Light-microscopic histochemistry of non-specific alkaline phosphatase using lanthanide-citrate complexes

New lanthanide methods for the histochemical detection of non-specific alkaline phosphatase in the light microscope are described and compared with already existing techniques for the light microscopical demonstration of this enzyme. To avoid formation of insoluble lanthanide hydroxide at alkaline pH citrate complexes with the capture ions cerium, lanthanum and didymium were used. A molar ratio of 11 mM citrate/14 mM capture reagent is proposed. For preincubated sections, pretreatment in chloroform-acetone and fixation in glutaraldehyde, for non-preincubated sections fixation in glutaraldehyde yielded the best results. 4-Methylumbelliferyl and 5-Br-4-Cl-3-indoxyl phosphate were found to be the most suitable substrates. For routine purposes 4-nitrophenyl, 1-naphthyl, 2-naphthyl and 2-glycerophosphate were also sufficient; naphthol AS phosphates were inferior but still suitable. After incubation for 5-60 min at 37 degrees C lanthanide phosphate was converted into lead phosphate which was visualized as lead sulfide. At pH 9.2-9.5 enzyme activity was demonstrated at many sites such as intestinal, uterine, placental, renal and epididymal microvillous zones, plasma membranes of arterial, sinus and capillary endothelial cells, vaginal and urethral epithelium, smooth muscle cells, myoepithelial cells as well as excretory duct cells of salivary and lacrimal glands and in secretory granules of laryngeal glands. In comparison with Gomori's calcium, Mayahara's lead, Burstone's and Pearse's azo-coupling, McGadey's tetrazolium salt and Gossrau's azoindoxyl coupling technique the lanthanide methods detected alkaline phosphatase activities at identical or additional sites depending on the respective procedure.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

New, improved lanthanide-based methods for the ultrastructural localization of acid and alkaline phosphatase activity

New, improved techniques for the ultrastructural localization of acid and alkaline phosphatase activity using lanthanide cations as the trapping agent were developed. Delayed penetration of the capture ions and the incubation constituents into cellular compartments was prevented by pretreating specimens with borohydride/saponin. Both the concentration of the capture agent in the incubation medium and the incubation time of the tissue specimens were optimized to achieve a satisfactory cytochemical reaction and to avoid precipitation artefacts caused by local matrix effects. The conversion of cerium phosphate into the almost insoluble cerium fluoride minimized losses of the reaction product during postincubation processing. Moreover, lanthanum itself as well as lanthanides other than cerium, e.g., gadolinium and didymium (praseodymium, neodymium), were successfully applied and can be recommended as capture agents for phosphatase cytochemistry.     

Factors affecting lead capture methods for the fine localization of rat lung acid phosphatase

Synopsis Gomori's lead capture method for acid phosphatase localization was adapted for the electron microscope by Holt & Hicks (1961a). The method gave good results in rat liver, but poor tissue preservation with no reaction product in rat lung, and was, therefore, investigated in order to find the optimum conditions for the ultrastructural localization of rat lung acid phosphatase. The conditions investigated included the use of glutaraldehyde or depolymerized paraformaldehyde as the fixative, with and without dimethylsulphoxide; the effect of freezing the tissue; the pH of the incubation medium; and the use of glycerophosphate, naphthol AS-BI phosphate or -naphthyl phosphate as substrates. Improved preservation of ultrastructure with increased yield of reaction product was obtained by prefixing lung in glutaraldehyde containing 10% dimethylsulphoxide, freezing the tissue and incubating at pH 5.7 with -naphthyl phosphate. Tissue preservation was acceptable and dense deposits of reaction product occurred in lysosomal elements of all the alveolar cells and especially in macrophages. Deposits were also found closely associated with the lamellae of the inclusion bodies of Type II cells.     

New,improved lanthanide-based methods for the ultrastructural localization of acid and alkaline phosphatase activity

Summary New, improved techniques for the ultrastructural localization of acid and alkaline phosphatase activity using lanthanide cations as the trapping agent were developed. Delayed penetration of the capture ions and the incubation constituents into cellular compartments was prevented by pretreating specimens with borohydride/saponin. Both the concentration of the capture agent in the incubation medium and the incubation time of the tissue specimens were optimized to achieve a satisfactory cytochemical reaction and to avoid precipitation artefacts caused by local matrix effects. The conversion of cerium phosphate into the almost insoluble cerium fluoride minimized losses of the reaction product during postincubation processing. Moreover, lanthanum itself as well as lanthanides other than cerium, e.g., gadolinium and didymium (praseodymium, neodymium), were successfully applied and can be recommended as capture agents for phosphatase cytochemistry.Dedicated to Professor Dr. T.H. Schiebler on the occasion of his 65th birthday     

