Physiological and biochemical analysis of overwintering and cold tolerance in two Central European populations of the spruce bark beetle, Ips typographus

Overwintering success is one of the key aspects affecting the development and outbreaks of the spruce bark beetle, Ips typographus (L.) populations. This paper brings detailed analysis of cold tolerance, and its influence on overwintering success, in two Central European populations of I. typographus during two cold seasons. Evidence for a supercooling strategy in overwintering adults is provided. The lower lethal temperature corresponds well to the supercooling point that ranges between −20 and −22 °C during winter months. The supercooled state is stabilized by the absence of internal ice nucleators and by seasonal accumulation of a mixture of sugars and polyols up to the sum concentration of 900 mM. The cryoprotective function of accumulated metabolites is probably based on increasing the osmolality and viscosity of supercooled body fluids and decreasing the relative proportion of water molecules available for lethal formation of ice nuclei. No activity of thermal hysteresis factors (stabilizers of supercooled state) was detected in hemolymph. Lethal times for 50% mortality (Lts50) in the supercooled state at −5, −10 or −15 °C are weeks (autumn, spring) or even months (winter), suggesting relatively little mortality caused by chill injury. Lts50 at −15 °C are significantly shorter in moist (6.9 days) than in dry (>42 days) microenvironment because there is higher probability of external ice nucleation and occurrence of lethal freezing in the moist situation.     

桉树枝瘿姬小蜂的耐寒性测定

桉树枝瘿姬小蜂Leptocybe invasa Fisher&LaSalle是一种新入侵的检疫性有害生物,为了明确其对极端低温的耐受性,以了解其适生范围,测定了桉树枝瘿姬小蜂幼虫、蛹、成虫及不同地区、不同寄主条件下雌雄成虫以及广东、广西、海南3省6地越冬幼虫12—3月的过冷却点和冰点。结果表明,不同虫态的过冷却点和冰点由低到高顺序为:蛹<幼虫<成虫。蛹的过冷却点和冰点分别为(-24.93±0.10)℃、(-22.81±0.14)℃,成虫的过冷却点和冰点为(-20.93±0.24)℃和(-17.33±0.27)℃。随着纬度的升高,桉树枝瘿姬小蜂的过冷却点和冰点都呈现降低的趋势。海南地区不同寄主桉树枝瘿姬小蜂过冷却点从低到高的顺序排列为:湛-201<小叶桉<广林9号。在12—3月,桉树枝瘿姬小蜂的越冬幼虫过冷却点和冰点随着环境温度的升高而升高,以广东广州地区1月份的越冬幼虫过冷却点和冰点为最低,其数值分别为(-25.44±0.17)℃和(-24.04±0.21)℃,个体过冷却点的最低值为-26.9℃。由实验结果可知,桉树枝瘿姬小蜂蛹和幼虫的耐寒力最强,以幼虫和蛹越冬。地区、寄主、温度对其耐寒力均有显著的影响,而且其有向现疫区以北的区域扩散的潜能。     

Overwintering Strategy and Mechanisms of Cold Tolerance in the Codling Moth (Cydia pomonella)

Background

The codling moth (Cydia pomonella) is a major insect pest of apples worldwide. Fully grown last instar larvae overwinter in diapause state. Their overwintering strategies and physiological principles of cold tolerance have been insufficiently studied. No elaborate analysis of overwintering physiology is available for European populations.

Principal Findings

We observed that codling moth larvae of a Central European population prefer to overwinter in the microhabitat of litter layer near the base of trees. Reliance on extensive supercooling, or freeze-avoidance, appears as their major strategy for survival of the winter cold. The supercooling point decreases from approximately −15.3°C during summer to −26.3°C during winter. Seasonal extension of supercooling capacity is assisted by partial dehydration, increasing osmolality of body fluids, and the accumulation of a complex mixture of winter specific metabolites. Glycogen and glutamine reserves are depleted, while fructose, alanine and some other sugars, polyols and free amino acids are accumulated during winter. The concentrations of trehalose and proline remain high and relatively constant throughout the season, and may contribute to the stabilization of proteins and membranes at subzero temperatures. In addition to supercooling, overwintering larvae acquire considerable capacity to survive at subzero temperatures, down to −15°C, even in partially frozen state.

