Multiple component system of sugars and polyols in the overwintering spruce bark beetle, Ips typographus

Overwintering adults of the spruce bark beetle, Ips typographus (L.) showed an unusually complex sugar/polyol cryoprotectant system. The major components of the multiple system were: glucose (177.6 mmolL(-1), March); trehalose (175.0 mmolL(-1), December); sorbitol (147.9 mmolL(-1), January); mannitol (81.2 mmolL(-1), March); and erythritol (40.7mmolL(-1), March) (in the parentheses, the maximum concentrations are shown and the month when they were reached). Other minor components were glycerol, fructose, threitol, myo-inositol, arabinitol and ribitol. Distinct seasonal patterns of accumulation/depletion in various components were found. Glycerol, trehalose and glucose started to accumulate first, during early autumn, when the air temperatures fluctuated between 20 and 0 degrees C, and diapause beetles continued in feeding. Glycerol was depleted, glucose remained stable and trehalose continued in accumulation during late autumn when the temperatures oscillated around 0 degrees C. During early winter severe frosts reaching -20 degrees C came, the beetles terminated their diapause and trehalose was partially depleted, while mannitol, sorbitol, fructose, threitol and erythritol started to accumulate. Cold weather continued also during late winter when the beetles remained quiescent. During this period, trehalose was re-accumulated, threitol and erythritol continued to increase, mannitol remained stable and sorbitol, fructose decreased. All cryoprotectans were finally cleared in the beetles which were spontaneously leaving bark during early spring. The seasonal maximum of total concentration of all cryoprotectants (578.2 mOsmol L(-1)) was reached in March. Such a concentration results in colligative depression of melting point of body fluids down by 1.08 degrees C only. It suggests that the potential cryoprotective effect of accumulated sugars and polyols was related rather to their non-colligative functions.     

Optimal temperature ranges for control of cooling rate.

Survival of hamster fibroblasts following cooling at 1 °C/min to various subzero temperatures in the presence of penetrating or nonpenetrating cryoprotective agents was examined. In the presence of nonpenetrating agents maximum recovery was obtained when the cooling rate was controlled between ?5 and ?20 °C followed by rapid cooling to ?196 °C. For penetrating agents recovery was maximal in samples cooled at 1 °C/min to ?30 °C or lower. These different temperature ranges for maximum recovery indicate different modes of actions of penetrating and nonpenetrating cryoprotective agents. The action of penetrating agents appear to be based on their colligative properties. Nonpenetrating agents may promote electrolyte leaks out of the cell and a corresponding osmotic efflux of cell water during slow cooling, thereby reducing the amount of intracellular ice present at ?196 °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.     

An evaluation of cryoprotective compounds on bovine spermatozoa

The potentially cryoprotective properties of 72 higher-molecular-weight polymeric additives and 69 low-molecular-weight compounds were evaluated. The polymeric compound selection was based on solubility in semen extender, toxicity and finally, on the cryoprotective effect on bull spermatozoa as measured by progressive motility. Five compounds showed cryoprotection to the cell, but with no significant improvement over that of TESNaK yolk, TEST yolk, or TEST yolk glycerol extenders used as controls. Low-molecular-weight compounds were selected on the basis of colligative properties particularly that of freezing-point depression. Elimination was based on precipitation of proteins in the extender, toxicity, and cryoprotection to bovine spermatozoa as measured by progressive motility. Nineteen compounds that yielded protection during cryopreservation of bovine spermatozoa were compared using post-thaw motility and membrane integrity using glutamic-oxaloacetic transaminase enzyme retained in the spermatozoa after freezing as an indicator. Semen was diluted with extender containing selected compounds at 35 or 5 °C to determine the effect of temperature at which the cryoprotective compound was added. Glycerol yielded the highest recovery. Diethylene glycol, dimethylsulfoxide, N-methylacetamide, and triethylene glycol appeared not to be different in freezing bovine spermatozoa. The temperature or method of addition of cryoprotective compound did not reveal a significant difference.     

Differing actions of penetrating and nonpenetrating cryoprotective agents.