Cytochemical localization of plasma membrane ATPase activity in plant cells

Summary The cytochemical localization of ATPase activity has been investigated in maize root cells using both lead and cerium-based capture methods. With both methods, staining at the plasma membrane was observed in all cells of the root, although the precipitate obtained with cerium was more uniform and granular than that with lead. Controls using no substrate or no magnesium, -glycerophosphate to replace ATP, vanadate or boiled tissue generally showed little or no staining. However, biochemical studies on purified plasma membrane fractions showed that ATPase activity was markedly inhibited by fixation, particularly by glutaraldehyde, and also by lead and cerium ions. Non-enzymic hydrolysis of ATP by cerium was greater than that by lead. The value and limitations of these procedures for the localization of plasma membrane H⁺-ATPase activity are summarized in relation to previous criticisms of these methods.Abbreviations DTT dithiothreitol - EDTA ethylene diaminetetraacetic acid - GP B-glycerophosphate - PCMBS p-chloromercuribenzene sulphonic acid - PMSF phenylmethylsulphonyl fluoride     

Localization of Phosphatases in Trypanosoma rhodesiense1

ABSTRACT. Phosphatase activity in Trypanosoma rhodesiense has been examined histochemically by light and electron microscopy and by enzymatic assay in homogenate fractions. Using a method with lead as capture ion, acid phosphatase was found in lysosome-like vesicles and in the flagellar pocket. No alkaline adenosine triphosphatase (ATPase) was detectable by this method. Direct assay of p-nitrophenylphosphatase activity in homogenate fractions showed that acid phosphatase activity was strongly membrane-bound, but that activity at pH 9 was minimal in both soluble and particulate fractions. “Endogenous” ATPase activity was localized specifically and reproducibly in the mitochondrial membranes and under the plasma membrane of the flagellum. This nonenzymic reaction product could not be eradicated by glycerol extraction or glucose depletion. Unlike the membrane staining, which was manifest only after lead treatment, heat-resistant electron-dense material was found in the matrix of lysosomal vesicles in trypanosomes fixed in glutaraldehyde only and not subjected to further treatment with heavy metal reagents. X-ray emission analysis showed the presence of calcium and phosphorus, indicating that the matrix might have a phosphate storage function.     

Gastric K+-stimulated p-nitrophenylphosphatase cytochemistry

Summary A cytochemical study of gastric K⁺-stimulated p-nitrophenylphosphatase (K-NPPase) activity, corresponding to a K⁺-stimulated phosphoprotein phosphatase of H-K-ATPase system, has been made by a new cytochemical method.Sections of fixed guinea pig gastric mucosa in a mixture of 2% paraformaldehyde and 0.25% glutaraldehyde, were incubated with the incubation medium (1.0 M glycine-0.1 M KOH buffer, pH 9.0, 2.5 ml; 1.1 M KCl, 0.5 ml; 10 mM lead citrate dissolved in 50 mM KOH, 4 ml; levamisole, 6.0 mg; dimethyl sulfoxide, 2.0 ml; 0.1 M p-nitrophenylphosphate (Mg-salt), 1.0 ml; ouabain, 73.0 mg) for 30 min at room temperature. Under a light microscope the specific gastric K-NPPase reaction was distributed only in the parietal cells of the fundic glands. The electron microscopic cytochemistry showed that the gastric K-NPPase activity was localized on the membrane lining the apical surfaces, secretory canaliculi and tubulovesicles. On the other hand, ouabain-sensitive K-NPPase activity (Na-K-ATPase) was demonstrated to localize only in the basolateral membrane of parietal cells with Mayahara's method.These findings support the interrelationships between the apical surface membrane, secretory canalicular membrane and tubulovesicles, and the functional differentiation of the membrane between the secretory membrane and basolateral membrane.In honour of Prof. P. van DuijnPart of this paper was presented at the 24th Annual Meeting of the Japan Society of Histochemistry and Cytochemistry held in Nagoya, October 27–28, 1983 (Ogawa KS, Fujimoto K, Ogawa K (1983) A new lead citrate method for the cytochemical demonstration of the H⁺–K⁺-ATPase with p-NPP as a substrate. Acta Histochem Cytochem 16:662)This study was supported by Grants-in-Aid for Encouragement of Young Scientists No. 60770019 to K. Fujimoto from the Ministry of Education, Science and Culture, the Japanese Government     

