Hatchling painted turtles (Chrysemys picta) survive exposure to subzero temperatures during hibernation by avoiding freezing

Hatchling painted turtles (Chrysemys picta) were placed individually into artificial nests constructed in jars of damp soil and then were cooled slowly to temperatures between-7.7 and-12.7 °C. Distinct exotherms were recorded in all jars when water in the soil began to freeze at temperatures between-0.9 and-2.4 °C. A second (animal) exotherm was subsequently detected in some of the jars when water in hatchlings also began to freeze. An animal exotherm occurred in the temperature records for all 23 hatchlings that died in tests terminating at temperatures between-7.7 and-10.8 °C, but no such exotherm was apparent in the temperature records for the 23 turtles that survived these treatments. Moreover, the 4 hatchlings that produced exotherms in tests terminating between-11.5 and-12.7 °C failed to survive, but 5 of 7 hatchlings that produced no exotherm in these tests also died. Thus, turtles that die at subzero temperatures above-11 °C apparently succumb to freezing when ice propagates across their integument from the frozen soil, but animals that die at temperatures below-11 °C generally perish from some other cause. These findings indicate that hatchling painted turtles overwintering inside their shallow, subterranean nests survive exposure to subzero temperatures by avoiding freezing instead of by tolerating freezing.     

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.     

Studies with dextran 40 in cryopreservation of blood

Whole blood from healthy donors was washed twice with phosphate-buffered saline (PBS) and then resuspended in sufficient PBS to give a final concentration of 2 × 10⁹/cells/ml. Aliquots were combined with equal volumes of the required diluents to give final dextran 40 concentrations of 0, 5, 10, 15, and 20% in PBS. Fifty-lambda samples in 50-lambda Micropets (Clay Adams) were frozen in alcohol baths at temperatures ranging from ?10 to ?80 °C. The specimens were frozen either for 1 min or 16 min, rapidly thawed, and resuspended in PBS or PBS plus dextran. Percentage of hemolysis was determined colorimetrically. Results indicate that concentraitons as low as 5% dextran exert a cryoprotective effect. Increased dextran concentration increases cryoprotection at high subzero bath temperatures (?10 ° and ?20 °C). Dextran concentrations beyond 12% have a damaging effect at low subzero bath temperatures (below ?30 °C). Based on this a two-factor hypothesis for cryopreservation is proposed. Apparent partial recovery of red blood cells without dextran or with 5% dextran during subzero storage was demonstrated.     

Mycelial growth of the snow mold fungus, Sclerotinia borealis, improved at low water potentials: an adaption to frozen environment

The snow mold fungus, Sclerotinia borealis, shows optimal growth at 4°C on potato dextrose agar (PDA) and can grow even at subzero temperature. Its mycelial growth was improved on frozen PDA at −1°C and on PDA containing potassium chloride (KCl) (water potential, −4.27 to −0.85 MPa) or d(−) sorbitol (−3.48 to −0.92 MPa). Its optimal growth temperature shifted from 4 to 10°C on PDA amended with KCl or sorbitol, indicating that inherent optimal growth occurs at high temperatures. These results suggest that S. borealis uses concentrated nutrients in the frozen environment and that such physiologic characteristics are critical for the fungus to prevail at subzero temperatures.     

The influence of temperature on the function of renal cortical slices frozen in various cryoprotectants

Renal cortical slices were frozen to various subzero temperatures after treatment with 2.1 M of one of three cryoprotectants, dimethyl sulfoxide (Me2SO), ethylene glycol, or glycerol. The effects on tissue [K+]/[Na+] of cooling to these temperatures were tested (using identical procedure times, cooling rates, and warming rates) by holding the slices at each experimental temperature for appropriate periods of time prior to rewarming. The effects of the holding time were assessed by comparison with slices which were cooled and rewarmed with no intermediate holding time. Slices treated with ethylene glycol or glycerol were found to exhibit a continuous decrease in [K+]/[Na+] with lowered temperatures, in contrast to those treated with Me2SO. Slices treated with Me2SO actually experienced a continuous increase in [K+]/[Na+] with lowered temperature (-12 to -33 degrees C). Me2SO does exhibit toxic effects at subzero temperatures. Adverse effects of holding time on viability are seen for Me2SO-treated slices at higher subzero temperatures. These effects were alleviated as the temperature is reduced, suggesting that temperature has a greater effect on survival of renal cortical tissue than Me2SO concentration. However, the toxicity observed at higher subzero temperatures is expected to be of importance, particularly for slowly cooled tissues which are exposed to these temperatures for relatively long periods of time.     

