Electron microscopic observation of the aggregation of membrane proteins in human erythrocyte by melittin

Human erythrocytes and erythrocyte ghost membranes were treated with native and modified melittins, up to 250 nmol/mg membrane protein. Native melittin induced aggregation of intramembranous particles (IMPs, observed by freeze-fracture electron microscopy), and created large, smooth bilayer areas devoid of IMP. The degree of IMP aggregation increased with increasing concentration of melittin, corresponding to hemolysis results. Membrane ghosts were slightly more susceptible to IMP aggregation than membranes on intact cells. The potency of inducing IMP aggregation was ranked in the order of: native melittin greater than acetylated melittin greater than succinylated melittin = 0. The concentration range of melittin which caused IMP aggregation corresponded to that which caused the immobilization of band 3 proteins as detected by measurement of rotational mobility by transient dichroism (Dufton et al. (1984) Eur. J. Biophys. 11, 17-24). Because both IMP aggregation and band 3 protein immobilization decreased with decreasing positive charge of the melittins used, the nature of melittin-protein interaction is likely to be at least in part electrostatic in the case of human erythrocyte membranes. Possible roles of IMP aggregation and the consequent creation of 'exposed' bilayer areas in the cytotoxic reaction of melittins are discussed.     

Structural changes in erythrocyte membranes during cooling studied by a spin probe method

Peculiarities of structural changes in erythrocyte membranes during freezing (from -20 degrees to -50 degrees) were studied by electron paramagnetic resonance method using spin-labelled derivative of stearic acid-5-doxylstearate. It was established that membranes underwent a number of structural reconstructions due to the temperature decrease and water freezing-out. Differences were found in temperature dependences that characterize lipid ordering during probe insertion into membranes of native erythrocytes, white ghosts, and liposomes from total lipids of erythrocyte membranes. The data obtained indicate the impairment in the structure of lipid components and lipid-protein interactions in erythrocyte membranes during cooling.     

Basic investigations on the freezing of human lymphocytes

Human lymphocytes were frozen at constant cooling rates in the range 2.4 to 1000 degrees K/min without cryoadditive on the cold stage of a thermally defined cryomicroscope. The volume loss due to water efflux was quantified optically for the cooling rates 2.4, 12, 48, and 120 degrees K/min. The likelihood of the formation of intracellular ice was determined as function of the cooling rate. Intracellular crystallization temperatures were obtained for ice formation during both cooling and rewarming. A theoretical analysis of the cell volume loss during freezing was compared to the experimental data and used for an indirect determination of the water permeability of the cells. A relative optimum of the cooling rate is predicted theoretically under the assumption of a critical level of intracellular salt concentration near the eutectic temperature. The dependence of survival and cooling rate was determined cryomicroscopically by simultaneously applying the FDA/EB fluorescence viability test. The optimal cooling rate of about 35 degrees K/min was also found for 2-ml samples frozen within the range of cooling rates of interest. The results show that for freezing in physiological saline solution (1) the optimum of the cooling rate is theoretically predictable, (2) cryomicroscopical data are significant for freezing of samples of larger volume, and (3) the lethal type of intracellular crystallization is cooling rate dependent and distinguishable from innocuous types.     

Cooling and freezing damage platelet membrane integrity.