Localization of acid phosphatase in lactating rat mammary glands

Summary Localization of acid phosphatase in mammary glands of lactating rats was studied by both biochemical and cytochemical methods. Cytochemically, acid phosphatase activity was detected by using lead citrate as the capture agent for the inorganic phosphate released from p-nitrophenyl phosphate. The activity was predominantly localized in the lumina of the endomembrane system and in the milk that had been secreted into the alveolar lumen. Biochemically, acid phosphatase was present in all the subcellular fractions with higher activities in the membrane-associated fractions. The localization of tartrate-resistant acid phosphatases within the endomembrane system of fully lactating rat mammary tissue suggests a possible role for these enzymes in milk secretory processes.Abbreviations ASMX 3-hydroxy-2-naphthoic acid 2,4-dimethylanilide - DMSO dimethylsulfoxide - DTT dithiothreitol - EDTA ethylenedinitrilo tetra-acetic acid - FGM fat globule membranes - MES 2-(N-morpholino) ethanesulfonic acid - PCMB p-chloromercuribenzoate - p-NPP p-nitrophenyl phosphate     

Alkaline lead citrate: a selective stain for glutaraldehyde precipitates of indolamines and primary catecholamines in electron microscopy.

Test-tube experiments proved that alkaline lead citrate (Reynolds, 1963), which is generally used as an electron-opaque stain, specifically reacts with precipitates formed by glutaraldehyde and biogenic amines (indolamines, primary catecholamines). Glutaraldehyde/osmium tetroxide fixation and staining of thin sections with alkaline lead citrate is recommended as an optimal preparation method of studying the above-mentioned amines at a fine structural level.     

Ultrastructural localization of several phosphatases with cerium

Cerium ions have been used as the capture agent for inorganic phosphate released during the enzymatic hydrolysis of phosphate-containing substrates by a variety of phosphatases. Cerium phosphate reaction product accumulation is proportional to the amount of enzyme present in a cell-free model system. Ultrastructurally, cerium phosphate reaction product appears as a very fine electron-dense precipitate. Cerium appears to be a better capture agent for inorganic phosphate than lead in that reaction product is usually more uniform and more consistently reproducible when cerium is used. Furthermore, nonspecific deposits of reaction product that are commonly encountered in lead-based phosphatase reactions are virtually nonexistent when cerium is the capture agent.     

Parathyroid cell variants may be provoked during immersion fixation

Summary Parathyroid glands of cattle, dogs, cats, mice and rats were immersed in glutaraldehyde or mixtures consisting of glutaraldehyde, formaldehyde and acrolein in either Na-phosphate, Na/K-phosphate or Na-cacodylate buffer, and postfixed with OsO₄ in the same buffers or, alternatively, in s-collidine.Excellent preservation of bovine, feline and murine parathyroid glands was achieved with fixation mixtures containing 1% glutaraldehyde, 1.5–2% formaldehyde and 2.5–5% acrolein in 0.1 M Na-cacodylate with or without Ca²⁺ and Mg²⁺, Na-phosphate or Na/K-phosphate at 4°C followed by postfixation with 1% OsO₄ in the same buffers or in s-collidine containing sucrose, Ca²⁺ and Mg²⁺. This procedure largely abolished the occurence of parathyroid cell variants. Bovine parathyroid glands were also satisfactorily preserved with 1% glutaraldehyde and 2% formaldehyde whereas 1% glutaraldehyde and 2.5 or 5% acrolein, lower or higher buffer osmolarity, or immersion at room temperature led to vacuolization of RER and to breakdown of membranes. In contrast, all fixation protocols led to the formation of dark and light cell variants and to multinucleated syncytial cells in dog and rat parathyroids. The results thus show that parathyroid cell variants arise during immersion fixation and that aldehydes, buffers and temperature are important factors for provoking parathyroid cell variants.     

Cytochemical demonstration of phosphatases in membrane-recycling structures of endodermal cells

We applied cytochemical procedures to demonstrate the presence of acid and alkaline phosphatase in the visceral yolk-sac endoderm of rats using frozen, aldehyde-fixed tissue with cerium as the capture agent. This procedure allowed more detailed topochemical localization than was possible using unfrozen tissue or with lead as the capture agent. Acid phosphatase was found to be present in lysosomes as well as in a small number of apical canaliculi, which are thought to be recycling structures of the cell membranes in endodermal cells. Reaction products of alkaline phosphatase were observed on the outer surface of apical, lateral, and basal cell membranes. In addition, some apical vacuoles contained alkaline phosphatase, and more apical canaliculi were positive for alkaline phosphatase than for acid phosphatase. However, most of the apical canaliculi were negative for both enzymes. It is suggested that acid and alkaline phosphatase are taken up by different numbers of apical canaliculi during the detachment of apical canaliculi from lysosomes and resorption vacuoles.     

Electron microscope histochemical localization of alkaline phosphatase(s) in Bacillus licheniformis.

