红脂大小蠹幼虫和成虫耐寒能力及耐寒物质的研究

为明确红脂大小蠹Dendroctonus valens LeConte的耐寒能力以及主要耐寒物质,对越冬期幼虫和成虫的过冷却点及冰点进行了测定,同时对越冬期及非越冬期幼虫和成虫体内的抗冻保护物质进行了测定.结果表明,越冬期幼虫和成虫的过冷却点差异不显著,分别为-18.34±0.26℃和-18.59±0.63℃,冰点差异显著,分别为-10.17±0.36℃和-15.90±0.70.越冬期幼虫体内脂肪、甘油、海藻糖和山梨醇含量均显著高于非越冬期幼虫,水分、糖原和蛋白质含量差异不显著;越冬期成虫体内糖原、甘油、海藻糖和山梨醇含量均显著高于非越冬期成虫,水分、脂肪和蛋白质含量差异不显著.甘油、海藻糖、山梨醇是红脂大小蠹幼虫和成虫的主要抗冻保护物质,在越冬过程中发挥重要作用;此外,脂肪在红脂大小蠹幼虫越冬过程中也发挥重要作用,糖原在红脂大小蠹成虫越冬过程中发挥重要作用.     

冷驯化对油松毛虫越冬幼虫过冷却点及主要耐寒物质的影响

【目的】冷驯化可增强昆虫的耐寒性,本文研究旨在明确不同冷驯化条件下油松毛虫Dendrolimus tabulaeformis Tsai et Liu越冬幼虫的过冷却点和主要耐寒物质的变化规律。【方法】利用热电偶方法测定越冬幼虫的过冷却点,分别采用差量法、氯仿甲醇法、苯酚硫酸法及毛细管气相测谱法测定其含水率、脂肪、糖原和小分子糖醇的含量。【结果】冷驯化会导致幼虫含水率显著降低;过冷却点和脂肪含量在低于环境气温5℃冷驯化后显著降低,当驯化温度低于环境气温10℃及以上则升高;糖原含量在9月份显著增加,越冬中期(1、3月份)含量略有降低但不显著;小分子糖醇含量的变化均不显著;海藻糖含量略降低;甘油、葡萄糖和半乳糖含量在低于环境气温5℃冷驯化后略降低,低于环境气温10℃冷驯化则升高。【结论】冷驯化使幼虫虫体含水率和脂肪含量降低,糖原含量提高,从而导致其过冷却点降低,耐寒能力提高;冷驯化的温度和时间均会影响其过冷却能力,在最适合的温度和时长可以最大程度提高其耐寒能力。研究结果为揭示油松毛幼虫的耐寒机制及潜在分布区预测提供了科学依据。     

驯化对始红蝽(Pyrrhocoris apterus)耐寒能力的影响及越冬适应策略

为阐明越冬期间始红蝽应对低温胁迫的耐寒策略及其影响因素,从生理生化水平探讨始红蝽成虫的耐寒能力,逐月测定了12月至翌年3月始红蝽低温驯化前后的过冷却点、低温存活率、LT_(50)以及始红蝽体内耐寒物质含量。结果表明,越冬期间始红蝽自然种群过冷却点最低为(-14.01±0.53)℃,-5、-10℃驯化30min后的始红蝽过冷却点最低降至为(-19.32±0.86)℃、(-25.56±1.09)℃。0℃驯化30min后暴露于-5、-10、-15℃1h的最高存活率依次为100%、39.1%±8.6%、10%;始红蝽自然种群LT_(50)最低为-8.53℃,0℃驯化后降至-9.21℃。越冬期间雌雄始红蝽体内自由水/结合水比值和游离蛋白质含量先下降后上升,12月达到最大值,雌雄分别为144.50±26.22和140.32±21.92,(15.81±0.10)mg/g和(15.47±0.01)mg/g;脂肪、海藻糖和甘油含量先上升后下降,2月达到最大值,雌雄脂肪含量分别为(16.33±0.48)mg/g和(13.15±1.32)mg/g,海藻糖含量分别为(11.98±0.01)mg/g和(10.88±0.02)mg/g,甘油含量分别为(14.74±0.01)mg/g和(15.06±0.03)mg/g。研究证明,低温驯化后始红蝽的过冷却点和LT_(50)明显降低,低温存活率显著提高,越冬期间始红蝽可通过调整体内抗逆物质含量以增强虫体耐寒能力。     

