Post-freeze recovery of peripheral nerve function in the freeze-tolerant wood frog,Rana sylvatica

We investigated the restoration of peripheral nerve function and simple neurobehavioral reflexes in the freeze-tolerant wood frog (Rana sylvatica). Thirty-two specimens, allowed to freeze for 39 h and ultimately cooled to-2.2°C, were sampled at various time intervals up to 60 h after thawing at 5°C was initiated. The sciatic nerves of treated frogs were initially unresponsive to stimulation, but usually regained excitability within 5 h. Except for a slight reduction in nerve excitability characteristics of the compound action potentials of treated frogs were indistinguishable from those of control frogs. Recovery times for the hindlimb retraction and righting reflexes were 8 h and 14 h, respectively. Concentrations of the cryoprotectant glucose increased 8.2-fold in the sciatic nerve and 10.5-fold in the underlying semimembranosis muscle of treated frogs, and remained elevated for at least 60 h after thawing was initiated. These organs lost 47.2% and 15.9%, respectively, of their water during freezing, but were rehydrated within 2 h of the onset of thawing. The accumulation of glucose and the withdrawal of tissue water apparently are cryoprotective responses which enable this species to survive freezing.     

Freeze tolerance in the gray treefrog: cryoprotectant mobilization and organ dehydration.

Freeze tolerance in the frog Rana sylvatica is supported by nonanticipatory mobilization of cryoprotectant (glucose) and redistribution of organ water. Other freeze-tolerant frogs may manifest these responses but differences exist. For example, the gray treefrog (Hyla versicolor) accumulates mostly glycerol as opposed to glucose. The current study reports additional novel features about cryoprotection in H. versicolor. Frogs were acclimated to low temperature for 12 weeks and frozen for 3 days at -2.4 degrees C. Some frogs were then thawed at 3 degrees C for 4 hr. Calorimetry revealed that frozen frogs had 53.9% +/- 11.1% of their body water in ice, and all frogs recovered following this procedure. Plasma glucose was low prior to the onset of freezing (1.1 +/- 0.9 micromol/ml) and it was 20x higher in postfreeze frogs. Constituting nearly 30% of plasma solute, glycerol was 117.2 +/- 13.6 micromol/ml prior to freezing and it remained equally high in postfreeze frogs. Liver water content was moderately lower in frozen frogs when compared to controls (62.9% +/- 3.7% vs. 68.6% +/- 1.7%), whereas postfreeze frogs excessively hydrated their livers (75.7% +/- 2.1%). Less-pronounced changes were seen in muscle water content. H. versicolor can mobilize its major cryoprotectant, glycerol, in response to extended cold acclimation, which is unique in comparison to other freeze-tolerant frogs, and it experiences only moderate organ dehydration during freezing. This species conforms with other freeze-tolerant frogs, however, by mobilizing glucose as a direct response to tissue freezing.     

Effects of dehydration on organ metabolism in the frogPseudacris crucifer: hyperglycemic responses to dehydration mimic freezing-induced cryoprotectant production

The metabolic effects of evaporative water loss at 5 °C were assessed for both fall- and spring-collected spring peepersPsuedacris crucifer. Frogs readily endured the loss of 50% of total body water. During dehydration organ water content was defended with no change in water content in skeletal muscle, gut, and kidney of 50% dehydrated frogs and reduced water content in liver, brain and heart. Dehydration stimulated a rapid and massive increase in liver glucose production. In fall-collected frogs liver glucose rose by 120-fold to 2690±400 nmol · mg protein^-1 or 220 mol · g ww^-1 in 50% dehydrated frogs and glucose in other organs increased by 2.6- to 60-fold. Spring-collected frogs showed the same qualitative response to dehydration although absolute glucose levels were lower, rising maximally by 8.4-fold in liver. Glucose synthesis was supported by glycogenolysis in liver and changes in the levels of glycolytic intermediates in liver indicated that an inhibitory block at the phosphofructokinase locus during desiccation helped to divert hexose phosphates into the production of glucose. Liver energy status (ATP, total adenylates, energy charge) was maintained even after the loss of 35% of total body water but at 50% dehydration all parameters showed a sharp decline; for example, energy charge fell from about 0.85 to 0.42. Severe dehydration also led to an accumulation of lactate in four organs, probably hypoxia-induced the to impaired circulation. The hyperglycemic response ofP. crucifer to dehydration mimics the cryoprotectant synthesis response seen during freezing of this freeze-tolerant frog, suggesting that these share a common regultory mechanism and that the cryoprotectant response may have arisen out of pre-existing volume regulatory responses of amphibians. The hyperglycemic response to dehydration might also be utilized during winter hibernation to help retard body water loss by raising the osmolality of the body fluids in situations where hibernaculum conditions become dry.Abbreviations bin body mass - bw body water - CrP creatine phosphate - dw dry weight - F6P fructose-6-phosphate - FBP fructose-1,6-bisphosphate - G6P glucose-6-phosphate - PEP phosphoenolpyruvate - PFK phosphofructokinase - PYR pyruvate - ww wet weight     

