Improved technique for detection of enhanced green fluorescent protein in transgenic mice.

One of the most exciting recent advances in cell biology is the possibility to use the green fluorescent protein and its various mutated forms as reporter proteins in studies carried out in vitro and in vivo. In the present study, several detection techniques for the enhanced green fluorescent protein (EGFP) were compared in transgenic mice, using fluorescence and confocal microscopy. In addition, different tissue preparation techniques (squash preparations, vibratome sections, frozen sections) were evaluated. As a model we used transgenic mice expressing EGFP under the control of a 5.0-kb fragment of the glutathione peroxidase isoenzyme 5 protein promoter (GPX5-EGFP) or under a 3.8-kb fragment of the cysteine rich protein-1 promoter (CRISP1-EGFP). In the GPX5-EGFP mice, expression of EGFP was observed in the distal part of the caput epididymis, while the CRISP1 promoter directed EGFP expression in the tubular compartment of the testis. Among the various tissue preparation procedures tested, the best morphological and histological preservation, and reproducibility in EGFP detection, were obtained using frozen sections after a slow tissue-freezing protocol developed in the present study. After slow tissue freezing, specimens of testis and epididymis could be stored at -70 degrees C for at least six weeks without any affect on EGFP fluorescence. Hence, the method developed offers the possibility to analyze EGFP fluorescence in tissues several weeks after specimen collection. The sensitivity achieved was equal to that found in immunohistochemistry, applying biotin-streptavidin-FITC detection. Confocal microscopy is known to have the advantage that fluorescence can be detected from cells in different layers. This was found to be important as regards detecting EGFP fluorescence because the fluorescence was destroyed at the cut surfaces of sections produced by either vibratome or cryomicrotome.     

A fixative for use in muscle histochemistry

A fixative solution that preserves the activity of some relevant enzymes in muscle histochemistry is described. Portions of human muscle biopsy specimens and selected murine muscles were fresh frozen or placed in the fixative at room temperature for up to 1 month before freezing. Cryostat sections of fresh frozen and fixed frozen tissue were assayed for nicotinamide adenine dinucleotide phosphate (NADH)-tetrazolium reductase (NADH), several adenosine triphosphatases (ATPases), myoadenylate deaminase (MD), and phosphorylase. NADH, ATPase, and MD activity were preserved following fixation but phosphorylase was not preserved. Murine spleen and kidney were similarly tested for acid phosphatase (acid phos), alkaline phosphatase (alk phos), and nonspecific esterase (NSE). Alk phos activity was preserved but acid phos and NSE activity were significantly reduced following fixation. This fixative is useful in some circumstances for processing or shipping human muscle biopsy specimens and experimental tissues.     

The combination of chemical fixation procedures with high pressure freezing and freeze substitution preserves highly labile tissue ultrastructure for electron tomography applications

The emergence of electron tomography as a tool for three dimensional structure determination of cells and tissues has brought its own challenges for the preparation of thick sections. High pressure freezing in combination with freeze substitution provides the best method for obtaining the largest volume of well-preserved tissue. However, for deeply embedded, heterogeneous, labile tissues needing careful dissection, such as brain, the damage due to anoxia and excision before cryofixation is significant. We previously demonstrated that chemical fixation prior to high pressure freezing preserves fragile tissues and produces superior tomographic reconstructions compared to equivalent tissue preserved by chemical fixation alone. Here, we provide further characterization of the technique, comparing the ultrastructure of Flock House Virus infected DL1 insect cells that were (1) high pressure frozen without fixation, (2) high pressure frozen following fixation, and (3) conventionally prepared with aldehyde fixatives. Aldehyde fixation prior to freezing produces ultrastructural preservation superior to that obtained through chemical fixation alone that is close to that obtained when cells are fast frozen without fixation. We demonstrate using a variety of nervous system tissues, including neurons that were injected with a fluorescent dye and then photooxidized, that this technique provides excellent preservation compared to chemical fixation alone and can be extended to selectively stained material where cryofixation is impractical.     