白马蝠蛾幼虫的抗寒性研究

本文报道了云南产冬虫夏草菌的优势寄主白马蝠蛾Hepialus baimaensis Liang幼虫抗寒能力.其1—6龄虫的过冷却点分别为-20.4℃、-20.6℃、21.5℃、-19.8℃、-18.8℃、-18.2℃,1—3龄幼虫的过冷却点明显低于其它龄虫,最低过冷却点达-27.8℃.越冬幼虫在高寒草甸土壤里,土壤温度-0.2—-6.8℃半年也不会死亡.越冬初期体内的脂肪、糖和无机盐类含量升高、水分下降有利于提高其抗寒作用.该虫经低温适应锻炼和在消化道里无残存食物的情况下能显著地提高耐寒能力.     

红褐斑腿蝗的耐寒能力及其季节性变化

用测定过冷却点的方法研究了红褐斑腿蝗(Catantops pinguis (Stal))在不同季节的抗寒能力,并就虫体含水量、粗脂肪、总蛋白和总糖等成分在不同季节的变化及其对过冷却点的影响进行了探讨.结果表明,红褐斑腿蝗的过冷却点存在显著的季节性差异,依次为秋季种群((-23.1 ± 0.2 )℃)＜ 越冬后种群((-19.3 ± 0.1) ℃)＜ 夏季种群((-4.0 ± 0.1) ℃).含水率在生长期极显著高于越冬期,越冬初期和越冬后期变化不大,说明红褐斑腿蝗在越冬准备期已排出了体内多余的游离水.越冬后蝗虫体内总糖含量和脂肪含量均显著低于越冬初期,说明蝗虫在越冬时主要靠消耗体内的碳水化合物和脂肪物质来维持体温,体内的营养物质消耗极大,导致越冬后过冷却点显著上升.含水率和含脂率在两性间差异不显著,雌性蝗虫的总蛋白含量在夏季种群略高于雄性,越冬期显著低于雄性,可能与雌蝗孕卵过程中动用了大量营养物质有关.     

双委夜蛾不同虫态耐寒性及体内生化物质含量变化

【目的】探索双委夜蛾Athetis dissimilis(Hampson)的耐寒策略及越冬虫态。【方法】以室内双委夜蛾种群为虫源,分别测定3龄、4龄、5龄、6龄和老熟幼虫以及蛹的过冷却点(supercooling point,SCP)、结冰点(freezing point,FP)、含水量以及脂肪、蛋白质、甘油、山梨醇和海藻糖含量。【结果】不同龄期幼虫和蛹之间过冷却点和结冰点存在显著差异,低龄幼虫SCP和FP较高;随着龄期增长,二者均降低,老熟幼虫的SCP和FP最低,分别为-18.20℃和-11.72℃。不同龄期幼虫和蛹的生化物质含量均存在显著差异。随着龄期的增加,含水量和甘油含量呈降低的趋势,蛹的含水量(65.33%)和甘油含量(154.90μg/mg)最低;脂肪和蛋白质含量随龄期的增加呈现增加的趋势,蛹的脂肪和蛋白质含量最高,分别为25.36%和2 298.37μg/mg。老熟幼虫海藻糖含量相对较高(57.28 mg/g),而山梨醇含量较低(15.49 mg/g)。【结论】与其他龄期相比,双委夜蛾老熟幼虫和蛹的耐寒性最强,是最可能的越冬虫态;脂肪、蛋白质和海藻糖可能是双委夜蛾重要的耐寒物质。     

