Supercooling characteristics of isolated peach flower bud primordia

The amount of unfrozen water in dormant peach (Prunus persica [L.] Batsch, cv Redhaven) flower buds, isolated primordia, and bud axes was determined during freezing using pulse nuclear magnetic resonance methods. Differential thermal analysis studies were conducted on whole buds and isolated primordia in the presence of ice nucleation. The results showed that some of the water in isolated primordia remained supercooled in the presence of ice nucleation. Although most tissue water froze (57.5%) following ice nucleation at −2.5°C, a considerable amount of water was found to supercool. In the presence of ice nucleation, increased hydration of isolated primordia resulted in the elimination of the supercooling characteristic. The structural integrity of isolated primordia appeared to be essential for supercooling.     

Supercooling in overwintering azalea flower buds: additional freezing parameters

Results of calorimetric, nuclear magnetic resonance, and low temperature light microscopic studies on supercooled azalea (Rhododendron kosterianum, Schneid.) floral primordia are reported. Heat release during freezing of the supercooled floral primordia is in the range predicted for supercooled pure water. Spin-lattice and spin-spin relaxation times measured by pulsed nuclear magnetic resonance spectroscopy decreased after freezing, suggesting that a redistribution of tissue water is associated with injury to the floral primordium. The calorimetric and low temperature microscopy studies showed no detectable ice formation in floral primordia until the major freezing event at low temperature. No resistance to ice growth is found to exist in the primordium tissues, indicating that a freezing barrier or thermodynamic equilibrium exists between the unfrozen primordium and other flower bud parts which contain ice at subfreezing temperatures.     

Freezing Tolerance of Shoot and Flower Primordia of Coniferous Buds by Extraorgan Freezing

Shoot and flower primordia of vegetative and flower buds ofextremely or very hardy conifers belonging to the subfamilyAbietoideae of the Pinaceae, survived between –40 and–70?C by extraorgan freezing, which differed greatly dependingupon species. The water in these organs gradually froze outwith decreasing temperatures when cooled very slowly, whichenabled these organs to survive %40?C or below. The same icesegregation in shoot and flower primordia by extraorgan freezingwas observed in most of the temperate conifers belonging toTaxaceae, Cephalotaxaceae, Taxodiaceae and Cuppressaceae, makingthem resistant to temperatures between –15 and –25?C.In these conifers, scales acted as an ice sink, unlike the conifersof Abietoideae. The rates of cooling and exosmosis of waterin the shoot or flower primordia, their size, and their abilityto tolerate freeze-dehydration or its related stress play animportant role in determining whether death is caused by freeze-dehydrationor intraorgan freezing. Even in very hardy conifers, low temperature exotherms fromfreezing within the shoot primordia appeared between –30and –35?C on the DTA profiles when cooled continuouslyunder laboratory conditions from 5?C to –50?C at 2 to5?C/h. Appearance of low temperature exotherms always resultedin death. However, in the coldest area of Hokkaido, where theair temperature cools down to –40?C or below nearly everyyear, such an intraorgan freezing seems seldom to occur, especiallyin natural stands. On the other hand, low temperatures below–25?C seldom occur in warm-temperate climates. Thus, itmay be considered that in both boreal and temperate coniferstheir shoot and flower primordia seem to tolerate freeze dehydrationby extraorgan freezing under natural conditions. ¹ Contribution No. 2431 from the rnstitute of Low TemperatureScience. (Received March 27, 1982; Accepted August 12, 1982)     

Cryo-scanning electron microscopic study on freezing behaviors of tissue cells in dormant buds of larch (Larix kaempferi)

The freezing behavior of dormant buds in larch, especially at the cellular level, was examined by a Cryo-SEM. The dormant buds exhibited typical extraorgan freezing. Extracellular ice crystals accumulated only in basal areas of scales and beneath crown tissues, areas in which only these living cells had thick walls unlike other tissue cells. By slow cooling (5 °C/day) of dormant buds to −50 °C, all living cells in bud tissues exhibited distinct shrinkage without intracellular ice formation detectable by Cryo-SEM. However, the recrystallization experiment of these slowly cooled tissue cells, which was done by further freezing of slowly cooled buds with LN and then rewarming to −20 °C, confirmed that some of the cells in the leaf primordia, shoot primordia and apical meristem, areas in which cells had thin walls and in which no extracellular ice accumulated, lost freezable water with slow cooling to −30 °C, indicating ability of these cells to adapt by extracellular freezing, whereas other cells in these tissues retained freezable water with slow cooling even to −50 °C, indicating adaptation of these cells by deep supercooling. On the other hand, all cells in crown tissues and in basal areas of scales, areas in which cells had thick walls and in which large masses of ice accumulated, had the ability to adapt by extracellular freezing. It is thought that the presence of two types of cells exhibiting different freezing adaptation abilities within a bud tissue is quite unique and may reflect sophisticated freezing adaptation mechanisms in dormant buds.     

