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Subzero Temperatures (subzero + temperature)
Selected AbstractsLactate and free glucose in supercooled hatchling Painted Turtles (Chrysemys picta) exposed to natural and semi-natural thermal regimesFUNCTIONAL ECOLOGY, Issue 3 2005M. J. PACKARD Summary 1Hatchlings of the North American Painted Turtle, Chrysemys picta (Schneider 1783) typically spend their first winter of life inside a shallow, terrestrial hibernaculum (the natal nest) where they commonly are exposed for extended periods to ice and cold. Current evidence indicates that turtles withstand such exposure by resisting freezing and becoming supercooled. 2Supercooled hatchlings held at constant temperatures in the laboratory experience circulatory impairment and stagnant hypoxia, and consequently rely on anaerobic metabolism to meet a portion of their energy needs. As a result, lactate accumulates in bodies of supercooled animals. 3The first experiment in the current investigation demonstrated that unfrozen hatchlings exposed to subzero temperatures like those recorded in a natural hibernaculum contained elevated quantities of lactic acid (and free glucose). This finding validates the widespread reliance on laboratory studies to gain insights regarding the physiology of animals overwintering in the field. 4In a second study, hatchling Painted Turtles held for 20 days at ,6 °C contained nearly twice as much lactate as turtles sampled after 10 days at that temperature. Hatchlings held for 10 days at ,6 °C and then for another 10 days at ,3 °C also contained more lactate than turtles sampled after 10 days at ,6 °C, but not as much as the hatchlings that spent 20 days at ,6 °C. Thus, animals held for part of the time at the higher subzero temperature still relied on anaerobic metabolism, but not to the same extent as turtles held continuously at the lower temperature. In contrast, hatchlings held for 10 days at ,6 °C and then for another 10 days at either 0 °C or +3 °C contained no more lactate than control animals that never were exposed to subzero temperatures. Hatchlings exposed for the second 10 days to either 0 °C or +3 °C apparently were able to catabolize or otherwise process all the lactate that was accumulated during the first 10 days of their treatment. 5Free glucose in bodies of hatchlings was elevated in all animals exposed to subzero temperatures, even when the initial exposure was followed by 10 days at temperatures as high as +3 °C. This finding has important implications with regard to the substrate that is used to support intermediary metabolism in supercooled turtles as well as to the metabolic pathways that are used to remove accumulated lactate once body temperature of the turtles rises at least to 0 °C. [source] Cryostructuring of polymer systems.JOURNAL OF APPLIED POLYMER SCIENCE, Issue 5 2008XXIX. Abstract Supermacroporous (spongy) agarose-based cryogels were prepared by a two-step freezing procedure (freezing at ,30°C followed by incubation at a warmer subzero temperature) and subsequent thawing. The cryogels were formed as cylinders in plastic syringes and as platelike samples in flat metal molds. The characteristic feature of the gel matrices thus obtained was their heterogeneous spongelike morphology with a system of interconnected gross (50,250-,m and larger) pores. The influence of the cryogenic processing regimes on the properties and porous morphology of such agarose cryogels was explored by flow-through analysis, optical microscopy, thermometry, and high-sensitivity differential scanning calorimetry. These biocompatible, spongelike matrices were used as three-dimensional scaffolds for culturing insulin-producing rat insulinoma cells self-assembled in multicellular spherical aggregates (pseudoislets). The cell morphology and functional activity of such pseudoislets indicate that supermacroporous agarose-based cryogels can be useful as a tool for engineering biohybrid insulin-producing tissue. © 2008 Wiley Periodicals, Inc. J Appl Polym Sci, 2008 [source] Morphology studies of doped polyaniline micro/nanocomposites containing TiO2 nanoparticles and Fe3O4 microparticlesPOLYMER COMPOSITES, Issue 7 2009Sook-Wai Phang To produce polyaniline (PAni) nanodevices that display excellent microwave absorbing behaviors, novel hexanoic acid-doped PAni micro/nanocomposites containing TiO2 nanoparticles and Fe3O4 microparticles (PAni/HA/TiO2/Fe3O4) were prepared by template-free method, particularly to improve the dielectric and magnetic property of PAni. PAni/HA/TiO2/Fe3O4 synthesized at different polymerization temperatures and polymerization time by various TiO2 and Fe3O4 contents, and