Diminution de la capacité de surfusion au cours de l'embryogenèse et du développement larvaire chez un coléoptère

Potential cold resistance of non-diapause eggs and first instar larvae of Osmoderma eremita (Coleoptera, Cetoniidae, Trichiinae) during embryogenesis and post-embryonic growth was assessed by measuring individual supercooling points (SCP): sterile eggs had a mean SCP of −24.3 ± 2.0 °C; fertilized newly laid eggs a mean SCP of −23.4 ± 3.2 °C and eggs about to hatch a mean SCP of −9.2 ± 2.9 °C. Water absorption by fertilized eggs is a necessary requirement for the development of the embryo and results in an increase in weight and water content: fertilized newly laid eggs had a mean fresh weight of 10.687 ± 1.072 mg and a mean water content (expressed as a percentage of the dry weight) of 79.5 ± 10.83%; eggs about to hatch had a mean fresh weight of 19.127 ± 3.183 mg and a mean water content of 250.10 ± 74.15%. The ex-ovo larvae, hatched 30 days after oviposition, had a mean SCP of −10.1 ± 3.6 °C (no significant difference with eggs about to hatch) and had gained in weight (24.845 ± 3.911 mg) and in water content (499.72 ± 55.49%). Feeding 1st instar larvae had a decreased supercooling ability (mean SCP = −5.7 ± 0.4 °C) whereas their mean fresh weight (99.858 ± 53.091 mg) and mean water content (665.83 ± 82.74%) increased. The eggs and larvae of O. eremita are freezing intolerant. Before overwintering, all larvae switch to being freezing tolerant and can survive ice formation in their tissues and body fluids, whereas their mean SCP stays at around −5 °C. However, recent experiments in the winter of 1996 have shown that frozen larva mortality does occur at temperatures lower than about −12 °C.     

Winter survival of an adult bark beetle Ips acuminatus Gyll

Freezing-susceptible adult Ips acuminatus hibernate underneath bark of Scots pine. The beetles lower their supercooling points from ?20 to ?34°C due to accumulation of low molecular weight antifreezes. The capability of specimens to supercool to about ?20°C in the absence of cryoprotective solutes during winter, seemed to be at least partially attributable to the presence of a thermal hysteresis factor at 3–4°C.Using a GC-MS-COM technique, a unique combination of accumulated solutes present only in specimens demonstrating supercooling points below ?20°C was identified as ethylene glycol, mannitol, sorbitol and dulcitol. Not previously found in nature, ethylene glycol was the major solute (90%) synthesized at sub-zero temperatures. Exposure to ?10°C was an effective cue to accumulation of ethylene glycol and nearly 5 times as effective in promoting sorbitol synthesis than was ?5°C. When low molecular weight substances were lost at high temperatures, they were not re-synthesized in beetles re-exposed to sub-zero temperature. The supercooling point was closely related to both the concentration of ethylene glycol and to the haemolymph melting point. Attempts to correlate changes in sorbitol concentrations to changes in supercooling points were not conclusive.Proliferation of thermal hysteresis was observed in the beginning of November. A melting-hysteresis freezing point differential of about 3.6°C was demonstrated in the haemolymph of beetles during December. No thermal hysteresis was demonstrated in the haemolymph of positive phototactic beetles or in the outdoor beetles in May. The combination of high temperature and long photoperiod appeared to be a more effective cue to the final loss of thermal hysteresis than was high temperature alone.     

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.     

Cold hardiness of larvae of the southwestern corn borer, Diatraea grandiosella

The cold-hardening capacity of field-collected larvae from southeast Missouri and laboratory-reared larvae of the southwestern corn borer, Diatraea grandiosella Dyar, was examined. Supercooling points of non-diapause and diapause larvae collected from maize plants grown in Missouri (36°30 N lat.) were ca.-7.0°C. The hemolymph melting points of diapause field larvae (-0.8°C) were significantly lower than those of non-diapause larvae collected in July (-0.5°C). The supercooling points of hemolymph from non-diapause and diapause field larvae ranged randomly from-10° to-18°C. Supercooling points of non-diapause laboratory larvae increased from-13° to-10°C prior to pupation, whereas those of diapause larvae increased similarly before the onset of diapause, but then decreased during diapause to ca.-17°C. No change in supercooling points or capacity to survive in the presence of ice was observed in diapause laboratory larvae acclimated at 4°C for 63 days. Laboratory and field larvae began to freeze at ca.-1.5°C in the presence of ice, but survived to several degrees below their melting points. The high supercooling points of field larvae appeared to be due to the presence of an environmental ice-nucleator. Although data for laboratory larvae indicate sufficiently low supercooling points to permit winter survival in southeastern Missouri, considerable larval mortality occurs in the field due to inoculative freezing and the presence of an ice-nucleator.     