Glycation of wood frog (Rana sylvatica) hemoglobin and blood proteins: In vivo and in vitro studies

The effects of in vivo freezing and glucose cryoprotectant on protein glycation were investigated in the wood frog, Rana sylvatica. Our studies revealed no difference in the fructoselysine content of blood plasma sampled from control, 27 h frozen and 18 h thawed wood frogs. Glycated hemoglobin (GHb) decreased slightly with 48 h freezing exposure and was below control levels after 7 d recovery, while glycated serum albumin was unchanged by 48 h freezing but did increase after 7 d of recovery. In vitro exposure of blood lysates to glucose revealed that the GHb production in wood frogs was similar to that of the rat but was lower than in leopard frogs. We conclude that wood frog hemoglobin was glycated in vitro; however, GHb production was not apparent during freezing and recovery when in vivo glucose is highly elevated. It is possible that wood frog blood proteins have different in vivo susceptibilities to glycation.     

Effect of cooling rate on the survival of frozen wood frogs,Rana sylvatica

Summary Wood frogs (Rana sylvatica) were frozen to-2.5°C under five distinct cooling regimes to investigate the effect of cooling rate on survival. Frogs survived freezing when cooled at -0.16°C · h^-1 or -0.18°C · h^-1, but mortality resulted at higher rates (-0.30°C · h^-1,-1.03°C · h^-1, and -1.17°C · h^-1). Surviving frogs in the latter groups required longer periods to recover, and transient injury to the neuromuscular system was evident. Some of the frogs that died had patches of discolored, apparently necrotic skin; vascular damage, as indicated by hematoma, also occurred. It is concluded that slow cooling may be critical to the freeze tolerance of wood frogs. Additional studies examined the effect of cooling rate on physiological responses promoting freeze tolerance. Mean glucose concentrations measured in plasma (15–16 mol · ml^-1) and liver (42–45 mol · g^-1) following a 2-h thaw did not differ between slowly- and rapidly-cooled frogs but in both groups were elevated relative to unfrozen controls. Thus freezing injury to rapidly-cooled frogs apparently was not mitigated by the presence of elevated glucose. Water contents of liver tissue, measured 2 h post-thawing, did not differ between slowly-cooled (mean = 77.6%) and rapidly-cooled (mean = 78.5%) frogs. However, the mean hematocrit of slowly-cooled frogs (48%) was significantly higher than that (37%) of frogs cooled rapidly, possibly owing to differences in the dynamics of tissue water during freezing.     

Second messenger and cAMP-dependent protein kinase responses to dehydration and anoxia stresses in frogs

The effects of whole body dehydration (up to 40% of total body water lost) or anoxia exposure (up to 2 days under N₂ gas) at 5 °C on tissue levels of adenosine 3′–5′ cyclic monophosphate (cAMP) and the percentage of cAMP-dependent protein kinase present as the free catalytic subunit (PKAc), as well as the levels of the protein kinase C (PKC) second messenger, inositol 1,4,5-trisphosphate (IP₃), were assessed in two anurans, the freeze-tolerant wood frog, Rana sylvatica, and the freeze-intolerant leopard frog, Rana pipiens. Dehydration of wood frogs resulted in a rapid elevation of liver cAMP and PKAc; cAMP was 3.4-fold greater than control values in animals that had lost 5% of total body water, whereas PKAc was elevated threefold in 20% dehydrated frogs. These results indicate protein kinase A mediation of the liver glycogenolysis and hyperglycemia that is induced by dehydration in this species. Skeletal muscle PKAc content also rose with dehydration but neither cAMP nor PKAc was affected by dehydration in leopard frog tissues. Anoxia exposure had different effects on signal transduction systems. PKAc was elevated after 1 h anoxia in R. sylvatica brain and was sustained over time but the enzyme was unaffected in other organs; by contrast, R. pipiens showed variable responses by PKAc to anoxia in three organs. Both species showed rapid (within 30 min) and large (3 to 7.8-fold) increases in IP₃ in liver of anoxic frogs that decreased slowly with continued anoxia. IP₃ also increased quickly in heart of anoxia-exposed wood frogs. This suggests that PKC may mediate various metabolic adjustments that promote hypoxia/anoxia resistance such as coordinating metabolic rate depression. A progressive rise in liver IP₃ during dehydration in wood frogs (reaching fourfold higher than controls in 40% dehydrated animals) may also mediate similar hypoxia resistance adaptations under this stress since anurans experience progressive hypoxia due to increased blood viscosity when water loss reaches high values. The patterns of second messenger and PKAc changes in wood frog liver during dehydration closely parallel the changes seen in these same parameters during natural freezing suggesting that the freeze tolerance of selected terrestrially hibernating anurans may have evolved out of various anuran mechanisms of dehydration resistance. Accepted: 2 January 1997     