我国大陆红火蚁不同等级和虫态过冷却点的测定

了解我国红火蚁Solenopsis invicta Buren的耐低温能力并为其风险分析提供科学依据,本文对采自我国4个地点红火蚁蚁群中不同等级和虫态的过冷却点,以及不同季节和室内不同饥饿程度的工蚁过冷却点进行了测定。结果表明：蚁群中不同等级和虫态的过冷却点差异显著。工蚁成虫的过冷却点（－11.8±0.4℃）显著低于有翅雌蚁（－8.1±0.6℃）及蚁后（－7.9±0.5℃）,工蚁蛹和幼虫的过冷却点分别为－13.6±0.3℃和－12.1±0.4℃,蚁后蛹和幼虫的分别为－13.3±0.3℃和－12.2±0.3℃。工蚁蛹的过冷却点均显著低于其成虫和幼虫。蚁后蛹与其幼虫的过冷却点没有显著差异,但与其成虫的差异显著。同一未成熟期不同等级之间的也没有显著差异;不同季节的工蚁过冷却点有显著差异,其中以春季的最高（－4.3±0.2℃）,夏季（－6.6±0.2℃）、秋季（－9.4±0.1℃）的次之,冬季的（－12.0±0.3℃）最低;深圳、珠海、广州和陆川4个地理种群的工蚁过冷却点在春、秋和冬季无显著差异,但夏季陆川种群的过冷却点显著低于其他3个种群的（P<0.05）。饥饿可使工蚁的过冷却点明显升高,但大工蚁的过冷却点较小工蚁升高的幅度更大,饥饿15 d后的大工蚁比饥饿前的过冷却点升高了7.0℃,而小工蚁仅升高了4.9℃。这些结果为评价红火蚁在我国潜在的传播风险提供了理论依据。     

柑桔大实蝇老熟幼虫和蛹过冷却点和结冰点的测定

为明确柑桔大实蝇Bactrocera minax (Enderlein)老熟幼虫和蛹的抗寒能力,对柑桔大实蝇老熟幼虫、滞育蛹和滞育解除蛹的过冷却点和结冰点进行了测定。结果显示,同一虫态不同个体间其过冷却点和结冰点具有不同程度的变异,但其变异范围均符合正态分布。柑桔大实蝇不同发育状态间的过冷却点和结冰点均具有显著差异,其中,已解除滞育进入发育状态的蛹的过冷却点和结冰点最低,分别为-11.15℃和-9.76℃;其次为滞育蛹,分别为-8.93℃和-7.63℃;而老熟幼虫最高,分别为-7.09℃和-3.43℃。此外,老熟幼虫的结冰点和过冷却点之间的差值最大为3.24℃,显著高于滞育蛹（1.30℃）和滞育解除蛹（1.39℃）。表明,倒春寒对已进入发育状态的柑桔大实蝇蛹不会造成不利影响。     

椰心叶甲的耐寒力测定

测定椰心叶甲Brontispalongissima(Gestro)的过冷却点和结冰点。各虫态中过冷却点值以卵和蛹最低,分别为-9.8℃和-9.0℃,成虫较高,雌、雄成虫分别为-5.9℃和-5.5℃;幼虫的过冷却点最高,平均为-4.5℃。结冰点由高到低依次为2龄幼虫、5龄幼虫、4龄幼虫、1龄幼虫、3龄幼虫、雄成虫、雌成虫、蛹和卵,分别为-0.3,-0.8,-1.1,-1.3,-1.3,-2.4,-2.7,-5.4和-5.5℃。综合分析认为,蛹、卵的耐寒能力最强。根据广东地区常年平均气温分析了在自然条件下该虫各虫态越冬情况,但由于生物学特性的限制,越冬虫态主要是成虫、蛹。     

细菌挥发物减缓伴生真菌对红脂大小蠹幼虫的不利作用

红脂大小蠹(Dendroctonus valens LeConte)携带着与其关系密切的真菌入侵中国,造成了数百万健康油松的死亡.红脂大小蠹的伴生真菌Ophiostoma minus在生长过程中与其幼虫竞争糖从而对红脂大小蠹幼虫的生长有明显的抑制作用.在小蠹虫与其伴生真菌的共生体系中,细菌挥发物在调节糖分分配中发挥着重要的作用.本文研究的3株红脂大小蠹幼虫主要伴生细菌Ralmella aquatilis,Serratia liquefaciens和Pseudomonas sp.7所产生的挥发物能够减缓O.minus对红脂大小蠹幼虫的拮抗作用,它们能抑制真菌的生长并减少真菌对葡萄糖的利用.利用SPME-GC-MS对3株细菌的挥发性物质进行分析,在Ralmella aquatilis B301中检测到了18种挥发物,在Serratia liquefaciens B310中检测到了21种挥发物,在Pseudomonas sp.7 B321中检测到了19种挥发物.上述挥发物丰度较高的3-甲基-1-丁醇、1,10-十一二碳烯、2-丁醇、2-庚酮、2,2-二甲基丁醇、(R)-2-己醇和氨能够显著性抑制O.minus的生长及其对主要糖的利用.本研究表明,优势伴生细菌所产生的挥发物能够抑制真菌的生长,调节红脂大小蠹幼虫-微生物体系中碳水化合物的分配,间接有利于红脂大小蠹幼虫的生长发育.     