Comparative analysis of overwintering physiology in nine species of semi‐aquatic bugs (Heteroptera: Gerromorpha)

In semi‐aquatic bugs (Heteroptera: Gerromorpha), the strategies of overwintering in a cryothermic state (i.e. at body temperatures below the equilibrium freezing point) remain largely unexplored. The present study provides an analysis of the ecophysiological aspects of overwintering in nine gerromorphan species. All nine species avoid ice formation by means of a more or less extensive supercooling of their body fluids. There is a tight correlation between the supercooling point (SCP) and the lower lethal temperature. Different species use different physiological adjustments to increase the likelihood of survival in a supercooled state. These include stabilization of the supercooled state by active antifreeze factors that cause thermal hysteresis between equilibrium melting and freezing points, the accumulation of low‐molecular weight sugars and polyols with putative cryoprotective functions, or by having a relatively high body fluid osmolality, combined with a low level of hydration. The majority of species under study overwinter only as adults, whereas Velia caprai Tamanini can overwinter either as an adult or in the egg stage. The supercooling capacity of V. caprai adults is insufficient to prevent the risk of lethal freezing. The adults therefore survive only opportunistically in suitable microhabitats, and/or during mild winters. The survival of V. caprai in winter is assured by extensive supercooling and having overwintering eggs that are highly cold tolerant.     

The supercooling ability of ticks (Acari,Ixodoidea)

 The supercooling capacity of nine laboratory- held species of ticks originating from different geographical areas, as well as five field-collected species from Germany, was investigated. All but one tick species showed mean supercooling points between about −17 and −23 °C, suggesting that the capacity to supercool to temperatures of ≤−17 °C might be an inherent property of many tick species unrelated to their geographic origin. Photoperiod did not influence the mean supercooling point in any of the species and there was also no distinct seasonal pattern of supercooling in seasonally acclimatized Dermacentor marginatus. Thus, the supercooling ability was independent of the presence/absence of diapause. The finding of thermal hysteresis in D. marginatus hemolymph raises the question of whether or not anti-freeze proteins are involved in the supercooling capacity of that species. An interspecies comparison revealed a weak negative correlation between relative water content and supercooling point of the ticks and an even weaker correlation between body mass or body water mass and the supercooling point. Since the ticks exhibited low supercooling points both before and shortly after feeding, the blood used as food should lack potent ice nucleators. Accepted: 14 June 1996     

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.     

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.     

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.     

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.     

Cold hardiness of Lymantria monacha and L. dispar (Lepidoptera: Erebidae) eggs to extreme winter temperatures: implications for predicting climate change impacts

1. It has been predicted that temperature increases of 3.6–5.8 °C would shift the northern distribution limit of Lymantria monacha (Linnaeus) and Lymantria dispar (Linnaeus) by 500–700 km, but these predictions ignore the effects of minimum winter temperatures. It was hypothesised that winter cold can limit range expansion due to high egg mortality in cold temperatures. 2. The present study determined the supercooling points of overwintering eggs of these forest pests, and compared these with recent minimum winter temperatures in the areas of origin of three populations. Eggs from one L. monacha and one L. dispar population from the species' core distribution area in Germany were included, as well as L. monacha eggs from Finland, near the northern border of the species' distribution. 3. The median supercooling points of both species were more than 10 °C lower than the median minimum winter temperatures of their areas of origin, and the median supercooling points of Finnish and German L. monacha eggs did not differ significantly. The median supercooling point of German L. monacha eggs differed from that of German L. dispar eggs. 4. Previous literature on the topic is referenced, and translations of the old German and Russian sources are given. Based on these results, it is argued that the frequent claim that L. monacha eggs can survive cold down to ?40 °C is unsupported, with a value near ?30 °C being a more likely limit. 5. Winter cold alone can limit the predicted range shifts of these species to 200–300 km under 3.6–5.8 °C increase scenarios, which is less than half the value of earlier estimates.     