X-ray microanalytical (EDX) investigation of potassium distributions in mesophyll cells of non-acclimated and cold-acclimated rye leaves

Electron probe X-ray microanalysis was used to analyse the effects of sub-zero temperatures on K⁺ distribution in compartments within non-acclimated and cold acclimated rye (Secale cereale L. cv Voima) leaf cells and to evaluate membrane leakage of ions caused by freezing-injury. The specimens were rapidly frozen from growing temperatures and from two different sub-zero temperatures (LT₅₀ and LT₁₀₀) to which the leaves had already been slowly cooled. Measurements were made in the cytoplasm, vacuole and cell walls in freeze-substituted mesophyll cells. At ambient temperatures, the mean K⁺ concentration in the cytoplasm (100 mol m^?3) differed significantly from that of the vacuole (49 mol m^?3) in the non-acclimated (NA) cells, while in cold acclimated (A) cells, the concentrations were similar (109 vs 93 mol m^?3, respectively). At LT₅₀ temperatures, the K⁺ concentration in NA-cells decreased significantly in the cytoplasm (59 mol m^?3) but increased in the cell walls. In the A-cells, on the other hand, the mean K⁺ concentration increased significantly (about three-fold) in all major compartments. At LT₁₀₀ temperatures, K⁺ concentrations in the cytoplasm and cell walls decreased when compared with corresponding LT₅₀ values in the A-cells but increased in the NA-cells. The increased potassium concentration in the cytoplasm of A-cells at LT₅₀ temperature is compatible with the observed cell shrinkage and an absence of plasma membrane damage. The decreased potassium concentration in the cytoplasm of NA-cells at LT₅₀ temperature is compatible with the slight cell shrinkage and suggests that the plasma membrane in these cells shows increased permeability due to freeze injury.     

Postfreeze reduction of locomotor endurance in the freeze-tolerant wood frog,Rana sylvatica

Considerable study has focused on the physiological adaptations for freeze tolerance in the wood frog, Rana sylvatica, a northern species that overwinters within the frost zone, but little attention has been paid to the associated costs to organismal performance. Here we report that freezing causes transient impairment of locomotor endurance and adverse changes in exercise physiology that persist for at least 96 h. Wood frogs frozen at -2 degrees C for 36 h exhibited normal behaviors and hydro-osmotic status and near-normal metabolite (glycogen, glucose, and lactate) levels within 24 h after thawing began. However, when exercised to exhaustion on a treadmill, these frogs showed a 40% reduction in endurance as compared to sham-treated (unfrozen) controls, a reduction that persisted for at least 96 h. Previously frozen frogs exhibited higher rates of lactate accumulation during exercise than controls, suggesting that prior freezing forces greater reliance on the glycolytic pathways of energy production to support exercise. Given that this species breeds in late winter, when subzero temperatures are common, freezing may result in reduced fitness by hampering their ability to reach the pond, avoid predators, and successfully obtain mates.     

Injury to human granulocytes at low temperatures

Granulocytes differ from other blood cells in that they are more sensitive to injury on freezing and thawing. Previous studies suggest that the difficulty in preserving them is related to their sensitivity to osmotic stress. A miniaturized system both for freezing granulocytes and testing their function in the same Terasaki plates has been developed. This allowed study of several factors simultaneously including concentration of protective additive, different cooling conditions, and dilution conditions on rewarming.We observed two types of injury to granulocytes frozen to higher subzero temperatures and thawed directly. The first type was initially severe but decreased with time in the frozen state under some conditions and appears not to have been reported in other cell systems. The second type of injury consists of conventional loss of function with longer holding times after freezing. Cells surviving these two classes of injury could be protected against the further stress of rapid cooling into liquid nitrogen, but this protection required a longer time during cooling in the frozen state than with other cell types.We have studied the interactions between several variables, e.g., time in DMSO before freezing and dilution rate after thawing in an attempt to characterize the unusual injurious mechanism at high subzero temperatures that, we believe, is the real cause of the difficulty of preserving these cells.     

