Thermal acclimation, growth, and burst swimming of threespine stickleback: enzymatic correlates and influence of photoperiod

Threespine sticklebacks (Gasterosteus aculeatus) that had been reared in the laboratory under natural photoperiods were acclimated to 23 degrees and 8 degrees C in late spring under increasing day lengths and again in late fall under decreasing day lengths. The parents of these fish were from the anadromous Isle Verte population. In the spring, cold- and warm-acclimated fish grew at the same rates and attained similar condition factors (mass L(-3)), although food intake was considerably higher at 23 degrees C. As both groups had similar increases in mass and condition, the higher axial muscle activities of citrate synthase and phosphofructokinase (measured at 20 degrees C) after cold acclimation were likely a direct response to temperature. Multiple regression analysis showed that axial muscle levels of cytochrome C oxidase and citrate synthase were correlated with the burst swimming speeds of the spring sticklebacks, while growth rates were positively correlated with lactate dehydrogenase levels in pectoral and axial muscles and creatine kinase levels in the axial muscle. In the fall, the fish in both acclimation groups grew little, although they fed at similar rates as in the spring experiment. Overall, the sticklebacks showed lower burst swimming speeds in the fall. In both spring and fall, the burst speeds of cold- and warm-acclimated sticklebacks only differed at warm temperatures. In the spring experiment, the cold-acclimated fish swam faster, whereas in the fall experiment the warm-acclimated fish swam faster despite their lower percentage of axial muscle. Swimming speeds were measured both at a fish's acclimation temperature and after 12 h at the other temperature. Cold-acclimated sticklebacks seem to have more facility in rapidly adjusting to warm temperatures when they have experienced increasing rather than decreasing day lengths, perhaps as a result of the requirements of the spring migration to the intertidal breeding grounds.     

Cold acclimation increases basal heart rate but decreases its thermal tolerance in rainbow trout (Oncorhynchus mykiss)

Rainbow trout (Oncorhynchus mykiss, Walbaum) were acclimated to 4 degrees C and 17 degrees C for more than 4 weeks and heart rate was determined in the absence and presence of adrenaline to see how thermal adaptation influences basal heart rate and its beta-adrenergic control in a eurythermal fish species. The basal heart rate in vitro was higher in cold-acclimated than warm-acclimated rainbow trout at temperatures below 17 degrees C. On the other hand, adaptation to cold decreased thermal tolerance of heart rate so that the maximal heart rates were achieved at 17 degrees C (75 +/- 4 bpm) and 24 degrees C (88 +/- 2 bpm) in cold-acclimated and warm-acclimated trout, respectively. Beta-adrenergic response of the heart was enhanced by cold-adaptation, since adrenaline (100 nmol l(-1)) caused stronger stimulation of heart rate in cold-acclimated (29 +/- 14%) than in warm-acclimated fish (10 +/- 1%; P = 0.03). Furthermore, adrenaline strongly opposed the temperature-dependent deterioration of force production in cold-acclimated trout but not in warm-acclimated trout. The results indicate that adaptation to cold increases basal heart rate but decreases its thermal tolerance in rainbow trout. Cold acclimation up-regulates the beta-adrenergic system, and beta-adrenoceptor activation seems to provide cardioprotection against high temperatures in the cold-adapted rainbow trout.     

Temperature adaptation of biological membranes. Compensation of the molar activity of cytochrome c oxidase in the mitochondrial energy-transducing membrane during thermal acclimation of the carp (Cyprinus carpio L.)