Sites of alkaline phosphatase (APase) activity in a facultative thermophilic strain of Bacillus licheniformis MC14 have been localized by electron microscope histochemistry, using a lead capture method. The effects of 3% glutaraldehyde and 3.0 mM lead on APase activity were investigated, and these compounds were found to significantly inhibit enzyme activity, 68 and 18%, respectively. A number of parameters were varied in studies to localize APase activity, including: growth temperature (55 and 37 degrees C); substrate concentration in the histochemical mixture (0.06, 0.15, 0.30, 1.00 mM); fixatives; protoplast preparations and whole cells; phosphate-repressed and -derepressed cells; and age of vegetative cells (mid-log and late log). These variations affected the number but not the location of lead phosphate deposits, which appeared at discrete sites along the inner side of the cytoplasmic membrane. Control cells incubated in histochemical mixtures lacking substrate, lead, or both exhibited no lead phosphate depositis. The histochemical localization at membrane sites correlated well with biochemical localization data, which indicated that greater than 80% of the APase activity was associated with the membrane fraction in logarithmically growing cells.     

Alkaline lead citrate: A selective stain for glutaraldehyde precipitates of indolamines and primary catecholamines in electron microscopy

Summary Test-tube experiments proved that alkaline lead citrate (Reynolds, 1963), which is generally used as an electron-opaque stain, specifically reacts with precipitates formed by glutaraldehyde and biogenic amines (indolamines, primary catecholamines). Glutaraldehyde/osmium tetroxide fixation and staining of thin sections with alkaline lead citrate is recommended as an optimal preparation method of studying the above-mentioned amines at a fine structural level.Supported by a grant from Deutsche Forschungsgemeinschaft, project No. Bo 525/1     

Cerium-Based Demonstration of Phosphatas Activity in Plastic-Embedded Sections: A Comparison with Conventional Methods

Cerium-based methods have been used for the demonstration of seve phatases at alkaline, acid and neutral pH in low temperature acetone-fixed, plastic-e sections. At alkaline pH calcium is used as capturing agent and the precipitated phosphate converted to cerium phosphate. At neutral and acid pH cerium is used d capturing agent. Cerium phosphate is subsequently visualized using the H₂C₂DAB n: comparison has been made with conventional calcium-cobalt and lead methods. It; that calcium-cobalt methods are more susceptible to improvement than lead methods     

Ultrastructural localization of alkaline phosphatase in the cyanobacteriaCoccochloris peniocytis andAnabaena cylindrica

Summary Histochemical techniques applied at the ultrastructural level have established the periplasmic space as the site of cell bound alkaline phosphatase activity inAnabaena cylindrica andCoccochloris peniocytis. For localization of activity unfixed cells were reacted with calcium nitrate, which acts as the initial capture reagent. After this deposition, the cells were suspended in 2% lead nitrate to convert the calcium phosphate to more electron dense lead phosphate. The majority of cell bound activity appeared to be associated with layer 3 of the cell wall. InA. cylindrica a secondary site of cell bound activity appeared to be in the sheath. Placement in a phosphate free medium caused a substantial increase in the enzyme activity ofA. cylindrica while the activity present in log phase cells ofC. peniocytis was similar to that found in phosphate starved cells.C. peniocytis also secretes the enzyme into the surrounding medium.     

Presence and activity of alkaline phosphatase in two human osteosarcoma cell lines

The presence and activity of alkaline phosphatase in SAOS-2 and TE-85 human osteosarcoma cells grown in culture were examined at the ultrastructural level. A monoclonal antibody raised against purified human bone osteosarcoma alkaline phosphatase was used to localize the enzyme in cultures of the osteosarcoma cells. Similar cultures were analyzed for alkaline phosphatase activity using an enzyme cytochemical method with cerium as the capture agent. Alkaline phosphatase was immunolocalized at the light microscopic level in an osteogenic sarcoma and ultrastructurally on the SAOS-2 cell membrane and the enclosing membrane of extracellular vesicular structures close to the cells. In contrast, the TE-85 cells were characterized by the absence of all but a few traces of immunolabeling at the cell surface. Enzyme cytochemical studies revealed strong alkaline phosphatase activity on the outer surface of the SAOS-2 cell membrane. Much lower enzyme activity was observed in the TE-85 cells. The results support biochemical data from previous studies and confirm that SAOS-2 cells have a significantly greater concentration of alkaline phosphatase at the plasma membrane.     

Cerium-based demonstration of phosphatase activity in plastic-embedded sections: a comparison with conventional methods

Cerium-based methods have been used for the demonstration of several phosphatases at alkaline, acid and neutral pH in low temperature acetone-fixed, plastic-embedded sections. At alkaline pH calcium is used as capturing agent and the precipitated calcium phosphate converted to cerium phosphate. At neutral and acid pH cerium is used directly as capturing agent. Cerium phosphate is subsequently visualized using the H2O2-DAB method. A comparison has been made with conventional calcium-cobalt and lead methods. It appeared that calcium-cobalt methods are more susceptible to improvement than lead methods.