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 role of macromolecular antifreeze in the darkling beetle,Meracantha contracta

Summary Macromolecular antifreeze solutes are present in the hemolymph of the overwintering larvae of the darkling beetle,Meracantha contracta. These antifreeze solutes produce a thermal hysteresis in the hemolymph of overwinteringMeracantha larvae whereby the freezing point of the hemolymph may be 3–4 °C below the melting point. This thermal hysteresis is very similar to that produced by proteinaceous and glycoproteinaceous antifreezes which are used by many cold water, marine teleost fishes to prevent freezing. One function of the macromolecular antifreeze inMeracantha may be to hinder inoculative freezing which might otherwise occur because of the dampness of the hibernaculae. A probably more important function is to depress the supercooling point of the frost susceptibleMeracantha larvae, thereby preventing lethal ice formation in the larvae's body fluids down to temperatures of approximately –11 °C.     

Divergent mechanisms of frost-hardiness in two populations of the gall fly, Eurosta solidaginsis

Two populations of the gall fly Eurosta solidaginsis utilize different strategies to endure seasonal exposure to temperatures below freezing. Both populations are freezing tolerant. In north temperate populations, supercooling points rise from ?10.2°C to ?6.2°C following exposures to temperatures below freezing. This level is maintained throughout winter and ensures frequent and prolonged periods of tissue freezing. South temperate populations depress the supercooling point to ?14.2°C during autumn and early winter, and this depression precludes extracellular ice formation during periods of supra-optimal temperature fluctuations. During mid-winter, supercooling points rise to the same level as in northern groups.Both populations accumulate three principal cryoprotective agents following first frost exposures (glycerol, sorbitol and trehalose). Cryoprotectants levels do not peak in northern populations until 4–6 weeks after first frost. In southern populations the accumulation profile is characterized by a high initial rate of synthesis, a protective overshoot and pronounced seasonal fluctuations. The relative survival advantages of each strategy are discussed.     

Freezing avoidance of the Antarctic icefishes (Channichthyidae) across thermal gradients in the Southern Ocean

Biogeographic studies separate the Antarctic Notothenioid fish fauna into high- and low-latitude species. Past studies indicate that some species found in the high-latitude freezing waters of the High-Antarctic Zone have low-serum hysteresis freezing points, while other species restricted to the low-latitude seasonal pack ice zone have higher serum hysteresis freezing points above the freezing point of seawater (−1.9°C), but the relationship has not been systematically investigated. Freeze avoidance was quantified in 11 species of Antarctic icefishes by determining the hysteresis freezing points of their blood serum, in addition, the freezing point depression from serum osmolytes, the antifreeze activity from serum antifreeze glycoproteins (AFGPs), and the antifreeze activity from serum antifreeze potentiating protein were measured for each species. Serum hysteresis freezing point, a proxy for organismal freeze avoidance, decreased as species were distributed at increasing latitude (linear regression r ² 0.66, slope −0.046°C °latitude⁻¹), which appeared largely independent of phylogenetic influences. Greater freeze avoidance at high latitudes was largely a result of higher levels of antifreeze activity from serum AFGPs relative to those in species inhabiting the low-latitude waters. The icefish fauna could be separated into a circum High-Antarctic Group of eight species that maintained serum hysteresis freezing points below −1.9°C even when sampled from less severe habitats. The remaining three species with low-latitude ranges restricted to the waters of the northern part of the west Antarctic Peninsula and Scotia Arc Islands had serum hysteresis freezing points at or above −1.9°C due to significantly lower combined activity from all of their serum antifreeze proteins than found in the High-Antarctic Zone icefish.     

Multiple stress tolerance in an antarctic terrestrial arthropod: Belgica antarctica

Terrestrial arthropods of the maritime Antarctic experience a diverse range of environmental Stressors including extended periods of ice and snow cover, anoxia, immersion in water of variable pH and salinity, and extensive habitat drying. The collembolan Cryptopygus antarcticus and the mite Alaskozetes antarcticus seasonally depress whole body supercooling points to avoid the lethal effects of freezing. Alternatively, the wingless chironomid Belgica antarctica has a relatively limited supercooling capacity (between −6 and −8 °C) and tolerates extracellular freezing. The lower limit of freeze tolerance remains unchanged near −13 °C throughout the year in B. antarctica. Summer larvae tolerate dehydration to a limit of 35% of initial body weight as well as extended periods of anoxia and immersion in freshwater and saltwater. Two weeks of exposure to variable pH (3–12) induced no mortality.     

