Development of a Plastic Embedding Method for Large-Volume and Fluorescent-Protein-Expressing Tissues

Fluorescent proteins serve as important biomarkers for visualizing both subcellular organelles in living cells and structural and functional details in large-volume tissues or organs. However, current techniques for plastic embedding are limited in their ability to preserve fluorescence while remaining suitable for micro-optical sectioning tomography of large-volume samples. In this study, we quantitatively evaluated the fluorescence preservation and penetration time of several commonly used resins in a Thy1-eYFP-H transgenic whole mouse brain, including glycol methacrylate (GMA), LR White, hydroxypropyl methacrylate (HPMA) and Unicryl. We found that HMPA embedding doubled the eYFP fluorescence intensity but required long durations of incubation for whole brain penetration. GMA, Unicryl and LR White each penetrated the brain rapidly but also led to variable quenching of eYFP fluorescence. Among the fast-penetrating resins, GMA preserved fluorescence better than LR White and Unicryl. We found that we could optimize the GMA formulation by reducing the polymerization temperature, removing 4-methoxyphenol and adjusting the pH of the resin solution to be alkaline. By optimizing the GMA formulation, we increased percentage of eYFP fluorescence preservation in GMA-embedded brains nearly two-fold. These results suggest that modified GMA is suitable for embedding large-volume tissues such as whole mouse brain and provide a novel approach for visualizing brain-wide networks.     

Immunoelectron microscopic demonstration of thyroglobulin and thyroid hormones in rat thyroid gland

We have developed a post-embedding immunogold technique for electron microscopic localization and quantitation of thyroglobulin (TG), thyroxine (T4), and triiodothyronine (T3) in rat thyroid. Labeling for TG was located on rough endoplasmic reticulum, Golgi apparatus, exocytotic vesicles, luminal colloid, colloid droplets, and lysosomes, whereas labeling for thyroid hormones was located on luminal colloid, colloid droplets, and lysosomes. We tested different procedures of fixation, dehydration, embedding, polymerization, and immunoincubation to optimize ultrastructural preservation and immunolabeling. Fixation with glutaraldehyde and osmium was possible with retained antigenicity. Dehydration temperature and the choice of embedding resin were the two crucial factors for good immunolabeling. Low-temperature dehydration greatly improved immunolabeling and could be combined with embedding in the methacrylate LR White or the epoxide Agar 100 (equivalent of Epon 812) polymerized at 40-60 degrees C, as the temperature during subsequent embedding and polymerization was of little importance for the immunoreactivity. Labeling on LR White sections was always higher than on Agar 100 sections. Various etching procedures were tested without improved specific labeling. Etching with hydrochloric acid gave nonspecific labeling of certain cell compartments.     

Ultrastructural and nuclear antigen preservation after high-pressure freezing/freeze-substitution and low-temperature LR White embedding of HeLa cells

A protocol for high-pressure freezing and LR White embedding of mammalian cells suitable for fine ultrastructural studies in combination with immunogold labelling is presented. HeLa S3 cells enclosed in low-temperature gelling agarose were high-pressure frozen, freeze-substituted in acetone, and embedded in LR White at 0°C. The morphology of such cells and the preservation of nuclear antigens were excellent in comparison with chemically fixed cells embedded in the same resin. The immunolabelling signal for different nuclear antigens was 4-to-13 times higher in high-pressure frozen than in chemically fixed cells. We conclude that one can successfully use high-pressure freezing/freeze-substitution and LR White embedding as an alternative of Lowicryl resins.     