Properties of peach flower buds which facilitate supercooling

Water in dormant peach (Prunus persica [L.] Batsch. var. `Harbrite') flower buds deep supercooled. Both supercooling and the freezing of water within the bud axis and primordium as distinct components depended on the viability of the bud axis tissue. The viability of the primordium was not critical. Supercooling was prevented by wounding buds with a dissecting needle, indicating that bud structural features were important. Bud morphological features appeared to prevent the propagation of ice through the vascular tissue and into the primordium. In dormant buds, procambial cells had not yet differentiated into xylem vessel elements. Xylem continuity between the bud primordium and adjacent tissues did not appear to be established until buds had deacclimated. It was concluded that structural, morphological, and physiological features of the bud facilitated supercooling.     

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.     

Overwintering adaptations of the stag beetle,Ceruchus piceus: removal of ice nucleators in the winter to promote supercooling

Summary Overwintering larvae and adults of the stag beetle,Ceruchus piceus, are freeze sensitive (i.e. cannot survive internal freezing). The most commonly described cold adaptation of freeze susceptible insects involves the production of antifreezes to promote supercooling, butCeruchus piceus larvae produced only low levels of antifreezes in the winter. However, by removing ice nucleators from the gut and hemolymph in the winter the larvae were able to depress their supercooling points from approximately –7°C in the summer to near –25°C in mid-winter. The ice nucleators present in the non-winter hemolymph were identified as lipoproteins. One of these lipoproteins with ice nucleator activity was purified using flotation ultracentrifugation and anion exchange (DEAE-Sephadex) chromatography.Removal of ice nucleators to promote supercooling in winter may be energetically preferable to costly production and maintenance of high, of-ten molar, concentrations of antifreeze. Obviously the ice nucleator must normally perform a function which the insect can spare over the winter. Hemolymph lipoproteins, which generally function in lipid transport, may fit this criterion during the winter period of reduced metabolic activity.Abbreviations LP I very low density lipoprotein - LP II low density lipoprotein - PAGE polyacrylamide gel electrophoresis - SCP supercooling point     

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.     

细菌冰核提高印度谷螟过冷却点的研究

印度谷螟(Plodia interpunctella)是一种不耐结冰的昆虫,在冬季它通过降低过冷却 点以避免结冰。现已查明,冰核活性细菌能显著提高植物的过冷却点,导致许多作物在较高 的温度下发生霜冻害。本文也证明细菌冰核能显著提高印度谷螟虫的过冷却点。对照的平均过冷却点是-17.6℃;分别用0.1g和1g细菌冰核与1kg面粉混合后进行处理,平均过冷却点分别比对照提高了12.8℃和13.6℃。研究结果支持这样的观点：细菌冰核有可能成为一种在冬季使用的、杀灭不耐结冰害虫的生物制剂。     

Change of supercooling capability in solutions containing different kinds of ice nucleators by flavonol glycosides from deep supercooling xylem parenchyma cells in trees

Deep supercooling xylem parenchyma cells (XPCs) in Katsura tree contain flavonol glycosides with high supercooling-facilitating capability in solutions containing the ice nucleation bacterium (INB) Erwinia ananas, which is thought to have an important role in deep supercooling of XPCs. The present study, in order to further clarify the roles of these flavonol glycosides in deep supercooling of XPCs, the effects of these supercooling-facilitating (anti-ice nucleating) flavonol glycosides, kaempferol 3-O-β-d-glucopyranoside (K3Glc), kaempferol 7-O-β-d-glucopyranoside (K7Glc) and quercetin 3-O-β-d-glucopyranoside (Q3Glc), in buffered Milli-Q water (BMQW) containing different kinds of ice nucleators, including INB Xanthomonas campestris, silver iodide and phloroglucinol, were examined by a droplet freezing assay. The results showed that all of the flavonol glycosides promoted supercooling in all solutions containing different kinds of ice nucleators, although the magnitudes of supercooling capability of each flavonol glycoside changed in solutions containing different kinds of ice nucleators. On the other hand, these flavonol glycosides exhibited complicated nucleating reactions in BMQW, which did not contain identified ice nucleators but contained only unidentified airborne impurities. Q3Glc exhibited both supercooling-facilitating and ice nucleating capabilities depending on the concentrations in such water. Both K3Glc and K7Glc exhibited only ice nucleation capability in such water. It was also shown by an emulsion freezing assay in BMQW that K3Glc and Q3Glc had no effect on homogeneous ice nucleation temperature, whereas K7Glc increased ice nucleation temperature. The results indicated that each flavonol glycoside affected ice nucleation by very complicated and varied reactions. More studies are necessary to determine the exact roles of these flavonol glycosides in deep supercooling of XPCs in which unidentified heterogeneous ice nucleators may exist.     

