Ultrastructural and biochemical studies of isolated adult rat hepatocytes prepared under hypoxic conditions : Cryopreservation of hepatocytes

Isolated adult rat hepatocytes were prepared under hypoxic conditions, following a two-step procedure as described by Seglen. A simple recirculating apparatus was used and some modifications were made. Electron microscope studies revealed that the fine structure of the hepatocytes was not extensively damaged during cell preparation. Isolated hepatocytes prepared under hypoxic conditions are functional as demonstrated by their ability to carry out gluconeogenesis under normal and stimulated conditions, by the selectivity of the cell membrane towards various substrates and by the preservation of insulin receptors on the cell membrane. As previously observed for other cell types, survival of hepatocytes after freezing was dependent on the cooling rate. About 80% of cells appeared to survive when cooled at 7-2 °C/min; this apparent optimum cooling rate was also found suitable to preserve insulin-binding sites; on the other hand, the gluconeogenic capacity of hepatocytes frozen under these conditions was consistently decreased and the fine structure of organelles was damaged.     

Cryopreservation of isolated rat hepatocytes

Summary Isolated parenchymal hepatocytes from adult rats were frozen in media containing 10% glycerol, 10% dimethylsulfoxide (DMSO), or 20% DMSO. Three microsome-associated functions were compared in nonfrozen cells and cells frozen in each of the above cryoprotectant solutions. Freezing in DMSO maintains cytochromes P-450 and b₅ and NADPH-cytochrome C reductase at levels nearer to control values than does freezing in glycerol. Cells frozen and subsequently thawed and cultured for 24 h lose a greater amount of cytochrome P-450 than do nonfrozen cultured cells. The levels of cytochrome b₅ and reductase in frozen-thawed cells remain close to control values. Cell viability (trypan blue dye exclusion and percentage of attached cells) after freezing is maintained better using DMSO as a cryoprotectant. Dimethylsulfoxide protects the hepatocytes from freeze-induced damage to the extent that many viable cells attach to collagen-coated petri dishes, survive for at least 24 h, and still maintain significant levels of enzymes of importance to drug and carcinogen metabolism. This work was supported by Grant CA-30241 from the National Institutes of Health, Bethesda, Maryland.     

Cryopreservation of isolated rat hepatocytes: a critical evaluation of freezing and thawing conditions

Various parameters, including the nature and proportion of the constituents of the cryoprotective medium, the cooling rate, and the composition of the thawing medium, were evaluated for the cryopreservation of adult rat hepatocytes. The highest percentage of cells able to survive in culture was obtained by freezing in L15 medium containing 16% dimethyl sulfoxide, at a rate of 3 degrees C/min, and by adding 0.8 M glucose to the thawing medium. More than 50% of hepatocytes capable of attachment just after cell isolation kept this property after freezing and survived in primary culture. Dead cells could be eliminated before seeding by centrifugation on a Percoll layer. In culture, frozen cells exhibited a morphology similar to that of unfrozen cells and after 24 hr their protein secretion rate was reduced by only about 40%.     

Mechanisms of intracellular ice formation.

The phenomenon of intracellular freezing in cells was investigated by designing experiments with cultured mouse fibroblasts on a cryomicroscope to critically assess the current hypotheses describing the genesis of intracellular ice: (a) intracellular freezing is a result of critical undercooling; (b) the cytoplasm is nucleated through aqueous pores in the plasma membrane; and (c) intracellular freezing is a result of membrane damage caused by electrical transients at the ice interface. The experimental data did not support any of these theories, but was consistent with the hypothesis that the plasma membrane is damaged at a critical gradient in osmotic pressure across the membrane, and intracellular freezing occurs as a result of this damage. An implication of this hypothesis is that mathematical models can be used to design protocols to avoid damaging gradients in osmotic pressure, allowing new approaches to the preservation of cells, tissues, and organs by rapid cooling.     

Effect of cold acclimation on intracellular ice formation in isolated protoplasts

When cooled at rapid rates to temperatures between −10 and −30°C, the incidence of intracellular ice formation was less in protoplasts enzymically isolated from cold acclimated leaves of rye (Secale cereale L. cv Puma) than that observed in protoplasts isolated from nonacclimated leaves. The extent of supercooling of the intracellular solution at any given temperature increased in both nonacclimated and acclimated protoplasts as the rate of cooling increased. There was no unique relationship between the extent of supercooling and the incidence of intracellular ice formation in either nonacclimated or acclimated protoplasts. In both nonacclimated and acclimated protoplasts, the extent of intracellular supercooling was similar under conditions that resulted in the greatest difference in the incidence of intracellular ice formation—cooling to −15 or −20°C at rates of 10 or 16°C/minute. Further, the hydraulic conductivity determined during freeze-induced dehydration at −5°C was similar for both nonacclimated and acclimated protoplasts. A major distinction between nonacclimated and acclimated protoplasts was the temperature at which nucleation occurred. In nonacclimated protoplasts, nucleation occurred over a relatively narrow temperature range with a median nucleation temperature of −15°C, whereas in acclimated protoplasts, nucleation occurred over a broader temperature range with a median nucleation temperature of −42°C. We conclude that the decreased incidence of intracellular ice formation in acclimated protoplasts is attributable to an increase in the stability of the plasma membrane which precludes nucleation of the supercooled intracellular solution and is not attributable to an increase in hydraulic conductivity of the plasma membrane which purportedly precludes supercooling of the intracellular solution.     