A two-step freezing technique has been used to examine the role of cryoprotective agents during cooling. Chinese hamster fibroblasts were cooled to various subzero holding temperatures and subsequently thawed or cooled to ?196 °C before thawing. Cells were suspended in various concentrations of dimethylsulfoxide (DMSO) or hydroxyethyl starch (HES) before freezing. The results indicated differing protective actions of DMSO and HES. These differences were verified using glycerol as either a penetrating or a nonpenetrating agent.The results are consistent with the concepts that cryoprotection is based on the avoidance or minimization of intracellular freezing and the minimization of damage to the cell from the environment of concentrated solutes during cooling, and that the colligative action of both penetrating and nonpenetrating agents allows the cells to survive the conditions for a reduction of cell water content during cooling thereby reducing the amount of intracellular freezing. The results indicate that penetrating and nonpenetrating agents accomplish this in different ways. Penetrating agents create the environment for a reduction of cell water content at temperatures sufficiently low to reduce the damaging effect of the concentrated solutes on the cells. Nonpenetrating agents osmotically “squeeze” water from the cells primarily during the initial phases of freezing at temperatures between ?10 and ?20 °C when these additives become concentrated in the extracellular regions.     

Supercooling ability and cold hardiness of the pollen beetle Meligethes aeneus

Supercooling point (SCP) and cold‐hardiness of the pollen beetle Meligethes aeneus (Fabricius) (Coleoptera: Nitidulidae) were investigated. Mature eggs from the oviduct were supercooled on average to ?28.0 °C and from oilseed rape buds to ?24.4 °C; first instars were supercooled to ?21.0 °C and second instars to ?16.8 °C. Despite their high supercooling ability, none of the eggs survived 24 h exposure to ?2.5 °C. The supercooling ability of adults varied significantly among feeding and non‐feeding beetles: high SCPs prevailed during the whole warm period, being about ?12 °C; low values of SCP of ?20 °C dominated in non‐feeding beetles. In spring and autumn, beetles displayed the same acclimation efficiency: after 1 week of exposure at 2.0 °C with no access to food their SCPs were depressed equally by about 3 °C. Meligethes aeneus beetles have a different response to low temperatures depending on the season. The lowest tolerance was found in reproductively active beetles after emergence from overwintering sites; the time needed to kill 50% of individuals (Ltime₅₀) was 56.2 h at ?7 °C and the lower lethal temperature needed to kill 50% (Ltemp₅₀) after 24 h exposure was ?8.6 °C. Cold hardiness increased from midsummer to midwinter; Ltime₅₀ was 80 h in August, 182.8 h in September, and 418.1 h in January. Lethal temperature after 24 h exposure was ?9.1 °C in August and ?9.8 °C in September. In February, after diapause, the beetles started to loose their cold tolerance, and Ltemp₅₀ was slightly increased to ?9.5 °C. Hibernating beetles tolerated long exposure at ?7 °C well, but mortality was high after short exposure if the temperature dropped below ?9 °C for 24 h. Despite the season, the beetles died at temperatures well above their mean SCP; consequently, SCP is not a suitable index for cold hardiness of M. aeneus.     

Cryopreservation of spinach chloroplast membranes by low-molecular-weight carbohydrates: II. Discrimination between colligative and noncolligative protection

Thylakoid membranes isolated from spinach leaves (Spinacia oleracea L. cv. Monatol) were subjected to a freeze-thaw cycle in the presence of various concentrations of sugars, polyhydric alcohols, and NaCl. Functional integrity of the membranes was assayed by means of cyclic photophosphorylation. From the nonideal activity—concentration profiles of the carbohydrates the effective NaCl concentrations in the surroundings of the membranes at the respective freezing temperatures were calculated.Comparison of the cryoprotective efficiency of the various polyols revealed that cryopreservation by low-molecular-weight compounds is predominantly due to colligative action of the solutes. In addition, specific effects of carbohydrates which cannot be explained by the colligative concept are involved in cryoprotection. At NaCl concentrations exceeding 15 mm, the relative contribution of noncolligative membrane protection of a given polyol to overall cryopreservation was independent of the salt concentration. However, during freezing in the presence of very low salt concentrations, for instance 1–4 mm NaCl, cryoprotection due to colligative phenomena is reduced in favor of other mechanisms.     

