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.     

Enzyme histochemical demonstration of alkaline phosphatase activity in plastic-embedded tissues using a Gomori-based cerium-DAB technique

We describe a new method for light microscopic demonstration of alkaline phosphatase (ALP) activity in plastic-embedded sections. Rat tissues were fixed in acetone (-20 degrees C), infiltrated in glycol methacrylate (GMA), and embedded at 0 degrees C. Sections were cut at 1 and 2 microns, dried at room temperature, and incubated in the conventional Gomori medium. Cerium chloride was used to convert calcium phosphate into cerium phosphate, which was subsequently converted into cerium perhydroxide. The slight yellow precipitate of cerium perhydroxide was amplified using 3,3'-diaminobenzidine tetrahydrochloride (DAB). For comparison, tissue sections were processed according to the calcium-cobalt method. The method described combines exact localization of ALP activity with optimal preservation of tissue morphology.     

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

Summary 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° 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. However, in contrast to the other methods especially the cerium citrate procedure yielded a more precisely localized and more stable reaction product, can be used with all available alkaline phosphatase substrates including those up till now less suitable or unsuitable for light microscopic alkaline phosphatase histochemistry.     

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)     

Ultrastructural localization of phosphatase activity in the guinea pig pineal gland by the cerium technique

Thiamine pyrophosphatase (TPPase), nucleoside diphosphatase (NDPase), and glucose-6-phosphatase (G-6-Pase) were localized by the cerium technique in guinea pig pinealocytes and compared with the corresponding lead technique. NDPase and TPPase were also compared at different pH values using the cerium technique. Vibratome sections of perfusion-fixed tissue were incubated with cerium chloride or lead nitrate. Substrates used were thiamine pyrophosphate (for TPPase), sodium inosine diphosphate (NDPase), and disodium glucose-6-phosphate (G-6-Pase). The 1-2 trans saccules of the Golgi apparatus showed TPPase and NDPase activity but none for G-6-Pase. The endoplasmic reticulum (ER) cisternae and perinuclear space had NDPase and G-6-Pase activity but not TPPase. The abluminal plasmalemma of endothelial cells and the plasmalemma of Schwann cells demonstrated TPPase and NDPase activity but the luminal plasmalemma of the endothelial cells and the plasmalemma of pinealocyte processes showed only NDPase activity. TPPase was active at all pH values tested, but NDPase was most active at pH values of 6.5 and 7.0. Lead phosphate precipitate was frequently seen in nuclei, perinuclear space, ER cisternae, and "synaptic" vesicles when lead was used as the capturing agent. These sites were usually not labeled when cerium was used.     

Light microscopical demonstration of non-specific alkaline phosphatase activity with an incubation medium containing cerium and two calcium as the capturing agents. The cerium/calcium-hydrogen peroxide-P-phenylenediamine/pyrocatechol (Ce/Ca-H2O2-PPD/PC) double capture technique.

A new method for the light microscopical demonstration of alPase activity in cryotome sections by using simultaneously cerium and calcium as capturing agents (double capture technique) is described. This method has an increased sensitivity compared with the single cerium-based and the Gomori based-cerium (single calcium and cerium converted) with techniques described previously. Presuming that the enzymatic activity during incubation of sections in the presence of a defined capturing agent is constant, the increased sensitivity after employment of the double capture method could be attributed to a decrease of enzyme inhibition by cerium through the presence of calcium. Based on model experiments it is assumed that calcium phosphate and cerium phosphate are the primary reaction products, the former converting into cerium phosphate already during incubation. The remaining calcium phosphate is converted completely by treatment with cerium citrate solution (conversion reaction). After oxidation with H2O2 the cerium perhydroxyphosphate was visualized in a paraphenylenediamine/pyrocatechol (Hanker-Yates reagent) solution without H2O2 to give a black reaction product. This visualization procedure is superior to the DAB or DAB-Ni mode as published earlier. Some results concerning the mode of inhibition of the pseudoperoxidase activity of the hemoglobin are presented.     

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.     

Phosphorylation of 5-iodo-5'-amino-2',5',dideoxyuridine by herpes simplex virus type 1 encoded thymidine kinase.

