Freeze-Fracture Replica Immunolabeling of Cryopreserved Membrane Compartments, Cultured Cells and Tissues.

Membrane topology information and views of membrane-embedded protein complexes promote our understanding of membrane organization and cell biological function involving membrane compartments. Freeze-fracturing of biological membranes offers both stunning views onto integral membrane proteins and perpendicular views over wide areas of the membrane at electron microscopical resolution. This information is directly assessable for 3D analyses and quantitative analyses of the distribution of components within the membrane if it were possible to specifically detect the components of interest in the membranes. Freeze-fracture replica immunolabeling (FRIL) achieves just that. In addition, FRIL preserves antigens in their genuine cellular context free of artifacts of chemical fixation, as FRIL uses chemically unfixed cellular samples that are rapidly cryofixed. In principle, the method is not limited to integral proteins spanning the membrane. Theoretically, all membrane components should be addressable as long as they are antigenic, embedded into at least one membrane leaflet, and accessible for immunolabeling from either the intracellular or the extracellular side. Consistently, integral proteins spanning both leaflets and only partially inserted membrane proteins have been successfully identified and studied for their molecular organization and distribution in the membrane and/or in relationship to specialized membrane domains. Here we describe the freeze-fracturing of both cultured cells and tissues and the sample preparations that allowed for a successful immunogold-labeling of caveolin1 and caveolin3 or even for double-immunolabelings of caveolins with members of the syndapin family of membrane-associating and -shaping BAR domain proteins as well as with cavin 1. For this purpose samples are cryopreserved, fractured, and replicated. We also describe how the obtained stabilized membrane fractures are then cleaned to remove all loosely attached material and immunogold labeled to finally be viewed by transmission electron microscopy.

Microscopy of membrane lipids: how precisely can we define their distribution?

Membrane lipids form the basic framework of biological membranes by forming the lipid bilayer, but it is becoming increasingly clear that individual lipid species play different functional roles. However, in comparison with proteins, relatively little is known about how lipids are distributed in the membrane. Several microscopic methods are available to study membrane lipid dynamics in living cells, but defining the distribution of lipids at the submicrometre scale is difficult, because lipids diffuse quickly in the membrane and most lipids do not react with aldehydes that are commonly used as fixatives. Quick-freezing appears to be the only practical method by which to stop the lipid movement instantaneously and capture the molecular localization at the moment of interest. Electron microscopic methods, using cryosections, resin sections, and freeze-fracture replicas are used to visualize lipids in quick-frozen samples. The method that employs the freeze-fracture replica is unique in that it requires no chemical treatment and provides a two-dimensional view of the membrane.

Fundamental technical elements of freeze-fracture/freeze-etch in biological electron microscopy.

Freeze-fracture/freeze-etch describes a process whereby specimens, typically biological or nanomaterial in nature, are frozen, fractured, and replicated to generate a carbon/platinum "cast" intended for examination by transmission electron microscopy. Specimens are subjected to ultrarapid freezing rates, often in the presence of cryoprotective agents to limit ice crystal formation, with subsequent fracturing of the specimen at liquid nitrogen cooled temperatures under high vacuum. The resultant fractured surface is replicated and stabilized by evaporation of carbon and platinum from an angle that confers surface three-dimensional detail to the cast. This technique has proved particularly enlightening for the investigation of cell membranes and their specializations and has contributed considerably to the understanding of cellular form to related cell function. In this report, we survey the instrument requirements and technical protocol for performing freeze-fracture, the associated nomenclature and characteristics of fracture planes, variations on the conventional procedure, and criteria for interpretation of freeze-fracture images. This technique has been widely used for ultrastructural investigation in many areas of cell biology and holds promise as an emerging imaging technique for molecular, nanotechnology, and materials science studies.

Electron microscopy of Paramecium (Ciliata).

Paramecium may be the best known single-celled organism in existence (Hausmann et al., 2003). Today its image often appears on television programs where the producers use it to illustrate a stereotypic microorganism, be it pathogenic or nonpathogenic, prokaryotic or eukaryotic. Paramecium was probably one of the first single-celled organisms observed with a light microscope by the Dutch cloth vendor and amateur lens maker Antoni van Leuwenhoek (1632-1723) (Dobell, 1932), and it is still being investigated in the 21st century in the days of the modern electron microscopes.

