共查询到20条相似文献,搜索用时 15 毫秒
1.
T. C. HAWES C. E. COULDRIDGE J. S. BALE M. R. WORLAND P. CONVEY 《Ecological Entomology》2006,31(5):450-459
Abstract. 1. Cold tolerance is a fundamental adaptation of insects to high latitudes. Flexibility in the cold hardening process, in turn, provides a useful indicator of the extent to which polar insects can respond to spatial and temporal variability in habitat temperature.
2. A scaling approach was adopted to investigate flexibility in the cold tolerance of the high Arctic collembolan, Hypogastrura tullbergi , over different time-scales. The cold hardiness of animals was compared from diurnal warming and cooling phases in the field, and controlled acclimation and cooling treatments in the laboratory. Plasticity in acclimation responses was examined using three parameters: low temperature survival, cold shock survival, and supercooling points (SCPs).
3. Over time-scales of 24–48 h, both field animals from warm diurnal phases and laboratory cultures from a 'warm' acclimation regime (18 °C) consistently showed greater or equivalent cold hardiness to animals from cool diurnal phases and acclimation regimes (3 °C).
4. No significant evidence was found of low temperature acclimation after either hours or days of low temperature exposure. The cold hardiness of H. tullbergi remained 'seasonal' in character and mortality throughout was indicative of the summer state of acclimatization.
5. These data suggest that H. tullbergi employs an 'all or nothing' cryoprotective strategy, cold hardening at seasonal but not diel-temporal scales.
6. It is hypothesised that rapid cold hardening offers little advantage to these high Arctic arthropods because sub-zero habitat temperatures during the summer on West Spitsbergen are rare and behavioural migration into soil profiles offers sufficient buffering against low summer temperatures. 相似文献
2. A scaling approach was adopted to investigate flexibility in the cold tolerance of the high Arctic collembolan, Hypogastrura tullbergi , over different time-scales. The cold hardiness of animals was compared from diurnal warming and cooling phases in the field, and controlled acclimation and cooling treatments in the laboratory. Plasticity in acclimation responses was examined using three parameters: low temperature survival, cold shock survival, and supercooling points (SCPs).
3. Over time-scales of 24–48 h, both field animals from warm diurnal phases and laboratory cultures from a 'warm' acclimation regime (18 °C) consistently showed greater or equivalent cold hardiness to animals from cool diurnal phases and acclimation regimes (3 °C).
4. No significant evidence was found of low temperature acclimation after either hours or days of low temperature exposure. The cold hardiness of H. tullbergi remained 'seasonal' in character and mortality throughout was indicative of the summer state of acclimatization.
5. These data suggest that H. tullbergi employs an 'all or nothing' cryoprotective strategy, cold hardening at seasonal but not diel-temporal scales.
6. It is hypothesised that rapid cold hardening offers little advantage to these high Arctic arthropods because sub-zero habitat temperatures during the summer on West Spitsbergen are rare and behavioural migration into soil profiles offers sufficient buffering against low summer temperatures. 相似文献
2.
Temperature preferences of the mite, Alaskozetes antarcticus, and the collembolan, Cryptopygus antarcticus from the maritime Antarctic 总被引:2,自引:0,他引:2
Abstract. The thermal preferences of Alaskozetes antarcticus (Acari, Cryptostigmata) and Cryptopygus antarcticus (Collembola, Isotomidae) were investigated over 6 h within a temperature gradient (?3 to +13 °C), under 100% relative humidity (RH) conditions. After 10 days of acclimation at ?2 or +11 °C, individual supercooling points (SCP) and thermopreferences were assessed, and compared with animals maintained for 10 days under fluctuating field conditions (?6 to +7 °C). Acclimation at ?2 °C lowered the mean SCP of both A. antarcticus (?24.2 ± 9.1) and C. antarcticus (?14.7 ± 7.7) compared to field samples (?19.0 ± 9.0 and ?10.7 ± 5.2, respectively). Acclimation at +11 °C increased A. antarcticus mean SCP values (?13.0 ± 8.5) relative to field samples, whereas those of C. antarcticus again decreased (?16.7 ± 9.1). Mites acclimated under field conditions or at +11 °C selected temperatures between ?3 and +1 °C. After acclimation at ?2 °C, both species preferred +1 to +5 °C. Cryptopygus antarcticus maintained under field conditions preferred +5 to +9 °C, whereas individuals acclimated at +11 °C selected +9 to +13 °C. For A. antarcticus, thermopreference was not influenced by its cold hardened state. The distribution of field specimens was further assessed within two combined temperature and humidity gradient systems: (i) 0–3 °C/12% RH, 3–6 °C/33% RH, 6–9 °C/75% RH and 9–12 °C/100% RH and (ii) 0–3 °C/100% RH, 3–6 °C/75% RH, 6–9 °C/33% RH and 9–12 °C/12% RH. In gradient (i), C. antarcticus distributed homogeneously, but, in gradient (ii), C. antarcticus preferred 0–3 °C/100% RH. Alaskozetes antarcticus selected temperatures between 0 and +6 °C regardless of RH conditions. Cryptopygus antarcticus appears better able than A. antarcticus to opportunistically utilize developmentally favourable thermal microclimates, when moisture availability is not restricted. The distribution of A. antarcticus appears more influenced by temperature, especially during regular freeze‐thaw transitions, when this species may select low temperature microhabitats to maintain a cold‐hardened state. 相似文献
3.
