不同家蚕品系的耐热性特征

研究了家蚕Bombyx mori 3个品系(Pure Mysore,NB4D2和CSR2）5龄幼虫和蛹在不同温度（35,38和40℃）下的耐热性,采用Probit分析测定了它们在各温度下的LT50值和置信限。结果表明：多化性品系Pure Mysore在高温下的存活率高于两个二化性品系NB4D2和CSR2,而两个二化性品系中NB4D2表现出更好的耐热性。家蚕幼虫接触38℃高温6 h和40℃高温3 h后,其血淋巴中出现90,70和29 kDa的热激蛋白条带。在恢复过程中,NB4D2和CSR2的血淋巴中未见29 kDa蛋白条带,而Pure Mysore幼虫的血淋巴中29 kDa蛋白仍然表达。当幼虫置于高温下时,血淋巴中90和70 kDa蛋白表达,但是检测不到29 kDa蛋白。研究认为热激蛋白表达与热带家蚕不同品系的耐热性以及与同一品系不同发育阶段的耐热性具有相关性。     

粘虫的血糖代谢

本文通过纸上层析和化学方法,研究了粘虫在蛹化前后各虫期血淋巴液中的总糖、海藻糖、葡萄糖和血淋巴的还原值,并与蓖麻蚕进行了比较。此外,还测定了血淋巴海藻糖酶的活性变化。结果表明:1)在蛹化前后血淋巴液中的总糖与海藻糖,自末龄幼虫进食以后开始大量积累,到幼虫老熟时达最高。在幼虫蜕皮和停食化蛹过程,血糖含量明显地减少。雌体含量均高于雄体。血淋巴液中的糖量变化与粘虫的生长发育有密切关系。2)和蓖麻蚕相似,在蜕皮和停食以后的化蛹过程,血淋巴中的还原值显著增加,这种增加主要是由于葡萄糖、核糖以及其它还原物质的出现或数量的增加所引起。3)末龄幼虫血淋巴液中的总糖及海藻糖的百分比含量,均比同虫期的蓖麻蚕的含量低2—5倍。粘虫幼虫血淋巴中的海藻糖量只占总糖的66.3%—94%,而蓖麻蚕则为98%—100%。4)幼虫血淋巴中的海藻糖酶活力与家蚕、蓖麻蚕的相同,均在进食期间无活力表现或活力极低;在幼虫蜕皮和化蛹过程则明显出现活力。5)血淋巴液中的糖量变化与海藻糖酶活力变化有明显的负相关。文中还分析和讨论了粘虫血糖代谢的特点以及各种糖类物质在生长发育中的作用。     

桑叶营养对家蚕血淋巴阳离子水平的调节作用

调查了取食不同品种桑树（M-5, S-36和V-1）叶片的家蚕（多化性品种Pure Mysore、 二化性品种NB4D2和CSR2）5龄幼虫血淋巴中阳离子的变化。结果表明: 家蚕幼虫血淋巴中Na+浓度低, K+和Mg2+浓度很高, Ca2+浓度较高。在幼虫活跃取食期间, 血淋巴中阳离子水平显著提高。血淋巴中阳离子水平与排泄物的量呈负相关。血淋巴中阳离子水平受阳离子外泌的控制。与非取食阶段相比, 取食阶段的阳离子清除速率低。家蚕二化性品种的血淋巴阳离子水平比多化性品种PM高出30%。结果说明家蚕品种对家蚕血淋巴阳离子变化的影响显著大于桑树品种或家蚕个体发育的影响。     

家蚕感染蛹虫草后的生理生化变化

蛹虫草分生孢子侵染5龄家蚕Bombyx mori后,家蚕血淋巴中总糖、海藻糖、蛋白质和甘油酯含量均有不同程度的下降,其中甘油酯含量下降最为明显。海藻糖酶活性在侵染初期也明显降低。接种后家蚕体内的保护酶超氧化物歧化酶、过氧化物酶和过氧化氢酶活性也有较大变化,其中超氧化物歧化酶活性上升最为明显,在4日内由441.841 U/mL升至601.255 U/mL。     

