Polymeric cryoprotectants in the preservation of biological ultrastructure. II. Physiological effects

Crystalline ice as a cryoprotectant: theoretical calculation of cooling speed in capillary tubes

It is generally assumed that vitrification of both cells and the surrounding medium provides the best preservation of ultrastructure of biological material for study by electron microscopy. At the same time it is known that the cell cytoplasm may provide substantial cryoprotection for internal cell structure even when the medium crystallizes. Thus, vitrification of the medium is not essential for good structural preservation. By contrast, a high cooling rate is an essential factor for good cryopreservation because it limits phase separation and movement of cellular components during freezing, thus preserving the native-like state. Here we present calculations of freezing rates that incorporate the effect of medium crystallization, using finite difference methods. We demonstrate that crystallization of the medium in capillary tubes may increase the cooling rate of suspended cells by a factor of 25-300 depending on the distance from the centre. We conclude that crystallization of the medium, for example due to low cryoprotectant content, may actually improve cryopreservation of some samples in a near native state.

Secretion of primary urine by glomeruli of the hagfish kidney

Adrenaline and noradrenaline increased the perfusion pressure (Pperf) and single glomerulus filtration rate (SGFR) of perfused hagfish glomeruli. Small amounts (0.1 % or 0.5 %) of bovine serum albumin (BSA) in perfusion fluids containing Ficoll 70 did not diminish the loss of colloid from hagfish glomerular capillaries as has been reported for other perfused capillaries. However, replacement of Ficoll 70 with an osmotically equivalent amount (3 %) of BSA appreciably reduced colloid loss. It was concluded that adrenaline and colloids enhanced flow through the urine-forming capillaries. Whereas adrenaline elevated the SGFR, colloid lowered the SGFR probably by a direct effect on the fluid permeability of the capillary walls. The flow-enhancing effect of adrenaline was used to ensure the exposure of urine-forming capillaries to two inhibitors of active fluid transport, ouabain and 2,4-dinitrophenol (DNP). Both substances lowered the single glomerulus filtration fraction (SGFF), probably by affecting a fluid secretion mechanism. In addition, DNP diminished the flow-enhancing effect of adrenaline. This study provides relatively unequivocal evidence that fluid secretion underlies the formation of primary urine by the hagfish.

Quick sampling and perpendicular cryosectioning of cell monolayers for the X-ray microanalysis of diffusible elements

A quick sampling and preparation method for freezing of cell monolayers is described. The cells are grown on a large Formvar film supported by a frame of polystyrene. A polyvinylpyrrolidone (PVP) solution is applied to one side of the film forming a flat disc when frozen with a pair of pliers precooled in liquid nitrogen. The PVP solution provides the specimen with sufficient strength and may be used as an elemental standard for absolute quantification if salts of known concentrations are added. Manipulation of the cells prior to freezing is thus restricted to a minimum, which eliminates possible harmful treatments like scraping and centrifugation. The procedure is quickly performed, the freezing being completed within 30 s of the cells having been removed from the culture well. The analytical results reveal low and stable Na:K ratios. Our results confirm that cells in vitro are comparable to cells in vivo with respect to elemental composition.

Biophysical chemical aspects of cellular cryobehavior

Freezing tolerance and resistance in nature are among the most important and challenging aspects of biochemical adaptation to extreme environments. Some biochemical strategies are known but their mechanism is still poorly understood. Cryopreservation of cells and tissues of sensitive organisms is still generally based on physical chemistry rather than on biophysical chemical mechanisms. This paper describes the main aspects of these problems and features new trends in their study.

Interactive effects of cryosolvents, ionic and macromolecular solutes on protein structures and functions

Surprisingly, cryosolvents may mimic the effects of ionic solutes on the structures and functions of macromolecular assemblages, showing additive or opposite effects depending on the respective concentrations. These interactive effects are hard to analyze precisely because they may result from so many possible contributions. However, studies on model systems clearly show the nature of the interactive effects and bring about useful information concerning the mechanism of action of cryosolvents and ions and the response of enzyme systems. Such results suggest new studies on the interaction of biopolymers and water and their possible impact on the cryobehavior of highly organized and living systems.

