator

Flight muscle fibers of Anax imperator nymphs, in different developmental stages are analyzed for several morphological features, such as the arragnement and numerical ratio of actin and myosin filaments, the pattern of the T system and sarcoplasmic reticulum, the number of microtubules and the fractional volume of mitochondria in each fiber. The T system is initially represented by longitudinal grooves on the cell surface, joined with vesicles of the sarcoplasmic reticulum; this pattern rapidly changes and the grooves start to break up into longitudinal segments. The thin to thick filament ratio is at first quite high (about 4-4.5:1) but rapidly falls to the final (3:1) when the myofibrils are well developed at the fiber periphery. Statistical analyses show that the measured values are significantly different in the various stages of development, also indicating a progressive reduction of the ratio variability. The reduction of thin to thick filament ratio and the variance decrease fit quite well with the hypothesis that the synthesis of actin and myosin depends on independently regulated messenger RNA molecules.     

Noctuid migration in Texas within the nocturnal aeroecological boundary layer

Long-distance migration of adult corn earworm moths (Helicoverpazea), and several other noctuid moth species, facilitates seasonalexpansion of pest populations and consequent increased infestationsof agricultural crops on a continental scale in North America.Long-term field studies of population dynamics and migratoryflights of H. zea and fall armyworm (Spodoptera frugiperda)in the United States were evaluated using X-band radar observationsand profiles of atmospheric conditions. These studies identifiedcharacteristic patterns of migratory flight that are largelyassociated with vertical profiles of temperature and wind speed.Collective patterns of moth migrations were generally highlycorrelated with wind headings, but often at a significant angulardeviation. Preliminary analyses are presented between moth distributionsin the aerosphere estimated from discrete moth counts usingX-band radar and bulk reflectivity data from NEXRAD Dopplerradar. Identification of associations between atmospheric factorsand noctuid population dynamics and migratory flights will improvethe ability to predict infestations by pest species throughouttheir broad seasonal range expansion.     

The length–tension curve in muscle depends on lattice spacing

Classic interpretations of the striated muscle length–tension curve focus on how force varies with overlap of thin (actin) and thick (myosin) filaments. New models of sarcomere geometry and experiments with skinned synchronous insect flight muscle suggest that changes in the radial distance between the actin and myosin filaments, the filament lattice spacing, are responsible for between 20% and 50% of the change in force seen between sarcomere lengths of 1.4 and 3.4 µm. Thus, lattice spacing is a significant force regulator, increasing the slope of muscle''s force–length dependence.