Insects can increase their resistance to cold stress by prior exposure to non-lethal cold temperatures. Here, we investigated the supercooling capacity and survival of eggs, 3rd and 5th instar larvae, and pupae of Spodoptera exigua (Lepidoptera: Noctuidae) during CA, and responses to various pre-treatment protocols, including constant temperatures, thermoperiods, and RCH, RHH, RCH + RHH and RHH + RCH combined with thermoperiods. Only acclimated eggs demonstrated a significant decrease in SCP, from −20.7 ± 0.3 to −22.9 ± 0.3 °C, among all experimental groups compared to non-acclimated stages. Survival increased by 17.5% for eggs, 40.0% and 13.3% for 3rd and 5th instar larvae, and by 20.0% for pupae after CA. Compared to controls, survival of eggs under the conditions of thermoperiod (5:15 °C), thermoperiod (5:15 °C) + RHH, and thermoperiod (5:15, 10:20, and 15:25 °C) + RCH significantly increased. In addition, survival of 3rd and 5th instar larvae and pupae increased under the conditions of thermoperiod (5:15 °C) and thermoperiod (5:15 °C) + RCH, possibly due to the induction of heat shock proteins or cryoprotectants. However, the pre-treatments of thermoperiod + RCH + RHH and thermoperiod + RHH + RCH did not significantly enhance survival of any developmental stage. These adaptive responses may allow S. exigua to enhance supercooling capacity and survival in response to seasonal or unexpected diurnal decreases in environmental temperatures. 相似文献
4.
Abstract. The effect of moulting on the cold hardiness of the oribatid mite Alaskozetes antarcticus (Michael) is investigated. Non moulting animals show clear seasonal patterns of cold hardiness with high supercooling points (SCPs) at the peak of summer and an increasing proportion of low SCPs with declining environmental temperatures. By contrast, both field-fresh and laboratory acclimated (5 °C) mites in the moult state are consistently found to have low SCPs regardless of environmental temperature. 相似文献
5.
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. 相似文献
6.
William Block 《Journal of thermal biology》1981,6(4):215-218
The main features of the cold hardiness strategies adopted by Antarctic terrestrial arthropods (principally Acari and Collembola) are reviewed. These include lethal low temperatures, chill-coma temperature, supercooling ability, cryoprotectants and survival in anoxic conditions. 相似文献
7.
不同强度快速冷驯化对广聚萤叶甲成虫耐寒性生理指标的影响 总被引:3,自引:0,他引:3
【目的】快速冷驯化能在短时间内迅速提高昆虫的耐寒性,是昆虫应对外界温度急剧变化以及短时低温胁迫的重要途径。本研究旨在探究入侵杂草豚草Ambrosia artemisiifolia生防天敌广聚萤叶甲Ophraella communa对不同强度快速冷驯化的生理响应机制。【方法】分别对广聚萤叶甲成虫进行了不同温度(-4, 0, 4和8℃)下4 h及0℃下不同时间(1, 4 , 8和16 h)的快速冷驯化处理,并对其体内的生理物质含量和保护酶活性进行了测定。【结果】除8℃/4 h,0℃/1 h和0℃/8 h外,其余冷驯化处理均使广聚萤叶甲成虫过冷却点显著降低(P<0.05),其中0℃/4 h处理组最低。而且,随着冷驯化温度降低、持续时间的增长,广聚萤叶甲成虫体甘油含量以及过氧化氢酶(CAT)、过氧化物酶(POD)和超氧化物歧化酶(SOD)活性呈曲线变化,并于0℃/4 h处理时达到极值,但冷驯化处理对虫体自由水和总糖含量的影响并不显著(P≥0.05)。【结论】广聚萤叶甲快速冷驯化的诱导具有其临界强度值和最适条件,过大强度的驯化处理反而不利于其耐寒性的提高。本研究结果对于深入阐明广聚萤叶甲越冬策略以及人工培育耐寒种群的实践具有一定参考价值。 相似文献
8.