Conclusion

Our detailed laboratory analysis of cold tolerance, and whole-winter survival assays in semi-natural conditions, suggest that the average winter cold does not represent a major threat for codling moth populations. More than 83% of larvae survived over winter in the field and pupated in spring irrespective of the overwintering microhabitat (cold-exposed tree trunk or temperature-buffered litter layer).     

Freezing induces a loss of freeze tolerance in an overwintering insect

Cold-hardy insects overwinter by one of two main strategies: freeze tolerance and freeze avoidance by supercooling. As a general model, many freeze-tolerant species overwinter in extreme climates, freeze above -10 degrees C via induction by ice-nucleating agents, and once frozen, can survive at temperatures of up to 40 degrees C or more below the initial freezing temperature or supercooling point (SCP). It has been assumed that the SCP of freeze-tolerant insects is unaffected by the freezing process and that the freeze-tolerant state is therefore retained in winter though successive freeze-thaw cycles of the body tissues and fluids. Studies on the freeze-tolerant larva of the hoverfly Syrphus ribesii reveal this assumption to be untrue. When a sample with a mean 'first freeze' SCP of -7.6 degrees C (range of -5 degrees C to -9.5 degrees C) were cooled, either to -10 degrees C or to their individual SCP, on five occasions, the mean SCP was significantly depressed, with some larvae subsequently freezing as low as -28 degrees C. Only larvae that froze at the same consistently high temperature above -10 degrees C were alive after being frozen five times. The wider occurrence of this phenomenon would require a fundamental reassessment of the dynamics and distinctions of the freeze-tolerant and freeze-avoiding strategies of insect overwintering.     

Factors affecting the cold hardiness of the peach-potato aphid Myzus persicae

Supercooling point studies were used to investigate the factors influencing the cold hardiness of the peach-potato aphid Myzus persicae, a freezing-susceptible insect. Overwintering adults lost cold hardiness as winter progressed, with a variable proportion showing a marked reduction in supercooling ability. Cold hardiness increased in spring so that all individuals demonstrated extensive supercooling ability typical of aphids reared in the laboratory at 20°C with a long photoperiod; these levels of cold hardiness were maintained in the field during summer and early autumn. First instar nymphs demonstrated considerable cold hardiness all year. Surface moisture caused inoculative freezing in some first instar nymphs and adults when supercooled, but the majority were unaffected. In the laboratory, adults starved for 7 days at 5°C showed distinct losses of supercooling potential equivalent to those observed in the field during mid to late winter. No loss of cold hardiness was found in first instar nymphs starved under the same conditions. The results demonstrate that the cold hardiness characteristics of M. persicae are atypical of those observed in other freezing-susceptible insects and it is suggested that continued feeding during mild winter conditions allows maintenance of cold hardiness particularly in adult aphids, and provides a possible explanation for the successful anholocyclic overwintering of M. persicae during such winters.     

Seasonal changes of free amino acids and thermal hysteresis in overwintering heteropteran insect, Pyrrhocoris apterus

Overwintering adults of Pyrrhocoris apterus do not tolerate freezing of their body fluids and rely on a supercooling strategy and seasonal accumulation of polyols to survive at subzero body temperatures. We sampled the adults monthly in the field during the cold season 2008-2009 and found active thermal hysteresis factors (THFs) in hemolymph of winter-sampled adults. The hysteresis between the equilibrium melting and freezing points ranged from 0.18°C to 0.30°C. No signs of THFs activity were found in the autumn- and spring-sampled insects. The total free amino acid pool almost doubled during winter time. The sum concentrations of 27 free amino acids ranged between 35 and 40mM in whole body water and 40-45mM in hemolymph during December-February. Two amino acids, Pro and α-Ala most significantly contributed to the seasonal increase, while Gln showed the most dramatic seasonal decrease. Moderate levels of amino acid accumulation in overwintering P. apterus suggest that they are by-products of protein degradation and pentose pathway activity during the state of metabolic suppression imposed by diapause and low body temperature. Potential colligative effects of accumulated amino acids, extending the supercooling capacity of overwintering P. apterus, are negligible. Non-colligative effects require further study.     