Immunoelectron microscopy of cell surface antigens: a quantitative analysis of antibody binding after different fixation protocols

Summary The effect of different fixation solutions on the denaturation of membrane-associated antigens in murine lymphoid cells was determined quantitatively using microfluorometric analysis and a radioimmunoassay. Paraformaldehyde and periodate-lysine-paraformaldehyde solutions preserved the antigenicity of cell surface-associated immunoglobulin (S–Ig) antigens when used in concentrations ranging from 0.01 to 4%. However, glutaraldehyde destroyed the antigenicity of S–Ig and Thy 1.2 molecules at concentrations higher than 0.1%. Electron microscopic analysis of the different fixed cell suspensions, after labelling of the cells with a rabbit anti-mouse immunoglobulin-horseradish peroxidase conjugate (RaM-Ig-HRP) showed that prefixation of the sample with 0.1% glutaraldehyde was optimal for immunoelectron microscopical studies, since this concentration preserved both the antigenicity of membrane-associated antigens as well as the ultrastructure of the cells under study. Prolonged fixation periods affected antibody binding. However, S–Ig molecules denatured at a slower rate than Thy 1.2 molecules. A preparation method for the immunoelectron microscopical localization of lymphoid and non-lymphoid cell types in lymphoid organs is reported.TheHistochemical Journal lecture 1979 given by Dr Van Ewijk to the Histochemistry and Cytochemistry Section of the Royal Microscopical Society on 12 July, 1979.     

TdTomato and EGFP identification in histological sections: insight and alternatives

Abstract

Tandem dimer Tomato (tdTomato) provides a useful alternative to enhanced green fluorescent protein (eGFP) for performing simultaneous detection of fluorescent protein in histological sections together with fluorescence immunohistochemistry (IHC). eGFP has many properties that make it useful for cell labeling; however, during simultaneous fluorescence IHC, the usefulness of eGFP may be limited. This limitation results from a fixation step required to identify eGFP in histological tissue sections that can mask antibody epitopes and adversely affect staining intensity. An alternative fluorescent protein, tdTomato, may assist concurrent detection of fluorescent protein within tissue sections and fluorescence IHC, because detection of tdTomato does not require tissue fixation. Tissue sections were obtained from various organs of mice ubiquitously expressing eGFP or tdTomato that were either unfixed or fixed with 4% paraformaldehyde. These tissues later were combined with fluorescence IHC. Both eGFP and tdTomato displayed robust signals in fixed frozen sections. Only tdTomato fluorescence, however, was detected in unfixed frozen sections. Simultaneous detection of fluorescence IHC and fluorescent protein in histological sections was observed only in unfixed frozen tdTomato tissue. For this reason, tdTomato is a useful substitute for eGFP for cell labeling when simultaneous fluorescence IHC is required.     

Frozen Section Micro-Incineration

A method for micro-incineration of frozen sections is described. Material containing diffusible or soluble salts is cut on the freezing microtome and the sections are placed into xylol and mounted out of xylol onto Corex D slides previously filmed with glycerin-gelatin medium. Material containing non-diffusible or insoluble salts can be fixed in 10% formalin before sectioning. Sections of the fixed material are dehydrated thru 50, 70, and 95% ethyl alcohol and mounted out of absolute alcohol onto Corex D slides previously fumed with glycerin-gelatin medium. After mounting by either procedure the sections are incinerated in an electric furnace and the temperature of incineration is dependent on the type of tissues to be incinerated and the character of the salts present. The method is time saving and when no fixation is required the whole procedure can be carried out in one hour.     

Methods for decreasing interstitial immunoglobulin in tissue slices and cryostat sections

To determine whether lymphoid antigens and cellular morphology can be preserved after long-distance transport in buffer or cell culture medium, we stained cryostat sections prepared from human tonsil samples that had been kept at 4 degrees C or 20 degrees C for 24, 48 or 72 h. B-Cell antigens, T-cell antigens, and Ia antigens were well preserved after storage up to 72 h in buffer or medium at 4 degrees C. Interstitial immunoglobulin (Ig) was decreased following all incubation procedures. We then investigated methods to diminish interstitial Ig in cryostat sections, since it would be inconvenient to keep 2-3 mm tissue slices in buffer or medium prior to freezing and subsequent Ig staining. Cryostat sections were air dried or briefly fixed in acetone prior to washing in buffer or medium at 4 degrees C, 20 degrees C or 37 degrees C for 1, 2 or 24 h. Then sections were air dried or washed prior to acetone fixation and immunostaining. A method for washing cryostat sections was developed which diminished interstitial Ig without compromising the quality of immunostaining or cellular detail. These methods are especially useful for studying samples of lymphoid tissue in which the presence of large quantities of interstitial Ig obscures the detection of monotypic Ig staining patterns.     