Visualization of Freezing Behaviors in Leaf and Flower Buds of Full-Moon Maple by Nuclear Magnetic Resonance Microscopy

1H-Nuclear magnetic resonance (NMR) microscopy was used to study the freezing behavior of wintering buds of full-moon maple (Acer japonicum Thunb.). The images obtained predominantly reflected the density of mobile (i.e. non-ice) protons from unfrozen water. A comparison of NMR images taken at different subfreezing temperatures revealed which tissues produced high- and low-temperature exotherms in differential thermal analyses. In leaf and lower buds of A. japonicum, the scales and stem bark tissues were already frozen by -7[deg]C, but the primordial inflorescence and terminal primordial shoots remained supercooled at -14[deg]C, and the lateral primordial shoots were unfrozen even at -21[deg]C. The freezing of these supercooled tissues was associated with their loss of viability. The size of the supercooled primordial shoots and inflorescences was gradually reduced with decreasing temperature, indicating extraorgan freezing in these tissues. During this process the formation of dark regions beneath the primordia and subsequent gradual darkening in the basal part of supercooled primordia were visible. As the lateral shoot primordia were cooled, the unfrozen area was considerably reduced. Since the lateral primordia remained viable down to -40[deg]C, with no detectable low-temperature exotherms, they probably underwent type I extraorgan freezing. Deep supercooling in the xylem was clearly imaged. NMR microscopy is a powerful tool for noninvasively visualizing harmonized freezing behaviors in complex plant organs.     

The inhibition of ice nucleators by insect antifreeze proteins is enhanced by glycerol and citrate

Antifreeze proteins depress the freezing point of water while not affecting the melting point, producing a characteristic difference in freezing and melting points termed thermal hysteresis. Larvae of the beetle Dendroides canadensis accumulate potent antifreeze proteins (DAFPs) in their hemolymph and gut, but to achieve high levels of thermal hysteresis requires enhancers, such as glycerol. DAFPs have previously been shown to inhibit the activity of bacterial and hemolymph protein ice nucleators, however, the effect was not large and therefore the effectiveness of the DAFPs in promoting supercooling of the larvae in winter was doubtful. However, this study demonstrates that DAFPs, in combination with the thermal hysteresis enhancers glycerol (1 M) or citrate (0.5 M), eliminated the activity of hemolymph protein ice nucleators and Pseudomonas syringae ice-nucleating active bacteria, and lowered the supercooling points (nucleation temperatures) of aqueous solutions containing these ice nucleators to those of water or buffer alone. This shows that the DAFPs, along with glycerol, play a critical role in promoting hemolymph supercooling in overwintering D. canadensis. Also, DAFPs in combination with enhancers may be useful in applications which require inhibition of ice nucleators.     

A method for quantitative determination of ice nucleating agents in insect hemolymph

The relationship between the concentration of insect hemolymph ice nucleators in samples of 0.9% NaCl solution and the supercooling points of the samples was determined by using a dilution technique. The supercooling points were only moderately reduced following dilution by a factor of up to 10³, whereas dilution beyond this point caused a marked drop in the supercooling points. The dilution factor corresponding to a 50% reduction in the nucleating activity of native hemolymph is taken as a measure of the concentration of ice nucleators in native hemolymph.This method was used to determine the concentration of ice nucleators in the hemolymph of Eurosta solidaginis larvae from Minnesota and Texas, acclimated to different temperatures. Significant levels of nucleators were found only in larvae from Minnesota, and +5 °C was found to be the optimal temperature for nucleator formation. This comparatively high temperature optimum is interpreted as a physiological adaptation, ensuring sufficient nucleator levels in the hemolymph by the time of the first exposure to freezing temperatures in the winter.     

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.     