Ni~(2+)对不同发育阶段斜纹夜蛾虫体血淋巴能量物质的影响

研究了饲料中不同浓度的Ni2+(140mg/kg)对连续3个世代斜纹夜蛾Spodoptera litura Fabricius6龄末幼虫、蛹和成虫血淋巴中能量物质总糖、蛋白质和脂肪含量及血淋巴中热量值的影响。结果表明,Ni2+胁迫1个世代,6龄末幼虫、蛹和成虫血淋巴中的总糖含量均低于对照,而血淋巴中的蛋白质含量则在低浓度Ni2+胁迫下增高,在高浓度Ni2+胁迫下降低;只有受120mg/kg Ni2+胁迫的6龄末幼虫血淋巴的脂肪含量高于对照,而蛹和成虫血淋巴中的脂肪含量及热量值均低于对照。在Ni2+胁迫的第2、3代,6龄末幼虫、蛹和成虫血淋巴中的总糖、蛋白含量和热量值与饲料中Ni2+浓度的反应关系均表现为低浓度Ni2+胁迫增加而高浓度Ni2+胁迫降低的趋势;然而,血淋巴中的脂肪含量随饲料中Ni2+浓度的增加而降低。因此,重金属Ni2+对S.litura能量物质的影响与虫体内能量物质的种类和虫体的发育阶段有一定的关联。     

柞蚕蛹脂肪体和血淋巴中糖类含量动态的温度和光周期效应

本文研究了柞蚕Antheraea pernyti滞育蛹和非滞育蛹的糖类含量动态.两类柞蚕蛹血淋巴中所含糖类均为海藻糖和葡萄糖,但葡萄糖始终处于极低水平.滞育蛹的脂肪体糖原与血淋巴海藻糖之间存在相互转化的关系,这种转化受温度的制约.温度对于滞育的终止和海藻糖积累量影响很大.在保种温度范围内,滞育蛹接触低温越早,温度越低,海藻糖积累量越高.非滞育蛹即使经长期低温(0℃左右)处理,体内也不积累海藻糖,且耐寒力显著低于滞育蛹.在25℃条件下,光周期对滞育蛹和非滞育蛹的影响不同.     

鞭角华扁叶蜂蜕皮甾类激素滴度的变化

用放射免疫分析法测定了鞭角华扁叶蜂Chinolyda flagellicornis末龄幼虫及滞育预蛹血淋巴中蜕皮甾类激素滴度。结果表明,末龄幼虫血淋巴中蜕皮甾类激素滴度在第2和4天各有一高峰;滞育预蛹血淋巴中保持一定滴度的蜕皮甾类激素,并随发育时期的不同有所波动;预蛹化蛹前一周血淋巴中蜕皮甾类激素滴度存在两个与变态相对应的峰值。表明鞭角华扁叶蜂的滞育与蜕皮甾类激素相关。     

感染布氏白僵菌后油松毛虫血淋巴中海藻糖酶活性、海藻糖和葡萄糖含量的变化

为了揭示病原真菌白僵菌Beauveria侵染昆虫过程中如何利用虫体内糖类物质作为自身营养, 本研究测定了布氏白僵菌Beauveria brongniartii (Sacc.) Petch （2382菌株）感染油松毛虫Dendrolimus tabulaeformis Tsai et Liu幼虫后, 虫体血淋巴中酸性海藻糖降解酶活性及海藻糖和葡萄糖含量的变化。油松毛虫4龄幼虫感染菌株孢子悬浮液后, 血淋巴中酸性海藻糖降解酶的活性明显高于对照组, 感染后第3天酶活性达到最大值（0.2786 U/mg）, 此后第4-6 天酶活性逐渐降低; 染菌后的6 d中, 血淋巴中海藻糖含量显著低于对照组, 同样在感染后第4天其含量逐渐降低, 第6天时降到最低值。相比之下, 处理组血淋巴中的葡萄糖含量显著高于对照组; 处理组其含量在第1-3天内呈现快速升高趋势, 在第3天达到最大值（7.7615 mmol/L）, 然后逐渐降低。结果说明, 白僵菌侵入昆虫血淋巴后, 菌株代谢产生酸性海藻糖降解酶, 将血淋巴中的海藻糖水解成为葡萄糖, 然后为真菌利用, 破坏了虫体内的血糖平衡, 这是一个相互连接的生理代谢和生化反应过程。     

