小菜蛾的耐热性

小菜蛾是世界范围内十字花科蔬菜上的重要害虫.临界高温(critical thermal maximum, CTMax)是昆虫耐热性的常用指标.采用动态加热方法,利用自行组装的装置测定了小菜蛾的临界高温,以此作为其耐热性指标,研究发育阶段、饲养温度、世代、性别和热激对小菜蛾耐热性的影响.结果表明： 25 ℃下饲养的小菜蛾4龄幼虫的CTMax 均值为50.31 ℃,显著高于1龄幼虫(43.03 ℃)、2龄幼虫(46.39 ℃)、3龄幼虫(49.67 ℃)以及雌性成虫(45.76 ℃)和雄性成虫(47.73 ℃);不同饲养温度(20、25和30 ℃)下成虫耐热性无显著差异;30 ℃下饲养1代、3代及6代的不同世代成虫CTMax也无显著变化;所有处理雌雄成虫的CTMax无显著差异;40 ℃下45 min热激可使5日龄雄成虫的CTMax值从45.51 ℃增加到46.49 ℃.     

原尾蜥虎的选择体温、热耐受性和食物同化的热依赖性

(Tsel)、热耐受性和体温对食物同化的影响。Tsel无显著的日时间变化,两性个体的Tsel、临界低温(CTMin)和临界高温(CTMax)无显著的差异。Tsel、CTMin和CTMax的平均值分别为30.9℃、3.2℃和43.3℃。体温对动物食物通过时间有显著的影响。在25℃-33℃范围内,食物通过时间随体温升高而缩短;体温超过33℃后,食物通过时间随体温升高而延长。温度对原尾蜥虎的摄食量、表观消化系数(ADC)和同化效率(AE)有显著的影响。在25℃-37℃范围内,动物在低体温下(25℃和27℃)的摄食量、ADC和AE小于更高体温下动物的对应数值。种间比较结果显示,原尾蜥虎是生活于南方的蜥蜴中具有较强耐受极端体温的种类。     

温度对中华通草蛉捕食麦长管蚜的影响

为明确温度对中华通草蛉 Chrysoperla sinica 捕食麦蚜能力的影响,充分发挥其控害潜能,本研究利用年龄-龄期两性生命表方法,研究了5个温度下(16℃、19℃、22℃、25℃、28℃)中华通草蛉幼虫对麦长管蚜 Sitobion avenae 的捕食能力。结果发现,1龄幼虫在19℃条件下捕食量最高,16℃条件下捕食量最低,且差异显著。2龄幼虫不同温度处理间捕食量均无显著性差异,3龄幼虫捕食麦长管蚜数量则随处理温度的提高而显著降低,而幼虫期总捕食量除28℃在不同温度间均无显著性差异。2龄幼虫平均捕食率高于1龄幼虫,但显著低于 3龄幼虫。年龄-龄期捕食率结果说明,温度升高缩短了幼虫发育时间,但提高了其捕食能力;虽然不同温度处理总捕食量不变,但高温缩短了幼虫捕食所消耗的时间。22℃条件下中华通草蛉雌成虫期长(96.63 d),产卵期长(55.36 d),繁殖力强(310.36),平均世代周期( T )短(48.99 d),容易产生世代重叠现象;内禀增长率( r )和周限增长率(λ)显示中华通草蛉种群呈正增长趋势。研究结果对于春季田间释放中华通草蛉防治麦长管蚜具有一定参考价值。     

极端高温和持续中等高温对小菜蛾耐热性的影响

气候变化频率的增加和持续时间的延长,导致具有较短生活史的大部分农业害虫的某一个或某几个生命阶段都可经历热浪的胁迫。热浪对小型昆虫的生态学效应取决于不同生命阶段的耐热性,因而解析特定龄期下昆虫生命阶段的耐热性对理解气候变暖热浪频发的生态学影响具有重要意义。本研究以世界重要蔬菜害虫小菜蛾为研究对象,试验了小菜蛾4龄幼虫、成虫的基底耐热性和诱导耐热性,以及1龄幼虫和3龄幼虫置于不同高温[(31±1)、33±1)、35±1)℃]和暴露时间(3、6、9、12d)组合的持续中等高温耐热性。试验发现幼虫和成虫具有不同的基底和诱导耐热性,具有较弱基底耐热性的幼虫反而具有更强的诱导耐热性。不同生命阶段在持续数天的中等高温胁迫下具有不同的存活表现,早期生命阶段存活率较后期阶段的低,而且这种差异在较强高温下表现得尤为明显。昆虫不同阶段耐热性的差异,对种群的维持具有重要的生态学意义。大多数农业害虫田间种群具有混合年龄结构,热浪后耐热的发育阶段的存活,保证种群可以一直生存和繁衍下去。     