Urea is not a universal cryoprotectant among hibernating anurans: Evidence from the freeze-tolerant boreal chorus frog (Pseudacris maculata)

Freeze-tolerant organisms accumulate a diversity of low molecular weight compounds to combat negative effects of ice formation. Previous studies of anuran freeze tolerance have implicated urea as a cryoprotectant in the wood frog (Lithobates sylvatica). However, a cryoprotective role for urea has been identified only for wood frogs, though urea accumulation is an evolutionarily conserved mechanism for coping with osmotic stress in amphibians. To identify whether multiple solutes are involved in freezing tolerance in the boreal chorus frog (Pseudacris maculata), we examined seasonal and freezing-induced variation in several potential cryoprotectants. We further tested for a cryoprotective role for urea by comparing survival and recovery from freezing in control and urea-loaded chorus frogs. Tissue levels of glucose, urea, and glycerol did not vary significantly among seasons for heart, liver, or leg muscle. Furthermore, no changes in urea or glycerol levels were detected with exposure to freezing temperatures in these tissues. Urea-loading increased tissue urea concentrations, but failed to enhance freezing survival or facilitate recovery from freezing in chorus frogs in this study, suggesting little role for urea as a natural cryoprotectant in this species. These data suggest that urea may not universally serve as a primary cryoprotectant among freeze-tolerant, terrestrially hibernating anurans.     

Regulation of pyruvate kinase in skeletal muscle of the freeze tolerant wood frog,Rana sylvatica

The wood frog (Rana sylvatica) can survive the winter in a frozen state, in which the frog’s tissues are also exposed to dehydration, ischemia, and anoxia. Critical to wood frog survival under these conditions is a global metabolic rate depression, the accumulation of glucose as a cryoprotectant, and a reliance on anaerobic glycolysis for energy production. Pyruvate kinase (PK) catalyzes the final reaction of aerobic glycolysis, generating pyruvate and ATP from phosphoenolpyruvate (PEP) and ADP. This study investigated the effect of each stress condition experienced by R. sylvatica during freezing, including dehydration and anoxia, on PK regulation. PK from muscle of frozen and dehydrated frogs exhibited a lower affinity for PEP (K_m = 0.098 ± 0.003 and K_m = 0.092 ± 0.008) than PK from control and anoxic conditions (K_m = 0.065 ± 0.003 and K_m = 0.073 ± 0.002). Immunoblotting showed greater serine phosphorylation on muscle PK from frozen and dehydrated frogs relative to control and anoxic states, suggesting a reversible phosphorylation regulatory mechanism for PK activity during freezing stress. Furthermore, PK from frozen animals exhibited greater stability under thermal and urea-induced denaturing conditions than PK from control animals. Phosphorylation of PK during freezing may contribute to mediating energy conservation and maintaining intracellular cryoprotectant levels, as well as increase enzyme stability during stress.     

Strategies for exploration of freeze responsive gene expression: advances in vertebrate freeze tolerance