Cytoskeletal rearrangements and a membrane lipid phase transition (liquid crystalline to gel) occur in platelets on cooling from 23 to 4 degrees C. A consequence of these structural alterations is irreversible cellular damage. We investigated whether platelet membrane integrity could be preserved by (a) previously studied combinations of a calcium chelator (EGTA) and microfilament stabilizer (cytochalasin B) with apparent benefit in protecting platelets from cooling injury or (b) agents of known benefit in protecting membranes and proteins from freezing injury. Platelet function and activation before and after freezing or cooling were measured by agglutination with ristocetin, aggregation with thrombin or ADP, platelet-induced clot retraction (PICR), and expression of P-selectin. Platelets were loaded with 10 nM fluorescein diacetate. After freezing or cooling, the preparations were centrifuged and the supernatant was measured for fluorescein. For cooling experiments, fresh platelets were chilled at 4 degrees C for 1 to 21 days with or without the combination of 80 microM EGTA/AM and 2 microM cytochalasin B (EGTA/AM-CytoB) and then warmed rapidly at 37 degrees C. For freezing experiments, 5% dimethyl sulfoxide (Me2SO) or 5 mM glycerol were added to fresh platelets. The preparations were then frozen at -1 degrees C/min to -70 degrees C and then thawed rapidly at 37 degrees C. Platelet membrane integrity, as measured by supernatant levels of fluorescein, correlated inversely with platelet function. Chilling platelets at 4 degrees C with EGTA/AM-CytoB showed a gradual loss of membrane integrity, with maximum loss reached on day 7. The loss of membrane integrity preceded complete loss of function as demonstrated by PICR. In contrast, platelets chilled without these agents had complete loss of membrane integrity and function after 1 day of storage. Freezing platelets in Me2SO resulted in far less release of fluorescein than did freezing with or without other cryoprotectants (P < 0.001). This result correlated with enhanced function as demonstrated by PICR and supports earlier observations that Me2SO protects platelet membranes from freezing injury. Release of fluorescein into the surrounding medium reflected loss of membrane integrity and function in both cooled and frozen platelets. Membrane cytoskeletal rearrangements are linked to membrane changes during storage. These results may be generally applicable to the study of platelet storage.     

Cryopreservation of human platelets with propane-1,2-diol

The preceding papers in this series have described techniques that permit the introduction and removal of propane-1,2-diol (propylene glycol, PG) with human platelets, in concentrations up to 2 M, without producing serious damage. These methods have now been used in attempts to cryopreserve platelets, with assessment of survival by the hypotonic stress response and ADP-induced aggregation. PG concentrations of 0.5, 1.0, 2.0, and 2.5 M and cooling rates between 0.4 and 100 degrees C/min were studied. The maximum response in the hypotonic stress test was no better than 17% and the greatest ADP-induced aggregation was only 6%; these results were obtained with 0.5 M PG, a cooling rate of 14 degrees C/min, and rapid warming (approximately 150 degrees C/min). The failure of PG concentrations greater than 0.5 M to improve survival was unexpected. When cooling was interrupted at progressively lower temperatures and function assessed, it was possible to relate the extent of damage to temperature and then, with the aid of phase diagrams, it was possible to show that, irrespective of the initial concentration of PG, the extent of damage was closely correlated with the concentration of PG produced at the minimum temperature used. It is concluded that the toxicity of PG increases so steeply with the increasing concentration produced by the separation of ice during freezing that this effect is sufficient to counteract the cryoprotective action of this solute for platelets.     

Temperature dependence of the survival of human erythrocytes frozen slowly in various concentrations of glycerol.

One widely accepted explanation of injury from slow freezing is that damage results when the concentration of electrolyte reaches a critical level in partly frozen solutions during freezing. We have conducted experiments on human red cells to further test this hypothesis. Cells were suspended in phosphate-buffered saline containing 0-3 M glycerol, held for 30 min at 20 degrees C to permit solute permeation, and frozen at 0.5 or 1.7 degrees C/min to various temperatures between -2 and -100 degrees C. Upon reaching the desired minimum temperature, the samples were warmed at rates ranging from 1 to 550 degrees C/min and the percent hemolysis was determined. The results for a cooling rate of 1.7 degrees C/min indicate the following: (a) Between 0.5 and 1.85 M glycerol, the temperature yielding 50% hemolysis (LT50) drops slowly from -18 to -35 degrees C. (b) The LT50's over this range of concentrations are relatively independent of warming rate. (c) With glycerol concentrations of 1.95 and 2.0 M, the LT50 drops abruptly to -60 degrees C and to below -100 degrees C, respectively, and becomes dependent on warming rate. The LT50 is lower with slow warming at 1 degree C/min than with rapid. With still higher concentrations (2.5 and 3.0 M), there is no LT50, i.e., more than 50% of the cells survive freezing to-100 degrees C. Results for cooling at 0.5 degrees C/min in 2 M glycerol were similar except that the LT50s were some 10-20 degrees C higher. A companion paper (Rall et al., Biophys. J. 23:101-120, 1978) examines the relation between survival and the concentrations of salts produced during freezing.     