Exposure to subfreezing temperature and a freeze-thaw cycle affect freezing tolerance of winter wheat in saturated soil

Winter wheat is sown in the autumn and harvested the following summer, necessitating the ability to survive subfreezing temperatures for several months. Autumn months in wheat-growing regions typically experience significant rainfall and several days or weeks of mild subfreezing temperatures at night, followed by above-freezing temperatures in the day. Hence, the wheat plants usually are first exposed to potentially damaging subfreezing temperatures when they have high moisture content, are growing in very wet soil, and have been exposed to freeze-thaw cycles for a period of time. These conditions are conducive to freezing stresses and plant responses that are different from those that occur under lower moisture conditions without freeze-thaw cycles. This study was conducted to investigate the impact of mild subfreezing temperature and a freeze-thaw cycle on the ability of 22 winter wheat cultivars to tolerate freezing in saturated soil. Seedlings that had been acclimated at +4°C for 5 weeks in saturated soil were frozen to potentially damaging temperatures under three treatment conditions: (1) without any subzero pre-freezing treatment; (2) with a 16-h period at ?3°C prior to freezing to potentially damaging temperatures; and (3) with a freeze-thaw cycle of ?3°C for 24 h followed by +4°C for 24 h, followed by a 16-h period at ?3°C prior to freezing to potentially damaging temperatures. In general, plants that had been exposed to the freeze-thaw cycle survived significantly more frequently than plants frozen under the other two treatments. Plants that had been exposed to 16 h at ?3° (without the freeze-thaw cycle) before freezing to potentially damaging temperatures survived significantly more frequently than plants that were frozen to potentially damaging temperatures without a subzero pre-freezing treatment. These results indicated that cold-acclimated wheat plants actively acclimate to freezing stress while exposed to mild subfreezing temperatures, and further acclimate when allowed to thaw at +4°C for 24 h. The cultivar Norstar had the lowest LT₅₀ (temperature predicted to be lethal to 50% of the plants) of the 22 cultivars when frozen with either of the subzero pre-freezing treatments, but several cultivars had lower LT₅₀ scores than Norstar when frozen without a subzero pre-freezing treatment. We conclude it may be possible to improve winterhardiness of wheat grown in saturated soil by combining the ability to effectively respond to mild subzero pre-freezing temperatures with a greater ability to withstand freezing to damaging temperatures without a subzero pre-freezing exposure.     

Experimental studies on the cold tolerance of Alaskozetes antarcticus

The cold tolerance mechanism of the Antarctic terrestrial mite Alaskozetes antarcticus (Michael) was investigated in cultured animals. Freezing is fatal in this species and winter survival occurs by means of supercooling, which is enhanced by the presence of glycerol in the body. There is an inverse, linear relationship between the concentration of glycerol and the supercooling point, which may be as low as ?30°C. Feeding detracts from supercooling ability by providing ice nucleators in the gut which initiate freezing at relatively high sub-zero temperatures. Experiments on the effects of various environmental factors showed that low temperature acclimation gave rise to increased glycerol concentrations and suppressed feeding, while desiccation also stimulated glycerol production. Photoperiod had no effect on cold tolerance in this species. The juvenile instars of A. antarcticus were found to possess a greater degree of low temperature tolerance than adults.     