The acclimation temperature of carp does not affect the amount of cytochrome c oxidase per mg mitochondrial protein as revealed from the reduced-minus-oxidized difference spectra of red muscle mitochondria from cold- and warm-acclimated carp. There are no differences between cold- and warm-acclimated fish in the substrate binding properties of the enzyme as judged from the Km values for cytochrome c at 30 degrees C (3.34 +/- 0.ee microM, acclimation temperature 10 degrees C and 3.55 +/- 0.31 microM, acclimation temperature 30 degrees C). The molar activities of the enzyme, however, differ for both acclimation temperatures: when intercalated in the 10 degrees C-acclimated mitochondrial membrane, the enzyme can catalyze the oxidation of 117.6 +/- 17.2 mol ferrocytochrome c/s per mol heme a as compared with 85.6 +/- 17.2 in the 30 degrees C-acclimated membrane (experimental temperature 30 degrees C). Correspondingly, higher specific activities of the succinate oxidase system are observed in mitochondria from cold-acclimated carp as compared with those obtained from warm-acclimated carp. The results indicate that cold acclimation of the eurythermic carp is accompanied by a partial compensation of the acute effect of decreasing temperature on the activity of cytochrome c oxidase in red muscle mitochondria. Based on the temperature-induced lipid adaptation reported for carp red muscle mitochondria (Wodtke, E. (1980) Biochim. Biophys. Acta 640, 698--709), it is concluded that during thermal acclimation the molar activity of cytochrome c oxidase is controlled by viscotropic regulation. The results fit to the conception that cardiolipin constitutes a lipid shell (annulus) surrounding the oxidase within the native membrane, but that it is the bilayer fluidity and not the annular fluidity which determines the activity of cytochrome c oxidase.     

The glutathione-dependent system of antioxidant defense is not modulated by temperature acclimation in muscle tissues from striped bass,Morone saxatilis

Cold temperature generally induces an enhancement of oxidative capacities, a greater content of intracellular lipids, and a remodeling of lipids in biological membranes. These physiological responses may pose a heightened risk of lipid peroxidation (LPO), while warm temperature could result in greater risk of LPO since rates involving reactive oxygen species and LPO will be elevated. The current study examines responses of the glutathione system of antioxidant defense after temperature acclimation. We measured total glutathione (tGSH), and protein levels of GPx1, GPx4, and GST (cardiac and skeletal muscles), and enzymatic activity (skeletal muscle) of glutathione-dependent antioxidants (GPx, GPx4, and GST) in tissues from striped bass (Morone saxatilis) acclimated for six weeks to 7 °C or 25 °C. tGSH of cardiac muscle from cold-acclimated animals was 1.2-times higher than in warm-bodied counterparts, but unchanged with temperature acclimation in skeletal muscle. A second low molecular weight antioxidant, ascorbate was 1.4- and 1.5-times higher in cardiac and skeletal muscle, respectively in warm- than cold-acclimated animals. Despite 1.2-times higher oxidative capacities (as indicated by citrate synthase activity), in skeletal muscle from cold- versus warm-acclimated fish, levels and activities of antioxidant enzymes were similar between acclimation groups. Lipid peroxidation products (as indicated by TBARS), normalized to tissue wet weight, were more than 2-times higher in skeletal muscle from cold- than warm-acclimated animals, however, when normalized to phospholipid content there was no statistical difference between acclimation groups. Our results demonstrate that the physiological changes, associated with acclimation to low temperature in the eurythermal striped bass, are not accompanied by an enhanced antioxidant defense in the glutathione-dependent system.     

Effect of extracellular calcium on the contractility of warm-and cold-acclimated crucian carp heart

