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

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

Microbial ecology and biodiversity in permafrost

Permafrost represents 26% of terrestrial soil ecosystems; yet its biology, essentially microbiology, remains relatively unexplored. The permafrost environment is considered extreme because indigenous microorganisms must survive prolonged exposure to subzero temperatures and background radiation for geological time scales in a habitat with low water activity and extremely low rates of nutrient and metabolite transfer. Yet considerable numbers and biodiversity of bacteria exist in permafrost, some of which may be among the most ancient viable life on Earth. This review describes the permafrost environment as a microbial habitat and reviews recent studies examining microbial biodiversity found in permafrost as well as microbial growth and activity at ambient in situ subzero temperatures. These investigations suggest that functional microbial ecosystems exist within the permafrost environment and may have important implications on global biogeochemical processes as well as the search for past or extant life in permafrost presumably present on Mars and other bodies in our solar system.     

Reproduction and metabolism at - 10 degrees C of bacteria isolated from Siberian permafrost

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 degrees C. One Gram-negative isolate metabolized and grew at - 10 degrees C, with a measured doubling time of 39 days. Metabolic studies of several isolates suggested that as temperature decreased below + 4 degrees 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 degrees C exhibited major morphological changes at the ultrastructural level.     

Bacterial genome replication at subzero temperatures in permafrost

Microbial metabolic activity occurs at subzero temperatures in permafrost, an environment representing ∼25% of the global soil organic matter. Although much of the observed subzero microbial activity may be due to basal metabolism or macromolecular repair, there is also ample evidence for cellular growth. Unfortunately, most metabolic measurements or culture-based laboratory experiments cannot elucidate the specific microorganisms responsible for metabolic activities in native permafrost, nor, can bulk approaches determine whether different members of the microbial community modulate their responses as a function of changing subzero temperatures. Here, we report on the use of stable isotope probing with ¹³C-acetate to demonstrate bacterial genome replication in Alaskan permafrost at temperatures of 0 to −20 °C. We found that the majority (80%) of operational taxonomic units detected in permafrost microcosms were active and could synthesize ¹³C-labeled DNA when supplemented with ¹³C-acetate at temperatures of 0 to −20 °C during a 6-month incubation. The data indicated that some members of the bacterial community were active across all of the experimental temperatures, whereas many others only synthesized DNA within a narrow subzero temperature range. Phylogenetic analysis of ¹³C-labeled 16S rRNA genes revealed that the subzero active bacteria were members of the Acidobacteria, Actinobacteria, Chloroflexi, Gemmatimonadetes and Proteobacteria phyla and were distantly related to currently cultivated psychrophiles. These results imply that small subzero temperature changes may lead to changes in the active microbial community, which could have consequences for biogeochemical cycling in permanently frozen systems.     

Exposure to subfreezing temperature and a freeze-thaw cycle affect freezing tolerance of winter wheat in saturated soil