Application of X-ray microanalysis to cell suspensions of oil palm (Elaeis guineensis Jacq.)

X-ray microanalysis has been used to determine the elemental composition of oil-palm (Elaeis guineesis) cell suspensions without the use of cryoprotectants. Results based on individual cells were gathered over a typical growth cycle of 14 d. During the log phase (5-7 d) there is an increase in the number of cells containing high concentrations of both K (400 mmol kg(-1) dry weight) and P (400 mmol kg(-1) dry weight). Morphologically these cells had thin cell walls and were frequently joined to other cells (two to five cells per clump).

An ultrastructural study of cryofractured myocardial cells with special attention to the relationship between mitochondria and sarcoplasmic reticulum

A comparative study of various cryofracturing techniques has been conducted on the mammalian myocardial cell. Quench freezing of fresh or fixed tissue in melting Freon 22 resulted in severe cellular damage due to ice crystallization. Fixation with Karnovsky's fixative prior to quenching had no modifying effect on the size and distribution of the ice crystals. The crystals were orientated primarily in the direction of the long axis of the myofibrils, manifested as empty tube-like structures in the scanning electron microscope (SEM). Regular cross-bridging often seen at the Z-band levels indicated that ice crystals, at least in some portions of the cells, were confined within the sarcomere. Within the same cell the size of the ice crystals could vary considerably. Treatment of the tissue with polyvinylpyrrolidone (PVP) prior to rapid freezing had no noticeable cryoprotective effect. The surface of the thin layer of PVP surrounding the freeze dried tissue appeared amorphous in the SEM. However, the first evidence of ice crystallization was found a few micrometers under the surface. The freezing artefacts were completely circumvented if the cryofracturing was carried out on ethanol-impregnated or on critical point dried material. While the first method resulted in a smooth fracture plane passing through the cell structures, the intracellular fracture plane of the critical point dried material followed the surface of the cell organelles. Separation of the cell organelles caused by freezing or by critical point drying revealed thread-like structures extending from the mitochondrial surface. Re-examination of SEM-processed material in the transmission electron microscope (TEM) revealed that these structures were part of the sarcoplasmic reticulum (SR), and that a close contact between the SR and the outer mitochondrial membrane existed. TEM of conventional prepared material revealed that strands of electron-dense material, here named 'mito-reticular junctional fibres', bridged the narrow gap between the mitochondrial surface and the SR. It is suggested that these fibres have a specific anchoring function.

Effect of the polymeric cryoprotectant dextran on fluid secretion in the isolated rabbit pancreas

Physiological effects of the polymeric cryoprotectant dextran on an ion-transporting epithelium were investigated. In the isolated rabbit pancreas, dextran caused inhibition of fluid secretion and an increase of the concentrations of Na+, K+ and Cl-in the secreted fluid. Dextran did not affect the basal or pancreozymin-stimulated enzyme secretion. These effects of dextran can partially be explained by the fact that it is osmotically active and does not permeate through the epithelium. The effect of dextran on water transport can be compensated by lowering the ion concentrations in the solvent of the cryoprotectant. It is concluded that in cryoprotected ion-transporting epithelia the absolute ion concentration values obtained by X-ray microanalysis of frozen-hydrated specimens may not be completely correct, but that valid conclusions about intracellular ion distribution may still be drawn.