particles size of TiO2 were prepared. The aim of this research is to investigate the effect of synthesis condition on the morphology behaviors of nanorods/tubes. The resulted nanorods/tubes indicated that PAni micro/nanocomposites exhibited polymerization through elongation. PAni micro/nanocomposites synthesized at 0°C resulted in large amounts of nanorods/tubes compared with those synthesized at subzero temperature and above 0°C. PAni/HA/TiO2 and PAni/HA/TiO2/Fe3O4 synthesized using TiO2 with diameter (particles size) 180 nm resulted in large amounts of nanorods/tubes (diameter nanorods/tubes = 80,140 nm) compared with those synthesized using TiO2 with diameter of 30 and 6 nm. Increasing TiO2 and Fe3O4 content above 10% will significantly reduce the amount of nanorods/tubes. In conclusion, synthesis parameters mentioned above are the significant factors that might affect the morphology behaviors of PAni nanostructures. POLYM. COMPOS., 2009. © 2008 Society of Plastics Engineers [source] Reproduction and metabolism at , 10°C of bacteria isolated from Siberian permafrostENVIRONMENTAL MICROBIOLOGY, Issue 4 2003Corien Bakermans Summary We report the isolation and properties of several species of bacteria from Siberian permafrost. Half of the isolates were spore-forming bacteria unable to grow or metabolize at subzero temperatures. Other Gram-positive isolates metabolized, but never exhibited any growth at , 10°C. One Gram-negative isolate metabolized and grew at , 10°C, with a measured doubling time of 39 days. Metabolic studies of several isolates suggested that as temperature decreased below + 4°C, the partitioning of energy changes with much more energy being used for cell maintenance as the temperature decreases. In addition, cells grown at , 10°C exhibited major morphological changes at the ultrastructural level. [source] Characterization of potential stress responses in ancient Siberian permafrost psychroactive bacteriaFEMS MICROBIOLOGY ECOLOGY, Issue 1 2005Monica A. Ponder Abstract Past studies of cold-acclimated bacteria have focused primarily on organisms not capable of sub-zero growth. Siberian permafrost isolates Exiguobacterium sp. 255-15 and Psychrobacter sp. 273-4, which grow at subzero temperatures, were used to study cold-acclimated physiology. Changes in membrane composition and exopolysaccharides were defined as a function of growth at 24, 4 and ,2.5 °C in the presence and absence of 5% NaCl. As expected, there was a decrease in fatty acid saturation and chain length at the colder temperatures and a further decrease in the degree of saturation at higher osmolarity. A shift in carbon source utilization and antibiotic resistance occurred at 4 versus 24 °C growth, perhaps due to changes in the membrane transport. Some carbon substrates were used uniquely at 4 °C and, in general, increased antibiotic sensitivity was observed at 4 °C. All the permafrost strains tested were resistant to long-term freezing (1 year) and were not particularly unique in their UVC tolerance. Most of the tested isolates had moderate ice nucleation activity, and particularly interesting was the fact that the Gram-positive Exiguobacterium showed some soluble ice nucleation activity. In general the features measured suggest that the Siberian organisms have adapted to the conditions of long-term freezing at least for the temperatures of the Kolyma region which are ,10 to ,12 °C where intracellular water is likely not frozen. [source] Lactate and free glucose in supercooled hatchling Painted Turtles (Chrysemys picta) exposed to natural and semi-natural thermal regimesFUNCTIONAL ECOLOGY, Issue 3 2005M. J. PACKARD Summary 1Hatchlings of the North American Painted Turtle, Chrysemys picta (Schneider 1783) typically spend their first winter of life inside a shallow, terrestrial hibernaculum (the natal nest) where they commonly are exposed for extended periods to ice and cold. Current evidence indicates that turtles withstand such exposure by resisting freezing and becoming supercooled. 2Supercooled hatchlings held at constant temperatures in the laboratory experience circulatory impairment and stagnant hypoxia, and consequently rely on anaerobic metabolism to meet a portion of their energy needs. As a result, lactate accumulates in bodies of supercooled animals. 3The first experiment in the current investigation demonstrated that unfrozen hatchlings exposed to subzero temperatures like those recorded in a natural hibernaculum contained elevated quantities of lactic acid (and free glucose). This finding validates the widespread reliance on laboratory studies to gain insights regarding the physiology of animals overwintering in the field. 