Ultrastructure of reconstituted rat liver microsomal membranes and cytochrome b5- or P-450-containing proteoliposomes

Thin sectioning and freeze-fracture electron microscopy have been used to show that it is possible to obtain topologically closed vesicles by means of reconstitution of rat liver microsomal membrane "ghosts." The reconstitution by 15 hr dialysis resulted in the formation of vesicles with intramembrane particles (IMP) while after 40 hr dialysis no IMP were observed in the membranes. The protein/lipid ratio and functional activity of NADPH- and NADH-linked enzyme systems were similar in both cases. Cytochrome P-450 (LM2) was incorporated into liposomes of different composition (protein: lipid ratio--1:200). IMP were observed only when the incorporation of cytochrome P-450 was performed in the presence of detergent Emulgen 913 as specific additive to the initial protein-lipid-sodium cholate mixture or in the course of incubation of proteoliposomal suspensions at 37 degrees C. After the incorporation of cytochrome b5 into azolectin liposomes vesicular membranes contain IMP if the incorporated membrane protein: lipid ratio is at least 1:50. Pronase-induced splitting off of a 11 kDa heme-containing fragment of cytochrome b5 did not affect IMP content. The conditions of IMP formation in reconstituted membranes and in microsomal ghosts are discussed.     

Improvement of parameters of freezing medium and freezing protocol for bull sperm using two osmotic supports

The aim of this study was to improve the freezing protocol of bull sperm, by investigating the influence on sperm viability after freeze/thawing of different freezing medium components, as well as the effect of cooling rates in the different stages of the cooling protocol, in single factor experiments. The experimental variables were: (1) salt-based versus a sugar-based medium (Tris versus sucrose); (2) glycerol concentration; (3) detergent (Equex) concentration; (4) presence of bicarbonate; (5) rate of cooling from 22 degrees C to holding temperature (CR1); (6) holding temperature (HT); (7) rate of cooling from holding temperature to -6 degrees C (CR2); (8) rate of cooling from -10 to -100 degrees C (CR3). All experiments were performed using five bulls per experiment (three ejaculates per bull). Sperm motility after freezing and thawing was assessed by CASA system, and sperm membrane integrity was assessed by flow cytometry. Sucrose-based medium did not offer a clear significant benefit compared to Tris medium. The concentration of Equex that gave the best results in Tris-based media group and sucrose-based media group was in a range between 2-7 and 4-7 g/l, respectively. In both media groups, a glycerol concentration of 800 mM was the best in any post-thaw viability parameters. In the Tris media group, the presence of bicarbonate had a negative effect on sperm viability. CR1 and CR2 had no significant effect on any of the post-thaw sperm viability parameters, but a CR1=0.2 degrees C/min and CR2=4 degrees C/min appeared to give better results in both media. The holding temperature (HT) that gave the best results was found to be in the range of 5-9 degrees C. There was a significant disadvantage of using a low CR3 of 10 degrees C/min, while 150 degrees C/min appeared to be the best cooling rate for either medium.     

Nucleation and growth of ice crystals inside cultured hepatocytes during freezing in the presence of dimethyl sulfoxide.

A three-part, coupled model of cell dehydration, nucleation, and crystal growth was used to study intracellular ice formation (IIF) in cultured hepatocytes frozen in the presence of dimethyl sulfoxide (DMSO). Heterogeneous nucleation temperatures were predicted as a function of DMSO concentration and were in good agreement with experimental data. Simulated freezing protocols correctly predicted and explained experimentally observed effects of cooling rate, warming rate, and storage temperature on hepatocyte function. For cells cooled to -40 degrees C, no IIF occurred for cooling rates less than 10 degrees C/min. IIF did occur at faster cooling rates, and the predicted volume of intracellular ice increased with increasing cooling rate. Cells cooled at 5 degrees C/min to -80 degrees C were shown to undergo nucleation at -46.8 degrees C, with the consequence that storage temperatures above this value resulted in high viability independent of warming rate, whereas colder storage temperatures resulted in cell injury for slow warming rates. Cell damage correlated positively with predicted intracellular ice volume, and an upper limit for the critical ice content was estimated to be 3.7% of the isotonic water content. The power of the model was limited by difficulties in estimating the cytosol viscosity and membrane permeability as functions of DMSO concentration at low temperatures.     