Adaptations to cold in Canadian arctic insects

The survival of insects that inhabit Canadian arctic regions depends on a number of factors which have important ecological, behavioral, physiological, and biochemical components. The ability to withstand low winter temperatures is one of the most conspicuous adaptations of northern insects and the one most closely studied in the laboratory. Most species studied so far conform to one or other of the two major overwintering strategies, namely, frost susceptibility, the ability to avoid freezing by supercooling to a considerable degree, or frost tolerance, the survival of actual ice formation within the body. The Arctic beetle, Pytho americanus Kirby, is frost tolerant in both larval and adult stages, a situation which would be congruous with its northern distribution and allow it to spread its life cycle over a number of growing seasons. The main biochemical correlates during the cold-hardening process in this species are increasing glycerol and decreasing glycogen concentrations. In addition to its normally assumed roles in cryoprotection there is evidence to suggest that glycerol may further serve to minimize dehydration in the overwintering insect by increasing the level of bound water. P. americanus larvae and adults have narrow supercooling ranges and maintain their supercooling points in the region of ?4 to ?8 °C. It is hypothesized that these elevated supercooling points are a result of the presence in the hemolymph of nucleating agents which ensure ice formation at high subzero temperatures.Low temperature tolerance strategies of some other arctic and alpine species have been examined and compared with those of relatives from more southerly latitudes. P. americanus has been collected in the Canadian Rockies at elevations of over 6000′, and its frost-tolerant attributes are identical to those of the population collected in the Arctic. A closely related species, P. deplanatus, from the Rockies, however, although it too exhibits frost tolerance in the larval stage, differs markedly from P. americanus in its ability to depress its supercooling range to ?54 °C. It appears that P. deplanatus does not have the ability to synthesize ice-nucleating agents and, therefore, can overwinter in a supercooled condition. Two congeneric species of willow leaf gall sawflies (Pontania spp.), one from Tuktoyaktuk, N.W.T., and the other from southern Vancouver Island have also been compared and contrasted. Pontania sp. on Salix glauca (Tuk., ca. 70 °N) is frost tolerant in its larval stage, has relatively high supercooling points (ca. ?9.0 °C), but does not accumulate glycerol. Pontania sp. from Salix lasiandra (Victoria, ca. 48 °N) has almost identical overwintering properties, indicating the close phylogenetic affinities of cold tolerance in this genus rather than independent adaptation to widely different climatic conditions. Some of the lowest supercooling points ever recorded are from willow stem gall forming insects. Rhabdophaga sp. (Cecidomyiidae) forms potato galls on the stems of Salix lanata in the Inuvik area, N.W.T. After low temperature acclimation, supercooling points down to ?66 °C have been recorded from individual larvae. This is a record, and it indicates that we may be dealing with a system in which most water is in a metabolically bound state. Glycerol levels reach 20% of the fresh body weight during this period. Diastrophus kincaidii Cynipidae) forms stem galls on Thimble Berry (Rubus parviflorus) on southern Vancouver Island. Both of the forementioned species overwinter as larvae in their galls and are, therefore, exposed to ambient air temperatures. A more benign winter climate on Vancouver Island is reflected in the fact that D. kincaidii has supercooling points only in the ?30 to ?33 °C range at the peak of low temperature acclimation, and glycerol levels just below 4% of fresh body weight. Both species are frost susceptible and depend on their supercooling abilities to survive low winter temperatures.     