4In a second study, hatchling Painted Turtles held for 20 days at ,6 °C contained nearly twice as much lactate as turtles sampled after 10 days at that temperature. Hatchlings held for 10 days at ,6 °C and then for another 10 days at ,3 °C also contained more lactate than turtles sampled after 10 days at ,6 °C, but not as much as the hatchlings that spent 20 days at ,6 °C. Thus, animals held for part of the time at the higher subzero temperature still relied on anaerobic metabolism, but not to the same extent as turtles held continuously at the lower temperature. In contrast, hatchlings held for 10 days at ,6 °C and then for another 10 days at either 0 °C or +3 °C contained no more lactate than control animals that never were exposed to subzero temperatures. Hatchlings exposed for the second 10 days to either 0 °C or +3 °C apparently were able to catabolize or otherwise process all the lactate that was accumulated during the first 10 days of their treatment. 5Free glucose in bodies of hatchlings was elevated in all animals exposed to subzero temperatures, even when the initial exposure was followed by 10 days at temperatures as high as +3 °C. This finding has important implications with regard to the substrate that is used to support intermediary metabolism in supercooled turtles as well as to the metabolic pathways that are used to remove accumulated lactate once body temperature of the turtles rises at least to 0 °C. [source] Variation in thermal tolerance is linked to phosphoglucose isomerase genotype in a montane leaf beetleFUNCTIONAL ECOLOGY, Issue 2 2003G. Neargarder Summary 1Sierra Nevada populations of the Willow Beetle Chrysomela aeneicollis (Schaeffer) experience extreme elevated and subzero temperatures in nature. In these populations, frequencies of phosphoglucose isomerase (PGI) alleles vary with latitude and altitude and respond to climate change. PGI genotypes differ in expression of a stress-inducible heat shock protein (Hsp70). 2Here, differences in tolerance of elevated and subzero extreme temperatures were compared for field-acclimatized and laboratory-acclimated larvae and adults possessing three common PGI genotypes (PGI 1,1, 1,4 and 4,4). Three indices of thermal tolerance were measured , CTmax, LT50 and Hsp70 expression level. 3Thermal tolerance depended on life stage, prior exposure to sublethal stress and PGI genotype. Larvae were generally less tolerant of thermal extremes than adults. For both adults and larvae, prior exposure to sublethal temperatures increased survival after exposure to subsequent stress. Survival after exposure to thermal extremes was consistently related to PGI genotype (1,1 > 1,4 > 4,4), as were expression levels of Hsp70 (1,1 > 1,4 > 4,4). 4These results suggest that PGI genotypes differ in tolerance of thermal extremes routinely experienced by beetles in nature. A trade-off between thermal tolerance and energy allocation may explain the persistence of the PGI polymorphism. [source] Water availability controls microbial temperature responses in frozen soil CO2 productionGLOBAL CHANGE BIOLOGY, Issue 11 2009MATS G. ÖQUIST Abstract Soil processes in high-latitude regions during winter are important contributors to global carbon circulation, but our understanding of the mechanisms controlling these processes is poor and observed temperature response coefficients of CO2 production in frozen soils deviate markedly from thermodynamically predicted responses (sometimes by several orders of magnitude). We investigated the temperature response of CO2 production in 23 unfrozen and frozen surface soil samples from various types of boreal forests and peatland ecosystems and also measured changes in water content in them after freezing. We demonstrate that deviations in temperature responses at subzero temperatures primarily emanates from water deficiency caused by freezing of the soil water, and that the amount of unfrozen water is mainly determined by the quality of the soil organic matter, which is linked to the vegetation cover. Factoring out the contribution of water limitation to the CO2 temperature responses yields response coefficients that agree well with expectations based on thermodynamic theory concerning biochemical temperature responses. This partitioning between a pure temperature response and the effect of water availability on the response of soil CO2 production at low temperatures is crucial for a thorough understanding of low-temperature soil processes and for accurate predictions of C-balances in northern terrestrial ecosystems. [source] Responses of shoot growth and survival to water stress gradient in diploid and tetraploid populations of Lolium