Cryopreservation of functionally active blood nuclear cell membranes at −80°C

Structural and functional changes in cytoplasmic membranes and cell organelles play a crucial role in cell damage at low temperatures. These changes are reversible if adequate measures are taken to protect biological membranes against cold-induced injuries. In this study, the possibility of cryopreservation of membrane integrity by long-term storage of samples at low temperatures (?80°C) is demonstrated using differentiated nuclear blood cells as an example. In addition to classical methods, freezing of human leukocyte suspensions was carried out in a novel nontoxic cryoprotecting solution under a newly developed exponential freezing program based on the use of cryoprotectors and repair additives. This program ensures the same cryopreservation effect as the linear program, but is economically more efficient and less labor-consuming. After exponential freezing in a cryoprotecting solution and storage at ?80°C, blood leukocytes retain their eosin resistance (91 ± 5% of thawed leukocytes) and phagocytic activity (76.7 ± 14.7% of thawed neutrophils) for 180 days. The novel technology of cell cryopreservation employing a nontoxic cryoprotecting solution, exponential freezing program, and fast thawing is economically efficient, easy to perform and applicable to storage of any animal cells.     

Effect of different cryopreservation protocols on cytoskeleton and gap junction mediated communication integrity in feline germinal vesicle stage oocytes

Oocyte cryopreservation in carnivores can significantly improve assisted reproductive technologies in animal breeding and preservation programs for endangered species. However, the cooling process severely affects the integrity and the survival of the oocyte after thawing and may irreversibly compromise its subsequent developmental capability.In the present study, two different methods of oocyte cryopreservation, slow freezing and vitrification, were evaluated in order to assess which of them proved more suitable for preserving the functional coupling with cumulus cells as well as nuclear and cytoplasmic competence after warming of immature feline oocytes.From a total of 422 cumulus enclosed oocytes (COCs) obtained from queens after ovariectomy, 137 were stored by vitrification in open pulled straws, 147 by slow freezing and 138 untreated oocytes were used as controls. Immediately after collection and then after warming, functional coupling was assessed by lucifer yellow injection and groups of fresh and cryopreserved oocytes were fixed to analyze tubulin and actin distribution, and chromatin organization. Finally, COCs cryopreserved with both treatments were matured in vitro after warming. In most cases, oocytes cryopreserved by slow freezing showed a cytoskeletal distribution similar to control oocytes, while the process of vitrification induced a loss of organization of cytoskeletal elements. The slow freezing protocol ensured a significantly higher percentage of COCs with functionally open and partially open communications (37.2 vs. 19.0) and higher maturational capability (32.5 vs. 14.1) compared to vitrified oocytes. We conclude that although both protocols impaired intercellular junctions, slow freezing represents a suitable method of GV stage cat oocytes banking since it more efficiently preserves the functional coupling with cumulus cells after thawing as well as nuclear and cytoplasmic competence. Further studies are needed to technically overcome the damage induced by the cryopreservation procedures on immature mammalian oocytes.     

Transient loss of plasmid-mediated mercuric ion resistance after stress in Pseudomonas aeruginosa

After freezing and thawing, Pseudomonas aeruginosa harboring a drug resistance plasmid (Hg2+r, Strr), became acutely sensitive to mercuric ions but not to streptomycin in the plating medium, whereas its sensitivity to both agents became more pronounced indicating a synergistic effect. This freeze-thaw-induced sensitivity was transient and capable of being repaired to a simple salts medium. Transient outer and cytoplasmic membrane damage was also observed in frozen and thawed preparations. From kinetics studies, repair of cytoplasmic membrane damage superseded repair of outer membrane damage and damage measured by mercuric ions and mercuric ions plus streptomycin. Osmotically shocked cells were also sensitive to mercuric ions, mercuric ions plus streptomycin, and sodium lauryl sulfate, but not to sodium chloride or streptomycin alone. This sensitivity was again transient and capable of repair in the same simple salts medium. Active transport of a non-metabolizable amino acid, alpha-amino isobutyric acid, was sensitive to mercuric ions and became more so after freezing and thawing. A freeze-thaw-resistant mercuric ion-dependent reduced nicotinamide adenine dinucleotide phosphate oxidoreductase was localized in the cytoplasm of this organism. This enzyme and an intact outer membrane appear to be required for mercuric ion resistance in this strain.     

Transient loss of plasmid-mediated mercuric ion resistance after stress in Pseudomonas aeruginosa.