Rafting in Antarctic Collembola 总被引:1,自引:0,他引:1
Darwin was an early exponent of the importance of 'occasional means of dispersal' in accounting for the present-day distribution of plants and animals. This study examined the implications of capture on the water surface of meltwater and seawater for the local and long-range dispersal of Antarctic springtails. Individuals of the maritime Antarctic collembolan Cryptopygus antarcticus , were floated on tap water and seawater at 0, 5 and 10°C. LT50 s on seawater were 34 (10°C), 65 (5°C) and 75 (0°C) days. On tap water, LT50 s were 69 (10°C), 126 (5°C) and 239 (0°C) days. Less than 20% escaped from the water surface. A significantly greater proportion of springtails moulted on tap water and viable offspring were produced on both tap water and seawater. Comparison across treatments of survival of moulting and non-moulting individuals found significantly greater survival in moulting animals for three of the treatment combinations. It is suggested that moult exuviae facilitate survival on the water film through the simultaneous provision of a flotation aid and a source of nourishment – that is, an 'edible raft'. A separate experiment measuring changes in haemolymph osmolality over time on tap water and seawater at 2 and 5°C found significant differences in all treatments. Causes of mortality are discussed in relation to osmoregulatory failure and starvation. 相似文献
9.
甘薯天蛾过冷却点变化与生化成分的关系 总被引:1,自引:0,他引:1
测定长沙地区甘薯天蛾Agrius convolvuli L.在发育过程中不同时期的过冷却点、虫体水分和粗脂肪含量,并对其动态变化和相互之间的相关性进行分析。结果表明:不同世代甘薯天蛾过冷却点均随发育进程显著升高,在蛹期明显下降;2龄幼虫的过冷却点均为-11℃左右,蛹的过冷却点在越冬代过冷却点为-7·38℃,比其他世代蛹低2~3℃。甘薯天蛾虫体含水量随发育进程不断降低,粗脂肪含量则不断升高,其越冬代蛹粗脂肪含量占其干重高达30·23%。甘薯天蛾过冷却点与虫体水分含量呈正相关;而与虫体粗脂肪含量呈负相关,且在第2、3代和越冬代均呈显著负相关。甘薯天蛾在发育过程中通过调节水分和粗脂肪含量可能是其抵抗低温的生理机制之一。 相似文献
10.
11.
In the maritime Antarctic, terrestrial arthropods have recourse to two strategies to mitigate low summer temperatures: (1)
physiological plasticity and (2) avoidance via microhabitat insulation. This study investigated the interaction between these
strategies in the springtail, Cryptopygus antarcticus, established in situ within contrasting microcosms (buffered vs. exposed) and within two sets of habitat simulations (wet
vs. dry) over diurnal scales through the Antarctic summer. Significant differences were found in the cold hardiness of springtails
sampled simultaneously from each microcosm. Exposed animals showed greater plasticity in the “true” austral summer, but as
field temperatures declined preceding the onset of winter, buffered animals showed greater resilience. Overall, water was
found to inhibit the buffering effect of moss and there was a significantly greater discrimination between buffered and exposed
microcosms in the dry treatment. Analysis of microhabitat temperatures indicate that it is thermal variability not lower temperature
that is responsible for the greater plasticity of exposed animals. 相似文献
12.
