Seasonal variations in the responses of glycolytic intermediates of human erythrocytes to acute cold exposure

Seven male students were studied to observe the effects of acute cold exposure (at 10°C for 60 min) on erythrocyte concentrations of glycolytic intermediates in summer and in winter. The subjects shivered slightly but frankly in both experiments. Significant decreases were observed in the concentrations of pyruvate and lactate during body cooling in summer, but not in winter. The lactate concentration remained significantly reduced 15 min after cold exposure. After 60 min of cold exposure in summer, a negative crossover point appeared to exist between phosphoenolpyruvate and pyruvate and erythrocyte pyruvate kinase activity showed a significant decrease. No seasonal difference was observed in the initial control values of the intermediates measured. From these results and the fact that glucose, pyruvate and lactate are evenly distributed between erythrocytes and plasma, it is likely that erythrocytes and skeletal muscles need less fuel substrate, glucose during cold exposure in winter than in summer, suggesting that an increased economy of energy for homeostasis is achieved.     

Renal responses to chronic cold exposure

The aim of this study was to assess our hypothesis that the release of antidiuretic hormone (ADH), the renal concentrating response to ADH, or both is decreased by prolonged cold exposure. Six groups (n = 6/group) of rats were used. Three groups were exposed to cold (5 degrees C), whilethe remaining three groups were kept at room temperature (25 degrees C). It was found that urine osmolality decreased significantly and serum osmolality increased significantly during cold exposure. The ratio of water/food intake was not affected by prolonged cold exposure. However, prolonged cold exposure increased the ratio of urine output/food intake in the cold-exposed rats, indicating that more urine flow is required by the cold-exposed rats to excrete the osmotic substance at a given food intake. The difference between water intake and urine output decreased significantly in the cold-exposed rats. Thus, prolonged cold exposure increases water loss from excretion. Renal concentrating responses to 24-h dehydration and Pitressin were decreased significantly in the cold-exposed rats. Plasma ADH levels remained unchanged, but renal ADH receptor (V2 receptor) mRNA was decreased significantly in the cold-exposed rats. The results strongly support the conclusion that cold exposure increases excretive water loss, and this may be due to suppression of renal V2 receptors rather than inhibition of ADH release.     

Blood pressure and thermal responses to whole body cold exposure in mildly hypertensive subjects

Six mildly hypertensive subjects were exposed three times to −15 °C (wind 3.5 m/s) for 15 min. After an initial exposure for familiarisation, second and third exposures were arranged in a random double blind, crossover fashion after a week's ingestion of hydrochlorothiazide or placebo. Cold decreased skin temperatures, but not rectal temperature. Blood pressure increased 30/20 mmHg and heart rate decreased 12 beats/min by cold. Blood pressure seems to react in 3 min to changes in ambient temperature. The skin temperatures of uncovered body parts were apparently responsible for that. Hydrochlorothiazide did not affect either cardiovascular or thermal responses in cold.     

Seasonal changes in human immune responses to malaria

Cellular as well as humorol immune responses to malaria antigens fluctuate in time in individuals living in molono-endemic areas, particularly where malaria transmission is seasonal. The most pronounced changes are seen in association with clinical attacks, but osymptomatic infection can also lead to apparent immune depression. However, recent data have shown that seasonal variation in cellular immune responses may occur even in the absence of detectable porositaemia. Here, Lars Hviid and Thor G. Theonder review the seasonal variation in human immune responses to malaria, and discuss its possible causes and implications.     

Seasonal changes in cold hardiness of Ophraella communa

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

Antioxidative and metabolic responses to extended cold exposure in rats

In this work, we investigated whether extended cold exposure increases oxidative damage and susceptibility to oxidants of rat liver, heart, kidney and lung which are metabolically active tissues. Moreover in this study the effect of cold stress on some of the lipid metabolic mediators were studied in rat experimental model. Male albino Sprague-Dawley rats were randomly divided into two groups: The control group (n=12) and the cold-stress group (n=12). Tissue superoxide dismutase (SOD), catalase (CAT), glutathion S-transferase (GST) and glutathion reductase (GR) activities and glutathion (GSH) were measured using standard protocols. The biochemical analyses for total lipid, cholesterol, trigliceride, HDL, VLDL and LDL were done on autoanalyzer. In cold-stress groups SOD activity was decreased in the lung whereas it increased in the heart and kidney. CAT activity was significantly decreased (except liver) in all the tissues in treated rats. GST activity of cold-induced rats increased in liver and heart while decreased in the lung. GR activity was significantly decreased (except in liver) in all the tissues in cold-stressed rats. GSH level was significantly increased in the heart but decreased in the lung of animals exposed to cold when compared to controls. It was found that among the groups trigliceride, total lipid, HDL and VLDL parameters varied significantly but cholesterol and LDL had no significant variance. In this study, we found that exposure of extended (48 h) cold (8 degrees C) caused changes both in the antioxidant defense system (as tissue and enzyme specific) and serum lipoprotein profiles in rats.     

