Effect of protective agents on amount and repair of sublethal freeze--thaw damage in mammalian cells.

Glycerol, DMSO, and HES are able to reduce by a factor of 2 the sublethal damage produced in mammalian cells after one freeze-thaw cycle. When sublethal freeze-thaw damage is already present, DMSO and HES are able to prevent about half of this damage from becoming lethal when a second freeze-thaw cycle is applied. Glycerol is only able to do this if dilution shock is avoided by thawing the cells into medium containing glycerol. The cells can repair 100% of this sublethal damage and do so in 2–3 hr at 37 °C in suspension. The data imply that the sites protected by DMSO, HES, and glycerol are the same as the sites repaired by the cells. The results also suggest that cells stop progressing in the cell cycle while repairing sublethal freeze-thaw damage.     

Large unit red cell cryopreservation with hydroxyethyl starch.

Full units of red blood cells frozen with 14% hydroxyethyl starch (HES) yield cell recoveries near 97% and saline stabilities greater than 80%. Potassium leaves the cells during the freeze-thaw cycle and increases the extracellular concentration of this ion to near 35 meq/l. Unwashed cells (those with plasma present) and saline washed cells yield similar results. Storage of the thawed red cells at 4 °C for up to 48 hr causes little change in the cells.Examination by electron microscopy of samples from thawed units reveals some red cells with portions of their membrane missing. We believe this represents damage from the freeze-thaw cycle and also that all free supernatant hemoglobin does not arise from completely lysed cells.     

Effects of culture conditions on the in vitro infection of fibroblasts by Candida albicans.

The effects of yeast culture age, carbon source, growth temperature, and germ-tube inducers on adherence to primary fibroblast cultures was studied in conjunction with the determination of adherence-mediated mammalian cell damage by measuring chromium-51 release from fibroblast monolayers. The results indicated that yeast culture age affected adherence only when the yeasts were grown at 37 degrees C, not after growth at 28 degrees C. At 37 degrees C, quantitatively fewer exponential-phase, glucose- or galactose-grown yeasts adhered to fibroblasts than did yeasts that were in lag or stationary phases. The reduced adherence correlated with less chromium-51 release and reduced germ-tube formation. The addition of germ-tube inducers, such as N-acetyl-D-glucosamine or serum, to exponential-phase yeasts caused an increase in germ-tube formation with a concomitant increase in yeast adherence and release of chromium-51 from the monolayers. Exponential-phase galactose-grown yeasts were more responsive to serum-induced germ-tube formation, germ-tube elongation, and fibroblast adherence than were exponential-phase glucose-grown yeasts. In addition, exponential-phase galactose-grown yeasts caused more chromium-51 release from monolayers in the presence of serum than did glucose-grown yeasts. Overall, conditions that enhanced germ-tube formation and elongation resulted in greatest adherence-mediated damage to the monolayers.     

Effects of pre- and post-thaw cell-to-cell contact and trypsin on survival of freeze-thaw damaged mammalian cells

When multicellular spheroids, which simulate small bits of tissue, are exposed to a freeze-thaw (FT) cycle, the survival of the individual cells in the spheroid is higher if the cells of the spheroid are trypsinized and plated as single cells immediately after thawing than if the spheroid is allowed to remain intact for 4 hr and then trypsinized for plating. The results imply either that cell-to-cell contact inhibits repair of potentially lethal damage (PLD) or that accumulation of additional lethal or sublethal damage during the post-thaw period for cells in contact is taking place. Pre- and post-FT trypsinization of single cells indicate that trypsin does not enhance repair of PLD caused by a FT cycle.     

Morphological and physiological changes induced by high hydrostatic pressure in exponential- and stationary-phase cells of Escherichia coli: relationship with cell death

The relationship between a loss of viability and several morphological and physiological changes was examined with Escherichia coli strain J1 subjected to high-pressure treatment. The pressure resistance of stationary-phase cells was much higher than that of exponential-phase cells, but in both types of cell, aggregation of cytoplasmic proteins and condensation of the nucleoid occurred after treatment at 200 MPa for 8 min. Although gross changes were detected in these cellular structures, they were not related to cell death, at least for stationary-phase cells. In addition to these events, exponential-phase cells showed changes in their cell envelopes that were not seen for stationary-phase cells, namely physical perturbations of the cell envelope structure, a loss of osmotic responsiveness, and a loss of protein and RNA to the extracellular medium. Based on these observations, we propose that exponential-phase cells are inactivated under high pressure by irreversible damage to the cell membrane. In contrast, stationary-phase cells have a cytoplasmic membrane that is robust enough to withstand pressurization up to very intense treatments. The retention of an intact membrane appears to allow the stationary-phase cell to repair gross changes in other cellular structures and to remain viable at pressures that are lethal to exponential-phase cells.     

