条背萤幼虫水生适应性形态与游泳行为研究

研究了条背萤Luciolasubstriata幼虫的形态特征及其对游泳行为的适应。形态及扫描电镜观察发现,条背萤幼虫存在二态现象。1～2龄幼虫虫体扁平,多毛。有7对呼吸鳃,分别位于腹部第1～7节。3～6龄幼虫虫体扁平呈船形,无呼吸鳃,靠气管呼吸。二者均具有扁平桨状的足、燕尾状尾节及位于尾节末端的圆柱形粘附器官。条背萤幼虫游动时身体腹面朝上,呈仰泳姿态,足向后划水。3～6龄幼虫仰泳时足共有8种摆动姿势。幼虫仰泳时足摆动1个周期所需时间为(0.611±0.16)s。腹部末端可上下左右摆动,当幼虫向前游动时,尾部上下摆动1个周期所需时间为(1.795±0.44)s。幼虫的游泳速度为(0.85±0.16)mh。仰泳中的幼虫改变方向时,头部和尾部同时向身体的一侧弯曲,当头部与尾部呈近90°时,幼虫用力将尾部伸直,此时水产生一个反作用力继续推动幼虫转向,幼虫转向的范围为0～90°。条背萤2种类型幼虫呼吸系统的不同决定着幼虫外部形态的差异及游泳行为的不同,而导致这种呼吸系统、形态及运动行为不同的原因很可能是条背萤对环境的适应性进化。     

条背萤成虫与幼虫发光器的超微结构观察

对水生萤火虫——条背萤Luciola substriata(Gorham)成虫和幼虫发光器的超微结构进行研究。结果表明,成虫发光器由明显的2层组成:反射层和发光层。反射层由排列紧密的“尿酸囊泡”构成,具有发达的气管结构,对光起反射作用;发光层由大量发光细胞构成,内含典型的发光颗粒、线粒体、内质网及大量糖原,该层通过发光细胞胞质内的生化反应而发光。2层均由非细胞层膜包被,间距25~30μm。发光器腹节由外向内依次为表皮、发光层、反射层和内部细胞层。幼虫发光器球形,由背射层和发光层构成,由非细胞层膜包被。背射层由单层柱状细胞构成,内含大量“尿酸囊泡”。发光层细胞膜相互绞缠,含有2种类型的发光颗粒:“致密”型和“凋亡”型,含有大量的线粒体和无定形颗粒,发光细胞之间分布着大量的气管、微气管及神经末梢,可观察到神经突触。与条背萤相比,陆生种成虫反射层和发光层均无非细胞层膜包被,2层间无明显间距,发光颗粒形状不规则,气管通常形成2分支;陆栖种幼虫发光层形状差异较大,背射层由单层或2~4层细胞构成;相似点在于,成虫发光器都由均由反射层和发光层构成,发光细胞内都含发光颗粒、线粒体及大量糖原,都具有发达的气管结构,发光颗粒相似。幼虫发光器都由背射层和发光层构成,都具有发达的气管和直接的神经支配,发光颗粒相似,都由非细胞层膜包被。     

灰胸突鳃金龟生物学特性研究

灰胸突鳃金龟是沙区的重要地下害虫,以幼虫为害花生等作物的地下部分。室内饲养和田间观察表明:该虫1年多发生1代,以3龄和2龄幼虫越冬。幼虫期326.3天;蛹期24.4天。成虫羽化一般在5月下旬和6月上旬。雄成虫有较强的趋光性,雌成虫趋光性较弱,成虫寿命20天。每头雌虫产卵8～74粒,散产在5～10cm深的松温沙土中。室内饲养:卵历期平均18.45天,田间观察卵孵化盛期在7月上中旬。     