Seasonal changes in cold hardiness of Ophraella communa

Insects can prepare themselves to tolerate subzero temperatures through various physiological changes, such as the alteration in body water or glycerol content. Indeed, it has been hypothesized that increasing glycerol body content has the benefit of decreasing the temperature necessary to freeze their body water and therefore increasing the supercooling point (SCP) and the cold hardiness. We here studied physiological plasticity in cold tolerance in Ophraella communa LeSage (Coleoptera: Chrysomelidae), a potential biological control agent of an invasive plant, the common ragweed, Ambrosia artemisiifolia L. (Asteraceae). Pupae of O. communa were collected from June to October, and the water and glycerol contents and the SCP of emerging adults were assessed. We found that SCP, water, and glycerol contents of beetles fluctuated significantly with season. Glycerol content of males and females increased with decreasing temperature between July and October, and glycerol content reached a maximum in October in the field. The lowest SCP was observed in adults in October prior to overwintering, and the highest SCP was evident in the summer population in July. Thus, cold hardiness of the beetles in the autumn population was significantly higher than in the summer population. We therefore conclude that cold tolerance, via changes in the relative composition of their body fluids and fats, is a plastic trait that can be influenced by fluctuations in abiotic factors (e.g., temperature) throughout the breeding season of the insect.     

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.     

Microwave properties of cryoprotectants

The values of the dielectric constant and of the loss tangent for pure samples of DMSO, ethylene glycol, and glycerol were determined over the temperature range of + 15 to −70 °C. An operating frequency range of 1.45 to 1.55 GHz was used, allowing direct application of the results of both 0.915 and 2.450 GHz studies. Strong temperature dependencies were found, with peaks and irregularities occuring at subfreezing temperatures. In order to design a suitable cryoprotective system for the long term preservation of whole organs, the effect of cryoprotectant concentration on microwave properties must be known.     

Extra- and intra-cellular ice formation in Stage I and II Xenopus laevis oocytes

We are currently investigating factors that influence intracellular ice formation (IIF) in mouse oocytes and oocytes of the frog Xenopus. A major reason for choosing these two species is that while their eggs normally do not possess aquaporin channels in their plasma membranes, these channels can be made to express. We wish to see whether IIF is affected by the presence of these channels. The present Xenopus study deals with control eggs not expressing aquaporins. The main factor studied has been the effect of a cryoprotective agent [ethylene glycol (EG) or glycerol] and its concentration. The general procedure was to (a) cool the oocytes on a cryostage to slightly below the temperatures at which extracellular ice formation occurs, (b) warm them to just below the melting point, and (c) then re-cool them to -50 degrees C at 10 degrees C/min. In the majority of cases, IIF occurs well into step (c), but a sizeable minority undergo IIF in steps (a) or (b). The former group we refer to as low-temperature flashers; the latter as high-temperature flashers. IIF is manifested as abrupt blackening of the egg, which we refer to as "flashing." Observations on the Linkam cryostage are restricted to Stage I and II oocytes, which have diameters of 200 300 microm. In the absence of a cryoprotective agent, that is in frog Ringers, the mean flash temperature for the low-temperature freezers is -11.4 degrees C, although a sizeable percentage flash at temperatures much closer to that of the EIF (-3.9 degrees C). When EG is present, the flash temperature for the low-temperatures freezers drops significantly to approximately -20 degrees C for EG concentrations ranging from 0.5 to 1.5 M. The presence of 1.5 M glycerol also substantially reduces the IIF temperature of the low-temperature freezers; namely, to -29 degrees C, but 0.5 and 1 M glycerol exert little or no effect. The IIF temperatures observed using the Linkam cryostage agree well with those estimated by calorimetry [F.W. Kleinhans, J.F. Guenther, D.M. Roberts, P. Mazur, Analysis of intracellular ice nucleation in Xenopus oocytes by differential scanning calorimetry, Cryobiology 52 (2006) 128-138]. The IIF temperatures in Xenopus are substantially higher than those observed in mouse oocytes [P. Mazur, S. Seki, I.L. Pinn, F.W. Kleinhans, K. Edashige, Extra- and intracellular ice formation in mouse oocytes, Cryobiology 51 (2005) 29-53]. Perhaps that is a reflection of their much larger size.     