Morphological and Physiological Changes Induced by High Hydrostatic Pressure in Exponential- and Stationary-Phase Cells of Escherichia coli: Relationship with Cell Death

The relationship between a loss of viability and several morphological and physiological changes was examined with Escherichia coli strain J1 subjected to high-pressure treatment. The pressure resistance of stationary-phase cells was much higher than that of exponential-phase cells, but in both types of cell, aggregation of cytoplasmic proteins and condensation of the nucleoid occurred after treatment at 200 MPa for 8 min. Although gross changes were detected in these cellular structures, they were not related to cell death, at least for stationary-phase cells. In addition to these events, exponential-phase cells showed changes in their cell envelopes that were not seen for stationary-phase cells, namely physical perturbations of the cell envelope structure, a loss of osmotic responsiveness, and a loss of protein and RNA to the extracellular medium. Based on these observations, we propose that exponential-phase cells are inactivated under high pressure by irreversible damage to the cell membrane. In contrast, stationary-phase cells have a cytoplasmic membrane that is robust enough to withstand pressurization up to very intense treatments. The retention of an intact membrane appears to allow the stationary-phase cell to repair gross changes in other cellular structures and to remain viable at pressures that are lethal to exponential-phase cells.     

Photosynthetic response of the Antarctic moss Polytrichum alpestre Hoppe to low temperatures and freeze-thaw stress

The effect of low temperatures and freeze-thaw stress on photosynthetic carbon exchange in an Antarctic population of the turf-forming moss species Polytrichum alpestre Hoppe was investigated using infra-red gas analysis. Photosynthetic recovery from freezing was found to depend on the absolute depth of low temperature experienced. Repeated freeze-thaw cycles caused a greater reduction in gross photosynthesis than constant freezing over the same period of time suggesting that the freeze-thaw event itself, and not just cold temperatures, causes damage. The frequency of freeze-thaw events was significant: freeze-thaw cycles every 12 h inflicted more damage than freezethaw cycles every 24 or 48 h. Most damage occurred during the first cycle; relatively little was recorded during subsequent cycles. At +10°C, gross CO₂ flux was directly proportional to moss water content between 0.3 and 3.5 g·g^–1 dry mass. Moss samples with a low water content withstood freeze-thaw cycles to -5, -10 and-20°C better than samples with a high water content indicating that desiccation in the field may improve survival at low temperatures. Microclimate data for field populations of Polytrichum alpestre at Signy Island suggest that sub-zero temperatures and freeze-thaw stress may act as limiting factors on the species' distribution and viability, particularly when the insulating effect of snow cover is small.     

Assessment of cellular damage during cooling to −196 °C using radiochemical markers

The release of ten radiochemical markers from MRC-5 and CHO cells after cooling at various rates and thawing from temperatures in the range of 0 to ?196 °C was measured. Many of these radiochemicals had specific sites of attachment on or within the cell and the aim was to determine the effect of freeze-thaw stresses on various parts of the cell. Cell death during cooling and thawing was, in most instances, accompanied by osmotic damage and loss of cytoplasmic constituents. Significant damage to the cell membrane occurred only after the cell was already dead and was related to the disruption of cells killed at higher temperatures and to osmotic stress during rewarming. The release of cations and other cytoplasmic markers was correlated to cell shrinkage and dehydration. The data were used to assess the relative effects of some of the proposed damaging factors in freeze-thaw injury (thermal shock, ice damage, dilution shock, etc.). CHO cells showed a much higher survival rate and release of cations after fast cooling than MRC-5 cells. This, and additional circumstantial information, indicated that CHO cells survived freeze-thaw cycles better than MRC-5 cells because they are able to dehydrate more readily, even at fast cooling rates.     

Why is Deinococcus radiodurans so resistant to ionizing radiation?