Thermally defined cryomicroscopy and thermodynamic analysis in lymphocyte freezing

A cryomicroscope is described which provides the possibility of quantifying the volume loss of cells during freezing, detection of intracellular ice formation during cooling and warming, as well as the determination of viability as function of (constant) cooling rates. The basic mechanisms occurring in cryopreservation have been studied with this system using the human lymphocyte suspended in pure saline as a biological model system; experimentally observed exosmosis during freezing is compared to predictions from a thermodynamic model. Cell volume loss during freezing has been determined experimentally for cooling rates of 2.4, 12, 48, and 120 degrees K/min. Exosmosis also was calculated corresponding to various assumptions regarding the concentration dependence of the hydraulic permeability of the cells. Further calculations of exosmosis are performed for determining the effects of the initial cell volume. The temperatures and transition cooling rate ranges of intracellular ice formation have been determined. On the basis of exosmosis and a lethal level of intracellular salt concentration, a hypothetical relative optimum of the cooling rate is theoretically predicted and compared to the experiments.     

Structure and thermotropic phase behaviour of detergent-resistant membrane raft fractions isolated from human and ruminant erythrocytes

Detergent-resistant membrane raft fractions have been prepared from human, goat, and sheep erythrocyte ghosts using Triton X-100. The structure and thermotropic phase behaviour of the fractions have been examined by freeze-fracture electron microscopy and synchrotron X-ray diffraction methods. The raft fractions are found to consist of vesicles and multilamellar structures indicating considerable rearrangement of the original ghost membrane. Few membrane-associated particles typical of freeze-fracture replicas of intact erythrocyte membranes are observed in the fracture planes. Synchrotron X-ray diffraction studies during heating and cooling scans showed that multilamellar structures formed by stacks of raft membranes from all three species have d-spacings of about 6.5 nm. These structures can be distinguished from peaks corresponding to d-spacings of about 5.5 nm, which were assigned to scattering from single bilayer vesicles on the basis of the temperature dependence of their d-spacings compared with the multilamellar arrangements. The spacings obtained from multilamellar stacks and vesicular suspensions of raft membranes were, on average, more than 0.5 nm greater than corresponding arrangements of erythrocyte ghost membranes from which they were derived. The trypsinization of human erythrocyte ghosts results in a small decrease in lamellar d-spacing, but rafts prepared from trypsinized ghosts exhibit an additional lamellar repeat 0.4 nm less than a lamellar repeat coinciding with rafts prepared from untreated ghosts. The trypsinization of sheep erythrocyte ghosts results in the phase separation of two lamellar repeat structures (d=6.00; 5.77 nm), but rafts from trypsinized ghosts produce a diffraction band almost identical to rafts from untreated ghosts. An examination of the structure and thermotropic phase behaviour of the dispersions of total polar lipid extracts of sheep detergent-resistant membrane preparations showed that a reversible phase separation of an inverted hexagonal structure from coexisting lamellar phase takes place upon heating above about 30 degrees C. Non-lamellar phases are not observed in erythrocytes or detergent-resistant membrane preparations heated up to 55 degrees C, suggesting that the lamellar arrangement is imposed on these membrane lipids by interaction with non-lipid components of rafts and/or that the topology of lipids in the erythrocyte membrane survives detergent treatment.     

Survival of Frozen Mycoplasmas

Cooling to -70 C killed a higher percentage of Acholeplasma laidlawii and Mycoplasma mycoides var. capri cells than cooling to -20 C. However, to preserve cell viability for prolonged periods storage at -70 C was much more preferable. The percentage of cells surviving freezing could be increased by increasing the initial cell concentration or by the addition of dimethyl sulfoxide or glycerol as cryoprotective agents. In the presence of 1.5 M of any one of these agents survival rates of up to 100% could be obtained. The optimal cooling rates for maximal survival of A. laidlawii under the experimental conditions tested were 11 C/min for cooling to -20 C and about 15 C/min for cooling to -70 C. Increasing the warming rate during thawing from 0.6 to 67 C/min increased survival by 3 log. Oleic acid enrichment of A. laidlawii membrane lipids, or reduction in the cholesterol content of M. mycoides var. capri membranes, increased the percentage of organisms surviving freezing. Hence, the composition of membrane lipids appears to have a marked influence on the susceptibility of mycoplasmas to freezing injury.     

Divalent cation-induced aggregation of chromaffin granule membranes.