光滑足距小蠹虫道真菌的组成和变化

本文同时采用分离和电镜扫描技术研究了光滑足距小蠹Xylosandrus germanus(Blan dford)不同发育阶段坑道和贮菌器内真菌种类的组成和变化。Ambrosiella hartigii是光滑足距小蠹扩散、蛀孔、越冬和体壁新硬化的成虫贮菌器内唯一分离到的真菌,而刚羽化的雌成虫贮菌器中没有分离到任何真菌种类,体壁新硬化的成虫贮菌器中真菌的分离频率最低。坑道内共分离到4种真菌：A. hartigii,Acremonium kiliense和2种镰刀菌Fusarium spp.。从卵期到蛹期的坑道中,A. hartigii总是能被分离到,占分离物总数的百分率较高,达40％～60％;而在成虫期坑道中,A. kiliense和Fusarium sp.1被分离率较高,都为34.6％。扫描电镜观察表明,A. hartigii为卵期到蛹期坑道中的优势种,而镰刀菌Fusarium spp.则是成虫期坑道中的优势种。这些结果均表明,Ambrosiella hartigii,Acremonium kiliense和2种镰刀菌Fusarium spp.是光滑足距小蠹的虫道真菌,而且这些真菌种类组成和优势种类是随着蠹虫的发育阶段而变化的。真菌种类的组成和变化可 能与幼虫和成虫的营养需求以及虫道真菌的生长特性有关。     

黄翅菜叶蜂的初步研究

黄翅菜叶蜂为油菜、白菜、萝卜等十字花科植物主要害虫之一。在四川凉山地区一年可发生五个重迭世代,以老熟幼虫在土壤中作蛹茧越冬,越冬成虫四月上旬出现,第一代成虫发生于5月上旬-6月中旬,第二代6月上旬-7月中旬,第三代7月上旬-8月下旬,第四代8月中旬-10月中旬,10月间开始越冬。成虫量与油菜生育期有极密切的关系,子叶期成虫量为80.1-93.0%。成虫有较强的伪死性,雨天、阴天伪死性较强,晴天较弱,成虫雨天不活动产卵。雌虫一般多于雄虫,雌虫为68.4-70.9%。雌虫最多产卵量为318粒,最少为35粒。雌成虫寿命5-12天,雌虫3-9天。卵期4-41天,卵孵化率一般为93.3-100%。幼虫有5龄,幼虫期10-36天,1-3龄幼虫多躲在叶背,不易发觉,老熟幼虫潜入1-11厘米土层内化蛹,前蛹期5-21天,蛹期7-25天。成虫初羽化时在土面爬行数分钟才能飞翔,晴天飞翔力强。耕翻土壤对蛹有一定机械损伤,暴露于土面的蛹在自然阳光下照晒其死亡率很高。 666、DDT对黄翅菜叶蜂幼虫具有极强的毒杀效果。敌百虫较差。     

李拭库蠓生活史的研究(双翅目:蠓科)

在重庆地区所作有关李拭库蠓生活史的研究,观察在实验条件结合自然情况下进行。设计了虫尸培养法,在虫尸培养内幼期处于严格控制的条件下,可以确切地观察卵的孵化、幼虫蜕皮、化蛹和羽化等现象,解决了库蠓变态发育的规律。 李拭库蠓的主要动物宿主是牛和家猪,雌虫吸取血液后糖类对卵巢的发育并不是必需的。9—11.5℃时胃血消化和卵巢发育仍能缓慢地进行。雌虫在20—28℃时一般在吸血后第3—4日间产卵,产卵数为40—213。 幼期发育的时间随温度和食物而改变。虫尸培养,在27±1℃时自卵至成虫为28—44天(卵期3天:第一龄幼虫6—8天:第二龄幼虫5—10天;第三龄幼虫6—9天:第四龄幼虫5一11天;蛹期3天)。当6.8—22℃时,共需101—212天(卵期3—8天;第一龄幼虫9—31天;第二龄幼虫27—35天;第三龄幼虫34—48天:第四龄幼虫25—80天:蛹期3—10天)。夏季室温条件下泥土培养基内自卵至成虫为22—32天。     

梨斑叶甲的发生与防治

记述了梨斑叶甲各虫期的形态。该虫每年发生1代,以成虫在土内越冬。3月下旬出蛰取食,产卵于寄生叶背面。卵期7～10天,幼虫期20天左右,蛹期11天左右,成虫期360天左右。在幼虫三龄以前用80％敌敌畏乳油、40％乐果乳油、20％杀灭菊酯乳油喷雾防治均有良好效果。     

凹眼萤——一类特殊的萤火虫

凹眼萤的发光虫态仅限于幼虫和幼虫型的雌成虫,是一类特殊的萤火虫。文章综述凹眼萤科的形态特征、分类历史和当前分类地位的争议及其地理分布。以大场凹眼萤为例,结合作者的野外观察,介绍凹眼萤的生物学习性。简要概述凹眼萤的胚胎学及分子生物学研究概况。     