Herpes simplex virus type 1 (HSV-1) encoded thymidine kinase converts 5-iodo-5'-amino-2',5'-dideoxyuridine (AIdUrd), a highly specific anti-herpes agent, into the 5'-diphosphate (AIdUDP) derivative in vitro. AIdUDP was identified by its acid lability, sensitivity to alkaline phosphatase hydrolysis, chromatographic behavior, and ratio of double isotope (125I, 32P) labeling. ATP, but not AMP, is a phosphate donor, and the direct transfer of the beta and gamma phosphate of ATP as pyrophosphate to AIdUrd was ruled out. The presence of a phosphoramidate bond was supported by the acid lability of AIdUDP which has a half life (t1/2) of 320 min at pH 3.0. At neutral pH, the hydrolysis products are AIdUrd and orthophosphate, with AIdUrd monophosphate being the probable hydrolytic intermediate at these pH values. However, at acidic pH, some pyrophosphate was detected in addition to AIdUrd and orthophosphate. AIdUrd competitively inhibited the phosphorylation of thymidine and deoxycytidine. Escherichia coli thymidine kinase, even though 100-fold higher in activity, was unable to phosphorylate AId-Urd under similar incubation conditions.     

Phosphate uptake in Chlorella pyrenoidosa : II. Effect of pH and of SH reagents.

The sensitivity of the phosphate transport system to pCMPS after phosphate starvation is dependent on protein synthesis. This fact is related to the development of transport activity at alkaline pH. In non-starved cells, the presence of only one peak of maximal activity for phosphate uptake at neutral pH (at low and high concentration) has been observed. However, in phosphate starved cells, two peaks of maximal activity (at low phosphate concentration) at neutral and alkaline pH are present. In starved cells, pCMPS inhibits more intensely the phosphate transport activity at alkaline pH than at neutral pH. By contrast, NEM inhibits the phosphate transport more strongly at neutral than at alkaline pH. Phosphate uptake at neutral and alkaline pH are sensitive to osmotic shock, but phosphate uptake at alkaline pH is decreased more than at neutral pH. The results could be interpreted either by assuming that the membrane surroundings change during phosphate starvation or that two transport systems are present in starved cells whereas only one transport system exists in non-starved cells.     

Soil chemistry and plant distributions in rock habitats of southern Sweden

The vascular plant flora of open land on superficial bedrock in southem Sweden (northwards to 59°N) is described and related to soil chemical properties. including soil acidity (pH), exchangeable Al, Ca, Fe, Mn, Mg, and phosphate, as well as to soil solution pH and concentrations of Al, Ca and Mg, and to the contents of soil organic matter, soil depth and bedrock types (sandstone, gneiss, granites, various dark igneous rocks and limestones). About 120 localities with totally 652 sites (4 m²) have been examined. Experimental evidence for the toxicity of acid soils and mineral nutrient deficiency of neutral and alkaline soils is related to field data. Hydrogen and Al ion toxicity in acid soils and low phosphate solubility in neutral - alkaline soils are identified as major factors limiting the field distributions of rock habitat plants. Some species (e.g., Rumex acetosella and Sedum telephium ) were limited by phosphate also in acid soils. The relative importance of H and Al ion concentrations to plant performance under variously acid soil conditions is discussed, and strong evidence is given for a decisive influence of Al ion toxicity on species diversity at pH-KCI > 4.5. The importance of grazing and former land use is considered briefly and the floristic differences between the western and the eastern half of the study area are discussed originating from differences in general distribution patterns of species and soil chemical properties.     

Light microscopic visualization of the reaction product of cerium used for localization of peroxisomal oxidases

The reaction product of cerium used for localization of peroxisomal oxidases is highly electron-dense but lacks sufficient contrast at the light microscopic level. We describe two methods for converting the reaction product of cerium to colored compounds visible by light microscopy. The first method is based on 3,3'-diaminobenzidine (DAB) amplification of transition metal compounds, of which cerium is one. Sections of glutaraldehyde-fixed rat liver or kidney are incubated first in media for various oxidases containing CeCl3, followed by treatment with DAB in Na acetate buffer, pH 5.3. To prevent any interference by the peroxidatic activity of catalase, NaN3 or Na pyruvate is added to the DAB amplification medium. Staining with DAB can be further intensified with NiCl2 or CoCl2. The second method is based on the conversion of the cerium reaction product with alkaline lead citrate and the final visualization of the lead compound with ammonium sulfide. These methods allow the evaluation of large sections for peroxisomal oxidases by light microscopy, making close correlation between light and electron microscopy possible.     