Crucian carp (Carassius carassius L.) were acclimated for at least 4 weeks to 2°C or 22°C, and the consequences of thermal acclimation on force development, time-course of contraction and action potential duration of the ventricular myocardium were studied. In cold-acclimated fish contraction was activated at much lower external [Ca] than in warm-acclimated fish: [Ca] for half-maximal force was 0.9±0.15 and 3.1±0.92 mmol·l^-1 (P<0.05) for cold- and warm-acclimated fish, respectively. Durations of contraction and relaxation were significantly longer in fish acclimated to 2°C than in fish acclimated to 22°C, especially at [Ca] below 2 mmol·l^-1. In low-Ca solution ventricular action potential was prolonged both in cold- and warm-acclimated fish. In 0.5 mmol·l^-1 Ca action potential duration at zero voltage level was longer in cold- than warm-acclimated fish. Although lengthening of action potential was evident in both acclimation groups, a marked prolongation of contraction duration by low-Ca solutions occurred only in cold-acclimated fish. This suggests that a plateau component of contraction is present in cold-acclimated fish but less well developed in warm-acclimated fish hearts. Contractions were strongly inhibited by sarcolemmal Ca-channel blocker, cadmium (100 and 300 mol·l^-1), in both warm- and cold-acclimated crucian carp hearts. However, the sarcoplasmic reticulum Ca release channel blocker, ryanodine (10 mol·l^-1), had no effect on the force of contraction in either acclimation group. These results suggest that the contraction of crucian carp heart is controlled by sarcolemmal mechanisms without contribution by sarcoplasmic reticulum Ca release. Since the Ca sensitivity of myofilaments was not altered by thermal acclimation, the results indicate that thermal acclimation alters Ca activation of contraction of the crucian carp heart at the level of sarcolemma.Abbreviations AP action potential - EGTA ethyleneglycol-bis-(-aminoethylether)-N,N,N,N-tetra-acetic acid - F _max maximum force - F _max maximum rate of contraction - F _min maximum rate of relaxation - HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulphonic acid - pCa log [Ca] - Pl action potential plateau - SL sarcolemma - SR sarcoplasmic reticulum - TPF time to peak force - T1/2R time to half relaxation from the peak force     

Muscle activity in steady swimming scup, Stenotomus chrysops, varies with fiber type and body position

The red and pink aerobic muscle fibers are used to power steady swimming in fishes. We examined red and pink muscle recruitment and function during swimming in scup, Stenotomus chrysops, through electromyography and high-speed ciné. Computer analysis of electromyograms (EMGs) allowed determination of initial speed of muscle recruitment and duty cycle and phase of muscle electromyographic activity for both fiber types. This analysis was carried out for three longitudinal positions over a range of swimming speeds. Fiber type and longitudinal position both affected swimming speed of initial recruitment. Posterior muscle is recruited at the lowest swimming speed, whereas more anterior muscle is not initially recruited until higher speeds. At more anterior positions, the initial recruitment of pink muscle occurs at a higher swimming speed than the recruitment of red muscle. The duty cycle of pink muscle EMG activity is significantly shorter than that of red muscle, reflecting a difference in the onset time of activation during each cycle of length change: pink muscle onset time follows that of red. The different patterns of usage of red and pink muscle reflect differences in their contraction kinetics. Because pink muscle generates force more rapidly than red muscle, it can be activated later in each tailbeat cycle. Pink muscle is used to augment red muscle power production at higher swimming speeds, allowing a higher aerobically based steady swimming speed than that possible by red muscle alone.     

Cold acclimation induces proliferation of sarcoplasmic reticulum without increase in Ca2+-ATPase activity in white axial muscle of striped bass (Morone saxatilis)

The effects of acclimation of striped bass to cold (5 degrees C) and warm (25 degrees C) temperatures upon ultrastructural features of white axial skeletal muscle are quantified. Surface density of sarcoplasmic reticulum (SR) increased by almost 30%, and SR volume density increased by about 20% during cold acclimation. Proliferation of SR suggests an increase in available SR surface for re-sequestration of Ca2+ and a decrease in diffusion path length for Ca2+ during cold acclimation. Average cross-sectional areas and cross-sectional perimeters of myofibrils situated in the center of muscle fibers decreased during cold acclimation by approximately 20% and 11%, respectively. Additionally, average major and minor axes of ellipses fit to central myofibrillar cross-sections decreased by approximately 12% and 8%, respectively, during cold acclimation. These measurements define a decrease in average myofibrillar diameter and suggest a decrease in diffusion path length for Ca2+ to and from myofibrillar activation sites. Measurements of peripheral myofibrils that had elongated profiles in cross-sections indicate that maximum profile length of these myofibrils decreases by about 17%. Peripheral myofibrils may break up into smaller myofibrils with more rounded cross-sectional profiles during cold acclimation. SR Ca2+-ATPase of white axial muscle was also measured in unfractionated homogenates and in crude SR-enriched subcellular fractions from cold- and warm-acclimated striped bass. No difference in SR Ca2+-ATPase activity per g wet weight was observed between cold- and warm-acclimated animals. Lack of increase in SR Ca2+-ATPase per g wet weight, despite a significant proliferation of SR, probably results in a decrease in average Ca2+-ATPase pump density within the SR membrane during cold acclimation. Thus, compensation for decreased diffusion coefficient of Ca2+ during cold acclimation appears due to the combined effects of proliferation of SR surface density and a decrease in average myofibrillar diameter.     