Winter survival for many cold-blooded species involves freeze tolerance, the capacity to endure the freezing of a high percentage of total body water as extracellular ice. The wood frog (Rana sylvatica) is the primary model animal used for studies of vertebrate freeze tolerance and current studies in my lab are focused on the freeze-induced changes in gene expression that support freezing survival. Using cDNA library screening, we have documented the freeze-induced up-regulation of a number of genes in wood frogs including both identifiable genes (fibrinogen, ATP/ADP translocase, and mitochondrial inorganic phosphate carrier) and novel proteins (FR10, FR47, and Li16). All three novel proteins share in common the presence of hydrophobic regions that may indicate that they have an association with membranes, but apart from that each shows unique tissue distribution patterns, stimulation by different signal transduction pathways and responses to two of the component stresses of freezing, anoxia, and dehydration. The new application of cDNA array screening technology is opening up a whole new world of possibilities in the search for molecular mechanisms that underlie freezing survival. Array screening of hearts from control versus frozen frogs hints at the up-regulation of adenosine receptor signaling for the possible mediation of metabolic rate suppression, hypoxia inducible factor mediated adjustments of anaerobic metabolism, natriuretic peptide regulation of fluid dynamics, enhanced glucose transporter capacity for cryoprotectant accumulation, defenses against the accumulation of advanced glycation end products, and improved antioxidant defenses as novel parts of natural freeze tolerance that remain to be explored.     

Multifaceted freezing injury in human polymorphonuclear cells at high subfreezing temperatures

Extracellular freezing injury at high subzero temperatures in human polymorphonuclear cells (PMNs) was studied with a cryomicroscope, electron microscope, and functional assays (phagocytosis, microbicidal activity, and chemotaxis). There are at least four major factors in freezing injury: osmotic stress, chilling, cold shock, and dilution shock. Extracellularly frozen PMNs lose functions when cooled to -2 degrees C without a cryoprotectant. Cells lose volume on freezing to the same degree as in hypertonic exposure. PMNs have a minimum volume to which they can shrink without injury. Greater dehydration produces irreversible injury to cellular functions, and cells eventually collapse under high osmotic stress. Chilling sensitivity is seen in slowly chilled, supercooled PMNs below -5 degrees C; at -7 degrees C, functions are lost in 1 h. This injury can be prevented by the addition of Me2SO but not glycerol. Me2SO does not, however, prevent cold shock (injury due to rapid cooling), which is seen during cooling at 10 degrees C/min to -14 degrees C, but not during slow cooling at 0.5 degrees C/min. One of the problems of using glycerol as a cryoprotectant stems from the high sensitivity of PMNs to dilution shock during the dilution or removal of glycerol.     

Triggering of cryoprotectant synthesis by the initiation of ice nucleation in the freeze tolerant frog,Rana sylvatica

Summary The triggering of cryoprotectant synthesis was examined in the freeze tolerant wood frog,Rana sylvatica. A slow decrease in ambient temperature (1°C every 2 days) from 3° to –2.1 °C was used to search for a specific trigger temperature. None was found. Instead it was found that, despite subzero temperature, animals which remained in a supercooled unfrozen state had low blood glucose (1.66±0.44 mol/ml) while those which had frozen had high blood glucose (181±16 mol/ml). These results indicate that it is the initiation of ice nucleation, rather than a specific subzero temperature, which triggers cryoprotectant glucose synthesis. This was confirmed by monitoring the freezing curves for individual frogs with sampling of blood and tissues at various times relative to the initiation of nucleation (detected as an instantaneous temperature jump from –3 to –1°C). Animals sampled before nucleation had low blood and liver glucose contents and a low percentage of liver phosphorylase in thea form. Within 4 min of the initiation of freezing, however, blood glucose had jumped to 16 mol/ml and liver glucose to 39.5 mol/g wet weight. Glucose in both compartments continued to increase as the time of freezing increased correlated with an increase in liver phosphorylasea content from 47% before nucleation to 100% after 50 min of freezing. The results clearly demonstrate that freeze tolerant frogs have no anticipatory synthesis of cryoprotectant as a preparation for winter but rather can translate the initiation of extracellular ice formation into a signal which rapidly activates cryoprotectant production by liver.     

Kinetics of Water Loss from Cells at Subzero Temperatures and the Likelihood of Intracellular Freezing

The survival of various cells subjected to low temperature exposure is higher when they are cooled slowly. This increase is consistent with the view that slow cooling decreases the probability of intracellular freezing by permitting water to leave the cell rapidly enough to keep the protoplasm at its freezing point. The present study derives a quantitative relation between the amount of water in a cell and temperature. The relation is a differential equation involving cooling rate, surface-volume ratio, membrane permeability to water, and the temperature coefficient of the permeability constant. Numerical solutions to this equation give calculated water contents which permit predictions as to the likelihood of intracellular ice formation. Both the calculated water contents and the predictions on internal freezing are consistent with the experimental observations of several investigators.     