Improved light microscopic demonstration of D-amino acid oxidase activity in cryotome sections using cerium ions as capturing and amplifying agent--the Ce/Ce-H2O2-DAB procedure.

The light microscopical demonstration of D-amino acid oxidase (AAOX) activity with cerium (Ce III) as the capturing agent was improved. The incubation medium was stabilized by the employment of triethanolamine and detrane complexed cerium. A considerable increase in intensity of the reaction was accomplished by treatment of the AAOX-incubated sections with Ce III which reacted with the primary reaction product Ce IV-perhydroxide to form Ce IV-hydroxide. In this way the primary reaction product was reduced and enlarged concomitantly. The Ce IV-hydroxide was converted into Ce IV-perhydroxide by H2O2, which was visualized by blue-black stained Ni-DAB complexes. Thus, Ce III is used as capturing agent as well as amplifier (Ce/Ce-H2O2-DAB method). The primary reaction product Ce III-phosphate formed by coreacting phosphatases was selectively extracted by citrate containing glycine-NaOH buffer while Ce IV-perhydroxide remained in the sections. In model experiments it was proven that the perhydroxide groups in the Ce IV-perhydroxide compound initiate predominantly the DAB polymerization while the contribution of Ce III and Ce IV is small.     

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.     

Phosphatase cytochemistry with cerium as trapping agent. Verification of acid phosphatase and glucose-6-phosphatase reactive sites

Lead is prevalently replaced by cerium as trapping agent in phosphatase cytochemistry to prevent non-specific precipitation. Recently, substrate specific but artefactual lead precipitates have been described in the nuclear envelope (NE) and rough endoplasmic reticulum (RER) due to a local matrix effect. In the present study a verification was carried out of the localization of acid phosphatase and glucose-6-phosphatase in the NE and RER of rat peritoneal macrophages and hepatocytes respectively with cerium. It appeared that precipitates of cerium phosphate in NE and RER of peritoneal macrophages do not represent sites of acid phosphatase activity but are due to the matrix effect. However, in rat hepatocytes these organelles demonstrate true reactive sites for glucose-6-phosphatase.     

Enzyme ultracytochemical demonstration of Ca(++)-ATPase in the rat cerebral cortex.

The localization of Ca(++)-ATPase activity was investigated in the rat cerebral cortex using an ultracytochemical method. Our cytochemical procedure for the detection of enzyme activity is based on an incubation medium consisting of tricine buffer, ATP-disodium salt as substrate, cerium chloride as capturing agent, CaCl2, and levamisole as a nonspecific alkaline phosphatase inhibitor. Final pH was 7.4. Reaction products showing Ca(++)-ATPase activity were localised on the pre- and postsynaptic plasma membrane in association with synaptic vesicles, postsynaptic dendrites and on the axolemma in myelinated nerve fibres. The verification of the main enzymatic properties of Ca(++)-ATPase localization activity is the subject of the following report.     

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     

Distribution and properties of an adenosine triphosphatase in the tanycyte ependyma of the IIIrd ventricle of the rat.

The distribution, histochemical properties and ultrastructural localization of adenosine triphosphate (ATP) hydrolyzing enzymes in the tanycyte ependyma of the third ventricle have been studied in female Wistar rats. Using a calcium-cobalt procedure and a lead capture technique, splitting of ATP could be demonstrated in perikarya and processes of tanycytes in the region of the ventromedial nucleus. The reaction showed no dependence on magnesium or sodium ions, did not occur with other monodi-, and tri-phosphates as substrates, and was inhibited by p-chlormercuribenzoate (PCMB) and sodium fluoride, but not by ouabain. With the calcium-cobalt method the highest intensity of reaction was found at pH 9.4, whereas the lead method gave optimal results at pH 6--8. At the ultrastructural level, the reaction product was found at the outer surface of the plasma membranes of tanycytes and reached its highest concentrations in the region of the region of the apical microvilli; From the findings it is concluded that splitting of ATP in tanycytes is due to a true ATPase. The enzyme might be involved in an active transport of substances by tanycytes.     