Immunogold labeling of luciferase in the luminous bacterium Vibrio harveyi after fast-freeze fixation and different freeze-substitution and embedding procedures

We studied the ultrastructural localization of luciferase on sections of the bioluminescent bacterium Vibrio harveyi by indirect immunogold staining, using a polyclonal antiluciferase antibody and the usual control tests, after chemical fixation or fast-freeze fixation (FFF) followed by different freeze-substitution (FS) procedures and embedding in either Epon or LR White. After liquid fixation with glutaraldehyde and paraformaldehyde and LR White embedding, labeling occurred over the cytoplasm but not over the condensed nucleoid. Epon embedding almost abolished it. FFF-FS considerably improved the morphological preservation and revealed cytoplasmic "patches" with a complex ultrastructure in Epon sections. The preservation was always less good in LR White. The patches were densely labeled, even in Epon sections, after FS in acetone. However, labeling intensity was 3.7 times greater in LR White than in Epon. With both resins, labeling diminished similarly when fixative agents were present in the FS medium. The localization of luciferase in the cytoplasm and particularly in the patches is discussed.     

Evaluation of LR white resin for histology of the undecalcified rat tibia

Histology of plastic embedded undecalcified bone represents a challenging problem to the histotechnologist. We outline here an exploration of LR White resin as a suitable medium for histologic study of undecalcified rat tibia. A procedure was developed for light microscopy of rat tibia embedded in LR White and sectioned by sawing-grinding technics. The specimens were fixed in 10% neutral buffered formalin or alcohol-acetic acid-formol, dehydrated in ethanol, defatted in chloroform followed by resin infiltration and heat-curing of embedded blocks. The procedure of dehydration, defatting, infiltration, and polymerization can be completed within 10 days. Cold curing with accelerator provided by the manufacturer did not yield superior results compared to blocks cured with heat. Thick sections were obtained using a diamond wire saw, attached to plexiform slides, then ground and polished. Surface staining with Von Kossa silver reagent or toluidine blue revealed satisfactory morphological preservation of the mineralized bone sections. Artifacts like small bubbles appeared occasionally and could not be avoided despite prolonged infiltration or cold curing of blocks. Our method is relatively simple for base-line histologic study of rat tibia. The method offers advantages such as easy adaptability, reliable stainability, contrast, and resolution of bone architecture and marrow cells. Two other embedding media, Micro-Bed resin and Unicryl, were also tested, but produced inferior results.     

Use of LR white resin for post-embedding immunolabelling of brain tissue.

The object of this study was to investigate the applicability of the acrylic resin 'LR White' to immunolabelling of various antigenic determinants in aldehydefixed rat CNS tissue. Antibodies were used, which worked well in paraffin sections and therefore were suitable to detect antigens resistant to complete dehydration and heat. Different LR White embedding protocols were employed in order to select the preparation conditions that adequately preserved both the antigenicity and fine structure. Specimens were completely dehydrated with up to 100% ethanol, which was followed by various infiltration times with LR White monomer. Polymerization of the resin was induced by heat, a chemical catalytic procedure (accelerator), or ultraviolet (UV) light. Paraffin, as well as semithin and ultrathin LR White sections were incubated with antibodies reacting to antigens located on the cell surface (stage-specific embryonic antigen-1; SSEA-1), within the plasma membrane (myelin basic protein), in the cytosol (HNK-1, S100 protein), in the cytoskeleton (GFAP, vimentin, neurofilament protein, INT-FIL), and in the extracellular matrix (laminin). All of the examined antigens were immunocytochemically detectable in paraffin-embedded material, while the carbohydrate moieties, HNK-1 and SSEA-1, were not immunoreactive in LR White sections. However, in cryostat sections processed for pre-embedding immunoelectron microscopy, the HNK-1 epitope and SSEA-1 were immunolabelled. Polymerization carried out under UV light led to better structural preservation of brain tissue than resin cured with heat or catalyst. The length of prior infiltration with monomer apparently had no effect on tissue preservation. Consequently, UV light-induced polymerization of LR White gives acceptable morphology of brain tissue. However, the use of this acrylic resin is restricted to the detection of some CNS antigens only.     