毒死蜱对不同温度下饲养的小菜蛾幼虫羧酸酯酶的抑制作用

毒死蜱对不同温度下饲养的小菜蛾3龄幼虫羧酸酯酶的体内抑制动态规律有明显的差异.饲养于不同温度下的小菜蛾幼虫羧酸酯酶活性在受到毒死蜱的抑制之后,其恢复速度不同,其中饲养于30℃的小菜蛾3龄幼虫羧酸酯酶活性恢复最快,饲养于20℃的次之,饲养于10℃的恢复最慢.     

幼虫期短时高温暴露对二点委夜蛾存活和繁殖的影响

【目的】随着全球气候变暖,夏季短时极端高温发生的频率逐渐增加。本研究旨在探明二点委夜蛾Athetis lepigone幼虫期对高温的适应性。【方法】将二点委夜蛾不同日龄(1,6,12和18日龄)幼虫在不同高温(35,38和41℃)条件下暴露不同时间(0.5,1,2,4和6 h)后转移至适温(26℃)继续饲养,观察短时高温对其存活率、发育历期、化蛹率、羽化率、雌虫寿命、单雌产卵量及次代卵孵化率的影响。【结果】幼虫期短时高温暴露的温度和时间对二点委夜蛾幼虫的存活率和发育历期有显著影响,而对化蛹率、成虫羽化率、雌虫寿命、单雌产卵量以及次代卵孵化率影响不显著。随着温度的升高和处理时间的延长,幼虫存活率逐渐降低,发育历期逐渐延长。其中,18日龄的幼虫最为敏感,38℃和41℃暴露6 h后存活率分别为58.3%和17.7%,显著低于对照,发育历期分别为25.5 d和29.2 d,较对照显著延长。【结论】幼虫期经历短时高温暴露仅对幼虫的存活和发育历期有影响,而对后续蛹和成虫的生长发育及成虫繁殖力没有影响。     

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。     

苹果蠹蛾热激蛋白Hsp90基因的克隆及热胁迫下的表达分析

世界检疫性害虫苹果蠹蛾Cydia pomonella是一种温度耐受可塑性很高的物种。本研究针对温度波动可能导致其耐热性增强的科学问题, 采用生测法鉴定了苹果蠹蛾实验种群的高温耐受阈值, 采用同源克隆、 RACE和实时荧光定量PCR (RT-qPCR)等方法研究了苹果蠹蛾热激蛋白Hsp90基因的应激表达对耐热性的重要作用。高温耐受阈值研究结果表明, 苹果蠹蛾实验种群的死亡率随温度的升高和时间的延长显著性升高, 1-5龄幼虫分别经50℃和52℃高温处理2, 5和10 min后, 3龄幼虫耐热性最差, 5龄幼虫最强。50℃和52℃分别处理10 min和5 min均可导致1-4龄幼虫全部死亡, 而5龄幼虫在这两种处理下仍有25.0%和11.1%的存活率。以35℃处理的5龄雌幼虫为材料克隆苹果蠹蛾Hsp90基因全长cDNA, 结果显示该基因全长为2 470 bp, 完整开放阅读框为2 148 bp, 共编码716个氨基酸, 预测分子量为82.07 kDa, 命名为Cphsp90 (GenBank登录号JN624775)。该基因编码的氨基酸序列与亚洲玉米螟Ostrinia furnacalis和甘蓝夜蛾Mamestra brassicae等昆虫的Hsp90的氨基酸序列一致性高达96%, 表明了Hsp90家族的保守特性。Cphsp90 mRNA的相对表达量在32~44℃高温胁迫下随温度的升高而显著增高, 证实Cphsp90是诱导型热激基因, 且mRNA相对表达量与胁迫程度正相关。Cphsp90基因的表达还具有组织特异性, 35℃处理幼虫的表皮中Cphsp90相对表达量显著高于血淋巴、 脂肪体和中肠, 应激响应最为活跃。与未经温热预处理的昆虫相比, 35℃温热预处理3 h后的5龄幼虫在40, 45和50℃更高的温度胁迫下, Cphsp90 mRNA达到最高表达量所需要的胁迫温度有所提升, 由未经预热处理的40℃处理10 min提高到45℃处理10 min, 这与温热预处理会增强5龄幼虫耐热性的现象相符, 表明Cphsp90基因的响应表达在苹果蠹蛾耐热性及其可塑性过程中发挥重要的作用。     

