Cytochemical characterization of deoxyribonucleoprotein by UV-microspectrophotometry on heat denatured cell nuclei

Denaturation of double-stranded DNA into a single-stranded state can be studied by heating fixed cells attached to quartz slides and then determining the increase in nuclear UV-absorption at 265 nm by microspectrophotometry at room temperature. In order to prevent renaturation as the slides are cooled, formaldehyde is added to the solution in which heat denaturation is performed. The influence of formaldehyde concentration, duration of heating and ionic strength on the stability of DNA to heat denaturation has been examined. The standard method involves heating of ethanol/acetone fixed cells to temperatures between 22°C and 100°C in 0.15 M NaCl, 0.015 M sodium citrate containing 4% formaldehyde for 20 min followed by cooling to room temperature and mounting in glycerol.     

Maturation of porcine oocytes after cooling at the germinal vesicle stage

Maturation of porcine oocytes was examined after oocytes were cooled at the germinal vesicle stage. Cumulus-oocyte complexes (COCs) collected from medium-sized follicles were cooled at 24 degrees C or 4 degrees C for 5, 30 or 120 min in a solution with or without 1.5 M dimethylsulfoxide (DMSO). After rewarming, COCs were cultured in maturation medium at 39 degrees C, 5% CO2 in air for 44 h. Meiotic spindle organisation (by immunostaining and confocal microscopy), nuclear maturation (by orcein staining) and cytoplasmic maturation (by intracellular glutathione assay) of oocytes were examined after maturation. When COCs were cooled at 24 degrees C for various times in the medium without DMSO, a tendency to decreased spindle formation, nuclear maturation and cytoplasmic maturation was observed, but there was no statistical difference compared with controls. Addition of DMSO during cooling inhibited subsequent nuclear maturation and spindle formation. When COCs were cooled at 4 degrees C, both nuclear and cytoplasmic maturation as well as spindle formation were inhibited in most oocytes in a time-dependent manner. DMSO during cooling did not have any beneficial effect on subsequent oocyte maturation and spindle formation. These results suggest that porcine oocytes are very sensitive to a drop in the temperature before exposure to culture. Cooling oocytes before maturation inhibits their subsequent spindle organisation, nuclear and cytoplasmic maturation. Addition of DMSO to the cooling solution did not protect porcine oocytes from cooling-induced damage.     

Cryopreservation of swine colostrum-derived cells

Mesenchymal stromal cells (MSCs) have been demonstrated to possess anti-inflammatory and antimicrobial properties and are of interest in biotechnologies that will require cryopreservation. Recently, MSC-like cells were isolated from colostrum and milk. We used an interrupted slow freezing procedure to examine cryoinjury incurred during slow cooling and rapid cooling of MSC-like cells from swine colostrum. Cells were loaded with either dimethyl sulfoxide (Me₂SO) or glycerol, cooled to a nucleation temperature, ice-nucleated, and further cooled at 1 °C/min. At several temperatures along the cooling path, cells were either thawed directly, or plunged into liquid nitrogen for storage and later thawed. The pattern of direct-thaw and plunge-thaw responses was used to guide optimization of cryopreservation protocol parameters. We found that both 5% Me₂SO (0.65 M, loaded for 15 min on ice) or 5% glycerol (0.55 M, loaded for 1 h at room temperature) yielded cells with high post-thaw membrane integrity when cells were cooled to at least −30 °C before being plunged into, and stored in, liquid nitrogen. Cells cultured post-thaw exhibited osteogenic differentiation similar to fresh unfrozen control. Fresh and cryopreserved MSC-like cells demonstrated antimicrobial activity against S. aureus. Also, the antimicrobial activity of cell-conditioned media was higher when both fresh and cryopreserved MSC-like cells were pre-exposed to S. aureus. Thus, we were able to demonstrate cryopreservation of colostrum-derived MSC-like cells using Me₂SO or glycerol, and show that both cryoprotectants yield highly viable cells with osteogenic potential, but that cells cryopreserved with glycerol retain higher antimicrobial activity post-thaw.     