Change in overwintering mechanism of the Cucujid beetle, Cucujus clavipes

Overwintering larvae of the Cucujid beetle, Cucujus clavipes, were freeze tolerant, able to survive the freezing of their extracellular body fluids, during the winter of 1978–1979. These larvae had high levels of polyols (glycerol and sorbitol), thermal hysteresis proteins and haemolymph ice nucleators that prevented extensive supercooling (the supercooling points of the larvae were ? 10°C), thus preventing lethal intracellular ice formation. In contrast, C. clavipes larvae were freeze suspectible, died if frozen, during the winter of 1982–1983, but supercooled to ～ ? 30°C. The absence of the ice nucleators in the 1982–1983 larvae, obviously essential in the now freeze-susceptible insects, was the major detected difference in the larvae from the 2 years. However, experiments in which the larvae were artifically seeded at ? 10°C (the temperature at which the natural haemolymph ice nucleators produced spontaneous nucleation in the 1978–1979 freeze tolerant larvae) demonstrated that the absence of the ice nucleators was not the critical factor, or at least not the only critical factor, responsible for the loss of freeze tolerance in the 1982–1983 larvae. The lower lethal temperatures for the larvae were approximately the same during the 2 winters in spite of the change in overwintering strategy.     

Subzero temperature tolerance in spiders: The role of thermal-hysteresis-factors

Summary The immature stages of two species of spiders which overwinter under the bark of standing dead trees survive subzero temperatures by depressing their supercooling points in winter. These are a crab spider,Philodromus sp. (Philodromidae), and a sac spider,Clubiona sp. (Clubionidae). The solutes which are at least partially responsible for the decrease in supercooling points in winter are: (1) proteins which produce a thermal hysteresis (a difference between the freezing and melting points) of approximately 2°C in the hemolymph and (2) glycerol. The thermal-hysteresis-factors and glycerol are only found in the spiders in winter. Acclimation of winter spiders to warm temperatures, at either long or short photoperiods, results in loss of the thermal hysteresis within two weeks. These thermal-hysteresis-factors appear to be similar to protein and glycoprotein antifreezes previously found in polar marine fishes and certain overwintering insects.     

Ice nucleation and antinucleation in nature

Plants and ectothermic animals use a variety of substances and mechanisms to survive exposure to subfreezing temperatures. Proteinaceous ice nucleators trigger freezing at high subzero temperatures, either to provide cold protection from released heat of fusion or to establish a protective extracellular freezing in freeze-tolerant species. Freeze-avoiding species increase their supercooling potential by removing ice nucleators and accumulating polyols. Terrestrial invertebrates and polar marine fish stabilize their supercooled state by means of noncolligatively acting antifreeze proteins. Some organisms also depress their body fluid melting point to ambient temperature by evaporation and/or solute accumulation.     

Variation in summer cold-hardiness of the Antarctic oribatid mite Alaskozetes antarcticus from contrasting habitats on King George Island

Summary The Antarctic oribatid mite Alaskozetes antarcticus was collected from several field habitats near Great Wall Station (62°13S, 58°58W) on King George Island during January and February 1990. The tritonymphs and adults were examined for their supercooling ability and survival at subzero temperatures in relation to inoculative freezing. The active tritonymphs and adults showed a wide range of supercooling points probably due to their polyphagous feeding activity and humid habitat conditions, with means ranging from -3.8° to -22.4°C. Detrivores were inferior to algivores in their supercooling ability. The former seemed to be transiently exposed to the hazard of freezing during the cool Antarctic summer. The resting (premoulting) tritonymphs exhibited the lowest mean supercooling point of -28.3°C. Inoculative freezing reduced the survival of A. antarcticus. Its effect became conspicuous at temperatures below -20°C and was serious in the deeply supercooled individuals, such as resting tritonymphs and algivorous adults. During the active season, spontaneous freezing probably started from the gut contents seemed to be more fatal than inoculative freezing for this freeze intolerant species.     