Winter wheat is sown in the autumn and harvested the following summer, necessitating the ability to survive subfreezing temperatures for several months. Autumn months in wheat-growing regions typically experience significant rainfall and several days or weeks of mild subfreezing temperatures at night, followed by above-freezing temperatures in the day. Hence, the wheat plants usually are first exposed to potentially damaging subfreezing temperatures when they have high moisture content, are growing in very wet soil, and have been exposed to freeze-thaw cycles for a period of time. These conditions are conducive to freezing stresses and plant responses that are different from those that occur under lower moisture conditions without freeze-thaw cycles. This study was conducted to investigate the impact of mild subfreezing temperature and a freeze-thaw cycle on the ability of 22 winter wheat cultivars to tolerate freezing in saturated soil. Seedlings that had been acclimated at +4°C for 5 weeks in saturated soil were frozen to potentially damaging temperatures under three treatment conditions: (1) without any subzero pre-freezing treatment; (2) with a 16-h period at ?3°C prior to freezing to potentially damaging temperatures; and (3) with a freeze-thaw cycle of ?3°C for 24 h followed by +4°C for 24 h, followed by a 16-h period at ?3°C prior to freezing to potentially damaging temperatures. In general, plants that had been exposed to the freeze-thaw cycle survived significantly more frequently than plants frozen under the other two treatments. Plants that had been exposed to 16 h at ?3° (without the freeze-thaw cycle) before freezing to potentially damaging temperatures survived significantly more frequently than plants that were frozen to potentially damaging temperatures without a subzero pre-freezing treatment. These results indicated that cold-acclimated wheat plants actively acclimate to freezing stress while exposed to mild subfreezing temperatures, and further acclimate when allowed to thaw at +4°C for 24 h. The cultivar Norstar had the lowest LT₅₀ (temperature predicted to be lethal to 50% of the plants) of the 22 cultivars when frozen with either of the subzero pre-freezing treatments, but several cultivars had lower LT₅₀ scores than Norstar when frozen without a subzero pre-freezing treatment. We conclude it may be possible to improve winterhardiness of wheat grown in saturated soil by combining the ability to effectively respond to mild subzero pre-freezing temperatures with a greater ability to withstand freezing to damaging temperatures without a subzero pre-freezing exposure.     

Bacterial activity in South Pole snow

Large populations (200 to 5,000 cells ml(-1) in snowmelt) of bacteria were present in surface snow and firn from the south pole sampled in January 1999 and 2000. DNA isolated from this snow yielded ribosomal DNA sequences similar to those of several psychrophilic bacteria and a bacterium which aligns closely with members of the genus Deinococcus, an ionizing-radiation- and desiccation-resistant genus. We also obtained evidence of low rates of bacterial DNA and protein synthesis which indicates that the organisms were metabolizing at ambient subzero temperatures (-12 to -17 degrees C).     

Fast photochemical reactions of cytochrome P450 at subzero temperatures.

Several reactions of the cytochrome P450 multi-step cycle have been studied by fast light activation combined with subzero temperatures. A flash device was adapted to an Aminco-Chance DW 2 spectrophotometer equipped for subzero temperature thermostatisation. The first electron can be introduced into the cycle by non specific reducing agents such as reduced flavin mononucleotide (FMNH2) or methylviologen radical (MV.). This first reduction remains a fast process even at subzero temperatures. The oxy-compound Fe2+-O2 can thus be formed either directly from Fe2+ or via the photodissociation of the carboxy-ferro adduct. Fe2+-O2 is stable at subzero temperatures towards spontaneous autoxidation as well as further reduction by FMNH2 or MW.. In addition, the recombination of CO after flash photodissociation of Fe2+-CO was used to study in more details the specific behaviors of the purified microsomal cytochrome.     

Biodiversity of cryopegs in permafrost

This study describes the biodiversity of the indigenous microbial community in the sodium-chloride water brines (cryopegs) derived from ancient marine sediments and sandwiched within permafrost 100-120,000 years ago after the Arctic Ocean regression. Cryopegs remain liquid at the in situ temperature of -9 to -11 degrees C and make up the only habitat on the Earth that is characterized by permanently subzero temperatures, high salinity, and the absence of external influence during geological time. From these cryopegs, anaerobic and aerobic, spore-less and spore-forming, halotolerant and halophilic, psychrophilic and psychrotrophic bacteria, mycelial fungi and yeast were isolated and their activity was detected below 0 degrees C.     