Studies on the Conditions Required for Optimum Recovery of Tetrahymena pyriformis Strain S (Phenoset A) after Freezing to and Thawing from –196 C

The toxicity of several cryoprotective agents was tested at room temperature (23 C) against Tetrahymena pyriformis strain S (Phenoset A) at different stages of the growth cycle. Polyvinylpyrrolidone (PVP-40) at 10% (v/v) concentration was without effect at any stage in the growth cycle, while 1.2 M glycerol immobilized the cells which were disrupted very shortly afterwards. The toxicity of 0.25 M glucose was largely independent of the position of the cells in the growth cycle, but the toxicity of 0.25 M sucrose and 1.4 M dimethylsulfoxide (DMSO) was most marked in late log- and stationary-phase cells. After log-phase cells had been equilibrated with 1.4 M DMSO for 1 hr, the number of cells surviving cooling at defined rates from 0.45 to 12 C/min decreased as the final temperature decreased from –30 to –60 C. A temperature of –53 C was found to be the optimum from which cells cooled at a given rate could be cooled rapidly to –196 C. Nevertheless, when cells were cooled at defined rates to –35, –45, or –53 C and then rapidly to –196 C the optimum rate of cooling to these temperatures was found to be 1 C/min. The optimum rate of cooling to –60 C prior to plunging into liquid nitrogen was found to be 2.7 C/min.     

Corneal tolerance of vitrifiable concentrations of glycerol.

Equilibration of corneas with sufficiently high concentrations of cryoprotectants to inhibit potentially damaging ice formation during cryopreservation has not yet been achieved. This study examined the effects on the structure and function of rabbit corneal endothelium of the low toxicity cryoprotectant glycerol. Corneas were exposed to concentrations ranging from 2.0 to 6.8 M glycerol in a Hepes-buffered Ringer's solution containing glutathione, adenosine, 5 mM sodium bicarbonate and 6% w/v bovine serum albumin. Endothelial function was assessed by monitoring corneal thickness during perfusion of the endothelial surface at 34 degrees C for 6 h. Endothelial structure was observed using specular microscopy during perfusion and scanning electron microscopy after perfusion. Corneas tolerated exposure to 2.0 and 3.4 M glycerol for 20 min at 4 and -5 degrees C, respectively. Tolerance of 4.8 M glycerol for 10 min at -10 degrees C was improved by decreasing the dilution temperatures. Ten-minute exposure to 6.1 and 6.8 M glycerol was tolerated at -15 degrees C. In all cases corneas initially showed signs of damage but endothelial function was regained following structural repair. Corneas exposed to 6.8 M glycerol and cooled below the glass transition temperature were nonfunctional after warming. Ice formation during warming was believed to be the cause of injury.     

Stabilization of frozen Lactobacillus delbrueckii subsp. bulgaricus in glycerol suspensions: Freezing kinetics and storage temperature effects

The interactions between freezing kinetics and subsequent storage temperatures and their effects on the biological activity of lactic acid bacteria have not been examined in studies to date. This paper investigates the effects of three freezing protocols and two storage temperatures on the viability and acidification activity of Lactobacillus delbrueckii subsp. bulgaricus CFL1 in the presence of glycerol. Samples were examined at -196 degrees C and -20 degrees C by freeze fracture and freeze substitution electron microscopy. Differential scanning calorimetry was used to measure proportions of ice and glass transition temperatures for each freezing condition tested. Following storage at low temperatures (-196 degrees C and -80 degrees C), the viability and acidification activity of L. delbrueckii subsp. bulgaricus decreased after freezing and were strongly dependent on freezing kinetics. High cooling rates obtained by direct immersion in liquid nitrogen resulted in the minimum loss of acidification activity and viability. The amount of ice formed in the freeze-concentrated matrix was determined by the freezing protocol, but no intracellular ice was observed in cells suspended in glycerol at any cooling rate. For samples stored at -20 degrees C, the maximum loss of viability and acidification activity was observed with rapidly cooled cells. By scanning electron microscopy, these cells were not observed to contain intracellular ice, and they were observed to be plasmolyzed. It is suggested that the cell damage which occurs in rapidly cooled cells during storage at high subzero temperatures is caused by an osmotic imbalance during warming, not the formation of intracellular ice.     