Field ecology of freezing: Linking microhabitat use with freezing tolerance in Litoria ewingii

A small number of vertebrate species, including some frogs, are freezing tolerant and survive ice forming in their bodies under ecologically relevant conditions. Habitat use information is critical for interpreting laboratory studies of freezing tolerance, but there is often little known about the winter habitat and behaviours of the species under study. This work describes microhabitats used by the freezing‐tolerant frog Litoria ewingii Duméril and Bibron 1841 and their temperature characteristics. In winter, L. ewingii used microhabitats with wood, located further away from water than in summer. Microhabitat temperature records showed that frog microhabitats regularly fell below the temperature at which frog body fluids freeze (?1°C), and cooled substantially more slowly than did the air temperature. Temperatures were highly variable between microhabitats, seasons and years, with a minimum of ?2.4°C and a maximum cooling rate of 0.77°C h^?1. Frozen frogs were observed to recover in the field, demonstrating freezing tolerance. Both the characteristics of microhabitats and their selection are important in ensuring freezing survival.     

Cryoprotectants and Extreme Freeze Tolerance in a Subarctic Population of the Wood Frog

Wood frogs (Rana sylvatica) exhibit marked geographic variation in freeze tolerance, with subarctic populations tolerating experimental freezing to temperatures at least 10-13 degrees Celsius below the lethal limits for conspecifics from more temperate locales. We determined how seasonal responses enhance the cryoprotectant system in these northern frogs, and also investigated their physiological responses to somatic freezing at extreme temperatures. Alaskan frogs collected in late summer had plasma urea levels near 10 μmol ml^-1, but this level rose during preparation for winter to 85.5 ± 2.9 μmol ml^-1 (mean ± SEM) in frogs that remained fully hydrated, and to 186.9 ± 12.4 μmol ml^-1 in frogs held under a restricted moisture regime. An osmolality gap indicated that the plasma of winter-conditioned frogs contained an as yet unidentified osmolyte(s) that contributed about 75 mOsmol kg^-1 to total osmotic pressure. Experimental freezing to –8°C, either directly or following three cycles of freezing/thawing between –4 and 0°C, or –16°C increased the liver’s synthesis of glucose and, to a lesser extent, urea. Concomitantly, organs shed up to one-half (skeletal muscle) or two-thirds (liver) of their water, with cryoprotectant in the remaining fluid reaching concentrations as high as 0.2 and 2.1 M, respectively. Freeze/thaw cycling, which was readily survived by winter-conditioned frogs, greatly increased hepatic glycogenolysis and delivery of glucose (but not urea) to skeletal muscle. We conclude that cryoprotectant accrual in anticipation of and in response to freezing have been greatly enhanced and contribute to extreme freeze tolerance in northern R. sylvatica.     

Stress-induced activation of the AMP-activated protein kinase in the freeze-tolerant frog Rana sylvatica

Survival in the frozen state depends on biochemical adaptations that deal with multiple stresses on cells including long-term ischaemia and tissue dehydration. We investigated whether the AMP-activated protein kinase (AMPK) could play a regulatory role in the metabolic re-sculpting that occurs during freezing. AMPK activity and the phosphorylation state of translation factors were measured in liver and skeletal muscle of wood frogs (Rana sylvatica) subjected to anoxia, dehydration, freezing, and thawing after freezing. AMPK activity was increased 2-fold in livers of frozen frogs compared with the controls whereas in skeletal muscle, AMPK activity increased 2.5-, 4.5- and 3-fold in dehydrated, frozen and frozen/thawed animals, respectively. Immunoblotting with phospho-specific antibodies revealed an increase in the phosphorylation state of eukaryotic elongation factor-2 at the inactivating Thr56 site in livers from frozen frogs and in skeletal muscles of anoxic frogs. No change in phosphorylation state of eukaryotic initiation factor-2alpha at the inactivating Ser51 site was seen in the tissues under any of the stress conditions. Surprisingly, ribosomal protein S6 phosphorylation was increased 2-fold in livers from frozen frogs and 10-fold in skeletal muscle from frozen/thawed animals. However, no change in translation capacity was detected in cell-free translation assays with skeletal muscle extracts under any of the experimental conditions. The changes in phosphorylation state of translation factors are discussed in relation to the control of protein synthesis and stress-induced AMPK activation.     