蓖麻蚕血淋巴蛋白质代谢的研究

本文研究了不同发育期的蓖麻蚕血淋巴中蛋白盾、游离氨基酸和核酸的含量变动,以及氨基酸激活酶活性的改变。血淋巴蛋白质的含量在五龄中期以前增加极慢,以后则急剧上升,至预蛹期达最高峰,化蛹时减少,在蛹的前半期变动不大,至后期则显著下降。血淋巴中游离氨基酸、氨基酸激活酶和核酸的变化各与蛋白质的变动有一定的相关性,反映了这些物质与血淋巴蛋白质在代谢上的相互联系。氨基酸激活酶活性的变化和蛋白质总含量的变化基本上相一致。游离氨基酸含量的减少往往伴随着蛋白质的相应增多。而RNA:DNA比的增加则一般发生于蛋白质的增加之前。从这几种物质的变动情况及相互联系,分析了血淋巴中蛋白质合成的可能性,并讨论了血淋巴蛋白质在发育中的作用。     

Ni2+胁迫对斜纹夜蛾幼虫血淋巴中能量物质水平的适应性调节

为明确食物中重金属胁迫对昆虫血淋巴能量物质和生长的影响,本研究测定了饲料中不同浓度的Ni²⁺ （1~40 mg/kg）对连续3个世代斜纹夜蛾Spodoptera litura Fabricius 5龄始龄（0 h）至6龄末幼虫（分别记为0,24,48,72,96和120 h幼虫）血淋巴中能量物质总糖、蛋白质和脂肪含量,血淋巴中热量值及5龄和6龄幼虫体重的影响。结果表明：第1和2代48 h和96 h幼虫血淋巴的总糖含量均低于对照;而连续3代其他处理幼虫血淋巴中的总糖含量均在低浓度Ni²⁺（1~5 mg/kg）胁迫下增高,在高浓度Ni²⁺ （20~40 mg/kg）胁迫下降低。连续3个世代的Ni²⁺胁迫均显著降低了0~48 h幼虫血淋巴中的蛋白含量;低浓度Ni²⁺（1~5 mg/kg）胁迫增加了连续3代72~120 h幼虫血淋巴中的蛋白含量,而高浓度Ni²⁺（20~40 mg/kg）胁迫只降低了第1代72~120 h幼虫以及第2代72 h幼虫血淋巴中的蛋白含量。第1代0 h,48~72 h和120 h幼虫血淋巴中的脂肪含量在1~20 mg/kg Ni²⁺胁迫下均高于对照,但24 h和96 h幼虫血淋巴中的脂肪含量均低于对照中的含量。连续3代0~48 h幼虫血淋巴中的热量值均随饲料中Ni²⁺浓度的增加而降低;低浓度Ni²⁺胁迫（1~5 mg/kg）增加,而高浓度Ni²⁺（20~40 mg/kg）的胁迫降低第2和3代72 ~120 h幼虫血淋巴中热量值。同时,低浓度Ni2+胁迫增加而高浓度Ni²⁺胁迫降低了第3代5龄和6龄幼虫的体重。因此推测,Ni²⁺胁迫对S. litura幼虫血淋巴的能源物质含量以及热量值的影响与能量物质的种类、虫体的发育阶段和Ni²⁺的胁迫世代等都有一定的联系。     

Fate and effects of the trehalase inhibitor trehazolin in the migratory locust (Locusta migratoria)