Freeze-fracture electron microscopy.

The freeze-fracture technique consists of physically breaking apart (fracturing) a frozen biological sample; structural detail exposed by the fracture plane is then visualized by vacuum-deposition of platinum-carbon to make a replica for examination in the transmission electron microscope. The four key steps in making a freeze-fracture replica are (i) rapid freezing, (ii) fracturing, (iii) replication and (iv) replica cleaning. In routine protocols, a pretreatment step is carried out before freezing, typically comprising fixation in glutaraldehyde followed by cryoprotection with glycerol. An optional etching step, involving vacuum sublimation of ice, may be carried out after fracturing. Freeze fracture is unique among electron microscopic techniques in providing planar views of the internal organization of membranes. Deep etching of ultrarapidly frozen samples permits visualization of the surface structure of cells and their components. Images provided by freeze fracture and related techniques have profoundly shaped our understanding of the functional morphology of the cell.

Cryo-SEM and subsequent TEM examinations of identical neural tissue specimen.

Low temperature scanning electron microscopy of frozen-fractured specimens under cryo-protecting, non-dehydrating, and non-etching "wet" conditions, that is, direct cryo-SEM, was followed by transmission electron microscopy (TEM) with the same neural tissue specimens. In comparison to replica TEM, direct cryo-SEM can obtain images with a smooth gradation of contrast. The major advantage of direct cryo-SEM combined with TEM was that time was saved in SEM preparation. It had a high potentiality at a wide-range survey of multi-dimensional specimen structures with less-artifacts. Because the specimens were prepared as quickly as possible under "wet" conditions, the target structures could be examined under lower through higher magnifications. In the present study, neuronal and glial elements, such as plasma membranes and cell organelles that include the synaptic vesicles, were localized on the fractured surface. In subsequent TEM examination, it was confirmed that the underlying internal structures could be further characterized from cytological as well as molecular biological aspects. In addition, direct cryo-SEM distinctively demonstrated small intra-membrane particles (ca. 10 nm in diameter). However, due to electron lucency, they could not be confirmed in the re-processed TEM specimens. Applying the present protocol, stereological and internal architectural examinations of the neural tissues have been simultaneously conducted at ultra-fine levels.

Direct observations of freeze-etching processes of ice-embedded biomembranes by atomic force microscopy.

We have fabricated a cryogenic atomic force microscope that is designed for structural investigation of freeze-fractured biological specimens. The apparatus is operated in liquid nitrogen gas at atmospheric pressure. Freeze-fracturing, freeze-etching and subsequent imaging are carried out in the same chamber, so that the surface topography of a fractured plane is easily visualized without ice contamination. A controlled superficial sublimation of volatile molecules allows us to obtain three-dimensional views of ultrastructures of biological membranes.

Molecular anatomy of freeze-fractured ultra-high-molecular-weight polyethylene as determined by low-voltage scanning electron microscopy.

Morphological similarities between virgin ultra-high-molecular-weight polyethylene (UHMWPE) powder and debris retrieved from failed UHMWPE total joint implants motivated this study's objective: to establish the internal microstructural features of consolidated UHMWPE. Cylindrical specimens were cored from a gamma-irradiation-sterilized tibial component (extruded from GUR 415 resin), and then these specimens were freeze-fractured at high strain rates. Low-voltage scanning electron microscopy was used to examine these surfaces. Two types of areas were observed. The first were uniform, homogeneous, and continuous with microridge structures (45-70 nm wide) and hillocks (0.1-0.3 microns in diameter). The second was nonhomogeneous and discontinuous with febrils (10-200 nm long), microridges, fenestra as small as 20 nm, and large crater-like structures (6-12 microns in diameter). Many of the submicronsized structures observed were similar to the structures observed in virgin powder, as well as those observed by others from wear debris retrieval studies. These data support the hypotheses that wear debris originates, in part, from structures originally present in the powder resin, and that these structures retain their identity throughout consolidation, machining, and in vivo wear, and are released into periprosthetic tissues as wear debris.

