Fine structural localization of alkaline phosphatase in the granular pneumonocytes of hamster lung.

The fine structural localization of nonspecific alkaline phosphatase was studied in the granular pneumonocytes (type II alveolar epithelial cells) of hamster lung by incubating sections of glutaraldehyde-fixed tissues in a medium containing lead ions and sodium beta-glycerophosphate or alpha-naphthyl acid phosphate. The specificity of the reaction was tested by exposing the sections to inhibitors of alkaline phosphatase. The results showed that alkaline phosphatase activity was present in the inclusion bodies of granular pneumonocytes. The enzyme reaction was strong in the membrane lining the inclusion bodies and a weaker reaction was generally detectable in the inclusion contents. Although only a proportion of the inclusion bodies showed enzyme activity, there was no obvious correlation between the reactivity of the inclusions and their intracellular position or size. The other organelles were unreactive. The finding of alkaline phosphatase activity within the inclusion bodies of granular pneumonocytes is an enigma as these organelles are generally considered to be lyosomes.     

Ultrastructural localization of alkaline phosphatase in the eggs of Hydatigera taeniaeformis (Taenia taeniaeformis)

Freshly shed gravid proglottids from a three-month-old infection of Hydatigera taeniaeformis collected from the faecal droppings of infected cats were used for this study. They were treated for transmission electron microscopy (TEM) followed by incubation using the lead precipitate method. Control sections were incubated in a substrate-free medium, a substrate medium containing 1.0 mM sodium fluoride (NaF) (an inhibitor), and the last sections were denatured at 90 degrees C for 1 min prior to incubation. Intensive alkaline phosphatase activity in the embryophoric blocks and the outer embryophoric membrane was revealed. The reaction products were also indicated in the oncospheral membrane. However, no enzyme activity was seen in any other part of the egg. The enzyme was also absent in the control sections. The presence of alkaline phosphatase activity in the outer embryophoric and oncospheral membranes suggested that this enzyme may be involved in carbohydrate metabolism and nutritional absorption, and also may play a role in the transport of nutrients and other substances from the adult to the developing embryo, respectively.     

Cytochemical Localization of Certain Phosphatases in Escherichia coli

Cytochemical studies of Escherichia coli at the light and electron microscopic levels have revealed alkaline phosphatase, hexose monophosphatase, and cyclic phosphodiesterase reaction products in the periplasmic space and at the cell surface. In preparations for both light and electron microscopy, reaction product filled polar caplike enlargements of the periplasmic space, such as those described in plasmolyzed cells, indicating significant terminal concentrations of these enzymes; dense substance was often seen within these polar caps in morphological specimens. Staining of the bacterial surface was commonly encountered, but could represent artifactual accumulation of precipitate along the cell wall. Alkaline phosphatase was demonstrated with several substrates (ethanolamine phosphate, glycerophosphate, p-nitrophenylphosphate, and glucose-6-phosphate) over a wide pH range in a bacterial strain (C-90) known to be constitutive for this enzyme, whereas strains deficient in this enzyme (U-7, repressed K-37), showed no activity with these substrates. Hexose monophosphatase and cyclic phosphodiesterase activities were characterized by reaction-product deposition with specific substrates at acid or neutral, but not at alkaline, pH in strains of E. coli lacking alkaline phosphatase (U-7 and repressed K-37). Fixation in Formalin or the use of calcium as a capture reagent seemed to interfere with periplasmic staining in cells prepared for electron microscopy. Formalin fixation had little effect on biochemical assays of the phosphatase activity of intact cells in suspension, but partially reduced the activity evident in sonically treated extracts or in suspensions of dispersed cryostat sections. Glutaraldehyde treatment impaired enzyme activity more drastically.     