ENTRY OF BASIC MACROMOLECULES INTO BARLEY ROOTS

The entry of labelled calf-thymus histone, lysozyme, and poly-L-lysine into barley root tips was studied at concentrations which strongly inhibit root elongation. The macromolecules were suitably labelled and at these concentrations it was found, by autoradiography and fluorescence microscopy, that histone and lysozyme readily entered the roots and appeared to bind mainly to cell walls of the epidermis and cortex and to penetrate the cytoplasm occasionally. Except in cap cells, nuclei were rarely penetrated. Poly-L-lysine readily permeated cell walls and invaded cytoplasm and nuclei throughout the root tip. Some cells were damaged by contact with basic macromolecules, as evidenced by a change in appearance of protoplasts under phase contrast and by the inability of these same protoplasts to exclude labelled β-lactoglobulin. Such damage was restricted to cells in contact with the outer solution. Interior to the epidermis, development of many cells was inhibited without visible signs of damage. Evidence supports the conclusion that in the presence of polybasic polymers the integrity of cell membranes is altered, thereby allowing leakage of some cell constituents essential for normal development.     

Effects of hydrostatic pressure on the ultrastructure and leakage of internal substances in the yeast Saccharomyces cerevisiae

The structural damage to and leakage of internal substances from Saccharomyces cerevisiae 0–39 cells induced by hydrostatic pressure were investigated. By scanning electron microscopy, yeast cells treated at room temperature with pressuresbellw 400 MPa for 10 min showed a slight alteration in outer shape. Transmission electron microscopy, however, showed that the inner structure of the cell began to be affected, especially the nuclear membrane, when treated with hydrostatic pressure around 100 MPa at room temperature for 10 min; at more than 400–600 MPa, further alterations appeared in the mitochondria and cytoplasm. Furthermore, when high pressure treatment was carried out at — 20° C, the inner structure of the cells was severely damaged even at 200 MPa, and almost all of the nuclear membrane disappeared, although the fluorescent nucleus in the cytoplasm was visible by 4,6-diamidino-2-phenylindole (DAPI) staining. The structural damage of pressure-treated cells was accompanied by the leakage of internal substances. The efflux of UV-absorbing substances including amino acid pools, peptides, and metal ions increased with increase in pressure up to 600 MPa. In particular, amounts of individual metal ion release varied with the magnitude of hydrostatic pressures over 300 MPa, which suggests that the ions can be removed from the yeast cells separately by hydrostatic pressure treatment. Correspondence to: S. Shimada     

31P-NMR observation of the temperature and glycerol induced non-lamellar phase formation in wheat thylakoid membranes

³¹P-NMR spectra at 162 MHz were used to monitor phase changes of wheat thylakoid membranes as a function of temperature. At room temperature the³¹P-NMR line was a superposition of anisotropic component characteristic of phospholipid lamellar phase and isotropic line due to inorganic phosphorus or small membrane vesicles arising as an effect of preparation. For temperatures higher than +35 °C an increase of the isotropic component occurs, which is irreversible as the sample is cooled. For the temperatures between +55 °C and +60 °C the presence of the hexagonal phase cylinders is suggested, as monitored by phosphorus lineshape. However, the addition of glycerol stimulates a formation of the isotropic phase. The effect of reconstitution of freeze-dried thylakoid membranes by addition of water or water-glycerol medium to the sample was examined. As lyophilizate was gradually diluted, the increase of isotropic line component was observed. For thylakoid membranes suspended in D₂O at the highest dilution examined, the line contribution due to small membrane fragments is not greater than 50%, but in presence of glycerol, this contribution could reach 70%. This suggests that the presence of glycerol increases the formation of the small membrane particles as the thylakoid membrane is reconstituted from lyophilizate. The wheat thylakoid membranes reconstituted from lyophilizate show, in comparison to native membranes, the increased contribution of small membrane vesicles. Moreover, the³¹P -NMR spectra suggest the appearance of the hexagonal phase cylinders even at +50 °C.Abbreviations DGDG digalactosyldiacylglycerol - DLPC dilinoleoyl phosphatidylcholine - DLPE dilinoleoyl phosphatidylethanolamine - EDTA ethylenediamine-tetraacetic acid - MGDG monogalactosyldiacylglycerol - NMR nuclear magnetic resonance - PC phosphatidylcholine - PG phosphatidylglycerol - PSII photosystem II - TGDG trigalactosyldiacylglycerol - Tris Tris-(hydroxymethyl)-aminomethan - S/N signal to noise ratio     

Ultrastructural damage due to freezing followed by thawing in shoot meristem and leaf mesophyll cells of tall fescue (Festuca arundinacea Schreb.)