The Shift of Thermoneutral Zone in Striped Hamster Acclimated to Different Temperatures

Temperature affects all biological functions and will therefore modulate ecologically significant interactions between animals and their environment. Here, we examined the effect of ambient temperature (T_a) on the thermal biology and energy budget in striped hamsters acclimated to cold (5°C), warm (21°C) and hot temperatures (31°C). Thermoneutral zone (TNZ) was 22.5–32.5°C, 25–32.5°C and 30–32.5°C in the cold-, warm- and hot-acclimated hamsters, respectively. The cold acclimation decreased the lower critical temperature and made the TNZ wider, and hot exposure elevated the lower critical temperature, resulting in a narrow TNZ. Within the TNZ, cold-acclimated hamsters showed a significantly higher rate of metabolism and thermogenesis than those acclimated to hot temperature. Digestive enzymes activities, including intestinal sucrase, maltase, L-alanine aminopeptidase-N and leucine aminopeptidase were higher in the cold than in the hot. The changes in metabolic rate and thermogenesis at different temperatures were in parallel with cytochrome c oxidase activity and uncoupling protein 1 gene expression of brown adipose tissue. This suggests that the shift of the lower critical temperature of TNZ is possibly associated with the rate of metabolism and thermogenesis, as well as with the digestive capacity of the gastrointestinal tract at different T_a. The upper critical temperature of TNZ may be independent of the changes in T_a. The changes of lower critical temperature of TNZ are an important strategy in adaption to variations of T_a.     

Temperature dependence and acclimatory response of amylase in the High Arctic springtail Onychiurus arcticus (Tullberg) compared with the temperate species Protaphorura armata (Tullberg)

Amylolytic activity was measured in whole body homogenates of High Arctic (Onychiurus arcticus) and temperate (Protaphorura armata) springtails (Collembola: Onychiuridae) in the temperature range 5-55 degrees C. A pH of ca. 8 was optimum for amylolytic activity in both species. A higher weight-specific amylolytic activity was observed in P. armata. In O. arcticus, amylolytic activity depended on thermal acclimation, which increased during 2 and 9 weeks of cold acclimation (5 degrees C) and decreased over 7 weeks of warming (15 degrees C) of animals that were previously acclimated to cold for 2 weeks. In cold-acclimated O. arcticus, a slower decrease of amylolytic activity occurred with lowering of temperature in the range 5-20 degrees C in comparison with warm-acclimated specimens and P. armata, which resulted in higher activity at 5 degrees C. The activation energy calculated from an Arrhenius plot for P. armata was 68.7 kJ.mol(-1). In O. arcticus it was between 30.2 and 61.5 kJ.mol(-1), being lower in cold-acclimated samples. The temperature optimum for amylolytic activity was higher in the temperate species (40 degrees C), whilst in O. arcticus it depended on the acclimation regime: it rose to 35 degrees C after warm acclimation and decreased to 20 degrees C after cold adaptation. The total soluble protein content of body tissues of O. arcticus also increased during cold acclimation. These differences between the two species suggest that amylolytic activity is an indicator of cold adaptation in the High Arctic O. arcticus.     

Alterations to the swimming performance of carp, Cyprinus carpio, as a result of temperature acclimation

Groups of common carp were acclimated to either 10°C or 28°C for 6 weeks. Fish were then exercised at 10°C or 20°C, and the critical swimming speed (fatigue velocity) was measured. At 10°C, cold-acclimated carp were capable of significantly higher swimming speeds. When exercised at 20°C. however, the situation was reversed, and warm-acclimated carp exhibited improved swimming ability. These results provide direct evidence that acclimation of the contractile proteins is beneficial across a wide temperature range. Following acclimation to low environmental temperatures the critical swimming speed exhibited a Q₁₀ of only 1.1 for the temperature range 10–20°C. compared to a value of 2.9 for fish acclimated to the higher temperature.     