Immunogold localization of TGFβ 1 protein and mRNA in human skin using a colloidal gold/digoxygenin system

Tissue preservation, and immunogold cytochemical and in-situ hybridization labelling intensities vary according to the preparatory protocols used. We wished to determine which preparative protocols produce optimal preservation, protein and mRNA labelling. Nine combinations of fixative and embedding resin were therefore studied using postembedding immunoelectron microscopy and a novel immunogold digoxygenin in situ hybridization (ISH) system, to quantitate the presence of transforming growth factor beta 1 (TGF 1) protein and message in human skin. The best preservation was observed in tissue fixed in 1% glutaraldehyde and embedded in LR White resin or low acid glycolmethacrylate resin (LA-GMA). Preservation was poor in tissue fixed with 1% glutaraldehyde and fair in 4% paraformaldeyde, when embedded in Unicryl. Ethanediol dehydration coupled with LA-GMA embedding resulted in reasonable preservation. Based on quantitative measures of the labelling density for TGF 1 protein and mRNA, immunogold labelling was adequate with 1% glutaraldehyde fixation coupled with LR White or LA-GMA resins, and also with 4% paraformaldehyde and LR White resin, but was best with ethanediol dehydration and LA-GMA embedding. ISH labelling under basal conditions was best in LA-GMA with 1% glutaraldehyde or 4% paraformaldehyde. The ISH label in tissue fixed with 1% glutaraldehyde and embedded in LA-GMA was significantly increased by treatment with proteinase K. Overall, ethanediol dehydration was associated with a good immunoelectron microscopic (IEM) label while LA-GMA with 1% glutaraldehyde or 4% paraformaldehyde resulted in a consistently detectable ISH label. LA-GMA embedding with 1% glutaraldehyde fixation gave a good result with both IEM and ISH labelling.     

Post embedding immunoelectron microscopy of human breast cancer: a comparison of three acrylic resins

Summary The suitability of three acrylic resins for the immunoelectron microscopical localization of cell surface and cytoskeletal antigens in surgically excised, immersion fixed human breast cancer, using an immunogold system, has been assessed.Good localization of milk fat globule membrane was achieved with LR White, LR Gold and Lowicryl K11M, although the embedding schedule for LR White had to be modified. The best results were achieved with Lowicryl K11M. Only scanty labelling of actin and cytokeratin was seen in LR White embedded tissue, whereas there was clear localization in LR Gold and Lowicryl K11M embedded samples. Tubulin and -actinin was detected at low level in tissues in the low temperature embedding resins, but not in LR White embedded samples. The morphology of the latter was poorer, and there was greater variability in ultrastructure and labelling.Of the two low temperature embedding resins, Lowicryl K11M gave slightly better results. However, the advantages could be outweighed by the problem incurred in achieving the low temperatures, and by poorer handling properties than LR Gold.     

Comparison of methods of high-pressure freezing and automated freeze-substitution of suspension cells combined with LR White embedding

In this study we present an optimized method of high-pressure freezing and automated freeze-substitution of cultured human cells, followed by LR White embedding, for subsequent immunolabeling. Also, the influence of various conditions of the freeze-substitution procedures such as temperature, duration, and additives in the substitution medium on the preservation of cryo-immobilized cells was analyzed. The recommended approach combines (1) automated freeze-substitution for high reproducibility and minimizing human-derived errors; (2) minimal addition of contrasting and fixing agents; (3) easy-to-use LR White resin for embedment; (4) good preservation of nuclei and nucleoli which are usually the most difficult structures to effectively vitrify and saturate in a resin; and (5) preservation of antigens for sensitive immunogold labeling.     

Application of microwave technology to the processing and immunolabeling of plastic-embedded and cryosections.