Deep supercooling enabled by surface impregnation with lipophilic substances explains the survival of overwintering buds at extreme freezing

The frost survival mechanism of vegetative buds of angiosperms was suggested to be extracellular freezing causing dehydration, elevated osmotic potential to prevent freezing. However, extreme dehydration would be needed to avoid freezing at the temperatures down to ?45°C encountered by many trees. Buds of Alnus alnobetula, in common with other frost hardy angiosperms, excrete a lipophilic substance, whose functional role remains unclear. Freezing of buds was studied by infrared thermography, psychrometry, and cryomicroscopy. Buds of A. alnobetula did not survive by extracellular ice tolerance but by deep supercooling, down to ?45°C. An internal ice barrier prevented ice penetration from the frozen stem into the bud. Cryomicroscopy revealed a new freezing mechanism. Until now, supercooled buds lost water towards ice masses that form in the subtending stem and/or bud scales. In A. alnobetula, ice forms harmlessly inside the bud between the supercooled leaves. This would immediately trigger intracellular freezing and kill the supercooled bud in other species. In A. alnobetula, lipophilic substances (triterpenoids and flavonoid aglycones) impregnate the surface of bud leaves. These prevent extrinsic ice nucleation so allowing supercooling. This suggests a means to protect forestry and agricultural crops from extrinsic ice nucleation allowing transient supercooling during night frosts.     

Survival of sub-zero temperatures by two South Georgian beetles (Coleoptera,Perimylopidae)

Summary The ability of adults and larvae of two species of perimylopid beetles (Hydromedion sparsutum, Perimylops antarcticus) to survive sub-zero temperatures was studied at Husvik, South Georgia in summer during October–December 1990. Experiments determined their survival at constant sub-zero temperatures, their lower lethal temperatures and individual supercooling points. The effects of cooling rates (0.015°, 0.5° and 2.0°C min^–1) and starvation on survival were also assessed. Mean supercooling points of field-collected individuals of both species were in the range -3.0° to -5.4°C with Perimylops having a deeper capacity (ca. 1.5°C) for supercooling relative to Hydromedion. The former species also survived freezing temperatures significantly better than the latter and its mean lower lethal temperature was 2.5°C lower. At a constant temperature of -8.5°C, the median survival times for Perimylops adults and larvae were 19 and 26 h respectively, whilst both stages of Hydromedion died within 3 h. The three cooling rates resulted in significantly different median survival temperatures for adult Hydromedion with 0.5°C min^–1 producing maximum survival. Prior starvation did not have a significant influence on the survival of either species at sub-zero temperatures although both adults survived less well. The results support field observations on the habitats and distribution of these insects, and suggest differing degrees of freezing tolerance.     

The ecology of overwintering among turtles: where turtles overwinter and its consequences

Turtles are a small taxon that has nevertheless attracted much attention from biologists for centuries. However, a major portion of their life cycle has received relatively little attention until recently - namely what turtles are doing, and how they are doing it, during the winter. In the northern parts of their ranges in North America, turtles may spend more than half of their lives in an overwintering state. In this review, I emphasise the ecological aspects of overwintering among turtles, and consider how overwintering stresses affect the physiology, behaviour, distributions, and life histories of various species.Sea turtles are the only group of turtles that migrate extensively, and can therefore avoid northern winters. Nevertheless, each year a number of turtles, largely juveniles, are killed when trapped by cold fronts before they move to safer waters. Evidently this risk is an acceptable trade-off for the benefits to a population of inhabiting northern developmental habitats during the summer.Terrestrial turtles pass the winter underground, either in burrows that they excavate or that are preformed. These refugia must provide protection against desiccation and lethal freezing levels. Some burrows are extensive (tortoise genus Gopherus), while others are shallow, or the turtles may simply dig into the ground to a safe depth (turtle genus Terrapene). In the latter genus, freeze tolerance may play an adaptive role.Most non-marine aquatic turtles overwinter underwater, although Clemmys (Actinemys) marmorata routinely overwinters on land when it occurs in riverine habitats, Kinosternon subrubrum often overwinters on land, and several others may overwinter terrestrially on occasion, especially in more southern climates. For northern species that overwinter underwater, there are two physiological groupings, those that are anoxia-tolerant and those that are relatively anoxia-intolerant. All species fare well physiologically in water with a high partial pressure of oxygen (PO2). A lack of anoxia tolerance limits the types of habitats that a freshwater turtle may live in, since unlike sea turtles, they cannot travel long distances to hibernate.Hatchlings of some species of turtles spend their first winter in or below the nest cavity, while hatchlings of other species in the same area, including northern areas, emerge in the autumn and presumably hibernate underwater. All hatchlings are relatively anoxia-intolerant, and there are no studies to date of where hatchling turtles that do not overwinter in or below the nest cavity spend their first winter. Equally little is known of the ontogeny of anoxia tolerance, other than that adults of all species are more anoxia-tolerant than their hatchlings, probably because of their better ossified shells, which provide adults with more buffer reserves and a larger site in which to sequester lactate. The northern limits of turtles are most likely determined by reproductive limitations (time for egg-laying, incubation, and hatching) than by the rigors of hibernation.Mortality is typically lower in turtle populations during hibernation than it is during their active periods. However, episodic mortality events do occur during hibernation, due to freezing, prolonged anoxia, or predation.     