Paraformaldehyde Fixation May Lead to Misinterpretation of the Subcellular Localization of Plant High Mobility Group Box Proteins

Arabidopsis High Mobility Group Box (HMBG) proteins were previously found associated with the interphase chromatin but not the metaphase chromosome. However, these studies are usually based on immunolocalization analysis involving paraformaldehyde fixation. Paraformaldehyde fixation has been widely adapted to preserved cell morphology before immunofluorescence staining. On one hand, the processed cells are no longer living. On the other hand, the processing may lead to misinterpretation of localization. HMGBs from Arabidopsis were fused with enhanced green fluorescence protein (EGFP) and transformed into tobacco BY-2 cells. Basically, the localization of these HMGB proteins detected with EGFP fluorescence in interphase agreed with previous publications. Upon 4% paraformaldehyde fixation, AtHMGB1 was found associated with interphase but not the metaphase chromosomes as previously reported. However, when EGFP fluorescence signal was directly observed under confocal microscope without fixation, association of AtHMGB1 with metaphase chromosomes can be detected. Paraformaldehyde fixation led to dissociation of EGFP tagged AtHMBG1 protein from metaphase chromosomes. This kind of pre-processing of live specimen may lead to dissociation of protein-protein or protein-nucleic acid interaction. Therefore, using of EGFP fusion proteins in live specimen is a better way to determine the correct localization and interaction of proteins.     

Demonstration of laminin, a basement membrane glycoprotein, in routinely processed formalin-fixed human tissues

Laminin was demonstrated by immunoperoxidase and immunofluorescence staining in sections of normal human tissues fixed in formalin and routinely processed in paraffin. Exposure of the sections to a solution of pepsin (Burns et al. (1980) Histochemistry 67:73-78) revealed the antigenicity of this basement membrane glycoprotein. Sections from paraffin blocks stored for years at room temperature could be stained with this procedure. Normal human tissues, developing fetal tissues and tumors could be stained with this method. The staining patterns were similar to those seen in unfixed frozen sections. It thus appears that basement membrane components can be detected by immunohistological means from routinely processed histological samples, once the sections are pretreated with proteases. Staining for laminin could be used in embryonic studies and in histopathology to study the relation of cells to basement membranes and for the visualization of normal and abnormal vascularization.     

Alteration of immunoglobulin-bearing lymphoma cells by fixation.

Four large cell lymphomas known to be monoclonal B-cell proliferations were studied with immunofluorescent and immunohistochemical methods for the detection of kappa- and lambda-light chains. Frozen sections of lymphoma tissues as well as formalin and B-5-fixed tissues embedded in paraffin were studied. Both immunofluorescent and immunohistochemical methods gave similar results on frozen sections; however, a number of discrepancies were noted between the results obtained on fixed tissues and those obtained on frozen tissues. In an effort to identify a fixative which did not alter immunoglobulin (Ig), mouse lymph nodes were fixed in different fixatives before Ig detection; but all of the fixatives tested destroyed the Ig present on normal cortical B lymphocytes. Immunoglobulin-bearing normal and neoplastic lymphocytes are better detected on frozen sections than on paraffin sections after routine fixation.     

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.     

Improved ultrastructural preservation ofPetunia andBrassica ovules and embryo sacs by high pressure freezing and freeze substitution

Summary In order to improve the ultrastructural preservation of the female gametophyte ofPetunia x hybrida andBrassica napus we tested several cryofixation techniques and compared the results with those of conventional chemical fixation methods. Ovules fixed with glutaraldehyde and osmium tetroxide in the presence or absence of potassium ferrocyanide showed poor cell morphological and ultrastructural preservation. In ovules cryo-fixed by plunging into liquid propane, the cell morphology was well preserved. However, at the ultrastructural level structure-distorting ice crystals were detected in all tissues. Due to the large size of the ovules, cryofixation by plunging in liquid propane is not adequate for ultrastructural studies. In contrast,P. x hybrida andB. napus ovules cryo-fixed by high pressure freezing showed improved cell morphological as well as ultrastructural preservation of the embryo sac and the surrounding integumentary tissues. The contrast of the cellular membranes after freeze substitution with 2% osmium tetroxide and 0.1% uranyl acetate in dry acetone was high. At the ultrastructural level, the most prominent improvements were: straight plasma membranes which were appressed to the cell walls; turgid appearing organelles with smooth surface contours; minimal extraction of cytoplasmic and extracellular substances. In contrast to the chemically fixed ovules, in high pressure frozen ovules numerous microtubules and multivesicular bodies could be distinguished.     