大叶黄杨尺蠖(Abraxas miranda Butler)的研究

一、大叶黄杨尺蠖(Abraxas miranda Butler)是重要的园林害虫之一,为害卫矛科的两种植物,即:大叶黄杨与爬行卫矛。在中国分布于江苏、浙江、贵州及东北等地。 二、大叶黄杨尺蠖在上海一年发生三代,但在室内饲育可完成四代,以蛹在土中越冬。第一代成虫自4月上旬开始羽化,幼虫自4月下旬开始为害,至5月下旬进入蛹期。第二代成虫自6月上旬开始羽化,幼虫自6月中旬开始为害、直至8月下旬进入蛹期。第三代成虫自8月中旬开始羽化、幼虫自9月上旬开始至11月中旬进入蛹期。 三、根据室内饲养,成虫的寿命第一代雄虫平均7.8天,雌虫平均9.6天;第二代雄虫平均11天,雌虫平均15.4天;第三代雄虫平均9天,雌虫平均10天;第四代雄虫平均12天,雌虫平均14.5天。卵期第一代为14.5天,第二代8.6天,第三代9天,第四代12天。幼虫期第一代平均34.9天,第二代平均23.4天,第三代平均25天,第四代平均58天。蛹期第一代平均11.4天,第二代平均45.8天,第三代平均15.9天,第四代为越冬蛹。 四、成虫飞行力很弱,白天栖息在大叶黄杨树下或附近草丛中,晚上活动,趋光性不强。成虫羽化多在下午3—5时,羽化后即可交尾,一般交尾时间为6—7小时,最长可达11小时,交尾后7小时即行产卵,每一雌蛾可产卵360余粒。 五、幼虫共五龄,羽化后3、4小时就开始取食,受     

黑广肩步甲形态特征及其生物学特性

记述了黑广肩步甲CalosomamaximocicziMorawitz各虫态的形态特征、生物学特性。在山东栖霞地区,该虫1年发生1代,以成虫在土壤中越冬。成虫在5月中旬至9月末发生,8月产卵。卵期平均为5d;幼虫共3龄,历期分别为5～6d,4～5d,5～6d;预蛹期约为25d;蛹期为24～27d。成、幼虫以多种鳞翅目幼虫为食。     

条背萤幼虫不同发育阶段呼吸系统构造的观察和比较

通过显微解剖,结合透射电镜和扫描电镜,观察比较了条背萤Luciola substriata幼虫两个不同发育阶段呼吸系统的差异。结果表明：1～2龄幼虫的呼吸系统中只有气管无气囊,3～6龄幼虫的呼吸系统中气管和气囊并存。1～2龄幼虫的尾气门和3～6龄幼虫的腹部侧气门及尾气门结构没有差异。透射电镜观察提示条背萤1～2龄幼虫体壁上的毛状物为气管鳃。     

Stage and segment specificity of the secretory cell of the dermal glands of the tobacco hornworm, Manduca sexta

The pair of epidermally derived Verson's glands on each segment of the tobacco hornworm, Manduca sexta, secretes at ecdysis proteinaceous products which coat the epicuticle. These proteins are produced by a single secretory cell which displays both stage- and segment-specificity during development. Three major 12-kDa polypeptides are synthesized at the larval molts, while higher molecular weight (14-93 kDa) polypeptides are produced at the pupal molt. In the pupa, but not in the larva, there are three segment-specific protein patterns, each involving both qualitative and quantitative differences: (1) thoracic (T) segments 1 and 2; (2) T3 and abdominal (A) segment 1; (3) A2-A8. Larval-specific proteins were found to be synthesized in low amounts throughout the penultimate fourth instar, with enhanced synthesis occurring during the molt, coincident with the molting surge of ecdysteroids. Synthesis of the major pupal products commenced about the time of wandering, with enhanced synthesis occurring throughout prepupal development, coincident with the prepupal surge in ecdysteroids. The onset of synthesis of the major pupal products differed, both within and between segments. Culture of fifth instar Day 2 glands in vitro showed that this synthesis depended on 20-hydroxyecdysone. The differential regulation within and between segments observed in vivo was also seen in vitro.     

