Ultrastructure of the frog retina after high-pressure freezing and freeze substitution

In many types of tissue, high-pressure freezing (HPF), followed by freeze substitution, can produce excellent ultrastructural preservation at depths over 10 times that obtained by other cryofixation techniques. However, in the case of neural tissue, the benefits of HPF have not been realized. In the present study, isolated frog ( Rana pipiens) retina was sliced at a thickness of 150 or 350 μm, rapidly frozen in a Balzers HPM 010 high-pressure freezer, and freeze substituted with 1% OsO₄ and 0.1% tannic acid in acetone. Specially designed HPF chambers and specific freezing media (35% high-MW dextran for 150-μm slices or 15% low-MW dextran for 350-μm slices) were required for adequate freezing.
The quality of preservation after HPF was excellent throughout the retina in both the 150- and 350-μm slices, compared with chemically fixed slices. Specifically, HPF resulted in better preserved cellular, mitochondrial and nuclear membranes in all retinal layers.
This is the first study to successfully cryofix all of the layers of the retina. The increased depths of adequate freezing achieved by HPF should facilitate various ultrastructural studies of retina, as well as of other CNS tissues, where preservation approaching that of the 'native' state is required.     

Development of the gametophyte of the fern Schizaea pusilla

Schizaea pusilla is a pteridophyte with several unique developmental characteristics. In contrast to most other fern species, S. pusilla gametophytes remain filamentous throughout their development, and the gametophytes are associated with an endophytic fungus which appears to be mycorrhizal. In terms of tropistic responses, apical filament cells of young gametophytes are negatively phototropic compared with germ filaments of other ferns which exhibit positive phototropism. Cryofixation (propane jet freezing and high-pressure freezing) in conjunction with freeze substitution electron microscopy was used to study young gametophytes. The results demonstrate that apical filament cells have a distinctive structural polarity and that rhizoids also can be successfully frozen by these methods. The cytoskeleton and endomembrane system were particularly well preserved in cryofixed cells. In addition, Schizaea gametophytes were used as a test system to evaluate potential artifacts of propane jet freezing and high pressure freezing. There was little apparent difference in ultrastructure between cells cryofixed by either freezing method. These gametophytes will be useful in determining the effectiveness of cryofixation techniques and as a model system in tip growth studies.     

Cryofixation of monolayer cell cultures for freeze-fracturing without chemical pre-treatments

A cryofixation method is presented which gives excellent ultrastructural preservation of monolayer cell cultures without any chemical pretreatments. Rat hepatocytes in primary culture were used in this study. The equipment needed is inexpensive and easy to manufacture. Cells are grown on a usual tissue culture support material (Thermanox plastic sheets). For cryofixation, samples are prepared essentially by a combined sandwich-cryogen-jet technique. 3 mm large discs are punched out and sandwiched with Cu- or Au-object holders of little mass; a 15 μm spacer is put in between. The viability of the cells is not impaired by the manipulations before freezing. The sandwich sample is quickly frozen by shooting a propane jet from a simple pressure chamber on to the metal object holder. The relevant parameters were optimized by parallel freeze-fracture analyses of 5% glycerol as a model system and by thermocouple measurements. Sandwich samples are then mounted in an appropriate double replication specimen table for further analysis by freeze-fracturing. It is possible to obtain a certain selectivity of the fracture plane with regard to apical, lateral or basal aspects of the cell layer. Alternatively, disc samples can be processed by chemical fixation methods (including freeze substitution to determine the freeze-fracture plane), since the support material Thermanox is insensitive to organic solvents and easy to cut. In each case the cells remain attached to their substratum throughout the whole procedure. Thus, the ultrastructural data can be directly correlated with parallel functional analyses obtained from the same cell cultures.     

The cryopuncher: A pneumatic cryofixation device for X-ray microanalysis of tissue specimens

A cryopunching device is described which allows cryofixation of tissue specimens by quick contact with a precooled copper surface during excision. The advantage of the cryopuncher for analytical electron microscopy of cells and tissues in defined functional states is illustrated by electron probe X-ray microanalysis of freeze-dried cryosections from rat liver and dogfish kidney. In comparison with results obtained from specimens plunged into liquid propane, cryopunching in situ results in similar preservation of morphology and remarkably improved intracellular K/Na ratio.     