Aerial and aquatic oxygen uptake by freely-diving snapping turtles (Chelydra serpentina)

Summary Aerial oxygen consumption of unrestrained, freely-diving warm-and cold-acclimated snapping turtles, Chelydra serpentina, was measured at 10, 20, and 30°C. Also, simultaneous determinations of aerial and aquatic oxygen uptake by voluntarilydiving animals were made at 4 and 20°C. The standard rates of aerial oxygen consumption are equivalent in cold-and warm-acclimated animals in water and in cold-acclimated ones in air; these rates are all lower than those of warm-acclimated animals in air. Thus either cold acclimation or voluntary submergence reduces the standard metabolic rate of snapping turtles but the effects are not additive. Aquatic oxygen uptake during voluntary submergence is more important at low than at moderate temperatures and probably contributes significantly to gas exchange in these animals as they overwinter beneath the ice of ponds and streams.     

Temperature acclimation of axonal functions in the crayfish Astacus astacus L.

1. 1.|Crayfish (Astacus astacus L.) were acclimated for 1–3 weeks at 5 and 20°C. The effects of temperature on the functions of the unicellular medial giant axon were studied.

2. 2.|The resting membrane potential of the giant axon increased slightly with the experimental temperature from 2 to 32°C. The temperature dependence of the resting membrane potential could be described by two lines, which intersected at about 12°C in cold-acclimated crayfish and at about 16°C in the warm-acclimated.

3. 3.|The amplitude of the action potential was stable at temperatures from 4 to 26°C. It decreased at temperatures above 26°C in both acclimation groups.

4. 4.|The duration of the falling phase of action potential was highly temperature dependent at low temperatures. A break in the slope of the dependence was found at about 14°C in cold-acclimated crayfish and at about 17°C in the warm-acclimated.

Thermal acclimation,mitochondrial capacities and organ metabolic profiles in a reptile (<Emphasis Type="Italic">Alligator mississippiensis</Emphasis>)

Reptiles thermoregulate behaviourally, but change their preferred temperature and the optimal temperature for performance seasonally. We evaluated whether the digestive and locomotor systems of the alligator show parallel metabolic adjustments during thermal acclimation. To this end, we allowed juvenile alligators to grow under thermal conditions typical of winter and summer, providing them with seasonally appropriate basking opportunities. Although mean body temperatures of alligators in these groups differed by approximately 10°C, their growth and final anatomic status was equivalent. While hepatic mitochondria isolated from cold-acclimated alligators had higher oxidative capacities at 30°C than those from warm-acclimated alligators, the capacities did not differ at 20°C. Cold acclimation decreased maximal oxidative capacities of muscle mitochondria. For mitochondria from both organs and acclimation groups, palmitate increased oligomycin-inhibited respiration. GDP addition reduced palmitate-uncoupled rates more in liver mitochondria from warm- than cold-acclimated alligators. In muscle mitochondria, carboxyatractyloside significantly reduced palmitate-uncoupled rates. This effect was not changed by thermal acclimation. The aerobic capacity of liver, skeletal muscle and duodenum, as estimated by activities of cytochrome c oxidase (COX), increased with cold acclimation. At acclimation temperatures, the activities of COX and citrate synthase (CS) in these organs were equivalent. By measuring COX and CS in isolated mitochondria and tissue extracts, we estimated that cold acclimation did not change the mitochondrial content in liver, but increased that of muscle. The thermal compensation of growth rates and of the aerobic capacity of the locomotor and digestive systems suggests that alligators optimised metabolic processes for the seasonally altered, preferred body temperature. The precision of this compensatory response exceeds that typically shown by aquatic ectotherms whose body temperatures are at the mercy of their habitat.     