Cold tolerance of a New Zealand alpine cockroach, Celatoblatta quinquemaculata (Dictyoptera, Blattidae)

Abstract. Ecophysiological features, including survival and recovery from freezing and determination of the freezable water content, are reported for a cold-adapted cockroach Celatoblatta quinquemaculata Johns 1966 (Dictyoptera, Blattidae) inhabiting alpine communities at altitudes greater than 1300 m a.s.l. in mountains of Central Otago, New Zealand. Nymphs ranged from 15 to 51 mg live weight of which 67% was water. Cockroaches had a mean supercooling point temperature of ?5.4 ± 0.1°C; with recovery from freezing close to this temperature being rapid, but no recovery was observed when frozen at ?9 to ?10°C. The duration of exposure to freezing conditions and the time allowed for recovery (24–96 h) both influenced individual recovery and subsequent survival. Comparison of supercooling point data and survival shows that this species possesses a few degrees of freeze tolerance, and individuals have been found frozen in the field when subzero temperatures occur. Differential scanning calorimetry showed ≈ 74% of body water froze during cooling and between 24 and 27% of total body water was osmotically inactive (unfreezable under the experimental conditions). Carbohydrates, other than glucose at 7.5μg/mg fresh weight, were in low concentrations in the body fluids, suggesting little cryoprotection. No thermal hysteresis from antifreeze protein activity was detected in haemolymph samples using calorimetric techniques. It is suggested that slow environmental cooling rates, together with high individual supercooling points, confer a small amount of freezing tolerance on this species enabling it to survive low winter temperatures. This has allowed it to colonize and maintain populations in alpine habitats > 1300 m a.s.1. in New Zealand.     

Cryopreservation of primary cultures of mammalian somatic cells in 96-well plates benefits from control of ice nucleation

Cryopreservation of mammalian cells has to date typically been conducted in cryovials, but there are applications where cryopreservation of primary cells in multiwell plates would be advantageous. However excessive supercooling in the small volumes of liquid in each well of the multiwell plates is inevitable without intervention and tends to result in high and variable cell mortality. Here, we describe a technique for cryopreservation of adhered primary bovine granulosa cells in 96-well plates by controlled rate freezing using controlled ice nucleation. Inducing ice nucleation at warm supercooled temperatures (less than 5 °C below the melting point) during cryopreservation using a manual seeding technique significantly improved post-thaw recovery from 29.6% (SD = 8.3%) where nucleation was left uncontrolled to 57.7% (9.3%) when averaged over 8 replicate cultures (p < 0.001). Detachment of thawed cells was qualitatively observed to be more prevalent in wells which did not have ice nucleation control which suggests cryopreserved cell monolayer detachment may be a consequence of deep supercooling. Using an infra-red thermography technique we showed that many aliquots of cryoprotectant solution in 96-well plates can supercool to temperatures below −20 °C when nucleation is not controlled, and also that the freezing temperatures observed are highly variable despite stringent attempts to remove contaminants acting as nucleation sites. We conclude that successful cryopreservation of cells in 96-well plates, or any small volume format, requires control of ice nucleation.     

Cold-hardiness and development of eggs of Rhopalosiphum insertum

Abstract. 1. The eggs of Rhopalosiphum insertum (Walker) showed a seasonal increase in cold-hardiness under field conditions. Their supercooling point fell from -35°C in November to below -40°C in January, then rose to-35°C or above by March.
2. Laboratory experiments demonstrated that both temperature and date affected cold-hardiness of the eggs. The supercooling points of eggs kept at 16 h photoperiod or in darkness did not, however, differ significantly.
3. Eggs brought from the field into warm, long-day conditions would not hatch until after mid-January. After this date, per cent hatch was significantly greater in 16 h photoperiod than in darkness; it did not differ between eggs kept at 5 or 0°C, but was reduced at -5°C.
4. It is concluded that eggs of Rinserturn are in diapause until mid-January, and that hatching rate and cold-hardiness are determined by separate environmental factors.     

Control of diapause and supercooling by the retrocerebral complex inPyrrhocoris apterus

Effects of external (photoperiod, temperature) and internal (retrocerebral complex, diapause condition) factors on supercooling were studied inPyrrhocoris apterus (L.) (Heteroptera: Pyrrhocoridae) adults. An increase in supercooling capacity is associated with the induction of diapause by short-day photoperiod or cardiacallatectomy of long-day non-diapause insects in spite of a high temperature of 26°C. The induction of diapause is a prerequisite for a further increase in supercooling capacity by cold acclimation. Post-diapause adults show low values of the supercooling point also in late January or early February, although their developmental potential is fully restored. Evidently the ability to supercool associated with diapause induction is maintained by a low ambient temperature in spite of diapause termination. The supercooling point increases rapidly when these adults are transferred to a high temperature of 26°C and cold re-acclimation is then no longer possible. The inhibition of morphogenesis (maturation of gonads) by cardiacallatectomy does not prevent the supercooling point from increasing in post-diapause adults at the high temperature.