Infective Juveniles of the Entomopathogenic Nematode,Steinernema feltiae Produce Cryoprotectants in Response to Freezing and Cold Acclimation

Steinernema feltiae is a moderately freeze-tolerant entomopathogenic nematode which survives intracellular freezing. We have detected by gas chromatography that infective juveniles of S. feltiae produce cryoprotectants in response to cold acclimation and to freezing. Since the survival of this nematode varies with temperature, we analyzed their cryoprotectant profiles under different acclimation and freezing regimes. The principal cryoprotectants detected were trehalose and glycerol with glucose being the minor component. The amount of cryoprotectants varied with the temperature and duration of exposure. Trehalose was accumulated in higher concentrations when nematodes were acclimated at 5°C for two weeks whereas glycerol level decreased from that of the non-acclimated controls. Nematodes were seeded with a small ice crystal and held at -1°C, a regime that does not produce freezing of the nematodes but their bodies lose water to the surrounding ice (cryoprotective dehydration). This increased the levels of both trehalose and glycerol, with glycerol reaching a higher concentration than trehalose. Nematodes frozen at -3°C, a regime that produces freezing of the nematodes and results in intracellular ice formation, had elevated glycerol levels while trehalose levels did not change. Steinernema feltiae thus has two strategies of cryoprotectant accumulation: one is an acclimation response to low temperature when the body fluids are in a cooled or supercooled state and the infective juveniles produce trehalose before freezing. During this process a portion of the glycerol is converted to trehalose. The second strategy is a rapid response to freezing which induces the production of glycerol but trehalose levels do not change. These low molecular weight compounds are surmised to act as cryoprotectants for this species and to play an important role in its freezing tolerance.     

Effects of cryoprotective agents and freezing on abdominal ganglia of aplysia.

Isolated Aplysia depilans abdominal ganglia were exposed to 10 and 20% dimethylsulphoxide (Me₂SO) or glycerol at room temperature. Results indicate that Me₂SO induced an irreversible depression of extracellularly recorded ganglionic spontaneous spike generation while glycerol proved to be non-toxic. Intracellular recordings of individual nerve cell spontaneous activity during exposure to the cryoprotective agents were obtained in a few preliminary experiments. Both Me₂SO and glycerol induced a decrement in the nerve cell membrane potential. The main difference between the action of the two cryoprotectants was in the rate and the amount of depolarization, both being higher in the case of Me₂SO exposure.The Aplysia abdominal ganglia were frozen to ?20 °C and to ?196 °C. In all but one ganglia frozen to ?20 °C, including the preparations frozen in the absence of any cryoprotective agent, functional recovery was obtained after thawing. However, only the application of 20% glycerol improved the recovery of the preparations to a significant extent. In ganglia protected with 20% glycerol a full recovery of the action potential amplitude and frequency was obtained. In ganglia protected with 20% glycerol intracellular recordings of individual nerve cells demonstrated spontaneous spike activities before freezing and after thawing.No functional recovery was observed in ganglia frozen to ?196 °C in the absence of a cryoprotective agent. While in most preparations frozen with a cryoprotectant spontaneously generated spikes were recorded after thawing. However, the action potential frequency and amplitude were significantly depressed. It is concluded that further investigation is required to improve the freezing technique so that Aplysia ganglia may be preserved at low temperatures. It is suggested that intracellular exploration of the effects of cryoprotectants and freezing on identified nerve cell membrane may prove to be useful in future investigations.     

Peculiarities of state diagrams of aqueous solutions of cryoprotective agents

The phase transitions in aqueous solutions of glycerol and PEO-1500 within the temperature range of +30 to −150 °C have been studied using the methods of thermoplastic analysis and volumetric scanning tensodilatometry. We present the revealed phenomenon of cluster cyrystallization of these solutions as well as principles of describing this phenomenon using state diagrams, containing the intervals of concentration corresponding to the existence of amorphous and cryocolloid fractions. We note that for the cryocolloid fraction, a low temperature association of molecules of cryoprotective agents leads the formation of ice nanocrystals either close to or directly inside the aggregations. These fractions exist in cooled cryoprotective solutions near the vitrification temperatures of the liquid phase and may contribute to the initiation of damaging events in cryopreserved biological systems. Our data may be helpful in explaining the peculiarities observed during crystallization of cryoprotective solutions and may further contribute to a broader understanding of the principles of protection and protocol optimization of biological materials at temperatures approaching vitrification.     