When exponential-phase cultures of Deinococcus radiodurans are exposed to a 5000-Gray dose of gamma radiation, individual cells suffer massive DNA damage. Despite this insult to their genetic integrity, these cells survive without loss of viability or evidence of mutation, repairing the damage by as-yet-poorly-understood mechanisms.     

Structure of the nucleoid in cells of Streptococcus faecalis

The structure of the nucleoid of Streptococcus faecalis (ATCC 9790) was examined and compared in the unfixed and fixed states by immersive refractometry and electron microscopy. It appears from these studies that the nucleoid structure is much more centralized in unfixed chloramphenicol-treated (stationary-phase) cells than it is in cells in the exponential phase of growth. The more dispersed configuration of the exponential-phase nucleoid could be preserved by fixation in glutaraldehyde, but not in Formalin or in osmium tetroxide. One important factor in explaining these differences in preservation is that glutaraldehyde (but not Formalin or osmium tetroxide) can rapidly cross-link the amino groups of macromolecules in cells. It was also observed that osmium tetroxide resulted in a preferential breakdown of nascent ribonucleic acid. These results are interpreted as indicating that glutaraldehyde is able to stabilize the exponential-phase nucleoid before it assumes the more central appearance seen in osmium tetroxide- and Formalin-fixed cells. These results are discussed in terms of the proposed organization of the exponential-phase nucleoid in unfixed cells.     

The effect of fluidity of membrane lipids on freeze-thaw survival of yeast.

One approach to studying the importance of membranes in freeze-thaw damage is to modify their composition and study the effect of this modification on survival after freeze-thaw damage. Fatty acid desaturase auxotrophs of yeast cells were enriched with two fatty acids having substantially different physical properties thus resulting in cells whose membranes had very different physical properties. The fatty acids were stearolic acid (mp = +45 °C) and linolenic acid (mp = ?10 °C). Electron-spin resonance studies showed that membranes containing the latter fatty acid were more fluid than those containing stearolic acid. The yeast were grown under either anaerobic or aerobic conditions. In the former case, the mitochondria appear as membraneous shells with little, if any, internal membrane structure; thus, the plasma and tonoplast membranes are the primary membranes. Yeast cells grown under these conditions survived freezethaw damage (?196 °C) significantly better when the fatty acid composition was mainly stearolic acid rather than linolenic acid. The absolute survival depended on the freezing rate and the differences in survival became small at fast rates. With yeast cells grown under aerobic conditions, when functional mitochondria are formed, the pattern in freeze-thaw survival reversed; cells with γ-linolenic acid in their membranes survived significantly better than cells containing stearolic acid.     

Cryopreservation of the cyclic 3',5'-adenosine monophosphate-dependent protein kinase from bovine cardiac muscle

A method for the cryogenic storage of the cAMP-dependent protein kinase from bovine cardiac muscle is described. The catalytic parameters, kcat, KM, and kcat/KM are used to assess the activity of the enzyme both prior and subsequent to the freeze-thaw cycle. The enzyme is stored in cryogenic vials at -196 degrees C in liquid nitrogen. Complete retention of catalytic activity is dependent upon a rapid and efficient freeze-thaw cycle and the use of morpholinepropanesulfonic acid as the buffer. In addition, this buffer appears to eliminate the KCl- or NaCl-induced damage typically observed for enzymes stored at low temperature in phosphate buffer. As a result, morpholinepropanesulfonic acid may prove to be a more appropriate cryopreservation buffer than phosphate when the presence of salt is required for enzyme solubility or stability.     

DNA damage measured using the alkaline elution assay depends on time between subculturing of cells and irradiation

In experiments utilizing the alkaline filter elution assay for radiation-induced DNA damage we observed an unexpected dependence of hypoxic dose-response curves on the length of time V79 cells were in exponential growth between subculturing and irradiation. Dose-response curves for DNA from cells irradiated in air were identical regardless of whether the exponential-phase cells had been subcultured 24 or 48 h prior to irradiation, but cells irradiated in hypoxia 24 h after subculture displayed a dose-response curve for DNA damage which was two times steeper than that obtained for cells irradiated in hypoxia 48 h after subculture. Possible mechanisms for this effect are discussed.     