A system for studying the effects of naturally-occurring subzero temperatures on winter barley

Thermostatically-controlled, electrical soil heating cables were used to examine the effects of subzero temperatures on winter barley growing in plots outdoors. Plants in plots without heating cables were exposed to naturally-occurring subzero temperatures (unheated), while those in corresponding plots with the cables (heated) were protected from such temperatures. Measurements of soil, plant and air temperatures in heated and unheated plots showed that the system can, at least with the temperatures encountered during the measurement periods, prevent plant temperature from falling below the temperature set on the thermostat. A field experiment involving different cultivars and sowing dates showed that subzero temperatures experienced did not significantly affect individual plant grain yield or the number of fertile ears produced per plant. However, small, but statistically significant, effects of naturally-occurring subzero temperatures were found in relation to the number of grains per ear, thousand grain weight and harvest index. The nature of these effects varied, and were dependent upon cultivar and/or sowing date. Subzero temperatures were also responsible for reducing the numbers of established plants in late-sown plots through soil heaving. Possible uses of the soil heating cable system for temperature-related studies in the Gramineae are discussed.     

Storage of Porcine Articular Cartilage at High Subzero Temperatures

Objective: Transplantation of osteochondral allograft tissue can treat large joint defects but is limited by tissue availability, surgical timing, and infectious disease transmission. Fresh allografts perform the best but requirements for infectious disease testing delay the procedure with subsequent decrease in cell viability and function. Hypothermic storage at lower temperatures can extend tissue banking time without loss of cell viability and, therefore, increase the supply of allograft tissue. This study investigated the effects of different cryoprotectant solutions on intact AC at various subzero temperatures. Design: 10 mm porcine osteochondral dowels were immersed for 30 minutes in various combinations of solutions [(XVIVO, propylene glycol (51% w/w), sucrose (46% w/w)] cooled to various subzero temperatures (−10, −15, and −20 °C), and held for 30 min. After warming, 70 μm slices were stained with membrane integrity dyes, viewed under fluorescence microscopy and cell recovery calculated relative to fresh controls. Results: Results demonstrated excellent cell recovery (>75%) at −10°C provided ice did not form. Excellent cell recovery (>70%) occurred at −15°C in solutions containing 51% propylene glycol but formation of extra-matrix ice in other solutions resulted in significant cell loss. All groups had <6% cell recovery at −20°C and propylene glycol did not provide a protective effect even though extra-matrix ice did not form Conclusions: These results suggest that extra-matrix ice plays an important role in cell damage during cryopreservation. Excellent cell recovery can be obtained after storage at subzero temperatures if ice does not form. Hypothermic preservation at high subzero temperatures may extend AC storage time in tissue banks compared to current techniques.     

Changes in the coordination geometry of the active-site metal during catalysis of benzylpenicillin hydrolysis by Bacillus cereus beta-lactamase II

Rapid-scanning stopped-flow spectroscopy (425-700 nm) has been used to study spectral changes in cobalt(II)-substituted Bacillus cereus beta-lactamase II during the binding and hydrolysis of benzylpenicillin. The experiments were carried out in aqueous solution over a temperature range of 3-20 degrees C. Three metallointermediates have been characterized by their visible absorption spectra. Two of them have visible absorption spectra identical with the intermediates ES1 and ES2 previously observed at subzero temperatures in a mixed aqueous/organic solvent [Bicknell, R., & Waley, S.G. (1985) Biochemistry 24, 6876-6887]. In addition, the branched kinetic pathway observed with the zinc(II) and cobalt(II) beta-lactamase II at subzero temperatures has been shown to occur with the cobalt(II)-substituted enzyme in aqueous solution at above-zero temperatures; thus, at pH 6.0 and 3 degrees C, the rate and equilibrium constants are readily determined for the reaction scheme: (Formula: see text). A third transient intermediate (called ES*) was found to precede ES1 in the pre-steady-state time period. The identity of the intermediates formed in aqueous solution with those previously observed in the cryostudy confirms that the mechanism is not changed either by the presence of an organic cosolvent or by subzero temperatures. Further characterization of ES1 and the steady-state intermediate ES2 at subzero temperatures, where their lifetime may be extended for up to several hours, has involved circular and magnetic circular dichroic studies. The magnetic circular dichroic spectra identify changes in the coordination sphere of the active-site metal during catalysis.(ABSTRACT TRUNCATED AT 250 WORDS)     