Analysis of supercooling activity of tannin-related polyphenols

Based on the discovery of novel supercooling-promoting hydrolyzable gallotannins from deep supercooling xylem parenchyma cells (XPCs) in Katsura tree (see Wang et al. (2012) [38]), supercooling capability of a wide variety of tannin-related polyphenols (TRPs) was examined in order to find more effective supercooling-promoting substances for their applications. The TRPs examined were single compounds including six kinds of hydrolyzable tannins, 11 kinds of catechin derivatives, two kinds of structural analogs of catechin and six kinds of phenolcarboxylic acid derivatives, 11 kinds of polyphenol mixtures and five kinds of crude plant tannin extracts. The effects of these TRPs on freezing were examined by droplet freezing assays using various solutions containing different kinds of identified ice nucleators such as the ice nucleation bacterium (INB) Erwinia ananas, the INB Xanthomonas campestris, silver iodide and phloroglucinol as well as a solution containing only unintentionally included unidentified airborne ice nucleators. Among the 41 kinds of TRPs examined, all of the hydrolyzable tannins, catechin derivatives, polyphenol mixtures and crude plant tannin extracts as well as a few structural analogs of catechin and phenolcarboxylic acid derivatives exhibited supercooling-promoting activity (SCA) with significant differences (p > 0.05) from at least one of the solutions containing different kinds of ice nucleators. It should be noted that there were no TRPs exhibiting ice nucleation-enhancing activity (INA) in all solutions containing identified ice nucleators, whereas there were many TRPs exhibiting INA with significant differences in solutions containing unidentified ice nucleators alone. An emulsion freezing assay confirmed that these TRPs did not essentially affect homogeneous ice nucleation temperatures. It is thought that not only SCA but also INA in the TRPs are produced by interactions with heterogeneous ice nucleators, not by direct interaction with water molecules. In the present study, several TRPs that might be useful for applications due to their high SCA in many solutions were identified.     

Cold adaptation of the terrestrial isopod,Porcellio scaber,to subnivean environments

The terrestrial isopod, Porcellio scaber, was susceptible to subzero temperature: both freezing and chilling were injurious. The level of cold hardiness against chilling and freezing showed different patterns in their seasonal variation. The lower lethal temperature causing 50% mortality, an indicator of the tolerance to chilling, ranged from-1.37°C in August to-4.58°C in December. The whole body supercooling point, the absolute limit of freeze avoidance, was kept at about-7°C throughout the year. The winter decrease in lower lethal temperature was concomitant with an accumulation of low molecular weight carbohydrates which are possible protective reagents against chilling injury, whereas the less seasonally variable supercooling point seemed to be associated with the year-round presence of gut content. Food derivatives may act as efficient ice nucleators. The different trend in seasonal changes between lower lethal temperature and supercooling point may be related to the microclimate of the hibernacula in subnivean environments, where the winter temperature became lower than the lower lethal temperature in the summer active phase, but remained higher than the summer supercooling point.Abbreviations LLT₅₀ lower lethal temperature inducing 50% mortality - SCP supercooling point - T _a ambient air temperature - T _s soil surface temperature     

Phylogenetic analyses in cornus substantiate ancestry of xylem supercooling freezing behavior and reveal lineage of desiccation related proteins

The response of woody plant tissues to freezing temperature has evolved into two distinct behaviors: an avoidance strategy, in which intracellular water supercools, and a freeze-tolerance strategy, where cells tolerate the loss of water to extracellular ice. Although both strategies involve extracellular ice formation, supercooling cells are thought to resist freeze-induced dehydration. Dehydrin proteins, which accumulate during cold acclimation in numerous herbaceous and woody plants, have been speculated to provide, among other things, protection from desiccative extracellular ice formation. Here we use Cornus as a model system to provide the first phylogenetic characterization of xylem freezing behavior and dehydrin-like proteins. Our data suggest that both freezing behavior and the accumulation of dehydrin-like proteins in Cornus are lineage related; supercooling and nonaccumulation of dehydrin-like proteins are ancestral within the genus. The nonsupercooling strategy evolved within the blue- or white-fruited subgroup where representative species exhibit high levels of freeze tolerance. Within the blue- or white-fruited lineage, a single origin of dehydrin-like proteins was documented and displayed a trend for size increase in molecular mass. Phylogenetic analyses revealed that an early divergent group of red-fruited supercooling dogwoods lack a similar protein. Dehydrin-like proteins were limited to neither nonsupercooling species nor to those that possess extreme freeze tolerance.     