Immunocytochemical localization of nerve growth factor: effects of fixation

The fixation dependence of immunocytochemically demonstrable nerve growth factor (NGF) was investigated. Several commonly used fixation methods have been employed, including buffered formaldehyde, Bouin's fluid, and chloroform-methanol, as well as freezing and cryostat sectioning. The immunostaining technique was an immunoenzyme bridge procedure on either paraffin sections or frozen sections. Of those methods tested, fixation for 1 hr in a buffered formaldehyde appeared to provide optimal preservation and localization of immunoreactive material. Using this method, reaction product was localized in granules of the granular tubule cells of the male mouse submandibular gland. Prolonged fixation in buffered formaldehyde resulted in a diffuse background staining and loss of granule immunoreactivity. In frozen sections and in tissues fixed with either Bouin's solution, chloroform-methanol, or buffered paraformaldehyde-glutaraldehyde increased cytoplasmic background staining and loss of granule immunoreactivity were observed. It was concluded that, for the localization of NGF at the light microscopic level, a brief (1 hr) buffered formaldehyde fixation is optimal.     

Confocal laser scanning microscopy of whole mouse ovaries: excellent morphology, apoptosis detection, and spectroscopy.

BACKGROUND: Ovaries consist of numerous follicles, oocytes, and granulosa cells in different stages of development. Many of these follicles will undergo an apoptotic process during the lifetime of the animal. By using proper tissue preparation methods, the events within the whole ovary can be observed by using 3D confocal microscopy. METHODS: Whole ovaries were stained with LysoTracker Red (LT), fixed with 4% paraformaldehyde (PF) and 1% glutaraldehyde (Glut), dehydrated with methanol (MEOH), and cleared with benzyl alcohol and benzyl benzoate (BABB). Using this tissue preparation technique, the ovary becomes relatively transparent, allowing its morphology to be observed with confocal microscopes. A spectral imaging system (PARISS) located on a conventional microscope was used to interpret the LT dye spectra and fixation products in the tissues with different excitation wavelengths. RESULTS: Apoptosis in the follicle was detected as clusters of intensely stained granulosa cells located in close proximity to the oocytes. The fixation with Glut and PF preserved morphological details, increased tissue fluorescence, thus increased the signal to noise of the background image. CONCLUSIONS: Thick tissues can be imaged after they are properly stained, aldehyde fixed, and BABB cleared. LT intensely stained single cells or clusters of apoptotic cells in the follicles and the nucleolus. Spectral differences between LT as an indicator of apoptosis and Glut-PF fixation was used to visualize ovarian morphology and apoptosis. The PARISS spectrophotometer revealed spectral peaks for LT at 609.6 nm and for Glut-PF at 471.3 nm. The proper use of the spectra from these fluorescence molecules is the foundation for high quality morphological images of apoptosis. By sequentially imaging the two probes with a 488 nm laser and a 543/568 nm laser, there was a reduction in fluorescent cross talk and an increase in image quality.     

Control of autofluorescence of archival formaldehyde-fixed, paraffin-embedded tissue in confocal laser scanning microscopy (CLSM).

Confocal laser scanning microscopy (CLSM) offers the advantage of quasi-theoretical resolution due to absence of interference with out-of-focus light. Prerequisites include minimal tissue autofluorescence, either intrinsic or induced by fixation and tissue processing, and minimal background fluorescence due to nonspecific binding of the fluorescent label. To eliminate or reduce autofluorescence, three different reagents, ammonia-ethanol, sodium borohydride, and Sudan Black B were tested on paraffin sections of archival formaldehyde-fixed tissue. Paraffin sections of biopsy specimens of human bone marrow, myocardium, and of bovine cartilage were compared by CLSM at 488-nm, 568-nm and 647-nm wavelengths with bone marrow frozen sections fixed either with formaldehyde or with glutaraldehyde. Autofluorescence of untreated sections related to both the specific type of tissue and to the tissue processing technique, including fixation. The reagents' effects also depended on the type of tissue and technique of tissue processing, including fixation, and so did the efficiency of the reagents tested. Therefore, no general recipe for the control of autofluorescence could be delineated. Ammonia-ethanol proved most efficient in archival bone marrow sections. Sudan Black B performed best on myocardium, and the combination of all three reagents proved most efficient on paraffin sections of cartilage and on frozen sections fixed in formaldehyde or glutaraldehyde. Sodium borohydride was required for the reduction of unwanted fluorescence in glutaraldehyde-fixed tissue. In formaldehyde-fixed tissue, however, sodium borohydride induced brilliant autofluorescence in erythrocytes that otherwise remained inconspicuous. Ammonia-ethanol is believed to reduce autofluorescence by improving the extraction of fluorescent molecules and by inactivating pH-sensitive fluorochromes. The efficiency of borohydride is related to its capacity of reducing aldehyde and keto-groups, thus changing the fluorescence of tissue constituents and especially of glutaraldehyde-derived condensates. Sudan Black B is suggested to mask fluorescent tissue components.     

Localization of GFP in frozen sections from unfixed mouse tissues: immobilization of a highly soluble marker protein by formaldehyde vapor.