A new spectrophotometric cuvette holder for low temperature studies; Its application to the study of carbonmonoxyhemoglobin oxidation rate

A new spectrophotometric cuvette holder to be used for subzero temperature is described. The device is easily adaptable to a commercial spectrophotometer and it was checked down to --40 degrees C. Satisfactory mixing of the reactants contained in the cuvette at low temperatures is attained using a special stirrer and suitable solution volumes. The rate of carbonmonoxyhemoglobin oxidation by K3Fe(CN)6 at different subzero temperatures has been studied using this apparatus; the results are in agreement with the extrapolated data at room temperature.     

Subzero-temperature preservation of reactive fluids in the undercooled state. I. The reduction of potassium ferricyanide by potassium cyanide

Many reactions show enhanced rates at subzero temperatures due to freeze concentration. The reduction of potassium ferricyanide by potassium cyanide has been studied at subzero temperatures in both the undercooled and the frozen state. The pseudo-first-order rate constants calculated differ greatly from those in previous reports. A high degree of freeze concentration and supersaturation in frozen bulk solutions occurs. It has been clearly demonstrated that undercooled preservation provides a useful method for the long-term storage of reactive mixtures.     

Bacterial Activity at -2 to -20 degrees C in Arctic wintertime sea ice

Arctic wintertime sea-ice cores, characterized by a temperature gradient of -2 to -20 degrees C, were investigated to better understand constraints on bacterial abundance, activity, and diversity at subzero temperatures. With the fluorescent stains 4',6'-diamidino-2-phenylindole 2HCl (DAPI) (for DNA) and 5-cyano-2,3-ditoyl tetrazolium chloride (CTC) (for O(2)-based respiration), the abundances of total, particle-associated (>3- micro m), free-living, and actively respiring bacteria were determined for ice-core samples melted at their in situ temperatures (-2 to -20 degrees C) and at the corresponding salinities of their brine inclusions (38 to 209 ppt). Fluorescence in situ hybridization was applied to determine the proportions of Bacteria, Cytophaga-Flavobacteria-Bacteroides (CFB), and ARCHAEA: Microtome-prepared ice sections also were examined microscopically under in situ conditions to evaluate bacterial abundance (by DAPI staining) and particle associations within the brine-inclusion network of the ice. For both melted and intact ice sections, more than 50% of cells were found to be associated with particles or surfaces (sediment grains, detritus, and ice-crystal boundaries). CTC-active bacteria (0.5 to 4% of the total) and cells detectable by rRNA probes (18 to 86% of the total) were found in all ice samples, including the coldest (-20 degrees C), where virtually all active cells were particle associated. The percentage of active bacteria associated with particles increased with decreasing temperature, as did the percentages of CFB (16 to 82% of Bacteria) and Archaea (0.0 to 3.4% of total cells). These results, combined with correlation analyses between bacterial variables and measures of particulate matter in the ice as well as the increase in CFB at lower temperatures, confirm the importance of particle or surface association to bacterial activity at subzero temperatures. Measuring activity down to -20 degrees C adds to the concept that liquid inclusions in frozen environments provide an adequate habitat for active microbial populations on Earth and possibly elsewhere.     

Kinetics of Freezing Damage in Apple Bark and Pine Needles

The time course of freezing damage in pine needles and in bark of apple trees was followed at different subzero temperatures. From these data the killing rate by freezing was determined for trees which differed in degree of cold hardiness. The activation energy of the killing reaction was also calculated. The killing rate was lowest in cold-acclimated trees, but the activation energy of the killing reaction was very high indicating a high degree of structured water in the cells. Non-acclimated trees showed uniform low values of the activation energy of the killing reaction at all subzero temperatures studied. It is suggested that intracellular supercooling could be a part of the mechanism of frost protection in cold-acclimated apple trees within the – 30 to – 20°C range, but not in the –20 to –10°C range.     