Developments in low-temperature biochemistry and biology

Though under most circumstances harmful changes are induced in cellular structures by subzero temperatures, conditions can be found under which such damage is avoided. Thus, in solution, biochemical reactions can be slowed and more easily analysed and many enzyme-substrate complexes can be stabilized and structurally analysed; in crystals, 'stop-action' pictures unveil the stereochemical changes along reaction pathways. The progressive 'solidification' of non-covalent bonds involved in protein structures should permit investigation of their dynamics. Studies at high pressures open the way to new investigations on 'activated' enzyme-substrate complexes and might permit the refinement of current concepts to a considerable degree, as a preliminary but decisive step towards a full description of enzyme mechanisms. The conditions of medium allowing such cryobiochemical studies fail to protect cellular structures against cold. Investigations of plasma membrane behaviour are now under way to determine processes leading to cryosensitivity or cryotolerance of cells.

A comparison of immunoferritin, immuno-enzyme and gold-labelled protein A methods for the localization of capsular antigen on frozen thin sections of the bacterium, Pasteurella haemolytica

The staphylococcal protein A-gold method was found to be superior to the enzyme-or ferritin-linked antibody techniques for locating capsular antigens on cryosections of Pasteurella haemolytica, and its sensitivity was similar to the enzyme-linked antibody method. The sensitivity of conventionally fixed and embedded material and cryosections of heavily fixed, lightly fixed and unfixed material were shown to be similar under routine laboratory conditions.

Thin frozen-dried cryosections and biological x-ray microanalysis

The application of X-ray microanalysis to problems of cell physiology required the development of methods to retain diffusible substances within the subcellular compartments that they occupied in vivo. Several groups have developed methods of rapidly freezing small samples in ways that minimize mechanical traumae and ice crystal formation. This provides a narrow zone from which cryosections, believed to be representative of the in vivo distribution of electrolytes, can be cut. The production of thin (less than 0.5 micrometers) cryosections that are apparently free of diffusion can be routinely performed when temperature parameters are kept below 173 K. Efficient cryosectioning requires several modifications to commercially available machines, in order to improve the ease and reliability with which various manipulations can be carried out. Initial attempts to localize calcium at the subcellular level were disturbed by the use of mechanically damaged specimens and by insufficiently cold conditions in the cryochamber. Such sections indicated that mitochondria were calcium-rich organelles. When tissue freezing and cryosectioning were performed under optimized conditions, mitochondrial calcium was so low as to be quantifiable only with difficulty. Available microanalytical results show that ER-rich cytoplasm and terminal cisternae of the sarcoplasmic reticulum seem to contain higher levels of calcium than mitochondria. Nuclei and secretory granules also contain more calcium than mitochondria.

Cryoultramicrotomy as a preparative method for x-ray microanalysis in pathology

The role of ion shifts in cell injury has become one of the most intriguing fields of application of X-ray microanalysis in pathology. In principle, cryo(ultra)-microtomy is the best preparative method for X-ray microanalysis of diffusible substances. In this review, the following points are discussed: the choice of freezing method and coolant, the use of high molecular weight polymer cryoprotectants and their possible physiological effects the choice of the cryosectioning temperature, and techniques for handling and transfer of sections. Experiences with the sectioning of cryoprotected tissue are presented. Finally, other preparative techniques for microanalysis are compared to cryoultramicrotomy.

Application of scanning electron microscopy to x-ray analysis of frozen-hydrated sections. I. Specimen handling techniques

X-ray microanalysis of frozen-hydrated tissue sections permits direct quantitative analysis of diffusible elements in defined cellular compartments. Because the sections are hydrated, elemental concentrations can be defined as wet-weight mass fractions. Use of these techniques should also permit determination of water fraction in cellular compartments. Reliable preparative techniques provide flat, smooth, 0.5 micrometers-thick sections with little elemental and morphological disruption. The specimen support and transfer system described permits hydrated sections to be transferred to the scanning electron microscope cold stage for examination and analysis without contamination or water loss and without introduction of extraneous x-ray radiation.