Green fluorescent protein (GFP) and its variants, such as enhanced GFP (EGFP), have been introduced into mammalian cells by transgenes, e.g., to distinguish donor from host cells after transplantation. Free GFP is extremely soluble and leaks out from liquid-covered cryostat sections so that fixation of whole organs before sectioning has been mandatory. This precludes the analysis of serial sections with respect to fixation-sensitive enzyme activities and antigens. We describe here a vapor fixation for sections from unfixed cryostat blocks of tissue that allows unrestricted enzyme and immunohistochemistry on adjacent sections, as demonstrated for cross-striated muscle and other tissues from EGFP transgenic "green mice" and for a transplantation experiment.     

Demonstration of laminin,a basement membrane glycoprotein,in routinely processed formalin-fixed human tissues

Summary Laminin was demonstrated by immunoperoxidase and immunofluorescence staining in sections of normal human tissues fixed in formalin and routinely processed in paraffin. Exposure of the sections to a solution of pepsin (Burns et al. (1980) Histochemistry 6773–78) revealed the antigenicity of this basement membrane glycoprotein. Sections from paraffin blocks stored for years at room temperature could be stained with this procedure. Normal human tissues, developing fetal tissues and tumors could be stained with this method. The staining patterns were similar to those seen in unfixed frozen sections. It thus appears that basement membrane components can be detected by immunohistological means from routinely processed histological samples, once the sections are pretreated with proteases. Staining for laminin could be used in embryonic studies and in histopathology to study the relation of cells to basement membranes and for the visualization of normal and abnormal vascularization.To whom offprint requests should be sent     

Cryofixed, freeze-dried and paraffin-embedded skin enables successful immunohistochemical staining of skin basement membrane antigens.

Conventional chemical fixation and paraffin-embedding procedures give good preservation of morphology, although the antigenicity of many proteins in the tissue sample is destroyed. On the other hand, fresh frozen sections can preserve the antigenicity, but provide poor morphological preservation. To overcome this dilemma, cryofixation and freeze drying were used on human skin tissue, applying methodology which has only been used to study lymphoid tissue. First, fresh human skin was cryofixed in liquid isopentane (-160 degrees C) cooled by liquid nitrogen. The skin was then freeze-dried at -40 degrees C and 10(-2) atmospheric pressure for 72 h, followed by embedding in paraffin. Sections 4 microns thick taken from this cryofixed, freeze-dried, and paraffin-embedded skin were stained with hematoxylin-eosin or used for immunolabeling with antibodies against basement membrane antigen, including type IV and type VII collagen, bullous pemphigoid antigen, epidermolysis bullosa acquisita antigen, and GB3 antigen. The morphological preservation of these sections was as good as that of routine formalin-fixed and paraffin-embedded skin sections. The basement membrane was clearly immunostained with all antibodies used, and the intensity of the reaction was as strong as that seen in frozen sections. Evaluation of antigen distribution in conjunction with the detailed skin structure was therefore possible in the same sections.     

Stabilization of cholesterol in myelin with digitonin: observation with polarized light.

Cholesterol can be preserved in tissues dehyrated for light microscopy by incorporating digitonin into glutaraldehyde fixation. Fresh and fixed frozen sections of rat sciatic nerve exhibit strong, radially positive birefringence when viewed with polarized optics. However, tissue fixed and dehydrated with standard methods for Epon embedding shows very weak radially positive birefringence. The use of digitonin with a variety of techniques generally permits retention of optical activity in embedded nerves. Such observations suggest a preservation of lipids (presumably cholesterol) in molecular orientations necessary to produce Maltese cross patterns.     

Use of dextran and post-primary antibody fixation in immunoperoxidase staining of fresh frozen tissue. Detection of immunoglobulin associated with squamous carcinomas of the head and neck

Use of unfixed fresh frozen tissue sections for immunocytochemical studies reduces the possibility of denaturation of antigenic determinants compared to formalin fixation and paraffin embedding procedures. However, tissue and cellular morphology can be extensively altered in the numerous application and washing steps with frozen tissue sections. We tested a number of buffer solutions and showed that the use of dextran-containing buffers and fixation by glutaraldehyde after primary antibody application preserves tissue morphology. The procedures described here are also applicable to ascertaining the presence of Fc receptors of leukocytes in sections of carcinoma tissues. The buffered dextran washes and post-primary antibody fixation method was used to demonstrate the presence of immunoglobulin associated with squamous carcinoma cells. The immunoglobulin was not removed by washing of tissue sections at 37 degrees C but could be removed by low or high pH buffer washes, suggesting that the immunoglobulin is bound in a specific manner.