Freezing preservation of the mammalian cardiac explant. V. Cryoprotection by ethanol.

We studied the colligative cryoprotective effect of ethanol (EtOH) in preserving the isolated rat heart frozen at -3.4 degrees C or unfrozen at -1.4 degrees C. Addition of 4.7% (v/v) EtOH to a cardioplegic solution, CP-14, raised the osmolality from 280 to 1100 mOsm/kg H2O and lowered the melting point from -0.52 to -2.1 degrees C. Freezing of the cardiac explant at -3.4 degrees C for 6 h resulted in 34.3 +/- 1.9% of the tissue water as ice; recovery of cardiac output (CO) was 50%. Polyethylene glycol, which at 5% (w/v) has been shown to cryoprotect the hearts during freezing at -1.4 degrees C, did not improve the protective effect of 4.7% EtOH. CP-14 + 4.7% EtOH did not freeze at -1.4 degrees C. After 6 h storage, CO in hearts flushed with CP-14 + 4.7% EtOH oxygenated with 95% O2/5%CO2 returned to almost control level and was much higher than that in hearts flushed with 100% O2 saturated-CP-14 + 4.7% EtOH. Storage of 8 and 12 h reduced CO to 87 +/- 9 and 60 +/- 5% of control. By employing EtOH as a colligative cryoprotectant, we preserved the adult mammalian heart frozen at -3.4 degrees C or unfrozen at -1.4 degrees C, suggesting that this small molecular weight, penetrating substance may be a suitable cryoprotectant for long-term storage of the cardiac explant at high subzero temperatures.     

Freeze Concentration of Some Foodstuffs Using Ice Nucleation-active Bacterial Cells Entrapped in Calcium Alginate Gel

Cells of an ice nucleation-active strain of Ermnia ananas were entrapped in calcium alginate to prepare an ice-nucleating gel usable as ice nuclei for freeze concentration. The ice-nucleating gel was also adjusted as to specific gravity. When it was placed at a desired position in a liquid material such as egg white, ice formed at this position as the material was cooled. It was possible to put the ice- nucleating gel in liquid foodstuffs such as egg white and lemon juice before their temperatures reached subzero points. Application of this method produced freeze-concentrated foods whose properties were not significantly deteriorated.     

Structure and dynamics of primary hydration shell of phosphatidylcholine bilayers at subzero temperatures.

Deuterium NMR relaxation and intensity measurements of the 2H-labeled H2O/dimyristoyl phosphatidylcholine bilayer were performed to understand the molecular origin of the freezing event of phospholipid headgroup and the structure and dynamics of unfrozen water molecules in the interbilayer space at subzero temperatures. The results suggest that about one to two water molecules associated with the phosphate group freeze during the freezing event of phospholipid headgroups, whereas about five to six waters near the trimethylammonium group behave as a water cluster and remain unfrozen at temperatures as low as -70 degrees C. In addition, temperature-dependent T1 and T2 relaxation times suggest that dynamic coupling occurs not only between the phosphate group and its bound water, but also between the methyl group and the adjacent water molecules. Based on these observations, the primary hydration shell of phosphatidylcholine headgroup at subzero temperatures is suggested to consist of two distinct regions: a clathrate-like water cluster, most likely a water pentamer, near the hydrophobic methyl group, and hydration water molecules associated with the phosphate group.     

Freeze drying and freeze substitution combined with low temperature-embedding

Summary An X-ray microanalytical and morphological investigation was carried out on rapidly frozen freeze-dried or freeze-substituted tissues. A comparison was made between different embedding and polymerisation procedures following freeze substitution and freeze drying. The investigation also included an analysis of specimens which had been infiltrated, embedded and polymerised by ultraviolet irradiation at low temperatures with Lowicryl-HM20. The method of freeze drying, followed by embedding and polymerisation at low temperatures in vacuo was found to give satisfactory results, comparable with more tedious and hazardous freeze substitution technique.     