Cryofixation of plant tissues without pretreatment

Root tips from Sorghum and Dahlia were frozen without cryoprotection by dipping into nitrogen slush, rapid immersion in liquid propane and by the high-pressure method. Structural preservation of the samples was studied using freeze-fracture (FF) and freeze-substitution (FS) techniques for electron microscopy. It was found that most of the organelles were disrupted by freezing in nitrogen slush and that only the boundary beween the cytoplasm and the vacuole remained visible. If the samples were frozen by rapid immersion in liquid propane, small membraneous organelles, such as dictyosomes, were preserved in peripheral regions of the rhizodermal cells up to 10 μm below the surface of the tissue. Specimens frozen by the high-pressure freezing technique showed good ultrastructural preservation throughout the tissues up to a depth of more than 100 μm.     

Preparation of resin embedded unicellular organisms without the use of fixatives and dehydration media.

A method is presented for processing single cells for conventional ultrathin sectioning without the use of fixatives and dehydration media. The cells were fixed by a physical method--spray freezing--which provides extremely high cooling rates, needs no pretreatment with cryoprotective agents and is therefore assumed to maintain the in vivo morphology of the cell. Hitherto cells prepared in this way have been investigated exclusively by freeze etching. To combine the advantages of this method with those of conventional ultrathin sectioning we have processed spray frozen cells with widely varying water contents (spermatozoa and lymphocytes) by freeze drying at 188 K and vacuum embedding. When compared to conventional chemical fixation the differences found in ultrastructural preservation of spermatozoa using this kind of preparation were confined to the arrangement of spermhead membranes and middlepiece structures. Lymphocyte structure was much closer to that known from chemical preparation, the only differences being a denser cytoplasm, denser mitochondrial matrices and thicker plasma membranes. These differences are probably due to the absence of eluating and dissolving effects present in conventional chemical preparations. The ultrastructural preservation of spray frozen cells is not different after freeze etching or after freeze-drying and vacuum embedding. This indicates clearly that drying and resin embedding does not produce artefacts and that structural preservation is therefore limited by the quality of cryofixation. Therefore this method is considered a contribution to the problem of preservation of the in vivo assembly of cellular substructure. Furthermore it seems to be a potential basis for preparation of soluble or diffusible substances or cellular compounds which would be influenced by fixatives and dehydrating agents.     

Recrystallization and ice-crystal growth in a biological specimen,as shown by a simple freeze substitution method

The sensory hairs of the silkmoth, Bombyx mori, are suitable test objects to check for recrystallization and secondary freezing damage in a biological object, because cryofixation by immersion into propane (90 K) routinely yields well-preserved specimens without noticeable freezing damage. After rewarming the frozen specimens for 10 min to 230 K (boiling propane), the tissue preservation has not deteriorated, and even after 45 min at 230 K, ice-crystal ghosts rarely exceed 50 nm. Two minutes at 250 K (in deep freezer) produced moderate freezing damage with ice-crystal ghosts of 30–75 nm, whereas 90 min at 250 K resulted in severe damage with ice-crystal ghosts well over 100 nm. Secondary freezing damage by ice-crystal growth upon rewarming well-frozen biological specimens, therefore, is a relatively slow process, depending not only on the temperature, but also on the exposure time. Moreover, with some biological specimens, secondary ice-crystal growth starts at much higher temperatures than previously guessed, and with short exposure times rarely should become a hazard in fine structure work.     

An improved cryo-jet freezing method

A new cryo-jet freezing apparatus is described that is easy to use and gives good results using a propane-butene mixture (3: 1). Our use of the freezer in the study of mouse spinal cord explant cultures is discussed. At the tissue surface, the quality of tissue preservation from freezing, followed by freeze substitution, rivals that of conventional electron microscopic methods. Certain intracellular structures are better visualized using our methods. There is no evidence of the tissue being distorted by the cryogen jet when the freezer is operated correctly. A new freeze substitution device is also discussed.     