The fine localization of acid phosphatase activity in the unvacuolated notochordal cells of the early chick embryo

Summary The electron microscopical localization of acid phosphatase activity was investigated in ultra-thin and semi-thin sections of unvacuolated notochordal cells of chick embryos from stages 9 to 14 (as defined by Hamburger & Hamilton). At stage 9, many notochordal cells show a lightly positive reaction for acid phosphatase activity. Thereafter, the acid phosphatase-positive cells of the notochord increase in number and, at stage 14, the reaction products for the enzyme are distributed throughout almost all the cisternae of the nuclear envelope and a well-differentiated endoplasmic reticulum, the parallel cisternal and reticular parts of the Golgi complex, and various lysosomes in nearly all notochordal cells. In the cisternae of the nuclear envelope and endoplasmic reticulum, the acid phosphatase reaction products are in a fine granular form. In the outermost layer of the cisternal parts of the Golgi complex, faint lead deposits similar to those in the endoplasmic reticulum are found, but in other cisternal and reticular regions which may correspond to the GERL, considerable amounts of reaction products are present. Knob-like projections are also seen protruding from the reticular parts of the Golgi complex. These results suggest that, at least up to stage 14, the notochordal cells are actively synthesizing acid phosphatase which is directly transported from the endoplasmic reticulum to the Golgi complex. The enzyme may be accumulated by the Golgi complex from which primary lysosomes are formed. Furthermore, the pattern of the ultrastructural localization of acid phosphatase activity in embryonic notochordal cells of the chick differs from that of adult cells of other animals.     

Acid phosphatase activity in normal and sarcolytic myotubes in muscle anlagen of the human hand

Summary During physiological embryonic and fetal sarcolysis, regressive changes occur in the affected myotubes in the muscle anlagen of the human hand. These result in the fragmentation and destruction of myotubes and phagocytosis of most of the fragments. To assess the extent of participation of autophagia in the course of such changes, the acid phosphatase activity in the myotubes was studied light microscopically and electron microscopically. By the Gomori method, a low activity of acid phosphatase was found in normal myotubes, which was confined to some vesicles of the Golgi apparatus and membranes of tubules and vesicles evidently belonging to the sarcoplasmic reticulum. The acid phosphatase activity was elevated in sarcolytic myotubes. The enzyme was localized in dense bodies (lysosomes) and on membranes of various vacuoles. The azo-coupling reaction carried out using the semipermeable-membrane technique revealed a much higher activity of acid phosphatase than did the Gomori method, particularly in sarcolytic myotubes. The activity was concentrated in a narrow strip on their periphery and in their center. In electronograms of sarcolytic myotubes, vacuoles were found in places where high acid phosphatase activity was found. At times, the reaction was rather diffuse in some sarcolytic myotubes. The reaction was weaker in normal myotubes.From these findings it may be concluded that a rise of acid phosphatase activity occurs in sarcolysis, indicating an activation of autophagia in myotubes. By the action of their own hydrolases, the myotubes disintegrate and are phagocytized by macrophages.     

Light microscopical visualization of phosphatase activities demonstrated with the cerium method in resin sections of the kidney with the microwave oven

The light microscopically invisible reaction product cerium phosphate in resin sections of rat kidney, that had been incubated for the demonstration of phosphatase activities before embedding, was converted into a visible reaction product by incubation for 10 min at 80 degrees C in alkaline lead citrate in a microwave oven. This method offers the possibility to study phosphatase activities with the cerium method in semithin Epon sections. Furthermore it is a suitable method to select areas with phosphatase activity to be studied with the electron microscope.     

Light microscopical visualization of phosphatase activities demonstrated with the cerium method in resin sections of the kidney with the microwave oven

Summary The light microscopically invisible reaction product cerium phosphate in resin sections of rat kidney, that had been incubated for the demonstration of phosphatase activities before embedding, was converted into a visible reaction product by incubation for 10 min at 80° C in alka-line lead citrate in a microwave oven. This method offers the possibility to study phosphatase activities with the cerium method in semithin Epon sections. Furthermore it is a suitable method to select areas with phosphatase activity to be studied with the electron microscope.     

Acid-beta-glycerophosphatase reaction products in the central nervous system mitochondria following x-ray irradiation.

A survey of the literature to date on the enzyme histochemistry of intracellular organelles has not yielded any reference to the presence of acid phosphatase reaction products in the mammalian mitochondria of the central nervous system. A combination of Gomori's acid phosphatase mehtod, however, with standard electron microscopy has disclosed the presence of enzyme reaction products in the mitochondria of the central nervous system of rats from 2 hr to 22 weeks after x-ray irradiation, as well as in a cerebral biopsy performed on a patient affected by Huntington's chorea. No enzyme reaction products, on the other hand, were observed in serial sections that had been incubated in substrates either containing sodium fluoride or lacking in beta-glycerophosphate. The abnormal mitochondrial enzyme reaction (chemical lesion) is considered to be the consequenco of the pathologic process affecting the ultrastructural-chemical organization of the organelle.     