Freezing damage of bovine erythrocytes: Simulation using glycerol concentration changes at subzero temperatures

When a cell is frozen and thawed, it is exposed to (i) lowered temperature, (ii) increased solute concentration during freezing, and (iii) decreased solute concentration during thawing. Without actually freezing the cells, an attempt has been made to simulate physical-chemical changes to which bovine erythrocytes are exposed when frozen and thawed in glycerol solutions. Experimentally, the study consisted of suspending erythrocytes in 1, 2, or 3 glycerol at 20 °C for various times and then exposing them to each of several dilution sequences. The dilution sequences were: (i) transfer from the initial glycerol concentration at 20 °C into the same concentration at −5 °C, (ii) transfer into an increased glycerol concentration at 20 °C, (iii) transfer into an increased followed by a decreased glycerol concentration at 20 °C, (iv) transfer into an increased glycerol concentration at −5 °C, and (v) transfer into an increased followed by a decreased glycerol concentration at −5 °C. This last sequence is analogous to the exposure that cells undergo at subzero temperatures to increased solute concentration during freezing and decreased solute concentration during thawing. This dilution sequence yielded a survival pattern very similar to that obtained when bovine erythrocytes are frozen and thawed, and thus does appear to mimic freezing damage. It is concluded that a major factor in freezing damage is the extent to which a cell must shrink or swell to achieve osmotic equilibrium at subzero temperatures in partially frozen or thawed solutions.     

On the mechanism of injury to slowly frozen erythrocytes.

When cells are frozen slowly in aqueous suspensions, the solutes in the suspending solution concentrate as the amount of ice increases; the cells undergo osmotic dehydration and are sequestered in ever-narrowing liquid-filled channels. Cryoprotective solutes, such as glycerol, reduce the amount of ice that forms at any specified subzero temperature, thereby controlling the buildup in concentration of those other solutes present, as well as increasing the volume of the channels that remain to accommodate the cells. It has generally been thought that freezing injury is mediated by the increase in electrolyte concentration in the milieu surrounding the cells, rather than reduction of temperature or any direct action of ice. In this study we have frozen human erythrocytes in isotonic solutions of sodium chloride and glycerol and have demonstrated a correlation between the extent of damage at specific subzero temperatures, and that caused by the action at 0 degrees C of solutions having the same composition as those produced by freezing. The cell lysis observed increased directly with glycerol concentration, both in the freezing experiments and when the cells were exposed to corresponding solutions at 0 degrees C, showing that the concentration of sodium chloride alone is not sufficient to account quantitatively for the damage observed. We then studied the effect of freezing in anisotonic solutions to break the fixed relationship between solute concentration and the volume of the unfrozen fraction, as described by Mazur, P., W. F. Rall, and N. Rigopoulos (1981. Biophys. J. 653-675). We confirmed their experimental findings, but we explain them differently. We ascribe the apparently dominant effect of the unfrozen fraction to the fact that the cells were frozen in, and returned to, anisotonic solutions in which their volume was either less than, or greater than, their physiological volume. When similar cell suspensions were subjected to a similar cycle of increase and then decrease in solution strength, but in the absence of ice (at 20 degrees C), a similar pattern of hemolysis was observed. We conclude that freezing injury to human erythrocytes is due solely to changes that occur in the composition of their surrounding milieu, and is most probably mediated by a temporary leak in the plasma membrane that occurs during the thawing (reexpansion) phase.     

Impact of short‐term exposure to low subzero temperatures on egg hatch in the hemlock looper,Lambdina fiscellaria

The frequency of extreme events, such as cold spells, is expected to increase under global warming. Therefore, the ability of insects to survive rapid changes in temperature is an important aspect to investigate in current population ecology. The hemlock looper (HL), Lambdina fiscellaria (Guenée) (Lepidoptera: Geometridae), a defoliator of boreal balsam fir forests in eastern Canada, overwinters at the egg stage on tree trunks and branches where eggs can be exposed to very low subzero air temperatures. Using eggs from the island of Newfoundland (NL) and Quebec mainland (QC), we undertook field and laboratory experiments to determine: (1) their supercooling point (SCP) in mid‐January and mid‐February; (2) overwintering mortality; (3) cold tolerance to various combinations of subzero temperatures (?25, ?30, ?33, ?35, or ?37 °C) and exposure durations (2, 4, 8, 12, or 16 h); and (4) potential causes of death at subzero temperatures above the SCP. Regardless of population or sampling date, eggs supercooled on average at ?40.1 °C. In the field, 59% of eggs from either population that overwintered in Sainte‐Foy (QC) and Corner Brook (NL) hatched successfully, whereas none did in Armagh (QC) or Epaule (QC). In the laboratory, 50% of eggs survived after 4 h at ?34.4 °C or after 14 h at ?32.9 °C. In contrast, regardless of exposure duration, >50% of eggs hatched at temperatures ≥?33 °C, but <50% did so at ≤?35 °C, suggesting high pre‐freeze mortality. However, when eggs were attached to thermocouples and exposed to temperatures ranging from ?25 to ?37 °C for 16 h, 69% froze at temperatures of ?35 to ?37 °C, but only 2% did at ?25 or ?30 °C. Time to freeze decreased as subzero temperatures declined, and this was more evident in island eggs than in mainland eggs. Overall, eggs can freeze after a brief exposure to subzero temperatures higher than the standard SCP, and are thus highly vulnerable to cold spells.     