Tillers of Festuca arundinacea Schreb. were subjected to-8°C in a bath of methylated spirits for three-quarters of an hour. They were thawed at room temperature and some material taken from the shoot apical meristem and leaf blade for electron microscopy. Similar material was taken from control plants for electron microscopy. Nine tillers subjected to-8°C and thawed subsequently failed to regrow. Nine control tillers regrew. All the treated meristem cells and about half the treated leaf mesophyll cells were extensively altered. Their nuclei were contracted, organelles were swollen or partly disrupted, plasmalemma and nuclear membranes were broken or absent and vacuoles were sometimes disrupted. Strongly osmiophilic material accumulated in the vicinity of membranes. About half the leaf mesophyll cells differed from the control mesophyll cells only in having more spherosomes and narrower thylakoids. Parallels with other ultrastructural studies of stress damage and the indications the results give of possible primary damaging events are discussed.Abbreviations ER endoplasmic reticulum - G golgi body - M mitochondrion - Mb microbody - N nucleus - NM nuclear membrane - No nucleolus - P plasmatemma - Pg plastoglobuli - Pp proplastid - Pr polysomes - S spherosome - SOM strongly osmiophilic material - T tonoplast - Th thylakoids - V vacuole     

Coral larvae conservation: physiology and reproduction

Coral species throughout the world's oceans are facing severe environmental pressures. We are interested in conserving coral larvae by means of cryopreservation, but little is known about their cellular physiology or cryobiology. These experiments examined cryoprotectant toxicity, dry weight, water and cryoprotectant permeability using cold and radiolabeled glycerol, spontaneous ice nucleation temperatures, chilling sensitivity, and settlement of coral larvae. Our two test species of coral larvae, Pocillopora damicornis (lace coral), and Fungia scutaria (mushroom coral) demonstrated a wide tolerance to cryoprotectants. Computer-aided morphometry determined that F. scutaria larvae were smaller than P. damicornis larvae. The average dry weight for P. damicornis was 24.5%, while that for F. scutaria was 17%, yielding osmotically inactive volumes (V(b)) of 0.22 and 0.15, respectively. The larvae from both species demonstrated radiolabeled glycerol uptake over time, suggesting they were permeable to the glycerol. Parameter fitting of the F. scutaria larvae data yielded a water permeability 2 microm/min/atm and a cryoprotectant permeability = 2.3 x 10(-4) cm/min while modeling indicated that glycerol reached 90% of final concentration in the larvae within 25 min. The spontaneous ice nucleation temperature for F. scutaria larvae in filtered seawater was -37.8+/-1.4 degrees C. However, when F. scutaria larvae were chilled from room temperature to -11 degrees C at various rates, they exhibited 100% mortality. When instantly cooled from room temperature to test temperatures, they showed damage below 10 degrees C. These data suggest that they are sensitive to both the rate of chilling and the absolute temperature, and indicate that vitrification may be the only means to successfully cryopreserve these organisms. Without prior cryopreservation, both species of coral settled under laboratory conditions.     