We have adapted existing microwave irradiation (MWI) protocols and applied them to the processing and immunoelectron microscopy of both plastic-embedded and frozen sections. Rat livers were fixed by rapid MW irradiation in a mild fixation solution. Fixed liver tissue was either cryosectioned or dehydrated and embedded in Spurr's, Unicryl, or LR White resin. Frozen sections and sections of acrylic-embedded tissue were immunolabeled in the MW oven with an anti-catalase antibody, followed by gold labeling. Controls were processed conventionally at room temperature (RT). The use of MWI greatly shortened the fixation, processing, and immunolabeling times without compromising the quality of ultrastructural preservation and the specificity of labeling. The higher immunogold labeling intensity was achieved after a 15-min incubation of primary antibody and gold markers under discontinued MWI at 37C. Quantification of the immunolabeling for catalase indicated a density increase of up to fourfold in the sections immunolabeled in the MW oven over that of samples immunolabeled at RT. These studies define the general conditions of fixation and immunolabeling for both acrylic resin-embedded material and frozen sections.     

Modern acrylics for post-embedding immunostaining techniques

We describe two methods for rapid processing of biological tissues into LR White acrylic plastic. Both methods make use of LR White's compatibility with small amounts of water, enabling non-osmicated tissue to be only partially dehydrated before infiltration with the plastic, a procedure that improves the sensitivity of post-embedding immunocytochemistry. In addition, both methods are designed to reduce the time for which tissue is exposed to the damaging influence of the plastic monomer, which can cause extraction and sudden shrinkage. The tissue example used in the first method is immersion-fixed, surgically removed human pituitary which, by virtue of its thorough fixation, can be processed quickly at 50 degrees C using catalytic polymerization at room temperature. The concentration of the catalyst is critically set to prevent the temperature rising above 60 degrees C in the tissue blocks. Penetration of immunoperoxidase reagents into 330-nm LR White sections is demonstrated and possible modes of action are discussed. When "lightly" fixed tissue is processed as above, serious polymerization artifacts can result from autocatalysis. A second method, based on the first but employing slower polymerization at 0 degrees C, has therefore been developed. The high level of fine structure that can be retained using this method is illustrated by the demonstration of the trans-tubular Golgi in perfusion-fixed kidney of rat. Biotinylated lectin is localized to cells of the kidney proximal tubule with streptavidin-colloidal gold, to illustrate tissue reactivity. In a second example, the structure of the bacterial cell envelope is shown to be similar in appearance after partial dehydration and LR White embedding to that seen after progressive lowering of temperature, dehydration, and Lowicryl embedding.     

Demonstration of anionic sites on the luminal and abluminal fronts of endothelial cells with poly-L-lysine-gold complex

An attempt was made to demonstrate the anionic sites on the endothelial cell (EC) surfaces of mouse brain micro-blood vessels (MBVs) after embedding of tissue samples in hydrophilic media: Lowicryl K4M, LR White, and Polyamph-10. As a cationic probe, poly-L-lysine-gold complex (PLG), prepared according to the procedure of Skutelsky and Roth (J Histochem Cytochem 34:693, 1986), was used. In ultra-thin sections of brain samples embedded in Lowicryl K4M and LR White, the anionic sites were demonstrated in the entire cross-section of the vessel wall. After embedding in Polyamph-10, however, the anionic sites could not be detected. Brain capillaries, representing blood-brain barrier type MBVs, showed polar distribution of anionic sites, evidenced by more intense labeling of luminal than of abluminal plasma membrane of the EC. Some differences in labeling of ECs and of basement membrane in arterioles and venules were also noted. The use of cationic gold and the ultra-thin sections of tissue samples embedded in hydrophilic media (Lowicryl K4M and LR White) seems to be a promising new method for detection of anionic constituents located on both luminal and abluminal surfaces of the EC, in the basement membrane, and in other components of the vessel wall.     