An effective reactivation of alkaline phosphatase in hard tissues completely decalcified for light and electron microscopy

Summary An effective procedure for reactivating alkaline phosphatase in tissues decalcified completely for light and electron microscopy was presented. It was indicated that an Mg ion supply as reactivator in the decalcified sections before, not during, incubation for demonstration of the enzyme was important. In addition, choice of buffer solutions as Mg ion solvent and as rinsing solution for the sections after reactivation were also important. Cacodylate buffer should not have been used as an Mg solvent because the reactivation effect of the Mg ion was seriously reduced. But it should have been used for rinsing reactivated sections in order to obtain reaction products at all sites of enzyme activity throughout thick sections used for electron microscopy.     

A new method for flat-embedding large native cryostat sections for targeting small preneoplastic lesions in comparative ultrastructural and ultracytochemical investigations

 Ultrastructural studies of rare and small cellular lesions in pathologically altered tissue are difficult to perform by applying conventional electron microscopic preparation. The search for lesions, often consisting of only a few cells in randomly obtained small specimen blocks, is time consuming and often without success. The methodological requirements for comparative enzyme cytochemical and morphological studies, i.e., preservation of both enzyme activity and ultrastructure, are divergent. By processing large native cryostat sections for electron microscopy, small preneoplastic focal lesions were successfully targeted in liver and kidney. Glucose-6-phosphatase, alkaline phosphatase, acid phosphatase, catalase, and cytochrome c oxidase activities were distinctly localized to endoplasmic reticulum, canalicular membrane, lysosomes, peroxisomes, and mitochondria, respectively, in the morphologically altered cells. Fixation of serial cryostat sections and enzyme reactions were both carried out through a semipermeable membrane except those for cytochrome c oxidase, which was demonstrated after fixation through the membrane by floating the section in incubation medium containing cytochrome c. Thereafter, the sections were flat embedded and polymerized between epoxy resin disks and aluminum dishes fitting exactly together. The objects of interest were identified in the light microscope, cut out, and reembedded in reversed gelatine capsules. By using this technique an ultrastructural preservation was achieved similar to that seen after immersion fixation. The enzyme activities were clearly localized without diffusion of the reaction product or unspecific deposits. The procedure permits precise targeting and complex studies of rare and small lesions, and opens new perspectives for the use of cryo-preserved tissue. Accepted: 10 March 1998     

Distribution of acid phosphatase, beta-glucuronidase, n-acetyl-beta-d-glucosaminidase and beta-galactosidase in cornea of albino rabbit.

Activities of acid phosphatase, beta-glucuronidase, N-acethyl-beta-D-glucosaminidase and acid beta-galactosidase were investigated histochemically in rabbit corneas. Frozen sections after block fixation in cold 4% formaldehyde with 1% CaCl2 followed by washing in cold physiological saline as well as cold microtome sections of corneas quenched in petroleter chilled with acetone-dry ice mixture, transferred to nonprecooled slides or semipermeable membranes were used. Standard aqueous media were employed in the case of free-floating frozen sections of fixed corneas as well as of cold mictrotome sections (postfixed in cold 4% formaldehyde). Agar media were used in connection with the technic of semipermeable membranes. Gomori method (in the case of acid phosphatase), simultaneous azocoupling methods (substrates derivated of naphthol-AS-BI with hexazonium-p-rosanilin) in the case of acid phosphatase, beta-glucuronidase and N-acetyl-beta-D-glucosaminidase and the indigogenic method in the case of acid beta-galactosidase were applied. Enzyme activities in sections of fixed corneas were minimal in comparison with those in cold microtome sections of unfixed material revealed particularly with the technic of semipermeable membranes which is to be preferred. This technic is recommended in studies concerned with lysosomal enzymes in the cornea, particularly in keratocytes. All enzymes investigated were present in corneal epithelium, keratocytes and endothelium. Acid phosphatase displayed the highest activity followed by beta-glucuronidase and acetyl-beta-D-glucosaminidase. The activity of beta-galactosidase was the lowest. For the demonstration of activities in keratocytes sections parallel to the surface are very suitable. In these sections enzyme activities were demonstrated in small granules (apparently lysosomes) present in the central part of their cytoplasm as well as in projections. Diffuse staining was also seen, being the highest in the case of acid phosphatase.     