光温条件对狭翅大刀螳生长发育的影响及其捕食功能研究

室内条件下饲养狭翅大刀螳(Tenodera angustipennis),研究温度与光照两个因子对狭翅大刀螳生长发育的影响。同时考察狭翅大刀螳若虫对不同密度小菜蛾幼虫与成虫及萝卜蚜的捕食功能反应．结果表明。温度对狭翅大刀螳生长发育的影响显著,随着温度的升高。在设定的温度范围内其历期明显缩短．狭翅大刀螳1～3龄若虫最适生长温度为25℃。而4、5龄若虫的最适生长温度为25～30℃．单因子光照对狭翅大刀螳生长发育无显著影响．捕食功能反应试验所得的数据,按HoUing模型进行模拟,经卡方检验。其理论值与实测值无显著差异。证明建立的模型能较好地模拟狭翅大刀螳的捕食情况．     

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。     

小菜蛾热休克蛋白基因的鉴定及其表达模式分析

热休克蛋白(heat shock protein, HSP)在昆虫应对外界胁迫刺激时起着重要作用。为了系统研究小菜蛾Plutella xylostella HSP基因家族, 根据家蚕的HSP蛋白序列, 采用本地Blast程序对小菜蛾全基因组数据库进行同源序列检索, 从小菜蛾基因组数据库中鉴定了25个HSP基因, 包括2个HSP90、 8个HSP70和15个sHSP（small heat shock protein, sHSP）基因。小菜蛾、 家蚕Bombyx mori、 黑腹果蝇Drosophila melanogaster和赤拟谷盗Tribolium castaneum的HSP系统进化分析显示, 昆虫的小分子量热休克蛋白sHSP具有很强的种属特异性, HSP70家族的保守性比sHSP强。小菜蛾HSP基因表达模式分析显示, 与敏感品系对比, 抗性品系（抗毒死蜱和抗氟虫氰品系）中HSP基因具有不同的表达模式。小菜蛾1, 2和3龄幼虫HSP基因表达模式较为接近, 而与4龄幼虫中的表达模式相差较大; 4龄幼虫和蛹中的表达模式相近; 雌成虫和雄成虫中的表达模式显著不同, 与果蝇精子形成有关的两个热休克蛋白HSP23和HSP27基因［分别为CCG003980.1 (Px23.5)和CCG005412.2 (Px27.5)］, 在小菜蛾雄成虫中的表达量显著高于雌成虫。研究结果表明小菜蛾HSP基因不仅在杀虫剂抗性、 发育分化, 甚至在生殖上均可能起着重要的作用。本研究为深入研究小菜蛾HSP与生长发育、 抗逆行为的相互关系奠定了基础。     

Northern grass lizards (<Emphasis Type="Italic">Takydromus septentrionalis</Emphasis>) from different populations do not differ in thermal preference and thermal tolerance when acclimated under identical thermal conditions

We acclimated adults of Takydromus septentrionalis (northern grass lizard) from four localities (populations) under identical thermal conditions to examine whether local thermal conditions have a fixed influence on thermal preference and thermal tolerance in the species. Selected body temperature (Tsel), critical thermal minimum (CTMin), and critical thermal maximum (CTMax) did not differ between sexes and among localities in lizards kept under identical laboratory conditions for ∼5 months, and the interaction effects between sex and locality on these measures were not significant. Lizards acclimated to the three constant temperatures (20, 25, and 35°C) differed in Tsel, CTMin, and CTMax. Tsel, CTMin, and CTMax all shifted upward as acclimation temperature increased, with Tsel shifting from 32.0 to 34.1°C, CTMin from 4.9 to 8.0°C, and CTMax from 42.0 to 44.5°C at the change-over of acclimation temperature from 20 to 35°C. Lizards acclimated to the three constant temperatures also differed in the range of viable body temperatures; the range was widest in the 25°C treatment (38.1°C) and narrowest in the 35°C treatment (36.5°C), with the 20°C treatment in between (37.2°C). The results of this study show that local thermal conditions do not have a fixed influence on thermal preference and thermal tolerance in T. septentrionalis.     