A simple ethanol-based freeze-substitution technique for marine invertebrate embryos which allows retention of antigenicity

A simple technique has been developed for flash freezing and freeze substituting small (0.5 mm) marine embryos, which effectively preserves both cellular and extracellular components, using inexpensive equipment that is readily available in most laboratories. To achieve this, embryos of the starfish, Pisaster ochraceus, were isolated on copper freeze-fracture EM grids. The embryos were then rapidly frozen by plunging the grids into a supercooled liquid cryogen, and stored in liquid nitrogen. Freeze substitution was carried out by placing the specimens in sealed vials containing anhydrous ethanol at ?90°C for 4–5 days. Following substitution, the specimens were passively warmed to ?20°C over 2 h and then to room temperature over a further 2 h. They were then embedded in either JB4 for light microscopy or Epon or LR White resins for transmission electron microscopy. Four different liquid cryogens, Freon 12, ethane, propane, and nitrogen slush, were tested. Freezing in propane, the best cryogen of the four, gave good preservation of the embryonic cells but poor preservation of the extracellular matrix (ECM). To overcome this, the embryos were exposed to four cryoprotective agents, dimethylsulphoxide, glycerol, ethylene glycol and propylene glycol prior to freezing, and the results were assessed. The experiments demonstrated that good preservation of both cells and ECM could be achieved by adding 15% propylene glycol in sea water to the embryos prior to freezing in propane. Material preserved in this manner not only gave excellent morphological results, but the antigenicity of both native antigens of ECM components and antibodies to which the animals had been exposed in vivo were retained. The application of this technique to other tissues and embryos should prove useful in many future studies.     

Embedding in Spurr's resin is a good choice for immunolabelling after freeze drying as shown with chemically unfixed dendritic cells

Immunocytochemical reactions on biological specimens depend on many factors, the most crucial one being the maintenance of antigenicity. Antigens are vulnerable at each stage during preparation for electron microscopy. One of the least traumatic methods of preparing biological tissues for post‐embedding immunolabelling includes the following steps: (1) physical stabilization of the native biological material by rapid freezing (cryofixation) and keeping the immobilized biological sample at low temperature, thereby avoiding any movements of water, ions and macromolecules; (2) dehydrating the frozen biological material by freeze‐drying at low temperature; (3) embedding of the dehydrated specimen. Here we show that embedding of chemically unfixed dendritic cells in Spurr's resin after cryofixation and freeze‐drying enables the conservation of fine ultrastructure without cell distortion or shrinkage. Furthermore, we demonstrate the feasibility of protein localization in ultrathin sections by immunolabelling of the major histocompatibility class II molecules.     

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 their mechanical properties render them useful as matrices for cryosectioning.     

Moving EM: the Rapid Transfer System as a new tool for correlative light and electron microscopy and high throughput for high-pressure freezing

In this paper, the Rapid Transfer System (RTS), an attachment to the Leica EMPACT2 high‐pressure freezer, is described as a new tool for special applications within the cryofixation field. The RTS is an automated system that allows for fast processing of samples (<5 s) that make it possible for the first time to use high‐pressure freezing in combination with high time resolution correlative light and electron microscopy. In addition, with a working cycle of 30 s this rapid turn over time allows one to acquire more samples of biopsy material before it deteriorates than with other HPF machines with longer cycle times. With the use of the RTS it was possible to obtain three samples each of four different tissues in 6 min. Together with the finding that 90% of samples of cells grown on sapphire discs were well frozen, the RTS was both fast and reliable. Most important, together with other newly developed accessories, the RTS made it possible to capture specific events occurring live in the cell as observed by light microscopy, to cryofix that sample/event within 4 s, and then to analyze that event at high resolution in the electron microscope with excellent preservation of ultra‐structure. These developments should give us the tools to unravel intracellular processes that can be observed by live cell imaging but are too rare or fast to be picked up by routine EM methods or where the history of a structure is necessary to be able to discern its nature.     