Trehalose is the main haemolymph sugar in many insect species. To be utilized trehalose must be hydrolysed into its glucose units by trehalase (EC 3.2.1.28). Inhibitors of trehalase have attracted interest as possible pesticides and tools for studying the regulation of trehalose metabolism in insects. To make full use of these inhibitors requires knowledge of their fate and effects in vivo. To this end we have measured trehazolin in locusts using a method based on the specific inhibition of a trehalase preparation. After injection of 20 μg, trehazolin decreased in haemolymph with a half-life of 2.6 days and after 10 days almost 95% had disappeared. Trehazolin did not reach the intracellular water space of locust tissues, but appeared with full inhibitory potency in locust faeces, suggesting that it was not metabolized, but quantitatively eliminated via the gut. Haemolymph trehalose increased transiently upon trehazolin injection, it was maximal after 3 days, then decreased and reached control level after 10 days. Inhibition of flight muscle trehalase by trehazolin was prolonged and still conspicuous 21 days post injection, suggesting that trehazolin inhibits trehalase activity irreversibly in vivo and that recovery requires de novo enzyme synthesis.     

Soluble and particle-bound trehalase in extracts from larvae, pupae, and adults of Musca domestica

Trehalase activity was measured in tissue homogenates and extracts from the larval, pupal, and adult stages of Musca domestica, the common housefly. The tissue homogenates were separated into soluble and particlebound fractions by differential centrifugation, and the trehalase activities of the fractions were measured. The trehalase specific activity (units of enzyme/mg protein) in homogenates from adult insects was nearly twenty times greater than activity in homogenates of larvae. Homogenates of pupae showed intermediate values. In both the adults and larvae the enzyme activity was approximately evenly distributed between soluble and particle-bound forms, whereas 95 per cent of the trehalase activity in the extract of pupae was in the soluble fraction. The results show that the form and amount of trehalase present during housefly development is adjusted to accommodate the enzyme's physiological rôle of splitting trehalose to glucose for the insect's use as an energy source.     

变温对粘虫生殖及主要能源物质代谢的影响

【目的】明确变温与粘虫Mythimna separata(Walker)生长发育和生殖的关系及变温条件下粘虫主要能源物质代谢的变化规律。【方法】将粘虫卵置于光周期均为14L∶10D,温度分别为25℃和30℃日恒温和白天30℃、夜晚20℃日变温的条件下饲养,观察记录25℃和30/20℃下的成虫产卵及卵巢管发育情况,再取30℃和30/20℃下饲养获得的3龄幼虫、6龄幼虫、蛹和1日龄成虫,测定其糖原、海藻糖和甘油三酯3种能源物质的含量及海藻糖酶、3-磷酸甘油醛脱氢酶、3-磷酸甘油脱氢酶及3-羟酰辅酶A脱氢酶等4种主要能源物质代谢酶的活性。【结果】25℃与30/20℃饲养条件下相比,1日龄雌成虫卵巢管发育明显滞后,但单雌产卵量显著较多;蛹期糖原、海藻糖和甘油三酯的含量均高于3龄和6龄幼虫,成虫期各能源物质含量均较低。30/20℃日变温下粘虫体内供试3种能源物质的含量显著高于30℃日恒温(6龄幼虫和蛹期甘油三酯含量在两温度下无显著差异);温度变化对供试4种酶活性的影响差异显著。【结论】温度变化对粘虫的生长发育和繁殖具有显著的影响。在粘虫生长发育过程中以糖代谢为主;变温会加速糖代谢,减缓部分发育阶段的脂代谢,更有利能源物质的积累。     

Correlations between juvenile hormone esterase activity,ecdysone titre and cellular reprogramming in Galleria mellonella

Juvenile hormone esterase (JHE) activity, ecdysone titre, and developmental competence of the epidermis were determined in last instar larvae and pupae of Galleria mellonella. Haemolymph JHE activity reaches a peak before increases are observed in ecdysone titre both during larval-pupal and pupal-adult metamorphosis. JHE activity is low during the penultimate larval instar although general esterase activity is relatively high. In last instar larvae two ecdysone peaks are noted after the increase in JHE activity. Furthermore, epidermal cell reprogramming occurs just after the increase in haemolymph JHE activity and possibly before the first increase in ecdysone titre. This was tested by injection of high doses of β-ecdysone into last instar larvae of different ages resulting in rapid cuticle deposition. Reprogramming occurred if the resulting cuticle was of the pupal type. These correlative observations may increase our understanding of the relative importance of an ecdysone surge in the absence of JH in reprogramming of the insect epidermis.     