multiflorum and L. perenneGRASSLAND SCIENCE, Issue 4 2006Shu-ichi Sugiyama Abstract Drought stress is one of the critical environmental factors in determining growth and survival of herbage grasses. In this study, by using a hydroponic culture system including different amounts of polyethylene glycol (PEG), responses of plant shoots to water stress in four different intensities (0 Mpa, ,0.6 Mpa, ,1.2 Mpa and ,1.8 Mpa) were examined in diploid and tetraploid cultivars of Italian ryegrass (Lolium multiflorum) and perennial ryegrass (L. perenne). Since freezing injury is caused by cell dehydration, freezing tolerance was also examined for six subzero temperatures (,11, ,12, ,14, ,16, ,18 and ,20°C) in both species. L. multiflorum had a larger shoot biomass at all stress intensities and a lower survival rate under severe water stress and freezing stress conditions than L. perenne. Thus, there was a trade-off (negative correlation) between potential growth under a stress-free condition and survival under a severe stress condition in diploid and tetraploid cultivars of both species. This trade-off was mediated by tissue water content. High water content led to a high growth rate through increasing specific leaf area, while low water content resulted in a high tissue osmotic potential that could confer high cell dehydration tolerance. [source] Cold adaptation in Arctic and Antarctic fungiNEW PHYTOLOGIST, Issue 2 2001Clare H. Robinson Summary Growth and activity at low temperatures and possible physiological and ecological mechanisms underlying survival of fungi isolated from the cold Arctic and Antarctic are reviewed here. Physiological mechanisms conferring cold tolerance in fungi are complex; they include increases in intracellular trehalose and polyol concentrations and unsaturated membrane lipids as well as secretion of antifreeze proteins and enzymes active at low temperatures. A combination of these mechanisms is necessary for the psychrotroph or psychrophile to function. Ecological mechanisms for survival might include cold avoidance; fungal spores may germinate annually in spring and summer, so avoiding the coldest months. Whether spores survive over winter or are dispersed from elsewhere is unknown. There are also few data on persistence of basidiomycete vs microfungal mycelia and on the relationship between low temperatures and the predominance of sterile mycelia in tundra soils. Acclimation of mycelia is a physiological adaptation to subzero temperatures; however, the extent to which this occurs in the natural environment is unclear. Melanin in dark septate hyphae, which predominate in polar soils, could protect hyphae from extreme temperatures and play a significant role in their persistence from year to year. [source] Physical modelling of bedrock brecciation by ice segregation in permafrostPERMAFROST AND PERIGLACIAL PROCESSES, Issue 3 2001J. B. Murton Abstract The lower half of a large block of moist chalk was maintained at subzero temperatures while the upper half was cyclically frozen and thawed, simulating 19 seasonal temperature cycles in an active layer above permafrost. During the experiment, the rock surface heaved vertically by at least 34.7 mm. Sixty-one percent of the heave occurred during freezing periods, and is attributed primarily to ice segregation accompanying upward freezing from the permafrost table during the early stages of simulated winters. Thirty-nine percent of the heave occurred during thawing periods, and is attributed to ice segregation in the frozen rock beneath the thaw front during the mid to late stages of simulated summers. By the end of the experiment, the middle horizon of the chalk, representing the upper part of the simulated permafrost and the basal part of the active layer, had become strongly brecciated and rich in segregated ice. The style of brecciation has similarities with that in perennially-frozen limestone, sandstone and shale in Svalbard and Canada, and chalk frozen during Quaternary cold stages in France and England. These similarities suggest that ice segregation during perennial and seasonal freezing is an important process of weathering and coarse-sediment supply in areas of frost-susceptible bedrock. Copyright © 2001 John Wiley & Sons, Ltd. RÉSUMÉ La moitié inférieure d'un gros bloc de craie humide a été maintenue à des températures inférieures à zéro degré (maintien d'un pergélisol) pendant que sa moitié supérieure était soumise alternativement au gel et au dégel, simulant ainsi 19 cycles saisonniers dans la couche active. Pendant l'expérience, la surface de la roche s'est soulevée verticalement de 34,7 mm. Soixante et un % du gonflement a été acquis pendant