Cold hardiness adaptations of codling moth, cydia pomonella

The cold hardiness adaptations of natural and laboratory reared populations of the codling moth, Cydia pomonella, were examined. Hemolymph, gut, and whole body supercooling points (SCPs), 24-h LT50s, polyhydroxy alcohol concentrations, hemolymph freezing points, and hemolymph melting points were determined. Nondiapausing codling moth larvae do not have appreciable levels of ice nucleators in the hemolymph or gut. Whole body supercooling points were higher than hemolymph supercooling points. For nondiapausing larvae, LT50s were significantly higher than both the whole body and the hemolymph supercooling points, indicating the presence of chill sensitivity. As the larvae left the food source and spun a cocoon, both hemolymph and whole body SCPs decreased. Diapause destined larvae had significantly lower hemolymph SCPs than nondiapausing larvae, but whole body SCPs were not significantly different from nondiapausing larvae of the same age. The LT50s of diapause destined and diapausing larvae were significantly lower than that of nondiapausing larvae. Codling moths are freezing intolerant, with LT50s close to the average whole body supercooling point in diapause destined and diapausing larvae. The overwintering, diapausing larvae effectively supercool to avoid lethal freezing by removal of ice nucleators from the gut and body without appreciable increase of antifreeze agents such as polyols or antifreeze proteins.     

Seasonal variation in the cold-hardiness of a free-living predatory antarctic nematode,Coomansus gerlachei (mononchidae)

Summary Coomansus gerlachei shows a strong seasonal variation in its supercooling ability, with most individuals freezing between -5° and -7°C, in a discrete high group, or between -15° and -26°C in a more diffuse low group. Increased cold-hardiness in winter is achieved by a strategy of freeze avoidance with an increase in the proportion of the population showing extensive supercooling ability. Smaller life-stages also exhibit lower supercooling points. Ice-nucleation at high sub-zero temperatures increases the probability of surviving freezing, a capacity which is enhanced in larger life-stages; adults and J4 stage juveniles show 50% survival at a supercooling point of -8.65° C. Laboratory incubations of field-fresh worms suggest that recent feeding is responsible for the movement between low and high groups. The cold-hardiness data for C. gerlachei provide interesting comparisons to the available data for microarthropods and create a precedent for seasonal changes between strategies of freezing tolerance and freezing intolerance in a field invertebrate population.     

Supercooling point plasticity during cold storage in the freeze‐tolerant sugarbeet root maggot Tetanops myopaeformis

Abstract The sugarbeet root maggot Tetanops myopaeformis (Röder) overwinters as a freeze‐tolerant third‐instar larva. Although most larvae are considered to overwinter for only 1 year, some may exhibit prolonged diapause in the field. In the laboratory, they can live for over 5 years using a combination of diapause and post‐diapause quiescence. In the present study, the cold survival strategies of these larvae during storage is investigated by measuring their supercooling points in combination with survival data. Supercooling points (SCPs) change significantly during storage, highlighted by a marked increase in the range of SCPs recorded, although the ability to tolerate freezing is not affected. Additionally, a freezing event ‘re‐focuses’ the SCPs of aged larvae to levels similar to those seen at diapause initiation. This change in SCPs is dependant not only on the initial freezing event, but also on the parameters of the incubation period between freezing events. Finally, the temperatures of larval overwintering microhabitats are monitored during the 2007–2008 boreal winter. The results indicate that, although overwintering larva are physiologically freeze‐tolerant, they may essentially be freeze avoidant during overwintering via microhabitat selection.     