微小花蝽对小菜蛾捕食控制的能力

为了明确微小花蝽以小菜蛾卵做为饲料的适宜性及其对小菜蛾的控制能力,在室内以桃蚜作为参比猎物,研究捕食小菜蛾卵对微小花蝽生长发育、繁殖的影响,并结合捕食功能反应评价微小花蝽对小菜蛾的捕食能力.结果表明: 微小花蝽取食小菜蛾卵能够完成世代发育,并能够正常繁育后代.取食小菜蛾卵时,微小花蝽雌、雄若虫的历期(♀: 12.3 d,♂: 12.2 d)、成虫体长[♀: (2.13±0.01) mm,♂: (1.91±0.00) mm]、体宽[♀: (0.87±0.01) mm,♂: (0.71±0.01) mm]、单雌产卵量(12.7±1.1)、产卵前期[(5.1±0.6) d]和产卵期[(3.7±0.4) d]均与桃蚜处理组无显著差异;雌、雄成虫寿命[♀: (10.7±1.4) d,♂: (9.1±1.3) d]显著长于桃蚜处理组[♀: (8.5±0.5) d,♂: (6.4±0.3) d];若虫存活率[(65.0±6.8)%]不及桃蚜处理组[(80.0±8.2)%],且雌性比例偏低.微小花蝽对小菜蛾的捕食功能反应符合HollingⅡ型方程.微小花蝽1～5龄若虫对小菜蛾卵的日均最大捕食量(N_max)分别为7.5、16.3、23.3、29.1和38.7粒;雌、雄成虫的日均最大捕食量分别为39.0和26.9粒;5龄若虫对小菜蛾低龄幼虫的日均最大捕食量为41.3头;雌、雄成虫的日均最大捕食量分别为40.8和23.9头.单头雌、雄微小花蝽一生中最多可捕食小菜蛾卵(711.3±58.1)和(535.4±30.6)粒,小菜蛾低龄幼虫(371.9±52.0)和(253.9±32.3)头.微小花蝽以小菜蛾卵饲养可行,且对小菜蛾具有良好的控制作用.     

The biology of Diadromus collaris (Hymenoptera: Ichneumonidae), a pupal parasitoid of Plutella xylostella (Lepidoptera: Plutellidae), and its interactions with Oomyzus sokolowskii (Hymenoptera: Eulophidae)

The ichneumonid Diadromus collaris (Gravenhorst) has been recorded in many parts of the world as an important parasitoid of the diamondback moth, Plutella xylostella (Linnaeus), a serious pest of brassica vegetable crops worldwide. Some aspects of its biology and its interactions with Oomyzus sokolowskii (Kurdjumov), another major parasitoid of the same pest, were studied in the laboratory. At 25 degrees C, female wasps did not have mature eggs in their ovaries until about 12 h after emergence. Both males and females mated successfully 24-48 h after emergence, and females started to oviposit one to two days after emergence. Unmated females produced male progeny only; mated females produced progeny of both sexes. The development rate of the parasitoid increased linearly with temperature from 15 to 30 degrees C, with an estimated low temperature threshold of 7.4 degrees C and a thermal constant of 225.1 day-degrees for development from egg to adulthood. Rates of survival from larva to adulthood were about 90% between 20 and 28 degrees C and decreased as temperature decreased or increased. No immatures survived to adulthood at 35 degrees C. When provided with honey solution, the females lived on average 8.3, 11.5 and 7.0 days, and parasitized 26, 44 and 46 host pupae at 20, 25 and 30 degrees C, respectively. Female wasps could be stored at 15 degrees C for up to four weeks without detrimental effects on reproduction. Females of D. collaris attacked host pupae already parasitized by O. sokolowskii, inserting their ovipositor into the hosts at a similar frequency as into unparasitized host pupae, but they did not lay eggs inside the hosts.     