Plasma catecholamine responses to tyrosine hydroxylase inhibition and cold exposure

The acute effect of α-methyl-p-tyrosine (αMPT), a tyrosine hydroxylase inhibitor, on plasma levels of norepinephrine (NE), epinephrine (E), dopamine (DA), and adrenal cholesterol content in male rats at room temperature (24°C) and during acute cold exposure (4°C) was evaluated. Compared to saline-treated controls, αMPT: 1) significantly reduced plasma NE and DA in both normal and cold stress conditions, 2) significantly increased plasma E in both environments, and 3) stimulated the adrenal cortex. These findings suggest that tyrosine hydroxylase inhibition and consequent catecholamine synthesis blockade disrupts the homeokinesis of adrenergic processes and may present a significant stress to the intact animal.     

Effects of physical conditioning in man on thermal responses to cold air

Thermal responses of ten relatively unfit young men (six lean, four obese) were determined during duplicate exposures of two hours each in air of 10°C. Mean heat production ( ), rectal (T_re), esophageal (T_es), skin (T_s), and subcutaneous (T_sc) temperatures were continuously measured during each exposure. All subjects were then physically conditioned for nine weeks, which increased their work capacity and maximal oxygen intake. On duplicate retesting, , T_re and T_es remained essentially similar to preconditioning values. Mean skin temperature (T_s) of both groups was lower following conditioning, due primarily to lower skin temperatures of the chest, thigh, forearm and upper arm. Toe temperature was unchanged. The T_sc to T_s gradients for the forearm and upper arm were greater in both groups after conditioning. Increased vasoconstriction and a different peripheral circulation pattern in the cold may result from physical conditioning.

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Zusammenfassung Die Wärmereaktionen von 10 relativ untrainierten jungen Männern (6 schlank, 4 fett) wurden im Doppelversuch während 2 Stunden Exponierung bei 10°C untersucht. Die Messungen der mittleren Wärmebildung ( ), rektalen (T_re), Oesophagus (T_es), Haut (T_s) und subkutanen (T_sc) temperaturen erfolgten fortlaufend während jeder Exponierung. Danach wurden alle Personen 9 Wochen körperlich trainiert. Dies führte zu einem signifikanten Anstieg der Arbeitsleistung und maximalen O₂-Aufnahme. Bei doppelter Wiederholung der Untersuchung ergaben sich für , T_re und T_es gleiche Werte wie vorher. Nach dem Training was T_s bei beiden Gruppen tiefer, als Folge tieferer Temperaturen über der Brust, den Oberschenkeln und den Armen. Die Zehentemperatur war unverändert. Die T_sc — T_s Grandienten waren am Vorder- und Oberarm in beiden Gruppen nach dem Training grösser. Eine erhöhte Vasokonstriktion und veränderte periphere Zirkulation in der Kälte ist wahrscheinlich Folge des Trainings.

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Resume La réaction à la chaleur de 10 jeunes gens relativement peu entraînés (6 maigres et 4 gras) a été examinée par l'exposition de 2 × 2 heures à 10°C. On a mesuré en permanence durant chaque exposition la production moyenne de chaleur ( ) et les températures rectale (T_re), de l'oesophage (T_es), de la peau (T_s) et subcutanée (T_sc). Ensuite, toutes ces personnes subirent un entraînement durant 9 semaines. Ceci eut pour conséquence une augmentation significative des aptitudes au travail musculaire et de l'absorption maximum de O₂. De nouvelles mesures répétées deux fois ont donné les mêmes valeurs que précédemment pour , T_re et T_es. Après l'entraînement, les deux groupes présentaient des valeurs inférieures pour T_s en raison de températures plus basses sur la poitrine, la cuisse et les bras. La température des orteils n'avait pas changé. Le gradient T_sc — T_s avait augmenté chez les deux groupes au bras et à l'avant-bras. Une constriction vasculaire plus élevée et une modification de la circulation périphérique sont probablement les conséquences d'un certain entraînement.