Ultrastructural effects of the high molecular weight cryoprotectants Dextran and polyvinyl pyrrolidone on liver and brown adipose tissue in vitro

The ultrastructural changes caused by incubation of rat liver and brown fat in buffered solutions of high molecular weight cryoprotectives (Dextran and polyvinyl pyrrolidone) at high concentrations (up to 25% w/v) have been examined. Under appropriate conditions of incubation rather small qualitative changes were found. Hepatocytes showed some signs of plasmolysis. Evidence for the endocytosis of Dextran and polyvinyl pyrrolidone was obtained. Cryoultramicrotomy of unfixed, quench-frozen specimens after the same incubation procedures showed good cutting properties and only slight ice-crystal damage. Several of the larger tissue compartments were recognizable in such sections. Although high molecular weight cryoprotectants do penetrate cells by endocytosis (and these effects require further functional evaluation), the present observations provide further support for the idea that such compounds significantly improve the quench-freezing of biological specimens and offer a practical way forward for the preparation of material for X-ray microanalysis of diffusible elements.

Distribution of calcium and other elements in cryosectioned Bacillus cereus T spores, determined by high-resolution scanning electron probe x-ray microanalysis

The distribution of a number of key elements in Bacillus cereus T spores was determined by high-resolution scanning electron probe X-ray microanalysis. To circumvent the redistribution of soluble or weakly bound elements, freeze-dried cryosections of spores, which had been rapidly frozen in 50% aqueous polyvinyl pyrrolidone, were employed. The sections were examined by using a modified Philips EM400 electron microscope fitted with a field emission gun, scanning transmission electron microscopy attachment, and a computer-linked energy-dispersive X-ray microanalysis system. X-ray maps for selected elements and the corresponding electron image were produced simultaneously by scanning the cryosections with a fine electron beam in a raster pattern, using the scanning transmission electron microscopy attachment. The results indicated that almost all of the calcium, magnesium, and manganese, together with most of the phosphorus, was located in the core region. An unexpectedly high concentration of silicon was found in the cortex/coat layer. Granules containing high concentrations of calcium, manganese, and phosphorus were demonstrated in spores containing reduced levels of dipicolinic acid. Spot mode analyses, in which a stationary beam was located over the region of interest in the spore cryosection, confirmed the results obtained with the scanning mode and also provided a more accurate quantitation of the elemental concentrations on a dry weight bases.

Ultrastructure of red cells frozen with hydroxyethyl starch

The freeze fracture appearance of red cells frozen in the presence of varying concentrations of hydroxyethyl starch (HES) is described. A technique is used which allows examination of a small portion of cells from a larger unit. The frozen cells appear distorted probably as a result of osmotic dehydration but indicate no evidence of intracellular ice. The frozen mixture with HES has three phases--a particulate phase consisting of the concentrated HES (and other salts), a sculptured ice phase and the red cells. When the concentration of HES is increased, the particulate phase becomes more prominent and at 14% HES appears to surround nearly all cells. In cells frozen in saline alone and 4% HES, the cytoplasm in a majority of cells has numerous cavities and depressions. Since such units haemolyse badly when thawed, it is possible that these regions indicate structural damage. In contrast, those units frozen with 14% HES (in which nearly 85% of the cells survive freeze-thaw) possess cells which only infrequently have such regions in the cytoplasm.

Biological X-ray microanalysis

By means of X-ray microanalysis it is now practical to detect approximately 10(-19) g of an element in a static-probe analysis within an ultrathin section, with analytical spatial resolution in the range 20--30 nm. The main difficulties for biological microanalysis are connected not with sensitivity but with specimen preparation and beam damage. Careful cryopreparation, beginning with the quench-freezing of a small block of tissue, is essential even for determining the storage sites, or sites of binding in vivo, of physiologically active elements. In frozen-dried or frozen-hydrated sections of quench-frozen tissue, it is now possible to measure local mass fractions of diffusible as well as of bound elements.