Double replicas allow the obtention of longitudinally freeze-fractured Trypanosoma cruzi.

The double replica device was used to obtain freeze-fracture replicas of gently pressed cells, allowing the visualization of a large number of longitudinally fractured epimastigote and trypomastigote forms of Trypanosoma cruzi. This technique revealed large areas of the plasma membrane, the region of attachment of the flagellum to the cell body and the branched mitochondria.

Double replicas allow the obtention of longitudinally freeze-fractured Trypanosoma cruzi

The double replica device was used to obtain freeze-fracture replicas of gently pressed cells, allowing the visualization of a large number of longitudinally fractured epimastigote and trypomastigote forms of Trypanosoma cruzi. This technique revealed large areas of the plasma membrane, the region of attachment of the flagellum to the cell body and the branched mitochondria.

Double replicas allow the obtention of longitudinally freeze-fractured Trypanosoma cruzi

The double replica device was used to obtain freeze-fracture replicas of gently pressed cells, allowing the visualization of a large number of longitudinally fractured epimastigote and trypomastigote forms of Trypanosoma cruzi. This technique revealed large areas of the plasma membrane, the region of attachment of the flagellum to the cell body and the branched mitochondria.(AU)

A stimulus timing device for capturing fast physiologic events by quick-freezing.

A timing device was designed that, in conjunction with an impact type of quick-freezing apparatus and an externally-triggerable stimulus generator, allows the application of an electrical stimulus to a muscle preparation at a selected time interval before quick-freezing and the measurement of the interval with submillisecond precision. This is needed for stopping fast physiological events in calcium release and excitation-contraction coupling and allows studying the morphological parameters (by freeze-fracture and freeze-substitution) and elemental distributions (by x-ray microanalysis) as a function of time after stimulation. The device should be adaptable for use with most equipment designed for quick-freezing electrically excitable tissue by impact on a cold solid surface.

Improved structural detail in freeze-fracture replicas: high-angle shadowing of gap junctions cooled below -170 degrees C and protected by liquid nitrogen-cooled shrouds.

In conventional freeze-fracture replicas, precise complementarity of membrane faces is seldom achieved. In a model system frequently used to evaluate replica quality, vertebrate gap junctions are usually visualized as patches of 8-10 nm P-face intramembrane particles separated by 1-2 nm spaces, while E-face images are represented by 4-6 nm conical pits separated by 5-7 nm wide membrane ridges. However, that disparity in sizes of particles versus pits, as well as the disparity in the widths of the spaces separating particles versus pits, suggests that a significant reduction in complementarity of membrane faces has occurred. In this investigation, a JEOL JFD-9000 freeze-etch machine was modified so that fracturing and replication could be performed at temperatures much colder than commonly employed. With the addition of cryopumps to improve overall vacuum and the installation of optically tight LN2-cooled shrouds surrounding the specimen and the knife, water vapor contamination arising from all sources within the vacuum chamber was reduced substantially, allowing replicas to be made at temperatures down to -185 degrees C. With the specimen at these much colder temperatures, water vapor released by the heat of cleaving was also reduced significantly, providing additional improvement in replica quality. In addition, with higher shadowing angles (greater than 60 degrees) and with the specimen at a much lower temperature, the grain size of the platinum film was noticeably reduced, thereby improving resolution at the molecular level. Under these improved conditions, replicas of rat liver gap junctions revealed that many of the P-face IMPs were tubes 6-7 nm in diameter, but that other IMPs had been stretched and distorted by the fracturing process. More important, however, these high resolution replicas revealed that the replicas of the E-face pits represented three-dimensional molecular casts of the transmembrane proteins comprising the connexon hexamer. This means that before they were replicated, the E-face pits faithfully maintained the shape that the IMPs had before fracturing. These more detailed images revealed a new structure in the center of each E-face pit: a 2-3 nm "peg" that may represent the frozen aqueous matrix of the connexon ion channel that remained after elastic extraction of the surrounding six connexin molecules. Thus, high-angle shadowing at very low specimen temperature under virtually non-contaminating conditions has revealed a new level of detail for membrane structure in freeze-fracture replicas.