Nucleation and growth of ice in deeply undercooled erythrocytes

Previous studies of the mechanism of freezing of erythrocytes in the absence of intracellular ice have been extended to define the catalytic sites responsible for promoting nucleation. The following aspects have been investigated: (1) the freeze propagation between undercooled erythrocytes, (2) the nucleation of ice in undercooled erythrocyte ghosts, and (3) the freezing behavior of undercooled hemoglobin solutions. The main findings are: (1) no cross-nucleation occurs between individual cells packed within the same emulsified water droplet; (2) the differential scanning calorimetric power-time curves of intact cells and ghosts are identical, indicating that hemoglobin does not affect ice nucleation; (3) the nucleation temperature of ice in an aqueous solution of hemoglobin (isolated from the cells) is substantially lower than that for the same solution when contained in the intact cell; (4) the threefold freeze concentration which accompanies the freezing of a 25% hemoglobin solution does not cause denaturation of the protein.     

Cold adaptation strategy in insects inhabiting central Yakutia

Cold hardiness in 20 insect species living in extremely cold climate of Yakutia has been investigated for the first time. It was shown that the Yakutian insects prefer to use the strategy of freeze tolerance according to which they produce special substances initiating the freezing of hemolymph at high subzero temperatures. The presence of ice-nucleating agents in the haemolymph of insects belonging to the phylogenetic group of Lepidopteran was shown. We postulate that Pieris rapae may shift between the different cold hardiness strategies when they move from moderately cold regions to a more severe environment.     

Subzero-temperature preservation of reactive fluids in the undercooled state. II. The effect on the oxidation of ascorbic acid of freeze concentration and undercooling

The rate of oxidation of ascorbic acid has been measured in both frozen and undercooled solutions. A new interpretation is advanced for changes in the rate of ascorbic acid oxidation in freeze-concentrated solutions. The results obtained with undercooled solutions indicate a rate reduction in line with that predicted by the Arrhenius equation. It is also demonstrated that undercoohng provides a method for greatly extending the shelf life of reactive fluids.     

Cold adaptation in insects of Central Yakutia

The mode of cold hardening was for the first time assessed for 20 insect species living in the extremely cold climate of Yakutia. All insects tested were found to adapt through freeze tolerance, producing ice-nucleating agents that cause the hemolymph to freeze at high subzero temperatures. For the first time ice-nucleating agents were demonstrated in Lepidoptera. Pieris rapae exemplified the possibility of switchover in the survival strategy depending on the climatic conditions.     

Infrared video thermography: a technique for assessing cold adaptation in insects

Insects can survive subzero temperatures by two main strategies: freeze tolerance and freeze avoidance. An array of techniques have been used to investigate the physiological limits of insects to low temperatures, such as differential scanning calorimetry, temperature-controlled cooling apparatus, thermocouples, and computer-controlled chart recording equipment. However, these techniques require animals to be stationary, precluding behavioral data. We used infrared video thermography to investigate cold adaptation in an alpine insect, expanding such investigations to include behavioral response as an indicator of physiological stress. This technique is noninvasive and provides a large amount of physiological information, such as supercooling points, lower lethal temperatures, and hemolymph melting points. Insect supercooling points in response to a constant cooling rate were variable; however, temperatures at the initiation of behavioral stress response were less variable. Assessments of supercooling points and lower lethal temperatures obtained in this way are more biologically meaningful because allowing unhindered movement of insects more closely resembles natural environments.