After freezing and thawing, Pseudomonas aeruginosa harboring a drug resistance plasmid (Hg2+r, Strr), became acutely sensitive to mercuric ions but not to streptomycin in the plating medium, whereas its sensitivity to both agents became more pronounced indicating a synergistic effect. This freeze-thaw-induced sensitivity was transient and capable of being repaired to a simple salts medium. Transient outer and cytoplasmic membrane damage was also observed in frozen and thawed preparations. From kinetics studies, repair of cytoplasmic membrane damage superseded repair of outer membrane damage and damage measured by mercuric ions and mercuric ions plus streptomycin. Osmotically shocked cells were also sensitive to mercuric ions, mercuric ions plus streptomycin, and sodium lauryl sulfate, but not to sodium chloride or streptomycin alone. This sensitivity was again transient and capable of repair in the same simple salts medium. Active transport of a non-metabolizable amino acid, alpha-amino isobutyric acid, was sensitive to mercuric ions and became more so after freezing and thawing. A freeze-thaw-resistant mercuric ion-dependent reduced nicotinamide adenine dinucleotide phosphate oxidoreductase was localized in the cytoplasm of this organism. This enzyme and an intact outer membrane appear to be required for mercuric ion resistance in this strain.     

An Adiabatic Calorimetry Method to Determine the Thermodynamic Characteristics of Cryoprotectants

Biophysics - Abstract—The efficiency of cryoprotectants used to protect cells from damage is usually evaluated by the changes in vital cell parameters after a freezing–thawing cycle....     

Membrane status of boar spermatozoa after cooling or cryopreservation

This study tested the hypothesis that sperm membrane changes during cooling contribute substantially to the membrane damage observed after cryopreservation of boar spermatozoa. Flow cytometry was used to assess viability (percentages of live and dead cells) of boar sperm cells after staining with SYBR-14 and propidium iodide (PI) and acrosome status after staining with FITC-pisum sativum agglutenin and PI. Incubation (38 degrees C, 4 h), cooling (to 15 or 5 degrees C) and freezing reduced the proportion of live spermatozoa compared with those in fresh semen. There were more membrane changes in spermatozoa cooled to 5 degrees C than to 15 degrees C. The proportion of live spermatozoa decreased during processing for cryopreservation and cooling to 5 degrees C, but was unaffected by freezing and thawing if held at 15 degrees C for 3.5 h during cooling. Spermatozoa not held during cooling exhibited further loss of viability after freezing and thawing. Holding the spermatozoa also increased the proportion of acrosome-intact spermatozoa at both 15 degrees C and 5 degrees C and at thawing compared with that of the unheld controls. The results of this study suggest that a substantial proportion of the membrane changes associated with cryopreservation of boar spermatozoa may be attributed to the cooling of the cells to 5 degrees C rather than to the freezing and thawing process, and that sperm membrane changes are reduced when semen is held at 15 degrees C during cooling.     

Ultrastructure of the lymphocytes in lymphoid organs following cryopreservation with PEO-400 protection

Electron microscopic examination of lymphocytes after cryopreservation with PEO-400 used as a cryoprotectant has shown that changes in the cytoplasmic membrane structures are of reversible character after thawing. Programmed freezing with a period of temperature holding is beneficial for lymphocyte cryopreservation.     

A comparative study of the effects of freezing and frozen storage on intact and demembranated bull spermatozoa

The damage caused to bull sperm by freezing and thawing them without cryoprotectants was assessed in both intact and membrane-extracted cells. Preparations of membrane-extracted cells were produced by treating the sperm with 0.1% Triton X-100 and motility was restored with exogenously applied ATP and Mg²⁺. Motile demembranated sperm showed no detectable reduction in motility after freezing and thawing. In contrast, when intact cells where subjected to freezing and thawing they lost all motility. These damaged cells were also restored to motility when exogenous ATP and Mg²⁺ were added to the sperm mixture. Apparently freezing and thawing sperm cells causes damage to the plasma membrane which permits ATP and Mg²⁺ to freely enter or leave the cells, but does not damage the components of the sperm cell which generate motility.The effects of storage temperature on frozen demembranated sperm were also explored. Sperm held at ?20 °C showed marked structural changes and progressively decreased motility after prolonged storage. When sperm were frozen at ?20 °C the mitochondrial structures were completely lost after 48 to 72 hr and ATP caused the disintegration of the flagellum rather than initiating motility. Sperm which were frozen at ?76 °C retained motility after short periods of storage, but showed a significant decline in motility when thawed after 8 days. Demembranated sperm which were kept frozen at ?196 °C showed no significant loss of motility when thawed after 1 year of storage.     

A histological analysis of liver injury in freezing storage

As part of a more extensive study on the use of high subzero freezing for cryopreservation of mammalian livers we have tried to single out the effects of freezing and thawing on tissue damage. We compared the morphology of livers after freezing and thawing with what we considered an optimal high subzero cryopreservation protocol with the morphology of livers preserved under the same thermal conditions and in the same solution in a supercooled state, without freezing. The results show that while hepatocytes survive high subzero cryopreservation, detachment of endothelial cells occurs in every freezing experiment. On the other hand, the endothelial cells in livers that are not frozen are intact. This suggests that endothelial cell damage is caused by freezing and may be an important factor in high subzero freezing cryopreservation of the liver.     