Design and operation of a simple environmental chamber for rapid freezing fixation.

Rapid freezing is the most important step in sample preparation for freeze-fracture and other cryotechniques for electron microscopy. We present the design and operation of a simple environmental chamber coupled to a plunger-driven freezing device that has provided simple and reliable freezing from temperatures and humidities other than ambient. The chamber can be constructed and operated with equipment and techniques common to most electron microscopy labs. Temperature control of +/- 0.1 degree C and relative humidities of greater than 90% were provided over the range -5-60 degrees C. Typical electron micrographs showing well preserved structures comparable to jet-freezing are presented.

A stopped-flow/rapid-freezing machine with millisecond time resolution to prepare intermediates in biochemical reactions for electron microscopy.

We have developed an instrument capable of freezing transient intermediates in rapid biochemical reactions for subsequent freeze-fracturing, replication, and viewing by transmission electron microscopy. The machine combines a rapid mixing unit similar to one widely used in chemical kinetics (Johnson, 1986) with a propane jet freezing unit previously used to prepare static samples for freeze-fracturing (Gilkey and Staehelin, 1986). The key element in the system is a unique thin-walled flow cell of copper that allows for injection and aging of the sample, followed by rapid freezing. During freeze-fracturing, a tangential cut is made along the wall of the flow cell to expose the sample for etching and replication. The dead time required for mixing and injection of the reactants into the flow cell is less than 5 ms. Electronic controls allow one to specify, on a millisecond time scale, any time above 5 ms between initiation of the reaction and quenching by rapid freezing.

Quick-freeze, deep-etch replication of cells in monolayers.

We have made several technical improvements for quick-freeze, deep-etch replication of monolayers of cells grown on, or attached to, glass coverslips. Cells studied include muscle cells of rat and Xenopus cultured on glass coverslips, and erythrocytes attached to coverslips coated with poly-L-lysine. We describe methods for identifying particular areas of cultures, e.g., clusters of acetylcholine receptors on muscle cells, by light microscopy and then relocating these areas after replication. For good preservation of structure by quick-freezing, it is necessary to ensure that the surface to be frozen is covered by a minimum depth of water (less than 10 microns). Insufficient or excess water left on the sample during freezing causes recognizable artifacts in its replica. We describe two ways to control the water table--one by improving visual control of water removal, the other by blowing excess water off the sample surface with a jet of nitrogen applied during its descent to the freezing block. Finally, we describe a new specimen holder that allows us to etch and replicate six samples at once with good thermal contact between the stage and samples.

An optimized freeze-fracture replication procedure for human skin.

This in vitro study aimed at substantial modification of the freeze-fracture replication technique (FFRT) which should result in an optimal visualization of the ultrastructure of human skin. The technique was modified in two ways: firstly, the conventional sample holders such as gold cups and copper plates were replaced by silver cylinders (83.5% silver, 16.5% copper) resulting in almost perpendicular cross fractures through the skin. Secondly, the replica cleaning procedure was optimized through the following sequence of treatments. Firstly, a mild tissue destruction was obtained by simultaneous lipid solvation and water extraction with absolute methanol (20 h), followed by protein denaturation with dimethyl sulfoxide (DMSO, 24 h). Subsequently, a final treatment was given using an alkaline sodium hypochlorite solution (20% KOH/13% NaClO; 1:3 v/v, 4 d). After rinsing the replicas for 45 min in aqua bidest, they were mounted on copper grids and examined in the transmission electron microscope (TEM). The combination of the unorthodox fracturing method and the optimized cleaning procedure yielded large, practically undamaged and very clean replicas of near perpendicular cross fractures through human skin. Common handicaps related to current freeze-fracture procedures when applied to skin, such as incomplete cleaning and fragmentation of replicas and oblique or irregular fracturing planes, can largely be avoided in this way. In this paper a complete description of the method is given, and a number of advantages are illustrated with the aid of TEM micrographs.