The effects of rapid cooling (cold shock) of ram semen, photoperiod, and egg yolk in diluents on the survival of spermatozoa before and after freezing

The effects of rapid cooling of semen (cold shock) from 30 degrees C to various temperatures above 0 degrees C on survival of ram spermatozoa suspended in diluents with or without egg yolk were assessed before and after freezing. Rapid cooling of extended semen from 30 to 15 degrees C had little or no effect on spermatozoa survival before or after freezing. Rapid cooling of extended semen from 30 degrees C to 10, 5, or 0 degrees C was accompanied by a progressive decrease in percentage of motile spermatozoa and percentage of intact acrosomes before freezing and a decrease in percentage of motile spermatozoa and after freezing. The ability of spermatozoa motile after cold shock to survive freezing and thawing, evaluated as cryosurvival, was not significantly (P greater than 0.05) affected by the temperature to which semen was cooled. The addition of egg yolk to the initial extender had a beneficial effect on percentage of motile spermatozoa particularly after rapid cooling of semen to 10 and 5 degrees C. Although egg yolk had little effect before freezing on semen rapidly cooled to temperatures above 15 degrees C and therefore not actually cold shocked, it substantially improved the subsequent survival of spermatozoa after freezing and thawing. Percentage of motile spermatozoa after cooling and after freezing was generally higher when the semen was collected during a decreasing photoperiod than during an increasing photoperiod.     

Time course for cryoprotectant synthesis in the freeze-tolerant chorus frog, Pseudacris triseriata

Increases in liver glycogen phosphorylase activity, along with inhibition of glycogen synthetase and phosphofructokinase-1, are associated with elevated cryoprotectant (glucose) levels during freezing in some freeze-tolerant anurans. In contrast, freeze-tolerant chorus frogs, Pseudacris triseriata, accumulate glucose during freezing but exhibit no increase in phosphorylase activity following 24-h freezing bouts. In the present study, chorus frogs were frozen for 5- and 30-min and 2- and 24-h durations. After freezing, glucose, glycogen, and glycogen phosphorylase and synthetase activities were measured in leg muscle and liver to determine if enzyme activities varied over shorter freezing durations, along with glucose accumulation. Liver and muscle glucose levels rose significantly (5-12-fold) during freezing. Glycogen showed no significant temporal variation in liver, but in muscle, glycogen was significantly elevated after 24 h of freezing relative to 5 and 30 min-frozen treatments. Hepatic phosphorylase a and total phosphorylase activities, as well as the percent of the enzyme in the active form, showed no significant temporal variation following freezing. Muscle phosphorylase a activity and percent active form increased significantly after 24 h of freezing, suggesting some enhancement of enzyme function following freezing in muscle. However, the significance of this enhanced activity is uncertain because of the concurrent increase in muscle glycogen with freezing. Neither glucose 6-phosphate independent (I) nor total glycogen synthetase activities were reduced in liver or muscle during freezing. Thus, chorus frogs displayed typical cryoprotectant accumulation compared with other freeze-tolerant anurans, but freezing did not significantly alter activities of hepatic enzymes associated with glycogen metabolism.     

Stress-induced antioxidant defense and protein chaperone response in the freeze-tolerant wood frog <Emphasis Type="Italic">Rana sylvatica</Emphasis>

Freeze tolerance is an adaptive response utilized by the wood frog Rana sylvatica to endure the sub-zero temperatures of winter. Survival of whole body freezing requires wood frogs to trigger cryoprotective mechanisms to deal with potential injuries associated with conversion of 65–70% of total body water into ice, including multiple consequences of ice formation such as cessation of blood flow and cell dehydration caused by water loss into ice masses. To understand how wood frogs defend against these stressors, we measured the expression of proteins known to be involved in the antioxidant defense and protein chaperone stress responses in brain and heart of wood frogs comparing freezing, anoxia, and dehydration stress. Our results showed that most stress proteins were regulated in a tissue- and stress-specific manner. Notably, protein levels of the cytosolic superoxide dismutase (SOD1) were upregulated by 1.37?±?0.11-fold in frozen brain, whereas the mitochondrial SOD2 isoform rose by 1.38?±?0.37-fold in the heart during freezing. Catalase protein levels were upregulated by 3.01?±?0.47-fold in the brain under anoxia stress, but remained unchanged in the heart. Similar context-specific regulatory patterns were also observed for the heat shock protein (Hsp) molecular chaperones. Hsp27 protein was down-regulated in the brain across the three stress conditions, whereas the mitochondrial Hsp60 was upregulated in anoxic brain by 1.73?±?0.38-fold and by 2.13?±?0.57-fold in the frozen heart. Overall, our study provides a snapshot of the regulatory expression of stress proteins in wood frogs under harsh environment conditions and shows that they are controlled in a tissue- and stress-specific manner.