Autofluorescence properties of isolated rat hepatocytes under different metabolic conditions.

The contribution of endogenous fluorophores - such as proteins, bound and free NAD(P)H, flavins, vitamin A, arachidonic acid - to the liver autofluorescence was studied on tissue homogenate extracts and on isolated hepatocytes by means of spectrofluorometric analysis. Autofluorescence spectral analysis was then applied to investigate the response of single living hepatocytes to experimental conditions resembling the various phases of the organ transplantation. The following conditions were considered: 1 h after cells isolation (reference condition); cold hypoxia; rewarming-reoxygenation after cold preservation. The main alterations occurred for NAD(P)H and flavins, the coenzymes strictly involved in energetic metabolism. During cold hypoxia NAD(P)H, mainly the bound form, showed an increase followed by a slow decrease, in agreement with the inability of the respiratory chain to reoxidize the coenzyme, and a subsequent NADH reoxidation through alternative anaerobic metabolic pathways. Both bound/free NAD(P)H and total NAD(P)H/flavin ratio values were altered during cold hypoxia, but approached the reference condition values after rewarming-reoxygenation, indicating the cells capability to restore the basal redox equilibrium. A decrease of arachidonic acid and vitamin A contributions occurred after cold hypoxia: in the former case it may depend on the balance between deacylation and reacylation of fatty acids, in the latter it might be related to the vitamin A antioxidant role. An influence of physico-chemical status and microenvironment on the fluorescence efficiency of these fluorophores cannot be excluded. In general, all the changes observed for cell autofluorescence properties were consistent with the complex metabolic pathways providing for energy supply.     

Short-term storage of isolated hepatocytes under profound hypothermic conditions

The hypothermic storage of rat liver parenchymal cells in the sucrose-salt medium is studied. It is demonstrated that short-term hepatocyte storage at 4 degrees C results in a slight imbalance, that evidences for sufficient adaptive potencies of these cells to the temperature fall.     

Cryopreservation of isolated human hepatocytes for transplantation: State of the art

Hepatocytes isolated from unused donor livers are being used for transplantation in patients with acute liver failure and liver-based metabolic defects. As large numbers of hepatocytes can be prepared from a single liver and hepatocytes need to be available for emergency and repeated treatment of patients it is essential to be able to cryopreserve and store cells with good thawed cell function. This review considers the current status of cryopreservation of human hepatocytes discussing the different stages involved in the process. These include pre-treatment of cells, freezing solution, cryoprotectants and freezing and thawing protocols. There are detrimental effects of cryopreservation on hepatocyte structure and metabolic function, including cell attachment, which is important to the engraftment of transplanted cells in the liver. Cryopreserved human hepatocytes have been successfully used in clinical transplantation, with evidence of replacement of missing function. Further optimisation of hepatocyte cryopreservation protocols is important for their use in hepatocyte transplantation.     

Composition of renal basement membranes isolated under various conditions

GBM isolated from a surgical biopsy directly or after a 22 hr incubation period--to imitate the usual interval between death and isolation--appeared to be nearly identical in amino acid composition. Sonication and detergent procedures for isolation of GBM and TBM lead to preparations of different chemical composition. Phosphorus analysis and electron micrographs indicate the presence of material of supposedly cellular origin in sonicated but not in detergent-treated bovine and human GBM. Detergent-treated bovine and human GBM preparations are more enriched in the collagen-typical amino acids than sonicated samples. SDS-PAGE analyses show a nearly identical polypeptide pattern. Sonicated and detergent-treated bovine TBM preparations are free of cellular material. They show in SDS-PAGE a similar heterogeneous polypeptide pattern, but with lower intensities of three components with molecular weights between 30 and 60 kdalton. Sulfated GAG's are present in higher concentration in sonicated than in detergent-treated GBM and TBM. Collagen is not extracted from glomeruli and tubules by detergent treatment.     

Mechanism of initiation of intracellular ice formation

Intracellular ice crystallization was studied by the method of cryomicroscopy in the systems modeling a biological suspension, such as erythrocyte concentrates. Initiation of crystallization by extracellular ice through hydrophilic channels has been shown to be the most probable mechanism of intracellular ice formation.     