Overwintering physiology and microhabitat use of Phyllocnistis populiella (Lepidoptera: Gracilliariidae) in interior Alaska

We investigated the overwintering physiology and behavior of Phyllocnistis populiella Chambers, the aspen leaf miner, which has caused severe and widespread damage to aspen in Alaska over the past 10 yr. Active P. populiella moths caught in spring and summer supercooled to an average temperature of -16°C, whereas dormant moths excavated from hibernacula in the leaf litter during fall and winter supercooled to an average of -32°C. None of the moths survived freezing in the laboratory. Counts of overwintering moths in leaf litter across microhabitats in interior Alaska demonstrated that moths occurred at significantly higher density beneath white spruce trees than beneath the aspen host, several other hardwood species, or in open areas among trees. During winter, the temperature 1-2 cm below the surface of the leaf litter beneath white spruce trees was on average 7-9°C colder than beneath aspen trees, and we estimate that during at least one period of the winter the temperature under some white spruce trees may have been cold enough to cause mortality. However, the leaf litter under white spruce trees was significantly drier than the litter from other microhabitats, which may assist P. populiella moths to avoid inoculative freezing because of physical contact with ice. We conclude that in interior Alaska, P. populiella overwinter in a supercooled state within leaf litter mainly under nonhost trees, and may prefer relatively dry microhabitats over moister ones at the expense of lower environmental temperature.     

The role of direct chilling injury and inoculative freezing in cold tolerance of Amblyomma americanum, Dermacentor variabilis and Ixodes scapularis

Abstract. Supercooling points and chill tolerance were compared among nymphs and adults of the ixodid ticks Dermacentor variabilis, Amblyomma americanum and Ixodes scapularis (Acari: Ixodidae).Supercooling points in the range of <-22 to -18°C were observed for nymphs, and -22 to -8°C for adults.The lower lethal temperatures observed under dry conditions, -14 to -10°C, were warmer than the supercooling points, but still much colder than -4.8°C, the lowest temperature recorded from a likely tick habitat in southwestern Ohio.Based on our experiments, spontaneous freezing and direct chilling injury are not significant mortality factors in these species in the field.Mortality was observed between -5 and -3°C for A.americanum and D.variabilis nymphs chilled for 2 h while in direct contact with ice.This mortality is probably due to inoculative freezing.Given the requirement for a rather humid microhabitat for off-host survival, these findings suggest that inoculative freezing is an important cause of overwintering mortality in these medically important species.     

Supercooling phenomenon and water content independence in the overwintering beetle, Coleomegilla maculata

Insect supercooling phenomena observed during overwintering have been coupled with the seasonality of water and nucleator content and feeding behaviour. However, the strength of the conclusion has in most cases rested on presumption and model systems since nucleator content is not readily quantifiable. The ladybird, Coleomegilla maculata is an overwintering adult insect that fasts for weeks before hibernation, does not accumulate identifiable cryoprotectants during cold exposures, and is freezing intolerant. This species would be expected to overwinter with a constancy of ice nucleators subject to relative increases due to winter dehydration and decreases in supercooling ranges.However, acclimatization and laboratory acclimation experiments have demonstrated both temporal and temperature independence of water content while supercooling levels varied substantially. Supercooling ranges were narrow during warm exposures with a unimodal peak at −6·3°C (±0·2 S.E.). Progressive temperature reductions yielded phasic shifts to multimodal ranges until a low temperature peak of −18·4°C (±0·5 S.E.) was attained. Induced feedings of controlled nucleator substances resulted in predictable supercooling variations while ‘nucleator free’ diets yielded results consistent with natural populations.