Insect antifreezes and ice-nucleating agents

Cold-tolerant, freeze-susceptible insects (those which die if frozen) survive subzero temperatures by proliferating antifreeze solutes which lower the freezing and supercooling points of their body fluids. These antifreezes are of two basic types. Lowmolecular-weight polyhydroxy alcohols and sugars depress the freezing point of water on a colligative basis, although at higher concentrations these solutes may deviate from linearity. Recent studies have shown that these solutes lower the supercooling point of aqueous solutions approximately two times more than they depress the freezing point. Consequently, if a freeze-susceptible insect accumulates sufficient glycerol to lower the freezing point by 5 °C, then the glycerol should depress the insect's supercooling point by 10 °C.Some cold-tolerant, freeze-susceptible insects produce proteins which produce a thermal hysteresis (a difference between the freezing and melting point) of several degrees in the body fluids. These thermal hysteresis proteins (THPs) are similar to the antifreeze proteins and glycoproteins of polar marine teleost fishes. The THPs lower the freezing, and presumably the supercooling, point by a noncolligative mechanism. Consequently, the insect can build up these antifreezes, and thereby gain protection from freezing, without the disruptive increases in osmotic pressure which accompany the accumulation of polyols or sugars. Therefore the THPs can be more easily accumulated and maintained during warm periods in anticipation of subzero temperatures. It is not surprising then that photoperiod, as well as temperature, is a critical environmental cue in the control of THP levels in insects.Some species of freeze-tolerant insects also produce THPs. This appears somewhat odd, since most freeze-tolerant insects produce ice nucleators which function to inhibit supercooling and it is therefore not clear why such an insect would produce antifreeze proteins. It is possible that the THPs have an alternate function in these species. However, it also appears that the THPs function as antifreezes during those periods of the year when these insects are not freeze tolerant (i.e., early autumn and spring) but when subzero temperatures could occur. In addition, at least one freeze-tolerant insect which produces THPs, Dendroides canadensis, typically loses freeze tolerance during midwinter thaws and then regains tolerance. The THPs could be important during those periods when Dendroides loses freeze tolerance by making the insect less susceptible to sudden temperature decreases.Comparatively little is known of the biochemistry of insect THPs. However, comparisons of those few insect THPs which have been purified with the THPs of fishes show some interesting differences. The insect THPs lack the large alanine component commonly found in the fish THPs. In addition, the insect THPs generally contain greater percentages of hydrophilic amino acids than do those of the fish. Perhaps the most interesting insect THPs are those from Tenebrio molitor which have an extremely large cysteine component (28% in one THP). Studies on the primary and higher-order structure of the insect THPs need to be carried out so that more critical comparisons with the fish THPs can be made. This may provide important insights into the mechanisms of freezing point and supercooling point depression exhibited by these molecules. In addition, comparative studies of the freezing and supercooling point depressing activities of the various THPs, in relation to their structures, should prove most interesting.It has become increasingly apparent over the last few years that most freeze-tolerant insects, unlike freeze-susceptible species, inhibit supercooling by accumulating ice-nucleating agents in their hemolymph. These nucleators function to ensure that ice formation occurs in the extracellular fluid at fairly high temperatures, thereby minimizing the possibility of formation of lethal intracellular ice. Little is known of the nature of the insect ice-nucleating agents. Those few which have been studied are heat sensitive and nondialyzable and are inactivated by proteolytic enzymes, thus indicating that they are proteinaceous. Studies on the structure-function relationships of these unique molecules should be done.     

The Siberian timberman Acanthocinus aedilis: a freeze-tolerant beetle with low supercooling points

Larvae of the Siberian timberman beetle Acanthocinus aedilis display a number of unique features, which may have important implications for the field of cold hardiness in general. Their supercooling points are scattered over a wide temperature range, and some individuals have supercooling points in the low range of other longhorn beetles. However, they differ from other longhorn beetles in being tolerant to freezing, and in the frozen state they tolerate cooling to below −37°C. In this respect they also differ from the European timberman beetles, which have moderate supercooling capacity and die if they freeze. The combination of freezing tolerance and low supercooling points is unusual and shows that freezing at a high subzero temperature is not an absolute requirement for freezing tolerance. Like other longhorn beetles, but in contrast to other freeze-tolerant insects, the larvae of the Siberian timberman have a low cuticular water permeability and can thus stay supercooled for long periods without a great water loss. This suggests that a major function of the extracellular ice nucleators of some freeze-tolerant insects may be to prevent intolerable water loss in insects with high cuticular water permeability, rather than to create a protective extracellular freezing as has generally been assumed. The freezing tolerance of the Siberian timberman larvae is likely to be an adaptation to the extreme winter cold of Siberia.     

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.