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This investigation was supported by Contract No AF 41 (609)-2696 from the Aerospace Medical Division (AFSC) Department of the Air Force.     

Thermoregulatory responses of young and older men to cold exposure.

Nine young (20-25 years) and ten older (60-71 years) men, matched for body fatness and surface area:mass ratio, underwent cold tests in summer and winter. The cold tests consisted of a 60-min exposure, wearing only swimming trunks, to an air temperature of 17 degrees C (both seasons) and 12 degrees C (winter only). Rectal (Tre) and mean skin (Tsk) temperatures, metabolic heat production (M), systolic (BPs) and diastolic (BPd) blood pressures and heart rate (fc) were measured. During the equilibrium period (28 degrees C air temperature) there were no age-related differences in Tre, Tsk, BPs, BPd, or fc regardless of season, although M of the older men was significantly lower (P < 0.003). The decrease in Tre and Tsk (due to the marked decrease in six of the older men) and the increase in BPs and BPd were significantly greater (P < 0.004) for the older men during all the cold exposures. The rate of increase in M was significantly greater (P < 0.01) for the older group when exposed to 12 degrees C in winter and 17 degrees C in summer (due to the marked increase in four of the older men). This trend was not apparent during the 17 degrees C exposure in winter. There was no age-related difference in fc during the exposures. Significant decreases in Tre and Tsk and increases in M, BPs and BPd during the 12 degrees C exposure were observed for the older group (P < 0.003) compared to their responses during the 17 degrees C exposure in winter. In contrast, Tre, M, BPs in the young group were not affected as much by the colder environment. It was concluded that older men have more variable responses and some appear more or less responsive to mild and moderate cold air than young men.     

Seasonal variation in physiological responses to mild cold air in young and older men

Eight men aged 60–65 years and six men aged 20–25 years, wearing only swimming trunks, were exposed to an air temperature of 17° C and 45% R.H. in each of the four seasons. The increase in the rate of metabolic heat production for the older group in the cold test was significantly higher in summer and autumn than in winter and spring (P<0.05), but did not differ in the young group between seasons. Compared to the young group the was significantly greater for the older group (due to a marked increase in four individuals) in summer and autumn (P<0.04). At the end of the period of cold exposure, the decrements of rectal temperature (T _re), mean skin temperature ( ; due to a marked decrease in four individuals) and foot skin temperature (T _foot) were significantly greater for the older group compared to the young group at all times of the year (P<0.003). Seasonal variations in the two groups were similar, e.g., theT_re gradually became smaller from summer to winter (P<0.05) and then increased slightly in the spring (P=0.07).T _foot for both groups decreased from summer to autumn (P<0.01) and remained unchanged subsequently. No seasonal variations were observed for in either group. The increase in diastolic blood pressure (BP_d) during the test was significantly smaller in winter in both groups (P<0.05). BP_d became larger again during spring in the older group (P<0.01), but remained low in the young group. The BP_d was significantly greater for the older group than the young group in winter and spring (P<0.05). Compared to young men these results suggest that older men may lose the tolerance acquired by earlier cold acclimatization as seen by the BP_d responses, and have a somewhat lower thermoregulatory capability in coping with mild cold air in all seasons.     

Seasonal changes in the numerical responses of predators to cyclic vole populations

Theoretical models predict that a delayed density-dependent mortality factor with a time lag of ca 9 months is able to drive 3–5-yr population cycles of northern voles. We studied numerical responses of predators in western Finland during 1986–92, in an area with 3-yr population cycles of voles. Abundances of small mammals were monitored in several farmland areas (each 3 km²) by snap-trapping in April, June, August, and October (only in 1986–90), and the abundances of avian, mammalian, and reptilian predators by visual censuses during trapping occasions. The 3-yr cycle studied was a cycle of Microtus voles (field vole M. agrestis and sibling vole M. rossiaemeridionalis ) and their small-sized predators (small mustelids and vole-eating birds of prey). The numerical responses of both migratory avian predators and small mustelids to changes in vole densities were more alike than different. In late summer (August), the time lag in the numerical response of all main predators was short (0–4 months), whereas longer time lags prevailed from spring to early summer. The length of the time lag in spring appeared to be related to the length of the winter, which indicates that strong seasonality may create longer time lags to the numerical response of predators at northern latitudes than at more southern latitudes. Our results suggest that, from spring to early summer, predation by migratory avian predators may act in concordance with mustelid predation to produce the long time lag necessary to drive the 3-yr cycle of voles, whereas almost direct density-dependent predation by all major predators in late summer may dampen spatial variation in prey densities.