Divalent cations induce the aggregation of chromaffin granule ghosts (CG membranes) at millimolar concentrations. Monovalent cations produce the same effect at 100-fold higher concentrations. The kinetics of the dimerization phase were followed by light-scattering changes observed in stopped-flow rapid mixing experiments. The rate constant for Ca2+-induced dimerization (kapp) is 0.86-1.0 x 10(9) M-1sec-1, based on the "molar" vesicle concentration. This value is close to the values predicted by theory for the case of diffusion-controlled reaction (7.02 x 10(9) M-1sec-1), indicating that there is no energy barrier to dimerization. Arrhenius plots between 10 degrees and 42 degrees C support this; the activation energy observed, +4.4 Kcal, is close to the value (4.6-4.8 Kcal) predicted for diffusion control according to theory. Artificial vesicles prepared from CG lipids were also found to have cation-induced aggregation, but the rates (values of kapp) were less than 1/100 as large as those with native CG membranes. Also, significant differences were found with respect to cation specificity. It is concluded that the slow rates are due to the low probability that the segments of membrane which approach will be matched in polar head group composition and disposition. Thus large numbers of approaches are necessary before matched segments come into aposition. The salient features of the chromaffin granule membrane aggregation mechanism are as follows: (a) In the absence of cations capable of shielding and binding, the membranes are held apart by electrostatic repulsion of their negatively charged surfaces. (b) The divalent and monovalent cation effects on aggregation are due to their ability to shield these charges, allowing a closer approach of the membrane surfaces. (c) The major determinants of the aggregation rates of CG membranes are proteins which protrude from the (phospholipid) surface of the membrane and serve as points of primary contact. Transmembrane contact between these proteins does not require full neutralization of the surface charge and surface potential arising from the negatively charged phospholipids. (d) After contact between proteins is established, the interaction between membranes can be strengthened through transmembrane hydrogen bonding of phosphatidyl ethanolamine polar head groups, divalent cation-mediated salt bridging, and segregation of phosphatidylcholine out of the region of contact.     

Freezing injury to erythrocytes. II. Morphological alterations of cell membranes.

Morphological alterations of human red blood cell membranes were examined with the cells containing different concentrations of glycerol being subjected to rapid rates of cooling, approximately 10⁴ and 10⁵ °C/min, and subsequent rewarming. Small membrane defects, similar to holes, were observed in specimens frozen with and without 10% glycerol. Various degrees of roughness were found on the surface of the cells at all freezing rates tested. The membrane alterations were reduced with increasing glycerol concentration, although roughness also appeared on the surface of the cells in 30% glycerol suspensions, frozen rapidly, and rewarmed to ?80 or ?60 °C. The cell membrane surface texture correlated with the growth of intra- and extracellular ice particles. There was also a positive correlation between these alterations and post-thaw hemolysis. It is concluded, therefore, that morphological alterations appearing on the erythrocyte membranes may be a manifestation of freezing damage.     

Freeze-thaw damage in isolated lobster sarcoplasmic reticulum membranes: A model system for membrane damage

Sarcoplasmic reticulum membrane vesicles (SRV), isolated from the abdominal muscle of Maine lobsters, were put through a freeze-thaw cycle in order to study membrane freezing damage on a molecular basis, The major membrane protein in SRV is a (Ca²⁺ − Mg²⁺) ATPase capable of accumulating Ca²⁺ with the concomitant hydrolysis of ATP, After being frozen and thawed in the presence of NaCl, the SRV showed an increased ATPase activity and a decreased ability to accumulate Ca²⁺. The degree of increased ATPase activity and decreased Ca²⁺ accumulation was dependent upon the NaCl concentration (damage increased with increased NaCl concentration) and cooling rate (damage was only observed at slow cooling rates, i.e., less than 10 °C/min). Slow thawing rates also increased the amount of damage.The freeze-thaw damage of the SRV membranes is probably not due to osmotic shock, since the vesicles are quite resistant to osmotic stress and are highly permeable to small molecules and monovalent ions. Incubation of the SRV in 2 NaCl at 22 °C has no effect on Ca²⁺ accumulation whereas freezing in 0.25 NaCl totally abolishes their ability to take up Ca²⁺. Thus, a combination of salt and low temperature is necessary for damage. The freeze-thaw damage can be largely prevented by the addition of DMSO, glycerol, or PVP. The factors above have implications for the storage of tissue or membranes for subsequent analysis of membrane-bound enzymes. The SRV mimic the behavior of cells in their response to cooling and thawing rates, salts and cryoprotectants.     