The interaction of nuclear and cytoplasmic damage after treatments with toxic chemicals

An attempt is made to show how the interaction of different degrees of nuclear and cytoplasmic damage may contribute to the ultimate whole cell damage by a chemical. It suggests that cytoplasmic, as well as nuclear damage, may be important in the action of chemical carcinogens. Using Amoeba proteus as a single cell model where nuclear and cytoplasmic damage can be separated by micrurgy, the mortality curves for the nucleus, the cytoplasm and the whole cell are examined after four different treatments: exposure to N-methyl-N-nitroso urethane, a potent carcinogen in mammalian systems; exposure to ββ₁ (dichlorodiethyl) methyl amine, an alkylating agent used in chemotherapy; exposure to methylmercury chloride, a very toxic organo-metal; and irradiation with X-rays. These illustrate how different relative nuclear/cytoplasmic sensitivities contribute to the death of the cell. The evidence for nuclear and cytoplasmic damage after treatment with the N-methyl-N-nitroso urethane is detailed, and possibilities of nuclear repair after the four different types of treatment examined. Work on Amoeba proteus makes no attempt to assess separately changes in structure or activity of any one of the cells many enzyme systems, but looks at the balance between nuclear and cytoplasmic damage as a whole.     

Morphologic characterization of acute injury to vascular endothelium of skin after frostbite

Cyclo-oxygenase inhibitors and free-radical scavengers protect the skin against necrosis induced by frostbite. However, the tissue component(s) that determine the evolution of skin necrosis and the mechanism of this pharmacologic protection are not precisely defined. We have studied freezing injury to rabbit ears by serial biopsies examined by light and electron microscopy. The morphologic evidence of skin injury due to freezing was localized exclusively in the endothelial cells, particularly in the arterioles. Within 1 hour, the entire microvasculature demonstrated endothelial damage. Intravascular platelet aggregation occurred just after thawing and closely paralleled the endothelial cell injury. Very few neutrophils were seen initially (at 10 minutes). By 1 hour, leukocyte aggregates were present, and they further increased at 6 hours. Swelling of the interstitium started 10 minutes after thawing, while extravasation of erythrocytes began to appear by 6 hours. Parenchymal elements of skin were relatively free of damage. In the ear cartilage, the chondrocytes showed evidence of damage immediately after freezing. The administration of superoxide dismutase (SOD) during thawing (reperfusion) did not qualitatively alter any of the initial morphologic changes induced by freezing. We conclude that the endothelial cell is the initial target of injury induced by freezing, an initial injury that is mediated by a non-free-radical-mediated mechanism. It is likely that this acute injury ultimately compromises blood flow and leads to skin necrosis.     

Ultrastructure of bovine embryos frozen and thawed by a two-step freezing method

An ultrastructural evaluation of a rapid tow-step freezing method, by which 6-7-day-old bovine embryos equilibrated in 1.4 M glycerol in Dulbecco's phosphate-buffered saline were frozen and thawed, was undertaken. In all non-frozen control embryos trophoblastic and embryonic cells formed a spherical structure enclosed by an intact zona pellucida. The spacial arrangement of the cells of the frozen embryos was less regular and the surrounding zona pellucida was damaged in approximately half of the cases. Some embryonic cells had increased electron density and lysosomal content showing reaction sites for acid phosphatase. In all frozen embryos, cytoplasmic defects appearing as non-membrane-bound 'empty spaces' were observed more frequently in the trophoblastic cells than in the embryonic cells. Culture of frozen embryos for 24 h revealed that cells appearing nondefective after culture may have the capability of organizing a viable embryonic structure. It was found that the most commonly used freezing method is associated with certain morphological changes. However, no additional cryoinjuries were observed in comparisons with the more complicated freezing procedures using dimethylsulfoxide as cryoprotectant.     

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.     

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.     

A brief review of lyophilization damage and repair in bacterial preparations

The principal concern of those responsible for the maintenance of culture collections has been to preserve viability, but nonlethal damage should not be ignored. Whether disruption of any element of a cell is nonlethal depends on the ability of the cell to repair the damage. Subsequent repair of DNA damage can lead to mutation.The protective effect of additives, as measured by survival after lyophilized cultures are reconstituted, sometimes depends upon the interval between making the addition and freezing. A rhythmic variation in the extent of viability has been observed, but increases in number of viable cells cannot be attributed to a repair mechanism. Instead, the changes in survival appear to be associated with a physiological condition of the cell at the instant of freezing.Virulence is generally maintained by lyophilized bacteria, but when stored cultures of Y. pestis were assayed immediately after reconstitution, virulence for mice was significantly reduced (as many as 4000 cells per 50% lethal dose). The virulence could be fully restored by holding reconstituted cultures for 24 hr at room temperature, or by subculture in fresh media. Obviously, the injury induced by lyophilization and storage is not to the DNA.     