Cryofixation rapidly preserves cytoskeletal arrays of leaf epidermal cells revealing microtubule co-alignments between neighbouring cells and adjacent actin and microtubule bundles in the cortex

Accurate preservation of microtubule and actin microfilament arrays is crucial for investigating their roles in plant cell development. Aldehyde fixatives such as paraformaldehyde or glutaraldehyde preserve cortical microtubule arrays but, unless actin microfilaments are stabilized with drugs such as m-maleimidobenzoyl N-hydroxysuccinimide ester (MBS), ethylene glycol bis[sulfosuccinimidylsuccinate] (sulfo-EGS) or phalloidin, their arrays are often poorly preserved. Cryofixation, used primarily for electron microscopy, preserves actin microfilaments well but is used rarely to fix plant cells for optical microscopy. We developed a novel whole-mount cryofixation method to preserve microtubule and microfilament arrays within Tradescantia virginiana leaf epidermal cells for investigation using confocal microscopy. Cortical microtubule arrays were often oriented in different directions on the internal and external faces of the epidermal cells. A number of arrays were aligned in several directions, parallel to microtubules of neighbouring cells. Actin microfilaments were particularly well preserved possibly due to the speed with which they were immobilized. No transverse cortical microfilament arrays were observed. On occasion, we observed co-aligned microfilament and microtubule bundles lying adjacent to the plasma membrane and positioned side by side suggesting a potential direct interaction between the cytoskeletal filaments at these locations. Cryofixation is therefore a valuable tool to investigate the interactions between cytoskeletal arrays in plant cells using confocal microscopy.     

Freeze-substitution of plant tissues with a new medium containing dimethoxypropane*

Meristematic cells from root tips of Dahlia variabilis (L.) and highly vacuolated storage parenchyma cells of Helianthus tuberosus (L.) were fixed by the high-pressure freezing technique and freeze-substituted. A new water-free medium for freeze-substitution was developed to obtain better preservation of the ultrastructure of plant tissues. Adding dimethoxypropane (DMP) to the substitution medium gave two positive results: (1) water could be withdrawn from the samples without an exchange of the medium and without adding drying agents or working in a nitrogen atmosphere, and (2) the ultrastructural preservation of the substituted tissues was better than in a methanol medium and at least as good as in tissues fixed chemically at room temperature.     

Cryofixation of epithelial cells grown on sapphire coverslips by impact freezing

Rapid cryofixation of cells cultured on coverslips without the use of chemical fixatives has proved advantageous for the immunolocalization of antigens by electron microscopy. Here, we demonstrate the application of sapphire‐attached tissue culture cells (PtK2 epithelial cells and mouse myoblasts) to metal‐mirror impact freezing. The potential of the Leica EM‐CPC cryoworkstation for routine freezing and for safe transfer of the cryofrozen samples into a sapphire disc magazine for freeze‐substitution (SD‐FS unit) has been exploited. Subsequently, the SD‐FS unit has been tested for its use in methanol freeze‐substitution and low temperature embedding for immunoelectron microscopy. The structural preservation of Lowicryl HM20‐embedded cells has been assessed as being free of damage by large ice crystals.     

Experiments on freezing damage with freeze substitution using moth antennae as test objects

Insect antennae can be easily frozen by immersion into propane at 90 K, freeze substituted at 194 K and, after warming up, embedded and sectioned at room temperature. Freezing damage (f.d.) may occur during cooling the specimen down (primary f.d.) or due to re-crystallization, during warming up, if substitution was not complete (secondary f.d.). Experimental evidence suggests that secondary freezing damage is not likely to occur with freeze substitution, provided the acetone is water free (by adding molecular sieve) and the rate of warming up is low. All freezing damage observed in the specimens therefore most probably is due to primary freezing damage during cooling. Propelling the specimen with high speed into the coolant, instead of merely dropping it in, does not improve the quality of preservation obtainable but increases the yield of well-frozen specimens.     

