Effects of hyaluronic acid in culture and cytochalasin B treatment before freezing on survival of cryopreserved bovine embryos produced in vitro

Response of the cell membrane-cytoskeleton complex to osmotic and freeze/thaw stresses. Part 2: The link between the state of the membrane-cytoskeleton complex and the cellular damage

In an earlier paper [35], we examined the mutual interaction between the actin cytoskeleton and the cell membrane and explored the role this interaction plays during freeze/thaw. In this follow-up paper, we investigate the physical and chemical stresses induced by freeze/thaw and explore the different mechanisms of damage caused by these stresses. Our results showed that changes in cell volume during freeze/thaw and the unfrozen water content in the solution alter the cytoskeleton stiffness, and the available membrane material. Combined with unfavorable ice-membrane interactions and increasing membrane stiffness, increased de-structuring of the membrane (such as bleb and microvilli formation) synergistically act on the membrane-cytoskeleton system generating irreversible damage.

Response of the cell membrane-cytoskeleton complex to osmotic and freeze/thaw stresses

In order to develop successful cryopreservation protocols a better understanding of the freeze- and dehydration-induced changes occurring in the cell membrane and its underlying support, the actin cytoskeleton, is required. In this study, we compared the biophysical response of model mammalian cells (human foreskin fibroblasts) to hyperosmotic stress and freeze/thaw. Transmitted light, infrared spectroscopy, fluorescence- and cryo-microscopy were used to investigate the changes in the cell membrane and the actin cytoskeleton. We observed that a purely hyperosmotic challenge at room temperature resulted in bleb formation. A decrease in temperature abrogated the blebbing behavior, but was accompanied by a decrease in viability. These results suggested that cell survival depended on the availability of the membrane material to accommodate the volumetric expansion back to the original cell volume at isotonic conditions. Our data also showed that freeze/thaw stresses altered the cell membrane morphology resulting in a loss of membrane material. There was also a significantly lower incidence of blebbing after freeze/thaw as compared to isothermal osmotic stress experiments at room temperature. Significant depolymerization of the actin cytoskeleton was seen in cells whose membranes had been compromised by freeze/thaw stresses. Actin depolymerization using cytochalasin D affected the stability of the membrane against mechanical stress at isothermal conditions. This study shows that both the membrane and cytoskeleton, as a system, are involved in the osmotic and freeze/thaw-induced responses of the mammalian cells.