Novel method for performing carbonic anhydrase histochemistry and immunocytochemistry on cryosections.

It is difficult to correlate structure with function in the kidney because of the extensive cell heterogeneity. Carbonic anhydrase (CA) is an enzyme that mediates renal acidification and is found predominantly in proximal tubule and collecting duct cells. We modified Hansson's method for histochemically identifying cellular CA activity on PLP-fixed rabbit kidney sections mounted on Millipore filters, and then removed the filters to perform peanut lectin and antibody labeling on the same sections. There was adequate preservation of morphology, and individual cells could be identified with CA activity in the cytosol and specific antibody or lectin labeling on the cell surfaces.     

Evaluation of tissue preparation methods and paired immunofluorescence staining for immunocytochemistry of lymphomas

Eight cross-linking fixatives were tested for preservation of extracellular or intracellular IgG, IgA, IgM, IgD, kappa and lambda light chains, J chain and secretory component. Most of the selected fixatives have been used in recent immunohistochemical studies of lymphoproliferative processes and comprised routine formalin, glutaraldehyde(1%)-formalin, Baker's formalin-calcium, formalin-sublimate, acetic acid(2%)-formalin-saline, Bouin's fluid, Susa fixative, and carbodiimide. The results obtained in artificial test substrates with defined amounts of IgG or IgA and in biological substrates (colon mucosa, tonsils, and different types of lymphomas) were compared by immunofluorescence with the antigenic preservation afforded by fixation in cold 96% ethanol (with or without inclusion of a pre-fixation 48 h washing period). An antigen concentration at least an eight-fold higher was necessary for detection with most other fixatives. Bouin's and Susa fixatives were peculiar in that they required antigen concentration 150 times higher for detection of IgG but only 3-8 times higher for IgA. Light chains were relatively well preserved by all fixatives except glutaraldehyde. For all cross-linking fixatives, the extent of antigenic masking depended on the concentration of environmental proteins, and the efficiency of unmasking with pronase or trypsin, therefore, varied with the location in the tissue. The J chain was particularly vulnerable to degradation during proteolytic treatment. The extensive masking of extracellular immunoglobulin in formalin-fixed tissue afforded a relatively good signal-to-noise ratio for immunoglobulin-producing cells when kappa and lambda chains were traced. Thus, differentiation between polyclonal and monoclonal B-cell processes on the basis of cytoplasmic labelling was often better in undigested sections. However, the light-chain type of membrane immunoglobulin could usually not be determined in directly fixed tissue. Ethanol fixation preceded by washing in saline afforded such determination and also preserved certain T-cell and HLA-DR antigens as well as diffuse alpha-naphthylbutyrate esterase. Reactive and malignant macrophages could further be traced by their cytoplasmic expression of L1 antigen, both in formalin- and ethanol-fixed material.     

Cryoelectron microscopy of refrozen cryosections

Cryoelectron microscopy makes it possible to record high-resolution detail from large and complex structures. However, its application to understanding cellular structure is limited by the requirement that samples should be no thicker than approximately 0.5-1 microm. Therefore it is important to develop the ability to section biological material so that it can be imaged in its native frozen state. Here we have adapted standard methods of preparing cryosections so that they can be imaged by cryoelectron microscopy. As used for immunolabeling, cryosections of chemically fixed, cryoprotected frozen rat cardiac muscle were thawed, applied to carbon-coated grids, and rinsed on a drop of buffer. The special step here is that the cryosections were then refrozen by being plunged into liquid ethane and imaged at approximately -180 degrees C in a 200-kV field-emission gun electron microscope. The unstained cryosections have good contrast, allowing the identification of optimum regions of the sample. Considerable fine detail is observed within the substructure of the sarcomere A-band and I-band. Fourier transform analysis of the micrographs shows that this method preserves high structural order, hence these sections are well-suited to 3D reconstruction. We conclude that this approach has considerable potential for obtaining intermediate- and high-resolution structural detail from bulk tissue.     

A modified mallory-cason staining procedure for large cryosections.

The classic Mallory-Cason staining procedure has been modified for application to sections "on tape" obtained from large deep frozen tissue specimens. These 20 microns cryosections are collected on tape from a large heavy duty cryomicrotome. The stained sections provide anatomical details that are not revealed by other techniques. The merit of this procedure is found in the support of modern medical modalities, both for research and educational purposes.     

Unfixed tissue for electron immunocytochemistry: a simple preparation method for colloidal gold localization of sensitive epitopes using ethanediol dehydration

Summary A quick, simple protocol is described for the preparation of tissue for electron immunocytochemistry without the use of fixatives or deleterious solvents. Fresh, normal human colon was rapidly dehydrated in ethanediol (ethylene glycol) then embedded directly in low-acid glycol methacrylate. Using both mono-and polyclonal antibodies, in conjunction with colloidal gold probes, a range of intra-and extracellular epitopes were localized; these epitopes included lysozyme, chromogranin, desmin and collagen IV. Overall, the tissue compared well with material fixed in glutaraldehyde, partially dehydrated and embedded in LR White acrylic resin. Ultrastructural detail was good and was further enhanced, without affecting probe density and epitope localization, by the addition of 1% tannic acid or 1% uranyl acetate to the dehydrant. The technique is applicable to a wide range of tissues, allowing excellent antigen retention which might prove useful for the immunolocalization of sensitive epitopes.     