Relationship between membrane damage and cell death in pressure-treated Escherichia coli cells: differences between exponential- and stationary-phase cells and variation among strains

The relationship between membrane damage and loss of viability following pressure treatment was examined in Escherichia coli strains C9490, H1071, and NCTC 8003. These strains showed high, medium, and low resistance to pressure, respectively, in stationary phase but similar resistance to pressure in exponential phase. Loss of membrane integrity was measured as loss of osmotic responsiveness or as increased uptake of the fluorescent dye propidium iodide. In exponential-phase cells, loss of viability was correlated with a permanent loss of membrane integrity in all strains, whereas in stationary-phase cells, a more complicated picture emerged in which cell membranes became leaky during pressure treatment but resealed to a greater or lesser extent following decompression. Strain H1071 displayed a very unusual pressure response in stationary phase in which survival decreased to a minimum at 300 MPa but then increased at 400 to 500 MPa before decreasing again. Membranes were unable to reseal after treatment at 300 MPa but could do so after treatment at higher pressures. Membrane damage in this strain was thus typical of exponential-phase cells under low-pressure conditions but of stationary-phase cells under higher-pressure conditions. Heat shock treatment of strain H1071 cells increased pressure resistance under low-pressure conditions and also allowed membrane damage to reseal. Growth in the presence of IPTG (isopropyl-beta-D-thiogalactopyranoside) increased resistance under high-pressure conditions. The mechanisms of inactivation may thus differ at high and low pressures. These studies support the view that membrane damage is an important event in the inactivation of bacteria by high pressure, but the nature of membrane damage and its relation to cell death may differ between species and phases of growth.     

Relative effects of cooling and warming rates on mammalian cells during the freeze-thaw cycle

The relative roles of cooling and warming rates on cell survival during a freeze-thaw cycle were investigated. Basically the faster the warming rate, the better the cells survive. One of the factors influencing this is the extended phase transition period at the slower thawing rates. The warming rate had a significant effect on cell damage and recovery, but this was not as great as comparative changes in the cooling rate were. This investigation also showed that under certain freeze-thaw conditions there was a lack of correlation between the two methods used for quantifying cell recovery (RI) and cell damage (PCR) as measured by radiochromate release. The analysis of the relationship between RI and PCR showed that PCR could be used to measure both lethal and nonlethal damage and enabled a clearer interpretation of cellular damage during cooling and thawing to be made.     

Suppression of ATP in Candida albicans by imidazole and derivative antifungal agents

Several antifungal agents, at concentrations of 10 micrograms/ml, were shown to suppress ATP concentrations very rapidly in intact cells and spheroplasts of Candida albicans. The highest ATP-suppressing activity was shown by the highly lipophilic imidazole derivatives difonazole, clotrimazole, econazole, isoconazole, miconazole, oxiconazole and tioconazole, which all caused a reduction of cellular ATP content of more than 50% in 10 min. Relatively hydrophilic imidazole derivatives such as ketoconazole were essentially inactive in the test, as were the triazole derivatives fluconazole, ICI 153066, itraconazole and terconazole, and 5-fluorocytosine. Amphotericin B and terbinafine possessed intermediate ATP-suppressing activity, and the dose-response and pH-response curves for these compounds suggested their mechanism of ATP suppression differed from that of the active imidazole derivatives. ATP suppression by azole antifungals did not involve leakage of ATP from the cells and the effect was entirely abrogated by the presence of serum. Intact cells and spheroplasts of yeast-form and hyphal-form C. albicans were generally equally sensitive to ATP suppression, but stationary-phase cells of both morphological forms were less sensitive than exponential-phase cells. The extent of ATP suppression was significantly reduced in stationary-phase yeast cells of a C. albicans strain with known resistance to azole antifungals, but exponential-phase cells of resistant and susceptible strains were equally sensitive. The effect is tentatively ascribed to membrane damage caused directly by the antifungals.     

Cold Shock Lethality and Injury in Clostridium perfringens

Several observations have been made in regard to cold shock lethality of Clostridium perfringens: (i) loss of viability was not consequence of exposure of the cells to air; (ii) stationary-phase cells were much more resistant to cold shock at 4 C than exponential-phase cells; (iii) at 4 C 96% of an initial population of exponential-phase cells was killed upon cold shock and 95% of the remaining population was killed within 90 min of continued exposure at 4 C; (iv) the minimal temperature differential for detectable cold shock lethality was between 17 and 23 C, and the maximum beyond which lethality was not appreciably increased was between 28 and 33 C. Up to 75% of viable cold-shocked cells were injured, as demonstrated by cold shocking late exponential-phase cells at 10 C and using differential plating procedure for recovery. Repair of injury was temperature dependent, and occurred in a complex medium and 0.1% peptone but not water. Nalidixic acid, chloramphenicol, and rifampin did not inhibit repair of injury.     