Changes in chemical structure and function in Escherichia coli cell membranes caused by freeze-thawing. I. Change of lipid state in bilayer vesicles and in the original membrane fragments depending on rate of freezing

The effect of different rates of freezing on the character of lipids in unilamellar lipid bilayer vesicles and in the original membrane fragments of Escherichia coli B cells was investigated by measuring the temperature-dependent fluorescence polarization ratio changes of cis- and trans-parinaric acids. In lipid bilayer vesicles, both slow and rapid freezing brought about significant alterations in fluorescence polarization ratios in the specimens derived from both logarithmic and stationary-phase cells. In the original membrane fragments derived from logarithmic-phase cells, slow freezing gave rise to a similar alteration in fluorescence polarization ratio change, but no such alteration was found in the case of rapid freezing. Logarithmic-phase cells suffered from a membrane permeability change during slow freezing, which subsequently resulted in low cell viability. The cells suffered only slight impairment in membrane function during rapid freezing, and maintained higher viability. These results suggest that the primary site of damage due to freezing of the cells is the cellular membranes, and this destruction is due to a lipid state change in the membranes brought about by freezing.     

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.     

Evidence of enhanced freezing damage in treeline plants during six years of CO2 enrichment and soil warming

Climate change and elevated atmospheric CO₂ levels could increase the vulnerability of plants to freezing. We analyzed tissue damage resulting from naturally occurring freezing events in plants from a long–term in situ CO₂ enrichment (+ 200 ppm, 2001–2009) and soil warming (+ 4°C since 2007) experiment at treeline in the Swiss Alps (Stillberg, Davos). Summer freezing events caused damage in several abundant subalpine and alpine plant species in four out of six years between 2005 and 2010. Most freezing damage occurred when temperatures dropped below –1.5°C two to three weeks after snow melt. The tree Larix decidua and the dwarf shrubs Vaccinium myrtillus and Empetrum hermaphroditum showed more freezing damage under experimentally elevated CO₂ and/or temperatures than under control conditions. Soil warming induced a 50% die‐back of E. hermaphroditum during a single freezing event due to melting of the protective snow cover. Although we could not identify a clear mechanism, we relate greater freezing susceptibility to a combination of advanced plant phenology in spring and changes in plant physiology. The climate record since 1975 at the treeline site indicated a summer warming by 0.58°C/decade and a 3.5 days/decade earlier snow melt, but no significant decrease in freezing events during the vegetation period. Therefore, in a warmer climate with higher CO₂ levels but constant likelihood of extreme weather events, subalpine and alpine plants may be more susceptible to freezing events, which may partially offset expected enhanced growth with global change. Hence, freezing damage should be considered when predicting changes in growth of alpine plants or changes in community composition under future atmospheric and climate conditions.     

Spatial differentiation in photosynthetic and non-photosynthetic membranes of Rhodopseudomonas palustris.

The cytoplasmic membrane and the photosynthetic intracytoplasmic membranes of Rhodopseudomonas palustris are spatially differentiated into regions of extremely high intramembrane-particle density (4,400 to 9,800/micron 2) and areas of lower intramembrane-particle density (2,700 to 5,900/micron 2). The high intramembrane-particle-density areas were always seen in association with photosynthetic membrane stacks. This differentiation was also seen in those areas of the cytoplasmic membrane which adhere to the underlying intracytoplasmic membranes, implying that the cytoplasmic membrane too is differentiated for photosynthesis in these regions. Changes in intramembrane-particle size distribution in response to changes in light intensity during growth were measured. We found that, as light levels were decreased from 8,500 to 100 lx, the average particle diameter in the protoplasmic face of stacked intracytoplasmic and cytoplasmic membranes increased from 8.6 to 10.3 nm. We also observed a distinct periodicity in the sizes of the intramembrane particles found in the stacked regions--7.5, 10.0, 12.5, and 15.0 nm--with the larger-size peaks becoming more pronounced as light intensity decreased. This suggests that, as light levels decrease, subunits of discrete size are being added to a core particle. A comparison of propane jet-frozen cells versus fixed, glycerinated, and then frozen cells indicated that ultrarapid freezing leads to a higher quality of fine-structure preservation than does chemical fixation followed by glycerination and conventional freezing in Freon-12 or propane. The intramembrane particles appeared to be more regular in size, lacking the deformed or jagged appearance displayed in fixed preparations.