Bacterial Activity in South Pole Snow

Large populations (200 to 5,000 cells ml⁻¹ in snowmelt) of bacteria were present in surface snow and firn from the south pole sampled in January 1999 and 2000. DNA isolated from this snow yielded ribosomal DNA sequences similar to those of several psychrophilic bacteria and a bacterium which aligns closely with members of the genus Deinococcus, an ionizing-radiation- and desiccation-resistant genus. We also obtained evidence of low rates of bacterial DNA and protein synthesis which indicates that the organisms were metabolizing at ambient subzero temperatures (−12 to −17°C).     

Proteomics of Colwellia psychrerythraea at subzero temperatures – a life with limited movement,flexible membranes and vital DNA repair

The mechanisms that allow psychrophilic bacteria to remain metabolically active at subzero temperatures result from form and function of their proteins. We present first proteomic evidence of physiological changes of the marine psychrophile Colwellia psychrerythraea 34H (Cp34H) after exposure to subzero temperatures (?1, and ?10°C in ice) through 8 weeks. Protein abundance was compared between different treatments to understand the effects of temperature and time, independently and jointly, within cells transitioning to, and being maintained in ice. Parallel [3H]‐leucine and [3H]–thymidine incubations indicated active protein and DNA synthesis to ?10°C. Mass spectrometry‐based proteomics identified 1763 proteins across four experimental treatments. Proteins involved in osmolyte regulation and polymer secretion were found constitutively present across all treatments, suggesting that they are required for metabolic success below 0°C. Differentially abundant protein groups indicated a reallocation of resources from DNA binding to DNA repair and from motility to chemo‐taxis and sensing. Changes to iron and nitrogen metabolism, cellular membrane structures, and protein synthesis and folding were also revealed. By elucidating vital strategies during life in ice, this study provides novel insight into the extensive molecular adaptations that occur in cold‐adapted marine organisms to sustain cellular function in their habitat.     

昆虫抗冻机理研究进展(英文)

大多数冰冻耐受性昆虫具有蛋白质／脂蛋白质或非溶性的晶体,它们相对地在较高温度下具有激活体内冰核的作用。最近已确证,许多昆虫肠道中正常的细菌和真菌是冰核激活菌丛。而对于非冰冻耐受性的昆虫,其存活是不允许体内冰的形成。它们在过冬过程中,关键是要调节体液的过冷却点,避免结冰。为了增加抗冻能力,非冰冻耐受性的过冬昆虫通过去除内源性冰核、积累低分子量的多元醇和糖类以及血淋巴中抗冻蛋白或抗冻肽的合成来降低体液的过冷却点。本文详尽综述了过冬昆虫抗冻机理的研究进展。     

Survival of step and ramp changes of temperature by the Queensland fruit fly, Dacus tryoni

ABSTRACT. Survival time at subzero temperatures is related to both long-term thermal history and the rate at which the insects are cooled. Insects cooled at one degree per hour survive for up to 3 times as long at a given test temperature than do insects cooled at 1C/min. Survival times are significantly shorter than times taken to freeze. Survival time at an extreme high temperature is related to long-term thermal history but the rate of heating makes no difference.     

PROGRESS IN THE RESEARCH ON MECHANISM OF INSECT COLD-HARDINESS

Abstract A number of freeze-tolerant insect species contain proteins/lipoproteins or insoluble crystals that are ice nucleating active at relatively high subzero temperatures. Recently ice nucleating active bacteria and fungi have been identified as normal flora in insect guts. However, most insects are unable to survive internal ice formation and the key factor in their overwintering survival is the regulation of the temperature at which they spontaneously freeze. To enhance their supercooling capacity overwintering insects eliminate endogenous ice nucleators, accumulate low molecular weight polyols and sugars, and synthesize hemolymph antifreeze proteins or peptides. The factors affecting the supercooling capacity of overwintering insects or the mechanism of cold-hardiness are discussed.