A new approach for cryofixation by high-pressure freezing

A newly designed high-pressure freezing machine for cryofixation was established and tested (Leica EMPACT), based on ideas originally proposed by Moor & Riehle in 1968. The new machine, essentially an improved version of our prototype, pressurizes the sample to 2000 bar in a small container (using methylcyclohexane as hydraulic fluid) and at the same time cools the outer surface of the container with a jet of liquid nitrogen. The advantage of this approach is that the machine uses little liquid nitrogen and can be built small and light. The machine is able to vitrify and freeze well a variety of specimens, for example, plant leaves, yeast cells, liver or nerve tissue (more samples are shown at: http://www.ana.unibe.ch/empact ). Cooling efficiency is the same as in the traditional machines that use liquid nitrogen to pressurize and simultaneously cool the sample.     

Cryofixation methods for ion localization in cells by electron probe microanalysis: a review

Electron probe microanalysis data on the intracellular content and distribution of electrolyte ions depends critically on the functional state of the cells at the moment of cryofixation. Whereas tissue specimens often require special in-situ freezing techniques, isolated and cultured cells can be frozen within their environmental medium under physiologically controlled conditions. Thus, they represent a feasible system to study functional ion-related intracellular parameters such as the K/Na ratio. Specifically modified freezing devices allow the study of ion shifts related to dynamic processes in cells, for example, locomotion and exocytosis. The time resolution achieved by time-controlled cryofixation is approximately 1 ms.     

Of plants and other pets: practical aspects of freeze-substitution and resin embedding

Representative tissues from higher plants (e.g. developing pollen, somatic anther tissues from the monocotyledonous angiosperm Ledebouria) and mammalian cell cultures were successfully cryoimmobilized by means of high‐pressure freezing. Various substitution and embedding protocols were then evaluated considering the preservation of ultrastructural details, membrane staining, immunolabelling properties, as well as reproducibility and ease of use. Two types of recipe proved to be highly suitable for most applications, regardless of type, developmental stage or physiological conditions of the cells: (i) the best choice for morphology is still osmium in acetone (optionally supplemented with uranyl acetate) followed by embedding in Epon and/or Araldite; (ii) feasible approaches for immunocytochemistry are freeze‐substitution with ethanol containing uranyl acetate and formaldehyde, or with pure acetone (in the case of fixation‐sensitive antigens), followed by embedding with LR‐white acrylic resin; though being far from optimal, these combinations represent, in my opinion, an acceptable compromise between labelling intensity, section stability, structural preservation and health hazards. Notably, the patterns observed in Ledebouria were consistent with data obtained from a broad range of other specimens from all kingdoms (e.g. leaves and callus cultures from angiosperms, gymnosperm roots with their ectomycorrhizal fungi, mammalian cell cultures and eubacteria). Finally, a warning is given as to the extractive potentials of embedding resins (Spurr's mixture, LR‐white, but also Epon) being sometimes the cause of unacceptable artefacts, both in plant and in mammalian cells prepared by cryoimmobilization and freeze‐substitution.     

Freeze-dried and resin-embedded biological material is well suited for ultrastructure research

Transmission electron micrographs of different biological material, cryofixed, freeze‐dried and embedded in Spurr's resin, in Epon, or in Lowicryl, are presented. The structure preservation obtained either without or with application of chemical fixatives after drying showed that freeze‐dried embedded specimens are particularly well suited for new morphological, immunocytochemical and microanalytical studies aimed at detecting the life‐like subcellular distribution of mobile macromolecules and ions. The results also indicate that the removal of cell water by freeze‐drying from the areas of best cryofixation is relatively slow. Ultrathin sections of well cryofixed biological material embedded after freeze‐drying in Spurr's resin or Epon reveal cellular plasma phases with very fine granularities and well defined membranes in negative contrast. This may be due to the preservation of the original structure of cellular macromolecules with a considerable amount of their hydration water. Sublimation studies with differently hydrated and cryofixed macromolecules are suggested to settle this issue.