Applicability of using acrylic resins in post-embedding ultrastructural immunolabelling of human neutrophil granule proteins

Summary In this study, quantitative assessments were carried out, (1) by light microscopy during tissue preparation for electron microscopy and (2) by electron microscopy after on-grid immunogold staining, to determine the suitability of using LR White and Lowicryl K4M thin sections to identify lactoferrin and elastase in the granules of human neutrophil leucocytes. Quantitative assessment of the effect of fixation, dehydration and embedding on the preservation of antigenicity during tissue preparation for electron microscopy, using light microscopic peroxidase anti-peroxidase immunocytochemistry, enabled the selection of preparation conditions that adequately preserved both antigenicity and ultrastructure. OsO₄ post-fixation, following primary aldehyde fixation, improved the retention of antigenicity during dehydration and embedding and the preservation of fine structure. Partial rather than complete dehydration retained more of the antigenicity. The efficiency, sensitivity and resolution of immunolabelling and the ultrastructure and quality of sections achieved after embedding in LR White were superior to those obtained after embedding in Lowicryl K4M. Consequently room temperature embedding in LR White following double fixation and partial dehydration is a better and more reliable preparation technique than low-temperature embedding in Lowicryl K4M following single fixation and partial dehydration for localizing lactoferrin and elastase to the specific and primary granules respectively in human neutrophilic granulocytes by the on-grid immunogold staining method.     

Visualization of identified GFP-expressing cells by light and electron microscopy.

We have developed a procedure for visualizing GFP expression in fixed tissue after embedding in LR White. We find that GFP fluorescence survives fixation in 4% paraformaldehyde/0.1% glutaraldehyde and can be visualized directly by fluorescence microscopy in unstained, 1 microm sections of LR White-embedded material. The antigenicity of the GFP is retained in these preparations, so that GFP localization can be visualized in the electron microscope after immunogold labeling with anti-GFP antibodies. The ultrastructural morphology of tissue fixed and embedded by this protocol is of quality sufficient for subcellular localization of GFP. Thus, expression of GFP constructs can be visualized in living tissue and the same cells relocated in semithin sections. Furthermore, semithin sections can be used to locate GFP-expressing cells for examination by immunoelectron microscopy of the same material after thin sectioning.     

Ultrastructural localization of HTLV-I gag proteins p19 and p24 by single and double immunogold labeling

We developed a post-embedding immunogold labeling procedure for the ultrastructural localization of the HTLV-I gag proteins p19 and p24 by the use of monoclonal antibodies (MAb). Both antigens were shown to withstand fixation with 1% glutaraldehyde. In addition, p19 antigenicity was found not to be affected by post-fixation with 1% osmium tetroxide. The choice of resin played a decisive role in the retention of antigenicity. P19 was preserved in Lowicryl K4M as well as in LR White, whereas p24 was preserved only in Lowicryl. Both p19 and p24 were found to be localized on the HTLV-I virions themselves, whereas no positive immunostaining could be observed on the infected cells. In Lowicryl-embedded samples, in which both antigens had been preserved, a double immunogold labeling procedure was performed that allowed the co-localization of p19 and p24 on the same section. In osmicated LR White-embedded samples the quality of ultrastructural preservation of HTLV-I virions was found to be comparable to results obtained with the traditional glutaraldehyde-osmium tetroxide-epoxy resin processing.     

Applications of plastic embedding to electron microscopic immunocytochemistry and in situ hybridization in observations of production and secretion of peptide hormones.

Plastic embedding has been used to localize various antigens in conjunction with immunohistochemistry. Peptide hormones have been among the antigens that have been studied extensively. Recent application of water-soluble plastics such as LR White and Lowicryl has extended the ranges of detectable antigens and enabled the observation of antigen-antigen or mRNA-antigen combinations. This review article deals with technical aspects, procedures, and applications in endocrine cells.     

Immunocytochemistry of contractile and cytoskeletal proteins in smooth muscle: Lowicryl,LR White,and polyvinylalcohol compared