Andreas Kahrer Anna Moyses Lisa Hochfellner Wolfgang Tiefenbrunner Alois Egartner Teresa Miglbauer Katharina Müllner Lara Reinbacher Christina Pilz Julia Votzi Helfried Scheifinger 《Journal of Applied Entomology》2019,143(10):1143-1153
In a series of laboratory experiments, acclimated pupae of Tuta absoluta were exposed to various constant low temperatures in order to estimate their maximum survival times (Kaplan–Meier, Lt99.99). A Weibull function was fitted to the data points, describing maximum survival time as a function of temperature. In another experiment at ?6°C, the progress of mortality increasing with exposure time was identified. These values were fitted by a sigmoidal function converging asymptotically to 100% mortality for very long exposure times. Analysing mortality data from the maximum survival experiment by a generalized linear model showed a significant common slope parameter (p < .001) that reveals parallelism of the survival curves at each temperature if a log time axis is used. These curves appear stretched (time scaled) if plotted with a nonlogarithmic time axis. By combining these mathematical relations, it was possible to calculate a species‐specific ‘mortality surface’ which exhibits mortalities, depending on temperature and duration of exposure. In order to accumulate hourly mortalities for courses of varying temperatures, an algorithm was developed which yields mortality values from that surface taking into account the attained mortality level. In validation experiments, recorded mortalities were compared against modelled mortalities. Prediction of mortality was partially supported by the model, but pupae experiencing intensely fluctuating temperatures showed decreased mortality, probably caused by rapid cold hardening during exposure. Despite this observation, mortality data converged to distinct levels very close to 100% depending on the intensity of temperature fluctuations that were characteristic for different types of experiments. The highest mortality limit occurred at intensely fluctuating temperatures in laboratory experiments. This constituted a benchmark that was not reached under various field conditions. Thus, it was possible to identify temperature limits for the extinction of field populations of Tuta absoluta pupae. 相似文献
13.
Insect thermal tolerance shows a range of responses to thermal history depending on the duration and severity of exposure. However, few studies have investigated these effects under relatively modest temperature variation or the interactions between short‐ and longer‐term exposures. In the present study, using a full‐factorial design, 1 week‐long acclimation responses of critical thermal minimum (CTmin) and critical thermal maximum (CTmax) to temperatures of 20, 25 and 30 °C are investigated, as well as their interactions with short‐term (2 h) sub‐lethal temperature exposures to these same conditions (20, 25 and 30 °C), in two fruit fly species Ceratitis capitata (Wiedemann) and Ceratitis rosa Karsch from South Africa. Flies generally improve heat tolerance with high temperature acclimation and resist low temperatures better after acclimation to cooler conditions. However, in several cases, significant interaction effects are evident for CTmax and CTmin between short‐ and long‐term temperature treatments. Furthermore, to better comprehend the flies' responses to natural microclimate conditions, the effects of variation in heating and cooling rates on CTmax and CTmin are explored. Slower heating rates result in higher CTmax, whereas slower cooling rates elicit lower CTmin, although more variation is detected in CTmin than in CTmax (approximately 1.2 versus 0.5 °C). Critical thermal limits estimated under conditions that most closely approximate natural diurnal temperature fluctuations (rate: 0.06 °C min?1) indicate a CTmax of approximately 42 °C and a CTmin of approximately 6 °C for these species in the wild, although some variation between these species has been found previously in CTmax. In conclusion, the results suggest critical thermal limits of adult fruit flies are moderated by temperature variation at both short and long time scales and may comprise both reversible and irreversible components. 相似文献
14.
15.
快速冷耐受比冷驯化更能提高越冬松针瘿蚊 (Thecodiplosis japonensis)幼虫的耐寒力(英文) 总被引:4,自引:0,他引:4
松针瘿蚊以三龄老熟幼虫在浅层土表越冬。本文比较两种温度处理过程 ,快速冷耐受 (rapidcoldhardening)和冷驯化 (coldacclimation)对松针瘿蚊获得耐寒性的能力。发现 3龄越冬幼虫具有一种特殊的生物学现象 -快速冷耐受。当越冬幼虫直接从 2 7℃转入 - 1 5℃ 3小时 ,其存活率仅为 1 7 9% ,然而在 - 1 5℃暴露之前 ,经 4℃ ,2h短暂处理 ,其存活率升高至 40 0 % ,而短时间 (1 5分钟 ) 2 7℃能抑制快速冷耐受的表达。快速冷耐受比冷驯化更能提高越冬松针瘿蚊幼虫的耐寒力。文中还讨论了快速冷耐受和冷驯化提高松针瘿蚊耐寒能力的不同机制 相似文献
16.