Cryopreservation of Sheep Red Blood Cells

The protection of sheep erythrocytes at freezing temperatures was investigated using glycerol, dimethylsulfoxide (DMSO), glucose and four different types of polyvinylpyrrolidone (PVP) as cryoprotective agents. Depending on type (molecular weight) and concentration good protection was obtained with PVP, whereas glycerol, DMSO and glucose were unsatisfactory. Recovery of cells after thawing was most successful when the cells had been frozen at a concentration of 1–2 × 109 cells/ml. No cells tolerated freezing at −20 °G. Best results were obtained when the cells were frozen directly in liquid nitrogen (−196°G).     

Physical and chemical changes associated with seasonal alterations in freezing tolerance in the adult northern tenebrionid, Upis ceramboides

The adult tenebrionid beetle Upis ceramboides overwinters in the northern taiga forests of North America in a hibernaculum typically just beneath loose tree bark above the snowline. The beetles may be exposed to temperatures as low as ?55°C, which is approximately the lower limit of cold tolerance found in specimens collected in mid-winter. Supercooling points average ?6.3°C throughout the year and, contrary to expectation, show no seasonal variation in spite of major alterations in haemolymph composition and freezing tolerance. Summer beetles are incapable of withstanding temperatures below the supercooling point but freezing tolerance increases during the fall (September–November) and the lower lethal temperature (LLT) is maintained at ca. ?55°C until March, after which it gradually rises to the summer level of ?6°C. Changes in freezing tolerance are closely associated with seasonal alterations in the polyhydric alcohols sorbitol and threitol. Neither polyol is present in measureable amount during summer; sorbitol accumulates to an average haemolymph concentration of 0.44 M/l in winter and threitol reaches 0.25 M/l. Summer beetles contain about 14% more water than beetles collected during the other seasons. Upis ceramboides thus undergoes unique seasonal changes in physical and chemical characteristics that enable it to tolerate severe, prolonged subfreezing temperatures.     

The effect of the cryoprotectants,dimethylsulfoxide and glycerol on water transport in the human red blood cell

The response of human red blood cells to the cryoprotective agents, DMSO and glycerol, has been investigated using a pulsed NMR method. The experimentally determined parameters are: (1) the intracellular transverse relaxation time, T_2a; (2) the mean residence time of intracellular water, τ_a, which is effectively a reciprocal measure of the rate of water transport across the red blood cell membrane; and (3) the activation energy for this process. The quantitative data indicate that the observed effects are colligative rather than species-specific in origin.     

Topical Application of Ice-Nucleating-Active Bacteria Decreases Insect Cold Tolerance

The majority of overwintering insects avoid lethal freezing by lowering the temperature at which ice spontaneously nucleates within their body fluids. We examined the effect of ice-nucleating-active bacteria on the cold-hardiness of the lady beetle, Hippodamia convergens, a freeze-intolerant species that overwinters by supercooling to ca. −16°C. Topical application of the ice-nucleating-active bacteria Pseudomonas syringae increased the supercooling point to temperatures as high as −3°C. This decrease in cold tolerance was maintained for at least 3 days after treatment. Various treatment doses (10⁸, 10⁶, and 10⁴ bacteria per ml) and modes of action (bacterial ingestion and topical application) were also compared. At the highest concentration of topically applied P. syringae, 50% of the beetles froze between −2 and −4°C. After topical application at the lowest concentration, 50% of the individuals froze by −11°C. In contrast, beetles fed bacteria at this concentration did not begin to freeze until −10°C, and 50% were frozen only at temperatures of −13°C or less. In addition to reducing the supercooling capacity in H. convergens, ice-nucleating-active bacteria also significantly reduced the cold-hardiness of four additional insects. These data demonstrate that ice-nucleating-active bacteria can be used to elevate the supercooling point and thereby decrease insect cold tolerance. The results of this study support the proposition that ice-nucleating-active bacteria may be used as a biological insecticide for the control of insect pests during the winter.