Phosphatases and the utilization of organic phosphorus by Rhizobium leguminosarum biovar viceae

Rhizobium leguminosarum biovar viceae strain TAL 1236 growing on different organic phosphorus compounds as sources of phosphate exhibited phosphatase activities. The strain was able to produce both acid and alkaline phosphatases. However, its ability to produce alkaline phosphatase was much higher. When cellular phosphate fell to 0.115% of cell protein, cellular and extracellular phosphatase activities were promoted. Mg²⁺, Co²⁺ and Ca²⁺ enhanced slightly the activity of alkaline phosphatase more than acid phosphatase. However, Mn²⁺ and Fe²⁺ activated acid phosphatase rather than alkaline phosphatase. It may be concluded that Rh. leguminosarum plays an important role in the release of phosphorus from its organic compounds through the action of phosphatases which can be slightly activated by a range of cations.     

Alkaline, acid, and neutral phosphatase activities are induced during development in Myxococcus xanthus.

One of the signals that has been reported to be important in stimulating fruiting body formation of Myxococcus xanthus is starvation for phosphate. We therefore chose to study phosphatase activity during M. xanthus development. Many phosphatases can cleave the substrate p-nitrophenol phosphate. Using this substrate in buffers at various pHs, we obtained a profile of phosphatase activities during development and germination of M. xanthus. These experiments indicated that there are five patterns of phosphatase activity in M. xanthus: two vegetative and three developmental. The two uniquely vegetative activities have pH optima at 7.2 and 8.5. Both require magnesium and both are inhibited by the reducing agent dithiothreitol. The developmental (spores) patterns of activity have pH optima of 5.2, 7.2, and 8.5. All three activities are Mg independent. Only the alkaline phosphatase activity is inhibited by dithiothreitol. The acid phosphatase activity is induced very early in development, within the first 2 to 4 h. Both the neutral and alkaline phosphatase Mg-independent activities are induced much later, about the time that myxospores become evident (24 to 30 h). The three activities are greatly diminished upon germination; however, the kinetics of loss differ for all three. The acid phosphatase activity declines very rapidly, the neutral activity begins to decline only after spores begin to convert to rods, and the alkaline phosphatase activity remains high until the time the cells begin to divide. All three developmental activities were measured in the developmental signalling mutants carrying asg, csg, and dsg. The pattern of expression obtained in the mutants was consistent with that of other developmentally regulated genes which exhibit similar patterns of expression during development. The ease with which phosphatases can be assayed should make the activities described in this report useful biochemical markers of stages of both fruiting body formation and germination.     

SOLUTION PROPERTIES OF β NERVE GROWTH FACTOR PROTEIN AND SOME OF ITS DERIVATIVES

Abstract— The molecular weight of β nerve growth factor protein determined by sedimentation equilibrium in sodium acetate buffer, pH 40, and at protein concentrations around 0-5 mg/ml agrees with the value obtained from the amino acid sequence and confirms the dimeric character of the protein under these conditions. At pH values of 5.0 or greater, β nerve growth factor protein shows either partial dissociation into monomers or aggregation to higher polymers or both phenomena. The extent of dissociation or aggregation depends on buffer type and pH and is most pronounced at alkaline pH. The variation of molecular weight of β nerve growth factor with solvent conditions is similar to that of insulin or proinsulin. Removal of either the two COOH-terminal arginine residues or the two NH₂-terminal octapeptide sequences from the protein has no effect on its solution properties at acid pH, the protein remaining a dimer. Species such as 2-5 S nerve growth factor or cyanogen bromide cleaved nerve growth factor which are partically deficient in COOH-terminal arginine residues and/or NH₂-octapeptide or nonapeptide sequences are also dimers at pH40. The protein derivative which lacks the two NH₂-terminal octapeptide sequence does not, like β-nerve growth factor, display dissociation or aggregation behavior at neutral pH, indicating that these sequences are involved in monomer-monomer interactions.