Rapid polymerization of LR-White for immunocytochemistry

Summary London Resin (LR) White a hydrophilic embedding medium for immunocytochemistry, can be polymerized in a commercial microwave oven in seven minutes using the chemical accelerator benzoyl peroxide. In order to minimize the effects of heating, the polymerization vessel was maintained in an ice bath. We demonstrate that this procedure does not affect the antigenicity of either barley aleurone nuclease or of the catalytic and regulatory subunits of rat parotid cAMP-dependent protein kinase.     

Air-dried smears for optimal diagnostic immunocytochemistry

OBJECTIVE: To exploit formalin-postfixed, air-dried smears for diagnostic immunocytochemistry (ICC). STUDY DESIGN: A series of 144 cases of diagnostic fine needle cytology samples in which air-dried, supplementary smears were available was used to exploit postfixation in the process of antigenic stabilization and rescue for immunocytochemical staining. RESULTS: Postfixation with formalin and with a formalin/ethanol solution gave comparable results as far as recovery and immunocytochemical detection of most monoclonal and polyclonal antibodies. The visualization of the antibody reactions was often superior to that obtained with wet-fixed slides, probably due to the interaction of slow cell dehydration with their consequent optimal flattening observed with formalin postfixation after short rehydration in physiologic saline. CONCLUSION: Although wet fixation of cytopathologic slides in 95% ethanol represents a common standard for ICC, the usage of formalin-postfixed air-dried smears proved reliable and efficient for antigenic rescue and may enter routine usage in cytopathology laboratories. Moreover, in some instances, the visual evaluation of results was easier in the larger, well-flattened cells obtained in air-dried cells.     

Rapid polymerization of LR-white for immunocytochemistry.

London Resin (LR) White a hydrophilic embedding medium for immunocytochemistry, can be polymerized in a commercial microwave oven in seven minutes using the chemical accelerator benzoyl peroxide. In order to minimize the effects of heating, the polymerization vessel was maintained in an ice bath. We demonstrate that this procedure does not affect the antigenicity of either barley aleurone nuclease or of the catalytic and regulatory subunits of rat parotid cAMP-dependent protein kinase.     

Advances in imaging the interphase nucleus using thin cryosections

The mammalian genome is partitioned amongst various chromosomes and encodes for approximately 30,000 protein-coding genes. Gene expression occurs after exit from mitosis, when chromosomes partially decondense within the cell nucleus to allow the enzymatic activities that work on chromatin to access each gene in a regulated fashion. Differential patterns of gene expression evolve during cell differentiation to give rise to the over 200 cell types in higher eukaryotes. The architectural organisation of the genome inside the interphase cell nucleus, and associated enzymatic activities, reveals dynamic and functional compartmentalization of the genome. In this review, I highlight the advantages of Tokuyasu cryosectioning on the investigation of nuclear structure and function. Robert Feulgen Prize 2007 Winner lecture presented at the 49th Symposium of the Society for Histochemistry in Freiburg i.Br., Germany, 26–29 September 2007.     

Double-labeling of tissue containing the carbocyanine dye DiI for immunocytochemistry

The fluorescent carbocyanine dye DiI can be used for retrograde and anterograde labeling of neuronal pathways. To investigate the possible neurochemical identity of DiI-labeled neuronal cell bodies and terminals, we used a procedure for double-labeling of the same tissue with antisera to specific neuroactive substances. This procedure involves visualizing the immunohistochemical label with an FITC-conjugated secondary antiserum. Both labels can be viewed in the same tissue by fluorescence microscopy, and individual cell bodies and processes double-labeled with DiI and antiserum can be identified by switching between filter sets appropriate for rhodamine (to see the DiI labeling) and for fluorescein (to see the immunhistochemical labeling). The method has been used with primary antisera to excitatory and inhibitory amino acid neurotransmitters, as well as to neuropeptides, and is likely to be useful with antibodies against a wide variety of substances. Several other immunocytochemical methods were found to be incompatible with DiI labeling.     

Protocol for rapid fluorescence in situ hybridization of bacteria in cryosections of microarthropods

A protocol was developed to detect bacteria inhabiting microarthropods by means of small-subunit rRNA-targeted fluorescence in situ hybridization and microscopy. The protocol is based on cryosections of whole specimens. In contrast to more commonly applied paraffin-embedding techniques, the protocol is quicker and reduces the number of manipulations which might damage the microscopic material. The method allowed the study of the bacterial colonization of Folsomia candida (Collembola) and the detection of bacteria in both the gut and tissue.