Cold hardiness in summer and winter diapause and post-diapause pupae of the cabbage armyworm, Mamestra brassicae L. under temperature acclimation

Cold hardiness and biochemical changes were investigated in winter and summer pupae of the cabbage armyworm Mamestra brassicae at the diapause and post-diapause stages under temperature acclimation. Diapause pupae were successively acclimated to 25, 20 and then 10 degrees C (warm-acclimated group). Pupae at the diapause and post-diapause stages were successively acclimated to 5, 0, -5 and then -10 degrees C (cold-acclimated groups). Supercooling point values in winter and summer pupae remained constant regardless of the diapause stages and acclimated temperatures. Warm-acclimated pupae at the diapause stage did not survive the subzero temperature exposure, whereas, cold-acclimated pupae achieved cold hardiness to various degrees. Winter pupae were more cold hardy than summer pupae, and pupae at the post-diapause stage were more cold hardy than those at the diapause stage. Trehalose contents in winter pupae rose under cold acclimation. Summer pupae accumulated far lower trehalose contents than winter pupae, with the maximal level occurring in winter pupae at the post-diapause stage. Glycogen content remained at a high level in diapause pupae after warm acclimation, whereas it decreased after cold acclimation. Alanine, the main free amino acid in haemolymph after cold acclimation, increased at lower temperatures in both diapause and post-diapause pupae, but the increase was greater in the diapause pupae. These results suggest that cold hardiness is more fully developed in winter pupae than in summer pupae, and cold acclimation provides higher cold hardiness in winter pupae at the post-diapause stage than at the diapause stage.     

Temperature acclimation modifies sinoatrial pacemaker mechanism of the rainbow trout heart

The hypothesis of pacemaker level origin of thermal compensation in heart rate was tested by recording action potentials (AP) in intact sinoatrial tissue and enzymatically isolated pacemaker cells of rainbow trout acclimated at 4 degrees C (cold) and 18 degrees C (warm). With electrophysiological recordings, the primary pacemaker was located at the base of the sinoatrial valve, where a morphologically distinct ring of tissue comprising myocytes and neural elements was found by histological examination. Intrinsic beating rate of this pacemaker was higher in cold-acclimated (46 +/- 6 APs/min) than warm-acclimated trout (38 +/- 3 APs/min; P < 0.05), and a similar difference was seen in beating rate of isolated pacemaker cells (44 +/- 6 vs. 38 +/- 6 APs/min; P < 0.05), supporting the hypothesis that thermal acclimation modifies the intrinsic pacemaker mechanism of fish heart. Inhibition of sarcoplasmic reticulum (SR) with 10 microM ryanodine and 1 microM thapsigargin did not affect heart rate in either warm- or cold-acclimated trout at 11 degrees C but reduced heart rate in warm-acclimated trout from 74 +/- 2 to 42 +/- 6 APs/min (P < 0.05) at 18 degrees C. At 11 degrees C, a half-maximal blockade of the delayed rectifier K+ current (I(Kr)) with 0.1 microM E-4031 reduced heart rate more in warm-acclimated (from 45 +/- 1 to 24 +/- 5 APs/min) than cold-acclimated trout (56 +/- 3 vs. 48 +/- 2 APs/min), whereas I(Kr) density was higher and AP duration less in cold-acclimated trout (P > 0.05). Collectively, these findings suggest that a cold-induced increase in AP discharge frequency is at least partly due to higher density of the I(Kr) in the cold-acclimated trout, whereas contribution of SR Ca2+ release to thermal compensation of heart rate is negligible.     

The effect of acclimation on mating frequency and mating competitiveness in the Queensland fruit fly, Dacus tryoni, in optimal and cool mating regimes

Mating frequency in groups of Dacus tryoni which had been either warm-acclimated or cold-acclimated were compared in temperature regimes ranging from just above mating-threshold to optimal. Cold-acclimation appeared to suppress initial mating ability of mature insects of both sexes to an extent which depended upon the acclimation regime used. The most favourable cold-acclimation regime produced flies which in certain circumstances were able to mate at an initial frequency similar to that of warm-acclimated flies. In no mating regime was initial mating significantly more frequent in any cold-acclimated group than it was in any warm-acclimated group. In most cases warm-acclimated flies in a given regime mated at high frequency for 1–2 days, whereas the cold-acclimated flies mated at low frequency for a greater number of days. In all cases, cold-acclimated flies accumulated a similar or significantly lower total number of matings than warm-acclimated groups. In experiments in which both warm-acclimated and cold-acclimated males competed for cold-acclimated females, the warm-acclimated males always out-competed the cold-acclimated males in two mild (near optimal) regimes. In a relatively harsh (near torpor threshold) regime, there was no significant difference in the competitive abilities of cold-acclimated and warm-acclimated males. The relevance of these results to possible acclimation procedures used in control campaigns involving release of sterile males is discussed.     