Metabolism and cold tolerance of Chinese white pine beetle Dendroctonus armandi (Coleoptera: Curculionidae: Scolytinae) during the overwintering period

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越冬期不同阶段二点委夜蛾越冬幼虫耐寒性变化

【目的】二点委夜蛾Athetis lepigone (Moschler)是我国夏玉米苗期的新害虫,随着耕作制度的改变,二点委夜蛾的发生危害区域和面积逐渐扩大。本研究探讨二点委夜蛾的抗寒能力,为揭示抗寒机理提供理论基础。【方法】分别在越冬期的3个不同阶段,即越冬初期（2012年11月7日）、越冬期（2012年1月20日）和越冬末期（2013年3月5日）,对二点委夜蛾老熟幼虫的体重、过冷却点（supercooling point, SCP）、结冰点（freezing point, FP）、含水量、脂肪和糖原含量进行测定。【结果】过冷却点在这3个时期有显著差异,最低值（-23.16±0.38℃）出现在1月份,最高值（-16.24±1.24℃）出现在越冬初期,结冰点变化趋势与过冷却点一致。通过定量检测发现,虫体鲜重与过冷却点无相关性（r=0.17, P=0.12）;脂肪含量在越冬初期含量最高,而在越冬末期最低;糖原含量在越冬期含量最低;自由水的含量随着过冷却能力升高而降低,随其降低而升高,而结合水含量恰好相反。【结论】二点委夜蛾的抗寒性在越冬期不同阶段出现明显的变化,即随着冬季低温的到来,其抗寒能力逐渐增强,冬季过后又随气温的回升,其抗寒力逐渐减弱。     

松突圆蚧种群耐寒性的季节变化

采用过冷却点、低温暴露死亡率、冷识别温度和致死中低温累积等指标评价不同季节松突圆蚧的耐寒性.结果表明:各季节松突圆蚧的过冷却点波动在-22.4～-3.1 ℃之间,以冬季雌成虫的平均过冷却点最低(-14.83 ℃),显著低于夏季雌成虫、冬季1龄若虫和初孵若虫(P＜0.01),但其它发育阶段在冬、夏季之间均无显著差异;冬季1龄若虫、2龄性分化前若虫、2龄性分化后雄若虫、雌成虫和种群总体在-20～0 ℃下的死亡率、冷识别温度和致死中低温累积均明显低于夏季;1龄若虫、2龄性分化后雄若虫和种群总体的致死中低温累积与季节性平均气温均呈显著正相关(R＞R0.05=0.950,n-2=2),但各发育阶段的过冷却点与其致死中低温累积的相关性均未达显著水平.松突圆蚧冬季种群耐寒性最强,夏季种群最弱;该虫耐寒性的这一季节适应性并不依赖于过冷却点,而与气温的季节变化密切相关.     

沙葱萤叶甲的过冷却能力与抗寒性

【目的】沙葱萤叶甲Galeruca daurica Joannis于2009年开始在内蒙古草原暴发成灾, 发生地区不断扩大, 危害日趋严重, 严重影响内蒙古草原畜牧业的可持续发展和生态安全。低温是影响昆虫生长发育和存活的关键因子, 而昆虫对低温的耐受性决定了其越冬存活率。了解沙葱萤叶甲的过冷却点及抗寒能力有助于预测其分布范围及种群数量动态。【方法】采用热电偶法, 在室内测定了沙葱萤叶甲各发育阶段的过冷却点; 比较了幼虫在不同低温条件下（-6~-14℃）暴露2 h及在-5℃低温条件下暴露不同时间（0.5~8 d）的存活率。【结果】沙葱萤叶甲不同发育阶段的过冷却点存在显著差异, 从低到高依次为卵（-29.8℃）、 1龄幼虫（-14.6℃）、 2龄幼虫（-13.3℃）、 蛹（-12.1℃）、 3龄幼虫（-10.2℃）和成虫（-9.0℃）; 越冬卵12月和1月的过冷却点最低, 2月的过冷却点最高。随着处理温度的降低和处理时间的延长, 幼虫的存活率降低。1, 2和3龄幼虫在-5℃下的半致死时间（Ltime₅₀）分别为3.84, 3.80和2.28 d, 低温处理2 h后半致死温度（Ltemp₅₀）分别为-10.1, -9.1和-8.5℃, 高于其过冷却点。【结论】说明沙葱萤叶甲幼虫为不耐寒冷型(chill-intolerant)。     