Patterns of distribution of phosphomono-esterases on surfaces of demineralized bone.

Decalcification over short periods (5 days) with MnNa2 EDTA, MgNa2 EDTA and EGTA according to a method described in the present paper, creates sections of high quality with simultaneous good preservation of phosphomonoesterases on bone surfaces. In fact, the enzyme distribution seems to be comparable to that obtained by using undecalcified sections. Na2 EDTA creates, on the other hand, poor preservation of alkaline phosphatase probably due to the fact that this chelate contrary to the other chelates removes the essential metal from the protein, leaving an unstable enzyme molecule which undergoes denaturation. Decalcification over longer periods (15 days) does not influence the pattern of distribution of acid phosphatase, whereas the alkaline phosphatase reaction becomes depressed in certain surface areas. The significance of this differential distribution is discussed. It might be an indication of differential processes of bone transformations in such a way that bone surfaces corresponding to areas of enzyme reactions are depository whereas bone surfaces corresponding to areas of lack of enzyme reaction are resorptive. New experimental designs are, however, necessary before the phenomenon is fully perceived. Two different coupling agents were used in connexion with the demonstration of acid phosphatase reaction. When HPR was used as the coupler the final enzyme distribution coincided with that usually described in the literature, i.e., strong reaction of cells adjacent to resorptive surfaces and weak reaction of cells adjacent to depository surfaces. When, however, Fast dark blue R was used all surface cells reacted markedly. This method also revealed certain cell types with nuclear reaction.     

Enzyme histochemical reactions in unfixed and undecalcified cryostat sections of mouse knee joints with special reference to arthritic lesions

Summary The use of unfixed and undecalcified cryostat sections of mouse knee joints is described for the study of enzyme histochemical reactions. Non-inflamed knee joints and knee joints of mice with antigen induced arthritis have been used. Joints were embedded in gelatin and subsequently cut at low speed with a motor-driven cryostat fitted with a tungsten carbide knife at an obtuse angle (10°). The sections were attached to transparent tape to keep the integrity of the tissue intact. The following histochemical reactions were carried out succesfully: the tetrazolium salt reaction for dehydrogenase and reductase activity, the post-azocoupling method for acid phosphatase and cathepsin B activity and the simultaneous azo-coupling method for esterase activity. In all cases the morphology and integrity of the sections were well kept and serial sections were obtained without any difficulty. Nonspecific staining of the tape did not occur. The localization of the final reaction product was meeting criteria for specific and precise histochemical methods with the exception of the metal salt method because of nonspecific staining of undecalcified bone. Cytophotometry of the final reaction product appeared to be reproducible and valid as demonstrated by reaction for glucose-6-phosphate dehydrogenase activity in synoviocytes from knee joints with induced arthritis. End point measurements as well as kinetic measurements of the formazan production were performed and linear relationships were found between the specific formazan formation and section thickness or incubation time, respectively. It is concluded that cryostat sections attached to transparent tape are an excellent tool for the study of the metabolism in tissues adjacent to bone matrix. Changes of enzyme activities in synoviocytes, chondrocytes and osteoclasts during induced arthritis are discussed.     

Acid phosphatase activity in Pisolithus arrhizus mycelium treated with cadmium dust

The influence of cadmium dust (containing lead, cadmium, copper, zinc, silicium and other elements) on acid phosphatase activity of Pisolithus arrhizus was observed by means of electron microscopy. Dust-treated mycelium showed increased activity of the enzyme, especially on the surface of the cell wall. There was an increase in abundance of autophagic vacuoles marked by a strong phosphatase reaction. An increase in the number of hyphae with diffuse enzyme activity within the cytoplasm coincided with a decrease of lifespan of the fungus, rapid changes in the mictoplasm stage, earlier closing of the dolipori and presumably the earlier autolysis of cell cytoplasm. Hyphae showing strong autolytic activity were separated from other hyphae by the material deposited within the doliporus and this whole area was devoid at that stage of acid phosphatase activity. The role of the enzyme in the mechanism of resistance to toxic elements is discussed.     