Temperature acclimation in brook trout muscle: Adenine nucleotide concentrations, phosphorylation state and adenylate energy charge

Summary Cold acclimation in fish is associated with an elevation in metabolic rate. The present study investigates the role of adenine nucleotides and related compounds in metabolic regulation following temperature acclimation. Brook trout (Salvelinus fontinalis) were acclimated for 10 weeks to either +4°C or +24°C. Both groups of fish were exercised at 2.5 body lengths s^–1 for 2 weeks prior to sacrifice in order to control for differences in spontaneous activity.Concentrations of ATP, ADP, AMP, P _i and PC were approximately 2-fold higher in white than red muscles. Temperature acclimation had little effect on total adenine nucleotide concentration in either muscle type. In white fibres acclimation to 4°C results in a 39% increase in [ADP] and [AMP], a 35% decrease in [PC] (phosphorylcreatine), and no significant change in [P _i ]. In contrast temperature has little effect on concentrations of these compounds in red muscle.Parameters of metabolic control — adenylate energy charge ([ATP]+0.5 [ADP]/[ATP]+[ADP]+[AMP]), phosphorylation state ([ATP]/[ADP]·[P _i ]), and the ratios [ATP][ADP] and [ATP][AMP] — were significantly lower in cold- than warm-acclimated white muscle. The observed changes in phosphorylation state and [ATP][AMP] are consistent with an increase in mitochondrial respiration and glycolysis, respectively.In conclusion, changes in metabolites may be an important factor in producing an enhanced metabolic rate in cold-acclimated fish.     

Induction of freezing tolerance in spinach is associated with the synthesis of cold acclimation induced proteins

Spinach (Spinacia oleracea L. cv Bloomsdale) seedlings cultured in vitro were used to study changes in protein synthesis during cold acclimation. Seedlings grown for 3 weeks postsowing on an inorganic-nutrient-agar medium were able to increase their freezing tolerance when grown at 5°C. During cold acclimation at 5°C and deacclimation at 25°C, the kinetics of freezing tolerance induction and loss were similar to that of soil-grown plants. Freezing tolerance increased after 1 day of cold acclimation and reached a maximum within 7 days. Upon deacclimation at 25°C, freezing tolerance declined within 1 day and was largely lost by the 7th day. Leaf proteins of intact plants grown at 5 and 25°C were in vivo radiolabeled, without wounding or injury, to high specific activities with [³⁵S]methionine. Leaf proteins were radiolabeled at 0, 1, 2, 3, 4, 7, and 14 days of cold acclimation and at 1, 3, and 7 days of deacclimation. Up to 500 labeled proteins were separated by two-dimensional gel electrophoresis and visualized by fluorography. A rapid and stable change in the protein synthesis pattern was observed when seedlings were transferred to the low temperature environment. Cold-acclimated leaves contained 22 polypeptides not found in nonacclimated leaves. Exposure to 5°C induced the synthesis of three high molecular weight cold acclimation proteins (CAPs) (M_r of about 160,000, 117,000, and 85,000) and greatly increased the synthesis of a fourth high molecular weight protein (M_r 79,000). These proteins were synthesized during day 1 and throughout the 14 day exposure to 5°C. During deacclimation, the synthesis of CAPs 160, 117, and 85 was greatly reduced by the first day of exposure to 25°C. However, CAP 79 was synthesized throughout the 7 day deacclimation treatment. Thus, the induction at low temperature and termination at warm temperature of the synthesis of CAPs 160, 117, and 85 was highly correlated with the induction and loss of freezing tolerance. Cold acclimation did not result in a general posttranslational modification of leaf proteins. Most of the observed changes in the two-dimensional gel patterns could be attributed to the de novo synthesis of proteins induced by low temperature. In spinach leaf tissue, heat shock altered the pattern of protein synthesis and induced the synthesis of several heat shock proteins (HSPs). One polypeptide synthesized in cold-acclimated leaves had a molecular weight and net charge (M_r 79,000, pI 4.8) similar to that of a HSP (M_r 83,000, pI 4.8). However, heat shock did not increase the freezing tolerance, and cold acclimation did not increase heat tolerance over that of nonacclimated plants, but heat-shocked leaf tissue was more tolerant to high temperatures than nonacclimated or cold-acclimated leaf tissue. When protein extracts from heat-shocked and cold-acclimated leaves were mixed and separated in the same two-dimensional gel, the CAP and HSP were shown to be two separate polypeptides with slightly different isoelectric points and molecular weights.     