Identification of an extracellular acid trehalase and its gene involved in fungal pathogenesis of Metarizium anisopliae

Trehalose is the main sugar in the haemolymph of insects and is a key nutrient source for an insect pathogenic fungus. Secretion of trehalose-hydrolysing enzymes may be a prerequisite for successful exploitation of this resource by the pathogen. An acid trehalase [EC 3.2.1.28] was purified to homogeneity from a culture of a locust-specific pathogen, Metarhizium anisopliae, and its properties were characterized. The gene (ATM1) of this acid trehalase was also isolated. The pure enzyme can efficiently hydrolyze haemolymph trehalose into glucose in vitro. The new acid trehalase appearing in the haemolymph of Locusta migratoria infected with M. anisopliae had the same pI and substrate specificity as the purified fungal acid trehalase, and the concentration of trehalose in the haemolymph decreased sharply after infection. RT-PCR also revealed the ATM1 gene's expression in the haemolymph of the infected insects. Our results indicated that the acid trehalase may serve as an "energy scavenger" and deplete blood trehalose during fungal pathogenesis.     

Trehalose-hydrolysing enzymes of Metarhizium anisopliae and their role in pathogenesis of the tobacco hornworm,Manduca sexta

Trehalose is the main haemolymph sugar in most insects including the tobacco hornworm, Manduca sexta, and is potentially a prime target for an invading pathogenic fungus. There was considerably more trehalose-hydrolysing activity in the haemolymph of caterpillars infected with Metarhizium anisopliae than in controls. This appeared to be due primarily to additional isoforms; one of which could also hydrolyse maltose and was designated an alpha-glucosidase. A comparable isoform was identified in in vitro culture of the fungus, supporting a fungal origin for the in vivo enzyme. The in vitro fungal enzyme, alpha-glucosidase-1 (alpha-gluc-1), was purified to homogeneity and partially characterised. A study with the trehalase inhibitor trehazolin and C14 trehalose suggested that extracellular hydrolysis is important for fungal mobilisation of trehalose. Haemolymph glucose increases significantly during mycosis of tobacco hornworm larvae by M. anisopliae, consistent with the hydrolysis of trehalose by extracellular fungal enzymes. The implications for the host insect are discussed.     

Tissue specific glucose-trehalose variations prior to spinning in the eri-silkworm, Philosamia ricini.

A sharp rise in trehalose level of haemolymph is observed towards the end of 4th instar accompanied with sudden fall of the sugar in fat body during the same period, but after moulting blood trehalose abruptly decreases. Whereas, blood glucose level is maintained constant throughout life span of both the instars. Silkgland of 5th instar larvae presents a consistent gradual increase in glucose-trehalose levels reaching to the maximum prior to spinning with a higher value for trehalose than glucose which can be attributed to the decrease in blood trehalose level during the period.     

Cellular localization and proposed function of midgut trehalase in the silkworm larva, Bombyx mori

A sorbitol density gradient analysis with the aid of several marker enzymes demonstrated that midgut trehalase of the silkworm larvae. Bombyx mori, was localized in the microsomal membranes, but not in mitochondria, lysosomes and microvilli at the apical surface. Electron microscopic examination showed that trehalase-enriched membrane fraction consisted of heterogeneous mixtures of membrane vesicles derived from the endoplasmic reticulum and plasma membrane parts other than the microvillus membrane. The enzyme-histochemical stains of trehalase activity on the midgut section could be detected only at the basal surface of the epithelium against haemocoel. Such a specific localization was further confirmed by immunohistochemistry with the peroxidase-conjugated antibody technique. Thus, it is concluded that midgut trehalase of silkworm larvae is situated on the plasma membrane at the basal surface of the epithelium. An intact preparation of midgut incubated in vitro in the medium containing [(14)C]trehalose could hydrolyse trehalose into glucose and take it up into the cell, although some glucose was liberated into the medium when incubated for extended periods. These results suggest that midgut trehalase plays a physiological role in utilization of haemolymph trehalose not in nutrient absorption.