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.

Quantitative in situ analysis of xanthine oxidoreductase activity in rat liver.

The tetrazolium salt method previously developed for the detection of xanthine oxidoreductase activity in unfixed cryostat sections has been validated for quantitative purposes. The specificity of the enzyme reaction was studied by incubating unfixed cryostat sections of rat liver in test medium containing the substrate hypoxanthine, in control medium that lacked the substrate, and in medium containing substrate and allopurinol, a specific inhibitor of xanthine oxidoreductase activity. The specific reaction rate was determined cytophotometrically by subtracting the amount of final reaction product generated in the control reaction from that formed in the test reaction. Highest specific enzyme activity in rat liver was found when the incubation medium contained 18% (w/v) polyvinyl alcohol, 100 mM phosphate buffer, pH 7.8, 0.45 mM 1-methoxyphenazine methosulfate, 5 mM tetranitro BT, and 0.5 mM hypoxanthine. Enzyme activity was present in liver parenchymal cells and in sinusoidal cells (endothelial and Kupffer cells) and was completely inhibited by allopurinol. A linear relationship was observed between the specific amount of final reaction product generated at 37 degrees C and incubation time at least up to 21 min, as well as section thickness up to 12 microns. Xanthine oxidoreductase activity, expressed as mumoles substrate converted per cm3 tissue/min, was 1.61 +/- 0.34 in pericentral areas and 1.24 +/- 0.16 in periportal areas. These values are similar to biochemical data reported in the literature. In conclusion, the tetrazolium method to detect xanthine oxidoreductase activity in unfixed cryostat sections of rat liver gives a reliable reflection of in situ activity.

Localization of uric acid oxidase activity in core and matrix of peroxisomes as detected in unfixed cryostat sections of rat liver.

Because of controversial data in the literature, we studied the localization of uric acid oxidase (UAOX) activity in rat liver by light microscopy (LM) and electron microscopy (EM). UAOX is partially inactivated by aldehyde fixation and therefore we developed a technique that permits the use of unfixed cryostat sections for both LM and EM studies. Sections of rat liver were mounted on a semipermeable membrane stretched over a gelled incubation medium containing urate as specific substrate for UAOX and cerium ions to capture H2O2 produced by oxidase activity. The specificity of the reaction was checked by comparing incubations in the presence of substrate with incubations either in the absence of substrate or in the presence of substrate and 2,6,8-trichloropurine, a competitive inhibitor of UAOX. After incubation the sections were either fixed immediately for EM or visualized for LM with a second-step incubation. At the LM level, final reaction product was found in a granular form, homogeneously distributed throughout the hepatocytes. EM revealed excellent subcellular morphology and electron-dense reaction product in both the core and the matrix of peroxisomes, but not in other organelles or the cytoplasmic matrix. After incubations without substrate or with substrate and inhibitor, hardly any reaction product was found. We conclude that, because of the use of unfixed tissue, UAOX is not inactivated, which results in localization of UAOX activity not only in the core of peroxisomes but also in the peroxisomal matrix.

A histochemical procedure for light microscopic demonstration of xanthine oxidase activity in unfixed cryostat sections using cerium ions and a semipermeable membrane technique.

Xanthine oxidoreductase exists in two functionally distinct forms. Under normal conditions, the larger part of the enzyme occurs as an NAD(+)-dependent dehydrogenase form which produces NADH and urate. The dehydrogenase can be transformed under various (patho)physiological conditions to an oxygen-dependent oxidase form which produces oxygen radicals and/or hydrogen peroxide and urate. Tetrazolium salts are used to demonstrate the total activity of both the dehydrogenase and the oxidase form of the enzyme. We have developed a procedure to detect the oxidase form only in unfixed cryostat sections with the use of cerium on the basis of the semipermeable membrane technique. The incubation medium contained hypoxanthine as substrate, cerium ions, and sodium azide to inhibit catalase and peroxidase activity. In a second-step reaction, diaminobenzidine was polymerized in the presence of cobalt ions by decomposition of cerium perhydroxide. Large amounts of final reaction product were found in milk droplets in the acini of lactating bovine mammary gland, whereas milk-secreting epithelial cells contained hardly any final reaction product. In rat duodenum, enzyme activity was found in the cytoplasm of enterocytes and goblet cells but not in the mucus. Control reactions performed in the absence of substrate or in the presence of substrate and allopurinol, a specific inhibitor of xanthine oxidase, were completely negative in both tissues, with the exception of polymorphonuclear leukocytes in the lamina propria of duodenum. The positive nonspecific reaction in these cells was caused by myeloperoxidase activity. We conclude that the present method is specific for the detection of xanthine oxidase activity. Moreover, conversion of the dehydrogenase form into the oxidase form can be prevented by omission of chemical fixation of the tissue in the present procedure.

The use of unfixed cryostat sections for electron microscopic study of D-amino acid oxidase activity in rat liver.

Unfixed cryostat sections of rat liver were incubated to demonstrate D-amino acid oxidase activity at the ultrastructural level. Incubation was performed by mounting the sections on a semipermeable membrane which was stretched over a gelled incubation medium containing D-proline as substrate and cerium ions as capture reagent for hydrogen peroxide. After an incubation period of 30 min, ultrastructural morphology was retained to such an extent that the final reaction product could be localized in peroxisomes, whereas the crystalline core remained unstained. Control incubations were performed in the absence of substrate; the lack of final reaction product in peroxisomes indicated the specificity of the reaction. We conclude that the semipermeable membrane technique opens new perspectives for localization of enzyme activities at the ultrastructural level without prior tissue fixation, thus enabling localization of the activity of soluble and/or labile enzymes.