Effects of adenosine on the contractility of normoxic rainbow trout heart

Temperature strongly affects oxygen solubility in water, oxygen convection in the blood and locomotor activity of the fish. Since oxygen supply and demand are temperature dependent, it was hypothesized that the purinergic control of the heart, one of the most important mediators in oxygen-limited conditions, might also show temperature dependence. Therefore, the present study examines the effects of adenosine (Ado), a purinergic agonist, on the contractile and electrical activity of the thermally acclimated trout ( Oncorhynchus mykiss Walbaum) heart. The fish were acclimated to either 4 degrees C or 17 degrees C and the experiments were conducted at the acclimation temperatures of the animals. In spontaneously beating hearts, Ado had a negative chronotropic and a positive inotropic effect in warm-acclimated rainbow trout while no response was detected in cold-acclimated trout. In paced atrial and ventricular preparations, Ado had a negative inotropic effect in both warm- and cold-acclimated fish, and the response was strongest in the atria of warm-acclimated trout. Ado shortened the duration of contraction 12-14% in atrial preparations but had no effect in ventricular muscle. Ado (10(-4) mol l(-1)) increased the density of the inwardly rectifying K(+) current from -3.5+/-0.6 pA pF(-1) to -8.4+/-1.4 pA pF(-1) (at -120 mV) in atrial myocytes of warm-acclimated trout but was without effect in atrial myocytes of cold-acclimated trout (-2.4+/-0.8 pA pF(-1) vs. -2.1+/-0.9 pA pF(-1)). Ado had no effect on K(+) currents of ventricular cells in either acclimation group. These results indicate that the effects of Ado on cardiac contractility and electrical activity are stronger in warm-acclimated than in cold-acclimated trout when measured at the physiological body temperatures of the fish. The balance between oxygen demand and supply of the heart might be better in the cold where more environmental oxygen is available and the power of the muscles is weaker thereby reducing the need for the purinergic control of the heart. Temperature-dependence of Ado response in the trout heart warrants that temperature should be taken into consideration when the purinergic system of the ectotherms is studied.     

The Roles of Pink and Red Muscle in Powering Steady Swimming in Scup, Stenotomus chrysops

Fishes power steady, undulatory swimming using both red andpink muscle. In this study we examined the roles of the twofiber types in generating power for swimming by using two-steptechnique. First, in vivo data is collected from swimming fish,and second, the electrical activity and muscle length changeconditions recorded in vivo are recreated in vitro with isolatedmuscle bundles. Force production and power generation by muscleduring swimming can then be estimated. In scup, both red andpink muscle are recruited to power swimming at the maximum sustainedswimming speed. For both fiber types, the duration of electricalactivity decreases from anterior to posterior. However, theamplitude of muscle length change increases anterior to posterior.Mass-specific power production increases posteriorly for bothmuscle types. The faster contraction kinetics of pink muscletranslate to higher power production pink muscle relative tored muscle for all longitudinal positions of the fish. Determinationof absolute power production, based on mass-specific power andmuscle mass, shows that the posterior regions of the fish generatethe most power for swimming. At 20°C, red muscle generatesmore absolute power than pink due to its higher muscle mass.However, at 10°C, pink muscle generates more absolute powerthan red, because red muscle produces little or no positivepower for all longitudinal positions.