Physical-Chemical Basis of the Protection of Slowly Frozen Human Erythrocytes by Glycerol

One theory of freezing damage suggests that slowly cooled cells are killed by being exposed to increasing concentrations of electrolytes as the suspending medium freezes. A corollary to this view is that protective additives such as glycerol protect cells by acting colligatively to reduce the electrolyte concentration at any subzero temperature. Recently published phase-diagram data for the ternary system glycerol-NaCl-water by M. L. Shepard et al. (Cryobiology, 13:9-23, 1976), in combination with the data on human red cell survival vs. subzero temperature presented here and in the companion study of Souzu and Mazur (Biophys. J., 23:89-100), permit a precise test of this theory. Appropriate liquidus phase-diagram information for the solutions used in the red cell freezing experiments was obtained by interpolation of the liquidus data of Shepard and his co-workers. The results of phase-diagram analysis of red cell survival indicate that the correlation between the temperature that yields 50% hemolysis (LT₅₀) and the electrolyte concentration attained at that temperature in various concentrations of glycerol is poor. With increasing concentrations of glycerol, the cells were killed at progressively lower concentrations of NaCl. For example, the LT₅₀ for cells frozen in the absence of glycerol corresponds to a NaCl concentration of 12 weight percent (2.4 molal), while for cells frozen in 1.75 M glycerol in buffered saline the LT₅₀ corresponds to 3.0 weight percent NaCl (1.3 molal). The data, in combination with other findings, lead to two conclusions: (a) The protection from glycerol is due to its colligative ability to reduce the concentration of sodium chloride in the external medium, but (b) the protection is less than that expected from colligative effects; apparently glycerol itself can also be a source of damage, probably because it renders the red cells susceptible to osmotic shock during thawing.     

Ultrastructural effects of pressure stress to the nucleus in Saccharomyces cerevisiae: a study by immunoelectron microscopy using frozen thin sections

Abstract The effects of hydrostatic pressure on subcellular structures, particularly the nucleus, of Saccharomyces cerevisiae were investigated by immunoelectron microscopy. Cells were treated with hydrostatic pressure from 0.1 to 400 MPa for 10 min at room temperature. Frozen thin sections of the cells revealed that spindle pole bodies disappeared at 100 MPa. At 150 MPa, the deposition of gold panicles for anti α-tubulin was noticed in the nucleus, although the filamentous structure of microtubules was lost. At 200 MPa, fewer gold particles were scattered in the nucleus and the nuclear membrane in several portions was also observed to be open at 300 MPa. These results show that elements of the nuclear division apparatus were susceptible to pressure stress, particularly spindle pole bodies and microtubules. The damage to spindle pole bodies, microtubules, and nuclear membrane caused by pressure stress was followed by the inhibition of nuclear division. After the release of pressure, the spindle pole bodies and microtubules of pressurized cells at below 200 MPa regained their normal appearance at 24 h.     

Changes of viability and composition of the Escherichia coli flora in faecal samples during long time storage

Long-time storage of faecal samples is necessary for investigations of intestinal microfloras. The aim of the present study was to evaluate how the viability and the composition of the Escherichia coli flora are affected in faecal samples during different storage conditions. Four fresh faecal samples (two from calves and two from infants) were divided into sub-samples and stored in four different ways: with and without addition of glycerol broth at -20 degrees C and at -70 degrees C. The viability and the phenotypic diversity of the E. coli flora in the sub-samples were evaluated after repeated thawings and after storage during 1 year. The samples stored for 1 year without thawing were also kept at room temperature for 5 days and subsequently analysed. According to phenotyping (PhP analysis) of 32 isolates per sample on day 0, all four samples contained two dominating strains of E. coli each, and between one and eight less common strains. Samples that were stored at -70 degrees C in glycerol broth showed equal or even higher bacterial numbers as the original samples, even after repeated thawings, whereas samples stored at -20 degrees C showed a considerably lower survival rate, also with addition of glycerol. Sub-samples containing glycerol broth that were kept at room temperature after storage for 1 year showed a clear increase in the number of viable cells as well as in diversity. The diversities in each sub-sample showed a tendency to decrease after several thawings as well as after storage. Generally, the E. coli populations in samples stored at -20 degrees C were less similar to the population of the original sample than that in samples stored at -70 degrees C. Samples that had been mixed with glycerol broth had an E. coli flora more similar to that in the original sample than those without glycerol broth. Furthermore, the sub-samples that were kept at room temperature after storage for 1 year generally were more similar to the original samples than if they were processed directly. We conclude that for long time storage of faecal samples, storage at -70 degrees C is preferable. If samples have to be thawed repeatedly, addition of glycerol is preferable both for samples stored at -70 degrees C and for samples stored at -20 degrees C. Our data also have indicated that when E. coli isolates from faecal samples are selected for, e.g. analysis of virulence factors, it is necessary to pick several isolates per sample in order to obtain at least one isolate representing the dominating strain(s).     