条背萤的闪光求偶行为

水栖萤火虫条背萤Luciola substriata (Gorh.)发出单脉冲周期性特异闪光信号进行求偶。室外观测发现,在23℃、86% RH时,雄萤飞行求偶闪光信号脉冲闪光持续时间为0.52 s,间隔时间为0.28 s,闪光信号的最大亮度为0.6 lx; 雌萤求偶信号周期为 0.67 s,最大亮度为0.4 lx。雄萤发出求偶信号0.22 s后,雌萤发出两个连续的回应信号。第一个回应信号为0.49 s,第二个为0.41 s, 两个回应信号的间隔时间为0.11 s。雄萤发现雌萤回应信号后,降落至离雌萤5～10 cm处,继续发出闪光信号,但闪光脉冲频率减小,闪光脉冲时间为1.23 s,间隔时间为0.50 s。条背萤交配时呈“V”或“一”字形交配姿势。     

黑紫蛱蝶生物学特性的研究

黑紫蛱蝶Sasainia funebris(Leech)一年发生1代,11月份以四龄幼虫在寄主植物枝条上越冬．翌年4月越冬幼虫眠起．6月化蛹,7月中旬为成虫羽化盛期。各虫态历期：卵6．5—7天,幼虫共6龄,计300天左右,蛹12—13天,成虫10—13天。同时,还记述了该蝶各虫态的形态特征、生活习性和天敌情况等。     

草地贪夜蛾海藻糖合成酶基因的克隆、时空表达谱及对温度胁迫的响应

【目的】本研究旨在通过克隆草地贪夜蛾Spodoptera frugiperda的海藻糖合成酶(trehalose-6-phosphate synthase)基因SfTPS,分析其在草地贪夜蛾不同发育阶段、不同组织中的表达水平及不同温度胁迫时5龄幼虫中的相对表达量,为进一步探究TPS在草地贪夜蛾生长发育及抗逆应激反应中的功能奠定基础。【方法】运用RT-PCR技术克隆草地贪夜蛾SfTPS的全长编码区,并进行生物信息学分析。运用RT-qPCR技术检测SfTPS在草地贪夜蛾不同发育阶段(卵、1-6龄幼虫、蛹和成虫)、5龄幼虫不同组织(体壁、中肠和脂肪体)中和经短期(2, 4和8 h)高(35℃)低温(10℃)胁迫后5龄幼虫中的表达变化。【结果】克隆获得2 571 bp的草地贪夜蛾TPS cDNA序列,命名为SfTPS(GenBank登录号： MT920672),全长开放阅读框(ORF)长2 481 bp,编码的826个氨基酸具有TPS和TPP两个保守结构域。同源比对和系统进化分析表明,昆虫TPS蛋白具有较高的保守性,SfTPS与斜纹夜蛾S. litura的TPS亲缘关系最近,序列一致性达到99.15%。SfTPS中α-螺旋、β-折叠和无规则卷曲占比分别为38.14%, 12.23%和48.55%;SfTPS的三级结构为同源二聚体。RT-qPCR结果表明,SfTPS在草地贪夜蛾卵期和1-5龄幼虫期低表达,在6龄幼虫期、蛹期和成虫期高表达,且草地贪夜蛾变态前后SfTPS的表达量变化较大。组织分布结果显示,SfTPS在5龄幼虫脂肪体中表达量最高。草地贪夜蛾5龄幼虫经2~8 h低温(10℃)和高温(35℃)胁迫后,SfTPS的相对表达量显著高于对照(25℃),分别为对照的4.43~9.34和2.50~6.03倍。【结论】SfTPS基因在草地贪夜蛾生长发育过程及抵御高低温度胁迫中可能具有重要作用。     

长蝎蛉幼期形态附生物学记述

【目的】蝎蛉科(Panorpidae)是长翅目(Mecoptera)最大的科,是重要的生态指示昆虫。然而,由于对环境条件要求苛刻,饲养困难,其幼期研究很不充分。【方法】本研究通过人工饲养成虫获得了长蝎蛉Panorpa macrostyla Hua的卵、幼虫和蛹等全部虫态,运用光学显微镜和扫描电子显微技术观察了其超微形态,并简要记载了其生物学特性。【结果】长蝎蛉每年发生1代,成虫发生于6月末至8月初。卵椭球形,卵壳表面覆盖一层隆起的网状结构。幼虫蠋型,具3对分4节的胸足和8对不分节的腹足;头壳高度骨化,具1对由26个小眼组成的复眼和1对3节的触角,口器咀嚼式;腹部第1-9节背面具有成对的背毛突,第10节仅有1根背毛突,腹部末端具有一个可伸缩的吸盘;呼吸系统为周气门式,具1对前胸气门和8对腹气门。幼虫共4个龄期,以预蛹期在土室内越冬。蛹为强颚离蛹,外形接近成虫,雄蛹腹部末端膨大。【结论】基于幼虫形态特征,长蝎蛉明显区别于新蝎蛉属Neopanorpa、华蝎蛉属Sinopanorpa、双角蝎蛉属Dicerapanorpa以及单角蝎蛉属Cerapanorpa幼虫。然而,长蝎蛉幼虫头部刚毛L2和SO2,腹部末节刚毛D2,SD1和SD2端部均膨大呈棒状,与蝎蛉属Panorpa其他种类区别明显,表明长蝎蛉的属级地位需要进一步研究。     