A freeze-etch study of the effects of extracellular freezing on cellular membranes of wheat

Seedlings of Triticum aestivum L. cv. Lennox were grown in different environments to obtain different hardiness. Pieces of laminae and leaf bases were slowly cooled to sub-zero temperatures and the damage caused was assessed by an ion-leakage method. Comparable pieces of tissue were slowly cooled to temperatures between 2° and-14°C and were then freeze-fixed and freeze-etched. Membranes generally retained their lamellar structures indicated by the abundance of typical membrane fracture faces in all treatments, and some membrane fracture faces had patches which lacked the usual scattering of intramembranous particles (IMP). These IMP-free areas were present in the plasma membrane of tissues given a damaging freezing treatment, but were absent from the plasma membrane of room-temperature controls, of supercooled tissues, and of tissues given a non-damaging freezing treatment. The frequency of IMP-free areas and the proportion of the plasma membrane affected increased with increasing damage. In the most damaged tissue (79% damage; leaf bases exposed to-8°C), 20% of the plasma membrane was IMP-free. The frequencies of IMP at a distance from the IMP-free areas were unaffected by freezing treatments. There was a patchy distribution of IMP in other membranes (nuclear envelope, tonoplast, thylakoids, chloroplast envelope), but only in the nuclear envelope did it appear possible that their occurrence coincided with damage. The IMP-free areas of several membranes were sometimes associated together in stacks. Such membranes lay both to the outside and inside of the plasma membrane, indicating that at least some of the adjacent membrane fragments arose as a result of membrane reorganization induced by the damaging treatment. Occasional views of folded IMP-free plasma membrane tended to confirm this conclusion. The following hypothesis is advanced to explain the damage induced by extracellular freezing. Areas of plasma membrane become free of IMP, probably as a result of the freezing-induced cellular dehydration. The lipids in these IMP-free patches may be in the fluid rather than the gel phase. The formation of these IMP-free patches, especially in the plasma membrane, initiates or involves proliferation and possibly fusion of membranes, and during or following this process, the cells become leaky.Abbreviations EF exoplasmatic fracture face - IMP intramembranous particles - PF protoplasmatic fracture face     

Differences among dogs in response of their spermatozoa to cryopreservation using various cooling and warming rates

Spermatozoa collected from the caudae epididymides of 16 dogs of various breeds were suspended in an isotonic salt solution (DIMI medium) containing 0.6 M glycerol, frozen in liquid nitrogen, and their "survival" was measured after thawing. In the first experimental series, duplicate samples of spermatozoa from each of 11 dogs were cooled at rates of 0.5, 3, 11, 58, or 209 degrees C/min, stored in liquid nitrogen, and the frozen samples warmed at approximately 830 or at 33 degrees C/min. Sperm "survival" was judged by microscopic assessments of motility and of membrane integrity, the latter as assayed with Fertilight, a double fluorescent stain. Motility of frozen spermatozoa that were thawed rapidly, averaged for 11 dogs, was low at low rates, increased to a maximum at 11 degrees C/min, and then decreased significantly at higher rates (P<0.01). This inverted V-shaped curve was also observed with slow thawing, although the apparent optimum cooling rate ranged from 3 to 11 degrees C/min. The integrity of sperm plasma membranes showed a similar dependence on cooling rate, although the percentages of spermatozoa with intact plasma membranes were higher than the percentages of motile spermatozoa. Motility of spermatozoa, as a function of cooling rate, varied considerably from male to male (P<0.01), whereas membrane integrity was much more consistent among the 11 dogs. In the second experimental series with spermatozoa from 5 dogs, motility of spermatozoa frozen at 0.5 degrees C/min and warmed at 3.6, 33, 140, or 830 degrees C/min also exhibited an inverted V-shaped survival curve, in this case as a function of warming rate. In summary, high survival of frozen-thawed canine epididymal spermatozoa depended on both cooling and warming rates, but spermatozoa from each dog exhibited their own sensitivity to cooling and warming rates.     