les périodes de gel simulant les hivers et attribué essentiellement à la ségrégation de glace accompagnant un gel à partir du sommet du pergélisol au début de ces périodes. Trente neuf % du gonflement a été enregistré pendant le milieu et la fin des périodes de dégel simulant les étés. Ceci est considéré comme le résultat de regels en-dessous du niveau atteint par le front de dégel. A la fin de l'expérience, la partie médiane du bloc, correspondant au sommet du pergélisol et à la base de la couche active, est apparue très fragmentée et riche en glace de ségrégation. Le type de fragmentation offre des aspects semblables à ceux qu'on observe dans les calcaires, grès et schistes gelés en permanence du Svalbard et du Canada et les craies soumises aux gels des stades froids du Quaternaire en France et en Angleterre. Cela suggère que la ségrégation de la glace pendant les périodes de gel permanent ou saisonnier est un important processus de fragmentation des roches et de fourniture de sédiments grossiers dans les régions où les roches sont sensibles au gel. Copyright © 2001 John Wiley & Sons, Ltd. [source] Responses of protein phosphatases and cAMP-dependent protein kinase in a freeze-avoiding insect, Epiblema scudderianaARCHIVES OF INSECT BIOCHEMISTRY AND PHYSIOLOGY (ELECTRONIC), Issue 1 2006Thomas D. Pfister Abstract Larvae of the goldenrod gall moth, Epiblema scudderiana, use the freeze avoidance strategy of winter cold hardiness and show multiple metabolic adaptations for subzero survival including accumulation of large amounts of glycerol as a colligative antifreeze. Induction and regulation of cold hardiness adaptations requires the intermediary action of signal transduction enzymes. Changes in the activities of several signaling enzymes including cAMP-dependent protein kinase (PKA), protein phosphatases 1 (PP1), 2A, 2C, and protein tyrosine phosphatases (PTPs) were monitored over the winter and during experimental exposures of larvae to subzero temperatures (,4°C, a temperature that triggers rapid glycerol synthesis, or ,20°C, a common midwinter ambient temperature) or anoxia. A strong increase in the amount of active PP1 in the latter part of the winter may be responsible for shutting off glycogenolysis once glycerol levels are maximized. There appears to be a limited role for PKA in overwintering but PP2A and PP2C activities rose when larvae were exposed to ,20°C and PTP activities rose significantly over the winter months and also in response to laboratory subzero (,20°C) and anoxia exposures. The strong responses by PTPs suggest that these may be involved in cell cycle and growth arrest during winter diapause. Arch. Insect Biochem. Physiol. 62:43,54, 2006. © 2006 Wiley-Liss, Inc. [source] Climatic variability and the evolution of insect freeze toleranceBIOLOGICAL REVIEWS, Issue 2 2003BRENT J. SINCLAIR ABSTRACT Insects may survive subzero temperatures by two general strategies: Freeze-tolerant insects withstand the formation of internal ice, while freeze-avoiding insects die upon freezing. While it is widely recognized that these represent alternative strategies to survive low temperatures, and mechanistic understanding of the physical and molecular process of cold tolerance are becoming well elucidated, the reasons why one strategy or the other is adopted remain unclear. Freeze avoidance is clearly basal within the arthropod lineages, and it seems that freeze tolerance has evolved convergently at least six times among the insects (in the Blattaria, Orthoptera, Coleoptera, Hymenoptera, Diptera and Lepidoptera). Of the pterygote insect species whose cold-tolerance strategy has been reported in the literature, 29% (69 of 241 species studied) of those in the Northern Hemisphere, whereas 85%(11 of 13 species) in the Southern Hemisphere exhibit freeze tolerance. A randomization test indicates that this predominance of freeze tolerance in the Southern Hemisphere is too great to be due to chance, and there is no evidence of a recent publication bias in favour of new reports of freeze-tolerant species. We conclude from this that the specific nature of cold insect habitats in the Southern Hemisphere, which are characterized by oceanic influence and climate variability must lead to strong selection in favour of freeze tolerance in this hemisphere. We envisage two main scenarios where it would prove advantageous for insects to be freeze tolerant. In the first, characteristic of cold continental habitats of the Northern Hemisphere, freeze tolerance allows insects to survive very low temperatures for long periods of time, and to avoid desiccation. These responses tend to be strongly seasonal, and insects in these