蠋蝽抗寒性对快速冷驯化的响应及其生理机制

快速冷驯化可以提高某些昆虫的耐寒性.为了探讨不同冷驯化诱导温度对蝎蝽抗寒性的影响及其生理机制,以室内人工饲养的第3代蝎蝽成虫为对象,利用热电偶、液相色谱分析等技术手段,测定了经15、10、4℃冷驯化4h和梯度降温(依次在15、10、4℃各驯化4h)冷驯化后,蠋蝽成虫过冷却点、虫体含水率及小分子碳水化合物、甘油和氨基酸含量,及其在不同暴露温度(0、-5、-10℃)下的耐寒性.结果表明:处理后暴露在-10℃时,梯度处理组和4℃冷驯化处理组的蝎蝽成虫存活率为58.3％,其他处理组及对照组(室温饲养)的存活率显著降低,平均为8.9％;梯度处理组与4℃冷驯化处理组蠋蝽成虫过冷却点平均为-15.6℃,比其他处理平均降低1.3℃;各处理虫体含水率无显著差异,平均为61.8％;与其他各组相比,梯度处理组和4℃冷驯化组蠋蝽成虫的葡萄糖、山梨醇和甘油含量分别增加2.82、2.65和3.49倍,丙氨酸和谷氨酸含量分别增加51.3％和80.2％,海藻糖、甘露糖和脯氨酸含量分别下降68.4％、52.2％和30.2％,而果糖含量各组间无显著差异.快速冷驯化对蠋蝽成虫具有临界诱导温度值,梯度降温驯化不能在快速冷驯化的基础上提高蠋蝽成虫的抗寒性.     

Seasonal thermal tolerance in marine Crustacea

Seasonal values of the critical thermal maximum (CTMax) of eight species of adult marine Crustacea from temperate latitudes were measured and found to range between 20 and 34 °C. The extent to which CTMax was dependent on acclimatization varied with species but for most of the species studied, summer-captured animals had significantly higher CTMax values than winter-captured animals. Heat shock resulted in an increase in thermotolerance in most species in winter-captured animals, but a different pattern was found for summer-captured animals. Then, only Cancer pagurus and Pagurus bernhardus showed a positive increment of CTMax on heat shock. Test for Serial Independence analysis indicated no significant phylogenetic autocorrelation between CTMax values in winter or summer-captured animals. Temperature measurements taken by remote data loggers in the intertidal zone of the North-East coast of England are reported. These suggest that several species, whose distribution extends into the intertidal zone, may experience temperatures close to their CTMax in summer.     

Developmental plasticity in the thermal tolerance of zebrafish Danio rerio

To evaluate developmental plasticity in thermal tolerance of zebrafish Danio rerio , common-stock zebrafish were reared from fertilization to adult in the five thermal regimes (two stable, two with constant diel cycles and one stochastic diel cycle) and their thermal tolerance at three acclimation temperatures compared. The energetic cost of developing in the five regimes was assessed by measuring body size over time. While acclimation accounted for most of the variability in thermal tolerance, there were also significant differences among fish reared in the different regimes, regardless of acclimation. Fish reared in more variable environments (as much as ±6° C diel cycle) had a greater tolerance than those from non-variable environments at the same mean temperature. Fish from the more variable environments were also significantly smaller than those from non-variable environments. These results indicate that the thermal history of individual zebrafish induces irreversible changes to the thermal tolerance of adults.     

Sex‐dependent thermal history influences cold tolerance,longevity and fecundity in false codling moth Thaumatotibia leucotreta (Lepidoptera: Tortricidae)

相似文献   

Dietary glycerol and adult access to water: effects on fecundity and longevity in the almond moth

The quality of food eaten by larval insects will affect traits such as gamete production, fat reserves, muscle bulk and body size in the adult. Moreover, larvae also depend on high moisture content in the diet for survival. The almond moth (Ephestia cautella) (W.) (Lepidoptera; Pyralidae) does not feed as an adult although it continues to drink water. We tested the idea that an almond moth could compensate for a low-water diet as a larva by increasing its water intake as an adult. We reared larvae on two different food sources with different moisture regimes; standard laboratory diet with glycerol (relatively wet) and standard diet without glycerol (relatively dry). Half the adult moths from each treatment were given water to drink before their first and only mating. Our results show that wet larval diets (i.e. containing glycerol) significantly decreased fecundity (total number of eggs laid and the proportion of hatched larvae), whilst it significantly increased male and female longevity. The interaction effect of water access for adult males and females was significant, independent of the glycerol in the larval diet. Longevity in females that were not presented with water as adults was slightly higher if mated with a male that had had access to water, suggesting a mating donation of water. However, females that received water as adults showed a decreased longevity if mated with a male who had also had access to water as an adult, indicating a negative effect of water if received by both males and females. In addition, when the larval diet included glycerol, increased number of eggs laid decreased female longevity, whilst an absence of glycerol in the larval diet resulted in low female longevity that was unlinked with fecundity. Glycerol is used in many artificial insect diets and the fact that it shows a strong effect on key life-history traits (reproductive output and longevity in this species), merits careful re-examination of its effects on these important traits in other laboratory models. We also discuss the possibility that larval diet can affect female reproductive decisions.