Smooth muscle cell injury after cryopreservation of human thoracic aortas

The cryopreservation protocol we use for arterial reconstructive surgery has been studied to evaluate smooth muscle cell (SMC) structural integrity and viability before implantation. Samples of human thoracic aortas (HTA) were harvested from five multi-organ donors. Sampling included unfrozen and cryopreserved specimens. Cryopreservation was performed using RPMI with human albumin and 10% Me(2)SO in a controlled-rate freezing apparatus. Thawing was accomplished by submerging bags in a water bath (39 degrees C) followed by washings in cooled saline. In situ cell preservation as investigated by light and transmission electron microscopy showed that SMCs from cryopreserved HTA had nuclear and cytoplasmic changes. A TUNEL assay, performed to detect DNA fragmentation in situ, showed increased SMC nuclear positivity in cryopreserved HTA when compared to unfrozen samples. 7-AAD flow cytometry assay of cells derived from cryopreserved HTA showed that an average of 49+/-16% cells were unlabeled after cryopreservation. Organ cultures aimed to study cell ability to recover cryopreservation damage showed a decreasing number of SMCs from day 4 to day 15 in cryopreserved HTA. In conclusion, the cryopreservation protocol applied in this study induces irreversible damage of a significant fraction of arterial SMCs.     

Stabilization of Frozen Lactobacillus delbrueckii subsp. bulgaricus in Glycerol Suspensions: Freezing Kinetics and Storage Temperature Effects

The interactions between freezing kinetics and subsequent storage temperatures and their effects on the biological activity of lactic acid bacteria have not been examined in studies to date. This paper investigates the effects of three freezing protocols and two storage temperatures on the viability and acidification activity of Lactobacillus delbrueckii subsp. bulgaricus CFL1 in the presence of glycerol. Samples were examined at −196°C and −20°C by freeze fracture and freeze substitution electron microscopy. Differential scanning calorimetry was used to measure proportions of ice and glass transition temperatures for each freezing condition tested. Following storage at low temperatures (−196°C and −80°C), the viability and acidification activity of L. delbrueckii subsp. bulgaricus decreased after freezing and were strongly dependent on freezing kinetics. High cooling rates obtained by direct immersion in liquid nitrogen resulted in the minimum loss of acidification activity and viability. The amount of ice formed in the freeze-concentrated matrix was determined by the freezing protocol, but no intracellular ice was observed in cells suspended in glycerol at any cooling rate. For samples stored at −20°C, the maximum loss of viability and acidification activity was observed with rapidly cooled cells. By scanning electron microscopy, these cells were not observed to contain intracellular ice, and they were observed to be plasmolyzed. It is suggested that the cell damage which occurs in rapidly cooled cells during storage at high subzero temperatures is caused by an osmotic imbalance during warming, not the formation of intracellular ice.     

Zernike phase contrast cryo-electron tomography of whole mounted frozen cells

Cryo-electron tomography of frozen hydrated cells has provided cell biologists with an indispensable tool for delineating three-dimensional arrangements of cellular ultrastructure. To avoid the damage induced by electron irradiation, images of frozen hydrated biological specimens are generally acquired under low-dose conditions, resulting in weakly contrasted images that are difficult to interpret, and in which ultrastructural details remain ambiguous. Zernike phase contrast transmission electron microscopy can improve contrast, and can also fix a fatal problem related to the inherent low contrast of conventional electron microscopy, namely, image modulation due to the unavoidable setting of deep defocus. In this study, we applied cryo-electron tomography enhanced with a Zernike phase plate, which avoids image modulation by allowing in-focus setting. The Zernike phase contrast cryo-electron tomography has a potential to suppress grainy background generation. Due to the smoother background in comparison with defocus phase contrast cryo-electron tomography, Zernike phase contrast cryo-electron tomography could yield higher visibility for particulate or filamentous ultrastructure inside the cells, and allowed us to clearly recognize membrane protein structures.     