New trends in cryoenzymology: I.-Supercooled aqueous solutions

A water in oil emulsion technique is proposed to investigate enzyme catalyzed reactions at sub-zero temperatures in the supercooled liquid state to avoid some reversible effects of the usual cosolvents on kinetics. Some results are listed: potentialities and technical problems of the procedure are discussed.

Cryo-ultramicrotomy and myofibrillar fine structure: a review

In the past, the techniques of electron microscopy and X-ray diffraction have both been very informative about the ultrastructure of the muscle myofibril But X-ray diffraction patterns are difficult to interpret unambiguously and until now specimen preservation in plastic embedded muscle has been sufficiently poor to make it difficult to use electron micrographs of muscle as a means of interpreting the available X-ray diffraction evidence. The possibility of using ultrathin sections of frozen muscle, in which the disruptive steps of chemical dehydration and plastic embedding can be avoided, promises to help to bridge the information gap between present X-ray and electron microscope results. For this reason we here review the application of the cryosectioning technique to muscle, we assess the technique in terms of the improvements in preservation which have so far been obtained and which might be expected and we discuss some of the many potential advantages and uses of this technique for studies of muscle ultrastructure and function. It is concluded that this technique should be developed vigorously since it promises to play a very important role in muscle research in the future.

Biological freezing and cryofixation

Freezing and freeze fixation are commonly used to achieve ultrastructural and biological preservation. Freezing in biological materials is complex because of their heterogeneous nature-water is unevenly distributed and the various domains are separated by semi-permeable membranes. Processes to be considered include: (1) osmotic gradients leading to redistribution of water, (2) nucleation and uncontrolled growth of ice crystals, (3) recrystallization of nucleated aqueous substrate. To avoid ultrastructural deformation in biological specimens cryofixatives are commonly employed. These are water soluble molecules, able to penetrate cell membranes (e.g. glycerol and dimethylsulphoxide). Interacting strongly with water, ions and bipolymers, they give rise to metabolic and physiological changes which render them useless for X-ray microprobe analytical studies. However, they can enable tissues to survive low temperature storage. Some plants and animals develop in vivo mechanisms which enable them to avoid or tolerate freezing. Alternative means of cryofixation have recently been developed. They rely on non-penetrating polymers of high and specific water binding capacity. These polymers enable the extracellular spaces to be vitrified rather than frozen. Such suppression of ice nuclei enables the cell contents to be maximally subcooled, resulting in the formation of nm dimension ice crystals. Since the polymers have a low osmotic activity and do not penetrate membranes, the interior of the cell is substantially undisturbed. Also hydrophilic polymers used as cryofixatives are physiologically less active than conventional cryoprotectants at equivalent weight concentrations, and th eir mechanical properties render them useful as matrices for cryosectioning.

Polymeric cryoprotectants in the preservation of biological ultrastructure. III. Morphological aspects

Two high molecular weight polymers, polyvinylpyrrolidone (PVP) and hydroxyethyl starch (HES), have been used as cryoprotectants for preparing specimens to be freeze fractured. Solutions of 25% (w/w) suppress the formation of intracellular ice in single cells and tissue blocks from both plants and animals to the extent that fine structural details of the cell can be elucidates. The mode of action of these cryoprotectants, together with the structures they reveal and the peculiar advantages attached to their use, is discussed.

Polymer cryoprotectants in the preservation of biological ultrastructure. I. Low temperature states of aqueous solutions of hydrophilic polymers

The solid states formed by vitrified and frozen aqueous solutions of some hydrophilic polymers, able to act as biological cryoprotectants, have been studied by differential scanning calorimetry and freeze fracture electron microscopy. Glass transitions, devitrification, recrystallization and melting behaviour of aqueous solutions of polyvinylpyrrolidone, hydroxyethyl starch and dextran have been established. The vitrified polymer solutions exhibit a characteristic microspheral morphology which is not induced by the quench cooling process but is an inherent feature of the solutions themselves.