Cold tolerance characteristics of Korean population of potato tuber moth,Phthorimaea operculella (Zeller), (Lepidoptera: Gelechiidae)

Potato tuber moth (PTM), Phthorimaea operculella (Zeller), (Lepidoptera: Gelechiidae) is an invasive insect pest damaging solanaceous crops. We measured the supercooling point (SCP) and survival at low temperature of different development stages to determine which would be capable of overwintering in the Korean climate and adapting to low temperatures. The SCP ranges from ?23.8°C of the egg to ?16.8 of fourth instar larvae (L4). After short periods of low temperature acclimation in L3 (third instar larva), L4 and prepupae, only the prepupal stage showed a significant lowered SCP from ?20.78 to ?22.37°C. When exposed to different subzero temperature for two hours the egg turned out to be the most cold tolerant stage showing LT₅₀ of ?21.7°C followed by the pupal stage with ?15.89°C. One hundred percent mortality was observed when the larvae or adults were exposed to temperatures below ?15.1°C even for a period as short as 2 h. The results suggest that PTM pupae and egg would be the main overwintering stage in Korea where winter temperature does not drop below ?15°C.     

荒漠昆虫光滑鳖甲的耐寒性季节变化及其生理机制

光滑鳖甲Anatolica polita borealis生活于温差大的新疆荒漠环境, 为探讨其耐寒性及耐寒机制, 本研究测定了其3-9月份成虫在－10℃的耐寒性、过冷却点（SCP）、含水量、甘油含量和血淋巴热滞活性(thermal hysteresis activity, THA)以及冷驯化对增强光滑鳖甲成虫耐寒性的效果, 还测定了光滑鳖甲不同发育阶段幼虫的SCP。结果表明: 光滑鳖甲成虫的耐寒性和SCP具有明显的季节性变化, 3月初SCP为－12.5℃, 7月为－6℃, 9月底为－13.6℃。4℃冷驯化能够提高光滑鳖甲成虫在－10℃的存活率, 未驯化组在40 min的存活率为50%, 而驯化2 h的为70%, 驯化24 h的为90%。虫体含水量在夏季有显著降低, 3月、7月和9月结合水与自由水的比值分别为10.8∶1,2.6∶1和5.4∶1。成虫甘油含量与SCP的回归方程为y=－0.6204x－5.681, R²=0.7714。成虫血淋巴THA与过冷却点的回归方程为y=－5.26x－1.713, R²=0.9049。血淋巴THA比甘油浓度更能影响过冷却点降低的程度。随着幼虫的发育, 其SCP逐渐降低。结果提示, 光滑鳖甲通过提高结合水与自由水的比值、增加抗冻蛋白和甘油的含量使虫体保持较低的SCP, 因而具有较高的耐寒性。     

Colonization patterns of the red turpentine beetle, Dendroctonus valens (Coleoptera: Curculionidae), in the Luliang Mountains, China

The alien red turpentine beetle (RTB), Dendroctonus valens LeConte, is one of the most economically destructive forest pests in China, having killed more than 6 million pines in recent years. There is a need to understand the basic biology and ecology of the beetle in order to develop an effective monitoring and management strategy. In this study, the effects of hillside exposure (south- and north-facing), host-tree locations according to relief (valley, mid-slope, and ridge-top) and tree diameters on RTB colonization were investigated in one valley (3 sites). The results showed that (i) RTB clearly preferred colonizing pines growing on south-facing hillsides, especially in the valley; (ii) RTB preferred to colonize the pines growing at the valley rather than pines growing at mid-slope or on ridge-top; (iii) RTB preferred to colonize trees with large diameter over small and medium-sized pines; (iv) the attack density of RTBs (measured by pitch tubes/pine) was obviously higher on larger trees standing in the valley than other trees standing at other places. We conclude from RTB colonization patterns, that RTB prefers to attack large trees in the valley, which may be useful in developing a pest-management strategy.     