Extra- and intracellular ice formation in mouse oocytes

The occurrence of intracellular ice formation (IIF) during freezing, or the lack there of, is the single most important factor determining whether or not cells survive cryopreservation. One important determinant of IIF is the temperature at which a supercooled cell nucleates. To avoid intracellular ice formation, the cell must be cooled slowly enough so that osmotic dehydration eliminates nearly all cell supercooling before reaching that temperature. This report is concerned with factors that determine the nucleation temperature in mouse oocytes. Chief among these is the concentration of cryoprotective additive (here, glycerol or ethylene glycol). The temperature for IIF decreases from -14 degrees C in buffered isotonic saline (PBS) to -41 degrees C in 1M glycerol/PBS and 1.5M ethylene glycol/PBS. The latter rapidly permeates the oocyte; the former does not. The initial extracellular freezing at -3.9 to -7.8 degrees C, depending on the CPA concentration, deforms the cell. In PBS that deformation often leads to IIF; in CPA it does not. The oocytes are surrounded by a zona pellucida. That structure appears to impede the growth of external ice through it, but not to block it. In most cases, IIF is characterized by an abrupt blackening or flashing during cooling. But in some cases, especially with dezonated oocytes, a pale brown veil abruptly forms during cooling followed by slower blackening during warming. Above -30 degrees C, flashing occurs in a fraction of a second. Below -30 degrees C, it commonly occurs much more slowly. We have observed instances where flashing is accompanied by the abrupt ejection of cytoplasm. During freezing, cells lie in unfrozen channels between the growing external ice. From phase diagram data, we have computed the fraction of water and solution that remains unfrozen at the observed flash temperatures and the concentrations of salt and CPA in those channels. The results are somewhat ambiguous as to which of these characteristics best correlates with IIF.     

Reduced and oxidized glutathione contents in adult rat hepatocytes under various culture conditions

Reduced and oxidized glutathione contents of adult rat hepatocytes in pure culture and in co-culture with rat epithelial cells were measured under various medium conditions. To the standard medium fetal calf serum, nicotinamide, H₂SeO₃, dimethylsulphoxide or no supplements were added. For freshly isolated hepatocytes, intracellular contents of 24 ± 7 nmol reduced and 0.7 ± 0.2 nmol oxidized glutathione/mg cellular protein were obtained, respectively. In pure culture as well as in co-culture and regardless of th medium conditions involved, the protein content stays constant during the culture time with the exception of a decrease in protein content after 6 days of pure culture, caused by deterioration and loss of the hepatocytes. In both culture systems, an initial increase in intracellular reduced glutathione levels was observed, followed by a decrease and a quick normalisation in co-culture. On the contrary, in pure culture, the decrease was slower, but not transient and a stabilized situation was never reached. The various supplementations of the culture media had no significant effect on the intracellular reduced glutathione contents of both culture systems. As far as the intra- and the extracellular oxidized glutathione contents and the extracellular reduced form are concerned, these were only present in small amounts.Abbreviations BSA bovine serum albumin - DMSO medium supplemented with 2% dimethylsulphoxide - FCS- medium without fetal calf serum - FCS+ medium supplemented with 10% fetal calf serum - GSH reduced glutathione - GSSG oxidized glutathione - HPLC high performance liquid chromatography - MEM minimal essential medium - Nic medium supplemented with 25 mM nicotinamide - PBS phosphate buffered saline - Se medium supplemented with 0.1 µM selenium - st standard medium     

Further studies on lipid-peroxide formation in isolated hepatocytes.

Lipid peroxide formation was initiated by the addition of either ADP-complexed Fe3+ or cumene hydroperoxide to a suspension of isolated hepatocytes. The reaction was monitored by malonaldehyde measurements. Upon the addition of iron, malonaldehyde production in the cells started immediately but ceased within 30-60 min, and the response was dose-related with iron concentrations ranging from 19 to 187 muM. Malonaldehyde formation was associated with increased oxygen uptake and conjugated diene production. The addition in vitro of N,N,N',N'-tetramethyl-p-phenylenediamine, menadione or p-benzoquinone inhibited the iron-induced malonaldehyde production. It was also possible to demonstrate an apparent disappearance of malonaldehyde from fresh cells by addition of adequate amounts of N,N,N',N'-tetramethyl-p-phenylenediamine (100 muM). The attenuation of the iron-induced malonaldehyde production was found to be correlated with an increased binding of iron to an intracellular ferritin fraction. Further, malonaldehyde formation was also associated with a conversion of reduced glutathione to the oxidized form which, in turn, revealed a faster permeation out of the cells into the surrounding medium of the oxidized than of the reduced thiol. So, concomitant with the redox alterations, there was also an overall loss of glutathione from the cells. Cumene hydroperoxide-induced malonaldehyde production could be initiated by the addition of this peroxide in concentrations ranging from 150 muM to the liver cell incubate. With concentrations below 150 muM, a lag phase was present which seemed to be glutathione-dependent. It is concluded that iron enters the cell, then is probably reduced inside the cell by NADPH via the NADPH-cytochrome P-450 reductase, and in the reduced state initiates lipid peroxidation. The reaction is inhibited by intracellular mechanisms, the glutathione redox system being of principal importance, and possibly terminated by the iron-apoferritin complex formation.