Abstract The responses of overwintering larvae of the pine needle gall midge Thecodiplosis japonensis Uchida et Inouye to rapid cold hardening and cold acclimation were studied. A rapid cold hardening response is found in the 3rd instar larvae of T. japonensis. When overwintering larvae are transferred directly from 27°C to ‐ 15°C for 3 h, there is only 17.9% survival, whereas exposure to 4°C for 2 h prior to transfer to ‐ 15°C increases survival to 40.0%. The acquired cold tolerance is transient and is rapidly lost (after 15 min at 27°C). Rapid cold hardening is more effective in maintaining larval survival than cold acclimation. Different mechanisms are suggested to regulate the insect's cold hardiness under rapid cold hardening and cold acclimation. 相似文献
17.
蠋蝽抗寒性对快速冷驯化的响应及其生理机制 总被引:1,自引:0,他引:1
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. 相似文献
18.
桔小实蝇不同发育阶段过冷却点的测定 总被引:6,自引:0,他引:6
对桔小实蝇Bactrocera dorsalis (Hendel)不同发育阶段的过冷却点进行了测定。结果表明:同一虫期个体间的过冷却点出现不同程度的变异,但均服从正态分布。不同虫期的过冷却点差异显著,其中蛹的过冷却点最低(-12.2℃~-15.0℃)。老熟幼虫的过冷却点为-8.1℃。成虫的过冷却点最低值为7日龄雄虫(-10.5℃)和雌虫(-10.1℃),最高值为60日龄雄虫(-5.9℃)和雌虫(-6.4℃),但同一发育时期的雌、雄成虫之间的过冷却点没有差异。测定结果提示蛹期最有可能是该虫在温带地区越冬的虫态。 相似文献
19.
本文描述了采自南极的三种弹尾目 ,其中详细描述了新种南极隐跳Cryptopygusnanjiensis头、胸、腹部诸如 :触角、角后器、足、弹器、腹管以及毛序等鉴别特征 ,并将两种已知种Tullbergiamediantarcti ca和Frieseawoyciechowskii与模式种进行了比较。新种及观察的已知种标本存放在中科院上海昆虫研究所的标本馆中 相似文献
20.
A. J. BURN 《Ecological Entomology》1984,9(1):11-21
Abstract. 1. Consumption, production and assimilation rates were determined for two age groups of Crypropygus antarcticus to give an estimate of energy utilization, and to investigate low temperature adaptation in its energy partitioning.
2. Feeding selectivity shown in laboratory preference tests was supported by gut analysis of field animals from contrasting sites. Although moulting rate was not significantly affected by food type, rates of growth were slowest and mortality highest when fed on a non-preferred substrate.
3. Both a radio labelling and a more direct method for measuring dry weight consumed gave similar results for Cvpropygus feeding on algae. The consuniption rate for animals when feeding on algae was lower than that on moss peat. The assimilation efficiency for immature animals feeding on algae was 46% and for mature animals was 19%; the values when feeding on moss peat were 7% and lo%, respectively, The net production efficiency ranged from 35%(inimatures) to 13% (matures) and was similar on both substrates.
4. Food consumption exceeded assimilation over the range 2.5–10°C, but the two converged from 2.5 to 0°C. Immature Cryptopygus maintained a net positive energy balance over 0–10°C, whilst below 1S°C respiration exceeded assimilation for mature individuals.
5. An estimate of the annual dry matter consumption (7 g m-1 y-1 ) by Ctypropygus in a moss turf at Signy Island agrees with one based on respiration data alone (Davis, 1981). The consumption at an alga-dominated site was c . 26 g m-2 y-l , and Crypropygus may have a locally limiting effect on net priniary production at such sites. 相似文献
2. Feeding selectivity shown in laboratory preference tests was supported by gut analysis of field animals from contrasting sites. Although moulting rate was not significantly affected by food type, rates of growth were slowest and mortality highest when fed on a non-preferred substrate.
3. Both a radio labelling and a more direct method for measuring dry weight consumed gave similar results for Cvpropygus feeding on algae. The consuniption rate for animals when feeding on algae was lower than that on moss peat. The assimilation efficiency for immature animals feeding on algae was 46% and for mature animals was 19%; the values when feeding on moss peat were 7% and lo%, respectively, The net production efficiency ranged from 35%(inimatures) to 13% (matures) and was similar on both substrates.
4. Food consumption exceeded assimilation over the range 2.5–10°C, but the two converged from 2.5 to 0°C. Immature Cryptopygus maintained a net positive energy balance over 0–10°C, whilst below 1S°C respiration exceeded assimilation for mature individuals.
5. An estimate of the annual dry matter consumption (7 g m