Summary Three embedding media have been compared with respect to post-embedding immunolabeling of contractile and cytoskeletal antigens in aldehyde-fixed smooth muscle tissue: the methacrylate derivates lowicryl K4M (cured at –35 or 60°C) and LR White (cured at 0 or 60°C) and the water soluble resin, polyvinylalcohol (dried at 60°C). Measurements of intensity of labeling of ultrathin sections in the fluorescence microscope showed that five antigens (actin, myosin light chain, tropomyosin, filamin and vinculin) reacted more or less equally with their respective antibodies in all the embedding media, including those cured at 60°C. One antibody (anti-light meromyosin) reacted well only with polyvinylalcohol-embedded tissue. In contrast to the relative invariance of antibody reactivity between media clear differences in the preservation of ultrastructural integrity were observed. Embedding in polyvinylalcohol (dried at 60°C) and in Lowicryl (cured at –35°C) resulted in superior preservation as compared to Lowicryl or LR White cured at 60°C. Examples of uitrastructural immunocytochemistry with the antibodies against filamin and myosin light chain, using the immunogold staining procedure are presented: the sites of localization by these antibodies were the same with all the media tried. The relative merits of the different methods are discussed.Abbreviations EGTA Ethyleneglycol-bis(-amino ethyl ether)N,N,N,N-tetra acetic acid - PIPES 1,4-Piperazinediethanesulfonic acid - LR London Resin     

Immunodetection of low concentrations of ovalbumin in cryoprocessed quail oviduct cells by semi-automatic quantitative analysis

Summary— In a previous paper (Quintana et al, Biol Cell 72, (1991) 167–180) we reported the anti-ovalbumin antibody immunolabeling in the cytoplasm of tubular gland cells from cryofixed, cryosubstituted and acrylic-resin embedded quail oviduct. To confirm these preliminary visual observations, we have carried out a semi-automatic quantitative study of immunogold labeling. The quantitative results confirm the previous data. In addition, we found a significantly higher immunolabeling with low temperature Lowicryl K11M embedding procedure as compared with high temperature LR White embedding.     

Colocalization of luciferin binding protein and luciferase to the scintillons ofGonyaulax polyedra revealed by double immunolabeling after fast-freeze fixation

Summary Two proteins,Gonyaulax luciferase and the luciferin binding protein, are involved in the bioluminescent reaction of the unicellular marine algaGonyaulax polyedra. Using antibodies raised separately against the purified proteins, their ultrastructural localizations were visualized by double immunogold labeling on sections after fast-freeze fixation, freeze-substitution and embedding in Epon or in LR White. Gold particles of two sizes attached to the secondary antibodies allowed the two primary antibodies to be distinguished. The two colocalized to cytoplasmic densifications (scintillons), which occurred in close association with the vacuolar membrane near the periphery of the cell. They also occurred in the cytoplasm of the Golgi area, either over densifications without associated membranes (prescintillons), or as very small colocalizations not associated with any evident cytoplasmic differentiation. No other site of colocalization was observed, thus unambiguously establishing the ultrastructural identity of the bioluminescent organelles.Abbreviations FFF fast-freeze fixation - FS freeze-substitution - IGS immunogold staining - LBP luciferin binding protein - PBS phosphate buffered saline - TBS tris-buffered saline Dedicated to the memory of Professor Beatrice Marcy Sweeney     

Histological investigation of organisms with hard skeletons: a case study of siliceous sponges.

Siliceous and calcareous sponges commonly are treated with acid to remove the spicules prior to embedding and cutting for histological investigations. Histology of spiculated sponge tissue represents a challenging problem in sponge histotechnology. Furthermore, fluorescence in situ hybridization (FISH), a key method for studying sponge-associated microbes, is not possible after acid treatment. For a broad range of siliceous sponge species, we developed and evaluated methods for embedding in paraffin, methylmethacrylate resins, LR White resin and cryomatrix. Different methods for cutting tissue blocks as well as mounting and staining sections also were tested. Our aim was to enable histological investigations and FISH without prior removal of the spicules. To obtain an overview of tissue and skeleton arrangement, we recommend embedding tissue blocks with LR White resin combined with en bloc staining techniques for large specimens with thick and numerous spicules, but paraffin embedding and subsequent staining for whole small specimens. For FISH on siliceous sponges, we recommend Histocryl embedding if the spicule content is high, but paraffin embedding if it is low. Classical histological techniques are used for detailed tissue examinations.