ULTRATHIN FROZEN SECTIONS : II. Demonstration of Enzymic Activity

Endogenous enzyme activity can be readily and routinely demonstrated in ultrathin, frozen sections for electron microscopy. The procedure employed to obtain the best structural preservation as well as enzyme activity in thin sections involved fixation in glutaraldehyde, embedding in thiolated gelatin or pure gelatin, partial dehydration in glycerol, and sectioning in a cryostat at -35°C with a slightly modified Porter-Blum microtome on which the tissue is maintained at -70°C and the knife at -23°C. Kidney cortex was used as test tissue, but a few other organs were occasionally used. Thin sections were floated on the surface of several incubation media routinely employed for enzyme cytochemistry. Positive, specific reactions were obtained for alkaline phosphatase in kidney brush border, for adenosine triphosphatase in brush border and in basal membranes of distal tubules, for acid phosphatase and esterase in lysosomes, and for NADH diaphorase in mitochondria. Mitochondrial ATPase was sporadically evident only in the distal tubule of the kidney. Localizations of enzyme activity reported by other technical approaches were confirmed and in some cases somewhat improved.     

Demonstration of tartrate-resistant acid phosphatase in un-decalcified, glycolmethacrylate-embedded mouse bone: a possible marker for (pre)osteoclast identification

Fixed, undecalcified mouse long bones were embedded in glycol methacrylate (GMA), sectioned, and incubated for acid phosphatase in the presence or absence of tartrate, to investigate the feasibility of tartrate-resistant acid phosphatase as a histochemical marker for osteoclast identification. Naphthol AS-BI phosphate was used as the substrate and hexazonium pararosanaline as coupler. Cytocentrifuge preparations of mouse, rat, and quail bone marrow or frozen and GMA sections of mouse splenic tissue were used as controls to specify acid phosphatase activity. After adequate fixation, acid phosphatase activity sensitive to tartrate inhibition (TS-AP) was demonstrated in macrophages from spleen, bone marrow, and loose connective tissue surrounding bone rudiments. Acid phosphatase activity resistant to tartrate inhibition (TR-AP), was detected in multi-nuclear osteoclasts and in some mononuclear cells from bone marrow and periosteum. In cytocentrifuge preparations and frozen sections of mouse spleen, TR-AP was demonstrated after simultaneous incubation with substrate and tartrate. In GMA sections, however, TR-AP could only be demonstrated after pre-incubation with tartrate before application of substrate. We suggest that histochemical demonstration of TR-AP versus TS-AP on GMA-embedded bone sections by means of a pre-incubation method can be used as an identification marker of (pre)osteoclasts. Plastic embedding is recommended for its excellent preservation of morphology and enzyme activity.     

Patterns of distribution of phosphomono-esterases on surfaces of demineralized bone

Summary Decalcification over short periods (5 days) with MnNa₂ EDTA, MgNa₂ EDTA and EGTA according to a method described in the present paper, creates sections of high quality with simultaneous good preservation of phosphomonoesterases on bone surfaces. In fact, the enzyme distribution seems to be comparable to that obtained by using undecalcified sections.Na₂ EDTA creates, on the other hand, poor preservation of alkaline phosphatase probably due to the fact that this chelate contrary to the other chelates removes the essential metal from the protein, leaving an unstable enzyme molecule which undergoes denaturation.Decalcification over longer periods (15 days) does not influence the pattern of distribution of acid phosphatase, whereas the alkaline phosphatase reaction becomes depressed in certain surface areas. The significance of this differential distribution is discussed. It might be an indication of differential processes of bone transformations in such a way that bone surfaces corresponding to areas of enzyme reactions are depository whereas bone surfaces corresponding to areas of lack of enzyme reaction are resorptive. New experimental designs are, however, necessary before the phenomenon is fully perceived. Two different coupling agents were used in connexion with the demonstration of acid phosphatase reaction. When HPR was used as the coupler the final enzyme distribution coincided with that usually described in the literature, i.e., strong reaction of cells adjacent to resorptive surfaces and weak reaction of cells adjacent to depository surfaces. When, however, Fast dark blue R was used all surface cells reacted markedly. This method also revealed certain cell types with nuclear reaction.     