外来入侵害虫红脂大小蠹对寄主挥发物的反应

2002年,利用寄主挥发性物质(+)-α-蒎烯、(-)-β-蒎烯、3-蒈烯和(-)柠檬烯按不同配比制成诱芯,采用自行研制的挥发物释放装置,在山西省关帝山森林经营局西葫芦林场对危害油松Pinus tabulaeformis Carr.的重大外来入侵林业害虫红脂大小蠹Dendroctomus valens LeConte进行了引诱试验。结果表明,3蒈烯对红脂大小蠹的引诱作用最强,明显优于单独使用(+)-α-蒎烯和(-)-β-蒎烯的诱虫效果,也比北美应用的标准诱芯［(+)- α蒎烯(-)-β-蒎烯与3-蒈烯的比例为1∶1∶1］效果好;在标准诱芯中加入油松另一主要成分-(-)柠檬烯会明显降低诱虫效果。红脂大小蠹引诱剂最佳释放量为150 mg/d。该研究不仅对我国红脂大小蠹的监控具有实际应用意义,也从理论上探讨了红脂大小蠹与寄主油松协同进化的化学生态学过程。     

Cold tolerance and cold hardening strategy of the Japanese pine sawyer Monochamus alternatus (Coleoptera: Cerambycidae)

The Japanese pine sawyer, Monochamus alternatus , is an important pine forest pest and vector transmitting the pine wilt nematode that causes pine wilt disease. Low temperatures in autumn, winter and spring often differentially affect mortality of M. alternatus larvae. In this paper, we mainly compared the differences of mortality and cold hardening of larvae from different seasons, based on supercooling point (SCP) and cumulative probability of individuals freezing (CPIF). The cold hardening of the larvae from autumn, winter and spring seasons were largely different. Correlations between mortality and CPIF of autumn and spring larvae were highest on day 1/4, and gradually decreased with prolonged exposure duration. This beetle's death mainly resulted from freezing in short exposure duration. However, the correlation between mortality and CPIF of winter larvae increased gradually with the prolonged exposure duration. Death did not mainly result from freezing in long exposure duration. Autumn larvae are more susceptible and adaptable than winter and spring larvae. Winter larvae have a slight freeze-tolerance trend. Our research showed that M. alternatus came into complex cold-hardening strategies under natural selection. Freeze avoidance is the primary strategy; with prolonged exposure duration to above SCP or < 0 °C, chill tolerance is more important; this is followed by freeze tolerance during harsh winters.     

False codling moth Thaumatotibia leucotreta (Lepidoptera,Tortricidae) larvae are chill‐susceptible

Abstract This study reports on the low temperature tolerance and cold hardiness of larvae of false codling moth, Thaumatotibia leucotreta. We found that larvae have mean critical thermal minima (lower limits of activity) of 6.7°C which was influenced by feeding status. The effects of low temperature exposure and duration of exposure on larval survival were assessed and showed that the temperature at which 50% of the population survives is ?11.5 ± 0.3°C after 2 h exposure. The supercooling point (SCP, i.e., freezing temperature) was investigated using a range of cooling rates and under different conditions (feeding and hydration status) and using inoculative freezing treatments (in contact with water or orange juice). The SCP decreased significantly from ?15.6°C to ?17.4°C after larvae were fasted for 24 h. Twenty‐four hour treatments at either high or low relative humidity (95.9% or 2.4%) also significantly decreased SCP to ?17.2°C and ?18.2°C respectively. Inoculative freezing (by water contact) raised SCP from ?15.6°C to ?6.8°C which could have important implications for post‐harvest sterilization. Cooling rates did not affect SCP which suggests that there is limited phenotypic plasticity of SCP during the larval life‐stage, at least over the short time‐scales investigated here. In conclusion, larvae of T. leucotreta are chill‐susceptible and die upon freezing. These results are important in understanding this pest's response to temperature variation, understanding pest risk status and improving post‐harvest sterilization efficacy.