Freezing monolayers of cells without gap junctions

Cells in monolayers have been reported to be more susceptible to freezing injury than the same cell type frozen in dispersed suspensions. There appears to be an enhanced susceptibility to intracellular freezing in the monolayers, which is thought to be facilitated by the presence of gap junctions allowing the spread of ice between neighbouring cells. MDCK Type II cells do not form gap junctions in monolayer culture. When frozen at rates of 0.2 to 10 degrees C/min, monolayers in 10% (v/v) propane-1,2-diol or dimethyl sulphoxide showed little influence of cooling rate on survival. This suggested that, in the absence of gap junctions, cells in monolayers did not display enhanced susceptibility to intracellular freezing. In contrast, however, monolayers frozen in glycerol showed a marked increase in cell damage when cooled at rates higher than 0.5 degrees C/min. This does not necessarily counter the suggestion that lack of gap junctions mitigates intracellular freezing as there is evidence that glycerol may itself promote intracellular freezing.     

Depression of the ice-nucleation temperature of rapidly cooled mouse embryos by glycerol and dimethyl sulfoxide.

The temperature at which ice formation occurs in supercooled cytoplasm is an important element in predicting the likelihood of intracellular freezing of cells cooled by various procedures to subzero temperatures. We have confirmed and extended prior indications that permeating cryoprotective additives decrease the ice nucleation temperature of cells, and have determined some possible mechanisms for the decrease. Our experiments were carried out on eight-cell mouse embryos equilibrated with various concentrations (0-2.0 M) of dimethyl sulfoxide or glycerol and then cooled rapidly. Two methods were used to assess the nucleation temperature. The first, indirect, method was to determine the in vitro survival of the rapidly cooled embryos as a function of temperature. The temperatures over which an abrupt drop in survival occurs are generally diagnostic of the temperature range for intracellular freezing. The second, direct, method was to observe the microscopic appearance during rapid cooling and note the temperature at which nucleation occurred. Both methods showed that the nucleation temperature decreased from - 10 to - 15 degrees C in saline alone to between - 38 degrees and - 44 degrees C in 1.0-2.0 M glycerol and dimethyl sulfoxide. The latter two temperatures are close to the homogeneous nucleation temperatures of the solutions in the embryo cytoplasm, and suggest that embryos equilibrated in these solutions do not contain heterogeneous nucleating agents and are not accessible to any extracellular nucleating agents, such as extracellular ice. The much higher freezing temperatures of cells in saline or in low concentrations of additive indicate that they are being nucleated by heterogeneous agents or, more likely, by extracellular ice.     

Partially irreversible cold-induced lipid phase transitions in mammalian sperm plasma membrane domains: freeze-fracture study

In an effort to investigate the nature of the cellular injury caused when mammalian spermatozoa are cooled prior to cryopreservation, the occurrence of thermal phase transitions amongs the lipid components of the sperm plasma membrane was investigated by the use of freeze-fracture electron microscopy. The mechanisms by which glycerol and egg yolk exert protective effects during semen cooling and freezing were also examined. Ram and blackbuck spermatozoa, maintained at 30 degrees C prior to fixation at this temperature, exhibited randomly distributed intramembranous particles over the acrosomal, postacrosomal, and flagellar regions of the plasma membrane. In contrast, spermatozoa fixed at 5 degrees C after slow cooling to this temperature exhibited particle clustering over the postacrosomal region of the head as well as over the tail. These effects were not influenced by the presence of egg yolk or glycerol during the cooling procedure, although these substances protected the spermatozoa against loss of motility. Particle clustering over the sperm tail, induced by the slow cooling process, was found to be only partially reversible. The extensive areas of particle-free lipid, noted to result from the cooling procedure, were absent if the spermatozoa were rewarmed to 30 degrees C; however, the original distribution of particles was not restored and numerous small particle-free domains persisted. It is proposed that this type of irreversible change within the sperm plasma membrane may contribute to the loss of motility and fertility suffered by spermatozoa after cooling and freezing. Furthermore, it is suggested that protective substances such as egg yolk may exert their effects by countering these deleterious changes, rather than by preventing their occurrence.