habitats are only freeze tolerant for the overwintering period. By contrast, in mild and unpredictable environments, characteristic of habitats influenced by the Southern Ocean, freeze tolerance allows insects which habitually have ice nucleators in their guts to survive summer cold snaps, and to take advantage of mild winter periods without the need for extensive seasonal cold hardening. Thus, we conclude that the climates of the two hemispheres have led to the parallel evolution of freeze tolerance for very different reasons, and that this hemispheric difference is symptomatic of many wide-scale disparities in Northern and Southern ecological processes. [source] Perdeuteration, purification, crystallization and preliminary neutron diffraction of an ocean pout type III antifreeze proteinACTA CRYSTALLOGRAPHICA SECTION F (ELECTRONIC), Issue 4 2009Isabelle Petit-Haertlein The highly homologous type III antifreeze protein (AFP) subfamily share the capability to inhibit ice growth at subzero temperatures. Extensive studies by X-ray crystallography have been conducted, mostly on AFPs from polar fishes. Although interactions between a defined flat ice-binding surface and a particular lattice plane of an ice crystal have now been identified, the fine structural features underlying the antifreeze mechanism still remain unclear owing to the intrinsic difficulty in identifying H atoms using X-ray diffraction data alone. Here, successful perdeuteration (i.e. complete deuteration) for neutron crystallographic studies of the North Atlantic ocean pout (Macrozoarces americanus) AFP in Escherichia coli high-density cell cultures is reported. The perdeuterated protein (AFP D) was expressed in inclusion bodies, refolded in deuterated buffer and purified by cation-exchange chromatography. Well shaped perdeuterated AFP D crystals have been grown in D2O by the sitting-drop method. Preliminary neutron Laue diffraction at 293,K using LADI-III at ILL showed that with a few exposures of 24,h a very low background and clear small spots up to a resolution of 1.85,Å were obtained using a `radically small' perdeuterated AFP D crystal of dimensions 0.70 × 0.55 × 0.35,mm, corresponding to a volume of 0.13,mm3. [source] Collapse temperature of solutions important for lyopreservation of living cells at ambient temperature,BIOTECHNOLOGY & BIOENGINEERING, Issue 2 2010Geer Yang Abstract In this study, the collapse temperature was determined using the freeze-drying microscopy (FDM) method for a variety of cell culture medium-based solutions (with 0.05,0.8,M trehalose) that are important for long-term stabilization of living cells in the dry state at ambient temperature (lyopreservation) by freeze-drying. Being consistent with what has been reported in the literature, the collapse temperature of binary water-trehalose solutions was found to be similar to the glass transition temperature (T,g , ,30°C) of the maximally freeze-concentrated trehalose solution (,80,wt% trehalose) during the freezing step of freeze-drying, regardless of the initial concentration of trehalose. However, the effect of the initial trehalose concentration on the collapse temperature of the cell culture medium-based trehalose solutions was identified to be much more significant, particularly when the trehalose concentration is less than 0.2,M (the collapse temperature can be as low as ,65°C). We also determined that cell density from 1 to 10,million cells/mL and ice seeding at high subzero temperatures (,4 and ,7°C) have negligible impact on the solution collapse temperature. However, ice seeding does significantly affect the ice crystal morphology formed during the freezing step and therefore the drying rate. Finally, bulking agents (mannitol) could significantly affect the collapse temperature only when trehalose concentration is low (<0.2,M). However, improving the collapse temperature by using a high concentration of trehalose might be preferred to the addition of bulking agents in the solutions for freeze-drying of living cells. We further confirmed the applicability of the collapse temperature measured with small-scale (2,µL) samples using the FDM system to freeze-drying of large-scale (1,mL) samples using scanning electron microscopy (SEM) data. Taken together, the results reported in this study should provide useful guidance to the development of optimal freeze-drying protocols for lyopreservation of living cells at ambient temperature for easy maintenance and convenient wide distribution to end users, which is important to the eventual success of modern cell-based medicine. Biotechnol. Bioeng. 2010;106: 247,259. © 2010 Wiley Periodicals, Inc. [source] | ||||||||||||||||