Thermal shock and dilution shock as the causes of freezing injury

We suggest that during slow freezing, cellular membranes are altered by the hypertonic solutions produced. This alteration in itself does not cause membrane leakage of normally impermeant solutes but it renders the cells susceptible to solute leakage on the application of a stress, which is provided during freezing by the reduction in temperature (thermal shock) and during thawing by dilution (dilution shock).During slow freezing the effects of cooling rate changes are due to the different times available for the hypertonic solutions to affect the membrane. At a given cooling rate cryoprotective agents reduce the effect on the cells at each temperature during freezing perhaps by reducing the ionic strength. The thermal shock stress during cooling and the dilution shock during thawing thus damages the cells less. With rapid freezing, there is insufficient time for these effects to take place during cooling, which allows the cells to reach low temperatures without thermal shock damage. However, the presence of extracellular ice and the formation of intracellular ice provide hypertonic conditions that render the cells liable to dilution shock on thawing. The slower the rate of thawing of rapidly cooled cells the greater will be the damage from this dilution shock.     

Suprazero cooling rate,rather than freezing rate,determines post thaw quality of rhesus macaque sperm

Sperm become most sensitive to cold shock when cooled from 37 °C to 5 °C at rates that are too fast or too slow; cold shock increases the susceptibility to oxidative damage owing to its influence on reactive oxygen species (ROS) production, which are significant stress factors generated during cooling and low temperature storage. In addition, ROS may be a main cause of decreased motility and fertility upon warming. They have been shown to change cellular function through the disruption of the sperm plasma membrane and through damage to proteins and DNA. The objective of this study was to determine which cryopreservation rates result in the lowest degree of oxidative damage and greatest sperm quality. In the rhesus model, it has not been determined whether suprazero cooling or subzero freezing rates causes a significant amount of ROS damage to sperm. Semen samples were collected from male rhesus macaques, washed, and resuspended in TEST-yolk cryopreservation buffer to 100 × 10⁶ sperm/mL. Sperm were frozen in 0.5-mL straws at four different combinations of suprazero and subzero rates. Three different suprazero rates were used between 22 °C and 0 °C: 0.5 °C/min (slow), 45 °C/min (medium), and 93 °C/min (fast). These suprazero rates were used in combination with two different subzero rates for temperatures 0 °C to −110 °C: 42 °C/min (medium) and 87 °C/min (fast). The different freezing groups were as follows: slow-med (SM), slow-fast (SF), med-med (MM), and fast-fast (FF). Flow cytometry was used to detect lipid peroxidation (LPO), a result of ROS generation. Motility was evaluated using a computer assisted sperm motion analyzer. The MM and FF treated sperm had less viable (P < 0.0001) and motile sperm (P < 0.001) than the SM, SF, or fresh sperm. Sperm exposed to MM and FF treatments demonstrated significantly higher oxidative damage than SM, SF, or fresh sperm (P < 0.05). The SM- and SF-treated sperm showed decreased motility, membrane integrity, and LPO compared with fresh semen (P < 0.001). Slow cooling from room temperature promotes higher membrane integrity and motility post thaw, compared with medium or fast cooling rates. Cells exposed to similar cooling rates with differing freezing rates were not different in motility and membrane integrity, whereas comparison of cells exposed to differing cooling rates with similar freezing rates indicated significant differences in motility, membrane integrity, and LPO. These data suggest that sperm quality seems to be more sensitive to the cooling, rather than freezing rate and highlight the role of the suprazero cooling rate in post thaw sperm quality.     

Cryopreservation of cornea: a low cooling rate improves functional survival of endothelium after freezing and thawing

AIM: To investigate the influence of low cooling rates on endothelial function and morphology of corneas frozen with propane-1,2-diol (PROH). METHODS: Rabbit corneas, mounted on support rings, were exposed to 1.4mol/l (10% v/v) PROH, seeded to initiate freezing, and cooled at 0.2 or 1 degrees C/min to -80 degrees C. Corneas were frozen immersed in liquid or suspended in air. After being held overnight in liquid nitrogen, corneas were warmed at 1 or 20 degrees C/min. After stepwise removal of the cryoprotectant, the ability of the endothelium actively to control corneal hydration was monitored during normothermic perfusion. Morphology was assessed after staining with trypan blue and alizarin red S, and by specular microscopy during perfusion. RESULTS: Functional survival was achieved only after slow cooling (0.2 degrees C/min) with the cornea immersed in the cryoprotectant medium, and rapid warming (20 degrees C/min). These conditions also gave the best morphology after freezing and thawing. CONCLUSION: Cooling rates lower than those typically applied to cornea improved functional survival of the endothelium. This result is in accord with previous observations showing the benefit of low cooling rates for cell monolayers [CryoLetters 17 (1996) 213-218].