Salt treatment induces frost hardiness in leaves and isolated thylakoids from spinach

Frost hardiness of spinach (Spinacia oleracea L.) leaves was increased by high concentrations of NaCl in the hydroponic culture medium. Freezing damage was determined by measurement of slow chlorophyll fluorescence quenching after freezing of leaves. Both the osmolality of the leaf sap and forst hardiness of the leaves were linearly correlated with the salt concentration in the hydroponic culture medium. Freezing damage occurred, irrespective of the extent of frost hardening, when dehydration of cells during extracellular ice formation decreased cellular volume to approximately 14% of the volume of unfrozen cells. The resistance of isolated, washed thylakoids against mechanical and chemical damage by freezing was investigated. Chemical damage by freezing caused by salt accumulation was measured as release of chloroplast coupling factor (CF1; EC 3.6.1.3), and mechanical damage was measured as release of the lumenal protein plastocyanin from the membranes during an in-vitro freeze-thaw cycle. Isolated thylakoids from salt-treated frost-hardy spinach and those from plants hardened under natural conditions did not exhibit improved tolerance against chemical freezing stress exerted by high salt concentrations. They were, however, more hardy than thylakoids from unhardened control leaves against mechanical damage by freezing.Abbreviation CF1 peripheral part of chloroplast coupling factor ATPase     

Yeast-phase cell cycle of the polymorphic fungus Wangiella dermatitidis.

The yeast-phase cell cycle of Wangiella dermatitidis was studied using flow microfluorimetry and the deoxyribonucleic acid (DNA) synthesis inhibitor hydroxyurea (HU). Exposure of exponential-phase yeastlike cells to 0.1 M HU for 3 to 6 h resulted in the arrest of the cells in DNA synthesis and produced a nearly homogeneous population of unbudded cells. Treatment of the yeast-phase cells with HU for 9 h or longer resulted in the accumulation of the cells predominantly as budded forms having either a single nucleus in the mother cell or a single nucleus arrested in the isthmus between the mother cell and the daughter bud. Exposure of unbudded stationary-phase cells to 0.1 M HU resulted in the accumulation of the cells in the same phenotypes. Analysis by flow microfluorimetry and cell counts of HU-inhibited mithramycin-stained cells indicated that the eventual progress of HU-inhibited cells from unbudded to the two budded forms was due to the limited continuation of the growth sequence of the cell cycle even in the absence of DNA synthesis, nuclear division, and in some cases nuclear migration. On the basis of these observations and the results of flow microfluorimetric analysis of exponential-phase cells, a map of the yeast-phase cell cycle was constructed. The cycle appears to consist of two independent sequences of events, a budding growth sequence and a DNA division sequence. The nuclear division cycle of yeast-phase cells growing exponentially with a 4.5-h generation time is composed of a G1 interval of 148 min, as S phase of 16 min, and a G2 plus M interval of 107 min.     

Investigation of the initial stages of interaction of the bacteriumAzospirillum brasilense with wheat seedling roots: Adsorption and root hair deformation

The initial stages of colonization of wheat roots by cells ofAzospirillum brasilense strains 75 and 80 isolated from soils of the Saratov oblast were studied. The adsorption of azospirilla on root hairs of soft spring wheats rapidly increased in the first hours of incubation, going then to a plateau phase. Within the first 15 h of incubation, exponential-phase cells were adsorbed more intensively than stationary-phase cells. Conversely, stationary-phase cells were adsorbed more intensively than exponential-phase cells, if the period of azospirilla incubation with the wheat roots was extended. As the time of incubation increased, the attachment of azospirilla to the wheat roots became stronger. The effect of cell attachment to root hairs was strain-dependent; the number of adsorbed cells of a given strain of azospirilla was greater in the case of host wheat cultivars. The deformation of wheat root hairs was affected by the polysaccharide-containing complexes isolated from the capsular material of azospirilla. The suggestion is made that common receptor systems are involved in the adsorption of azospirilla on roots and in root hair deformation