Histochemical studies on the localization and activity of acid phosphatase in calcifying tissues

Summary Acid phosphatase activity has been studied in cold microtome sections and using simultaneous azo coupling method in developing teeth and bone, and serial sections were made for the demonstrations of alkaline phosphatase.1. In developing teeth, strongest activity of acid phosphatase was found in the distal portion of high columnar ameloblasts associated with heavy calcification in the rodent incisor, and ameloblasts and odontoblasts in adjacent occlusal surface in molar teeth. However, the activity of immatured ameloblast and crevicular aspects of molar were weaker.2. In the epiphyseal bone trabeculae a striking acid phosphatase reaction was found.3. As regards to the effects of decalcifying solutions to the enzymatic activity, the use of EDTA decalcifying agent (10% and pH 7 to 4) showed the best results. That is, a decrease of decalcifying time and a greater preservation of acid phosphatase activity.With 11 Figures in the Text     

Demonstration of lysosomal and extralysosomal sites for acid phosphatase in mouse kidney tubule cells with p-nitrophenylphosphate lead-salt technique.

Dual localization of acid phosphatase in lysosomal and extralysosomal sites of the tubule epithelial cells of normal mouse kidney was observed at the light and electron microscope level using a modified Gomori lead-salt method with p-nitrophenylphosphate (pNPP) as substrate. Based on previous biochemical and cytochemical findings, we developed optimal conditions for the enzyme activity in extralysosomal sites. The conditions used for the light microscopic level consisted of 1.5 mM PNPP, 2.0 MM Pb(NO3)2 and 0.05 M acetate buffer (pH 5.8). Those for the electron microscopic study required 3.0 mM PNPP, 3.6 MM Pb(NO3)2 and 0.1 M acetate buffer (pH 5.8). This modified lead-salt technique was highly specific and provided a suitable method for the demonstration of nonlysosomal as well as lysosomal sites of acid phosphatase activity in the tubule epithelial cells of normal mouse kidney. As expected, the enzyme activity appeared in the lysosomes, but the prominent reaction in the brush border, the rough endoplasmic reticulum and basal infolding plasma membranes was not anticipated. We were able to demonstrate in situ organelle precursors of microsomal acid phosphatase such as endoplasmic reticulum, plasma membrane and basal infolding membranes showing the same substrate preference, which had been observed previously in biochemical studies in our laboratory. Since the possible participation of alkaline phosphatases, K+-pNPPase or Na+-K+-adenosine triphosphatase was ruled out by use of appropriate inhibitors, the enzyme-reactive sites can be interpreted as reflecting nonspecific acid phosphatase.     

Ultrastructural demonstration of phosphatases by perfusion fixation followed by perfusion incubation of rat liver.

An alternative to previous methods (tissue chopper, frozen sections) for the ultrastructural demonstration of phosphatases is described. The present approach is based on a short vascular perfusion of rat liver with glutaraldehyde through the inferior caval vein, followed by vascular perfusion incubation with a medium containing the enzyme substrates. The effect of glutaraldehyde on three different types of phosphatases was investigated, namely a lysosomal enzyme (acid phosphatase) a tightly bound microsomal enzyme (G6Pase) and a loosely bound microsomal enzyme (IDPase). It is demonstrated that by perfusion with glutaraldehyde for three minutes good cellular morphology is obtained and that 50-60% of the initial activity of glucose-6-phosphatase, inosine-diphosphatase and acid phosphatase remains. The localization and deposition of G6Pase activity were distinct and observed throughout the endoplasmic reticulum and the nuclear envelope. For acid phosphatase, the reaction product was confined to various types of lysosomes including presumed autophagic vacuoles. No signs of enzyme diffusion were noted. The present approach seems to offer some advantages: it is simple and requires no extra equipment, penetration of the fixative and incubation enzyme medium is good, and finally freeze artifacts are avoided.