Hemolymph concentrations of host ecdysteroids are strongly suppressed in precocious prepupae of Trichoplusia ni parasitized and pseudoparasitized by Chelonus near curvimaculatus.

Regulation of ecdysteroid production in lepidopteran prepupae was studied using a parasitic wasp (C. near curvimaculatus) which specifically suppresses host prepupal ecdysteroid production after the induction of precocious host metamorphosis. At the developmental stage at which the hemolymph of the unparasitized metamorphosing host has its maximum titer of prepupal ecdysteroids, the hemolymph of 4th instar "truly parasitized" hosts (hosts with a surviving endoparasite) had a strongly reduced ecdysteroid titer. However, during the photophase about 12 h later, just prior to emergence of the parasite larva, an ecdysteroid peak was observed in the host hemolymph. Fourth instar pseudoparasitized prepupal hosts (in which the endoparasite was not present or died early in development) exhibited a sustained suppression in the hemolymph ecdysteroid titer. Small 5th instar pseudoparasitized hosts, which normally would molt to a 6th instar prior to metamorphosis, but which precociously attained the prepupal stage, also had a strongly reduced ecdysteroid titer. The late increase observed in truly parasitized hosts could be completely prevented by surgical removal of the parasite 24 h earlier, resulting in a titer similar to that in pseudoparasitized hosts. HPLC analysis of ecdysteroids in normal, truly parasitized, and 4th or 5th instar pseudoparasitized prepupae showed that both ecdysone and 20-OH ecdysone* were suppressed in truly and pseudoparasitized prepupae, with ecdysteroid levels being lowest in pseudoparasitized hosts. These data, and those of Brown and Reed-Larsen (Biol Contr 1, 136 [1992]), showing endoparasite secretion of ecdysteroids just prior to its emergence from the host, strongly indicate that: (1) the prepupal peak in truly parasitized hosts originates from the endoparasite, and (2) the low level of ecdysteroids in pseudoparasitized hosts results from the host's intrinsic inability to express a normal level of prepupal ecdysteroid titer. While precocious 4th or 5th instar prepupae of similar size had similarly suppressed ecdysteroid titers, smaller 4th instar prepupae had a lower ecdysteroid titer than larger, precocious 5th instar prepupae. Rare 5th instar pseudoparasitized prepupae that were of nearly normal size showed a prepupal ecdysteroid titer distinctly greater than those of the usual smaller, precocious 5th instar prepupae. The data suggest that the competence of the host to express a normal hemolymph titer of prepupal ecdysteroids is more closely correlated with the size of the prepupae than with the instar attained.     

Titres of juvenile hormone I,II and III in Spodoptera littoralis (Noctuidae) from the egg to the pupal moult and their modification by the egg-larval parasitoid Chelonus inanitus (Braconidae)

Physico-chemical analysis of juvenile hormones (JHs) of Spodoptera littoralis revealed highest quantities in the second half of embryonic development and in newly hatched 1st instar larvae. At these stages, mostly JH II, JH I and little JH III were found, while in later stages only JH II and JH III were found. Titres fluctuated in a similar manner in all larval instars, being lowest during the moults. In last (=6th) instar larvae, JHs disappeared in the late feeding-digging stage and again increased in the early prepupal stage. Parasitisation with Chelonus inanitus, a solitary egg-larval parasitoid which induces in its host the precocious onset of metamorphosis in the 5th instar, did not alter JH homologue composition but led to a disappearance of JHs in the 5th instar. Implantation of a parasitoid larva into early 5th instar larvae containing polydnavirus/venom caused a drop in the JH titre which indicates that the parasitoid larva plays an important role in the manipulation of the host's JH titre. In the parasitoid larva, only JH III was found; titres were highest in the 2nd larval instar, a stage when the host is in the 5th instar and contains almost no JHs. Thus, JHs of the parasitoid and the host fluctuate in an independent manner.