Mechanisms of metal-salt methods in enzyme cytochemistry with special reference to acid phosphatase

Summary This review is concerned with theoretical and experimental aspects of the factors governing the localizing potentialities of cytochemical enzyme reactions that are based on the metal-salt principle, that is, the precipitation of the primary product of the enzymatic reaction by a heavy-metal ion at the enzymatic site. Special attention is given to the lead phosphate precipitation process in acid phosphatase cytochemistry. The various model systems developed for the study of the factors involved in precipitation are described and their advantages and disadvantages discussed. Furthermore, the various cytochemical methods so far used for the demonstration of acid phosphatase activity are critically evaluated in the light of the results obtained with the model systems.     

A new optical multichannel microspectrofluorometer.

A new microspectrofluorometer has been developed that combines a photometric fluorescence microscope with an optical multichannel analyzer. This instrument provides fluorescence emission spectra of biological materials by detecting the entire spectrum simultaneously in real time. These spectra are subsequently recorded and corrected so as to identify the fluorescent reaction products or to test whether fluorescent cytochemical probes bind to the expected substrate within cells. The procedures and advantages of optical multichannel analysis are described, and an application of microspectrofluorometry to acriflavine-Feulgen cytochemistry is given.     

Glucose-6-phosphate dehydrogenase cytochemistry using a copper ferrocyanide method and its application to rapidly frozen cells

We describe an improved copper ferrocyanide-based method for cytochemical detection of glucose-6-phosphate dehydrogenase (G6PD), which was used to localize the enzyme within the ultrastructure of rat hepatocytes and adrenocortical cells. With this method, glutaraldehyde fixation and the addition of exogenous electron carriers (for example, phenazine methosulfate) to the cytochemical reaction medium were essential. Copper ferrocyanide reaction product showing the distribution of G6PD was readily recognized at the light microscopic level as Hatchett’s brown staining and at the electron microscopic level as electron-dense deposits. Within stained regions, enzyme cytochemical G6PD activity was found to be associated with ribosome-like structures. Because G6PD is a soluble, cytosolic enzyme, its displacement or extraction may occur during conventional fixation. We, therefore, combined a rapid-freezing technique with G6PD enzyme cytochemistry. The resultant rapid-freezing enzyme cytochemistry enabled us to show the subcellular distribution of G6PD in a more life-like state; the localization of G6PD in rapidly frozen cells was in substantial agreement with that in conventionally fixed cells. Accepted: 14 July 1999     

Enzyme layers on glass as a new model for the quantitative study of capture reactions in cytochemistry,with special attention to acid phosphatase

Summary A model system is described for the study of capture reactions for diffusable compounds in enzyme cytochemistry. The model, which allows the investigation of the influence of the composition of the cytochemical medium, the enzymatic activity, and the dimensions of the enzymatic site on the capture reaction, consists of very thin homogeneous layers of enzyme (0.01–0.1 m thick) on glass, which are incubated in the cytochemical medium. The fraction of the total amount of liberated product precipitated in the enzyme layer is dependent not only on the trapping efficiency of the cytochemical medium but also on the concentration of the primary reaction product that can be built up in the enzyme layer. Calculations were performed to determine the steady-state concentration of the primary reaction product that can be built up in the enzyme layer. Acid phosphatase was used as enzyme. The problems associated with the model and its applicability to other types of cytochemical reactions are discussed.     

Freeze-fracture cytochemistry: a new fracture-labeling method for topological analysis of biomembrane molecules

Freeze-fracture cytochemistry allows visualization of cellular and molecular characteristics of biomembranes in situ. In this review, we discuss freeze-fracture cytochemistry with special reference to a new cytochemical labeling of replicas, the detergent-digestion fracture-labeling technique. In this procedure, unfixed cells are rapidly-frozen, freeze-fractured, and physically stabilized by evaporated platinum/carbon. The frozen cells are then removed from the freeze-fracture apparatus to thaw and are subsequently treated with detergents. After detergent-digestion, replicas are labeled with cytochemical markers. We demonstrate that the technique is a versatile tool for direct analysis of the macromolecular architecture of biomembranes and allows identification of particular intracellular membrane organelles. In addition, we demonstrate the application of ultrasmall gold to freeze-fracture immunocytochemistry. Freeze-fracture cytochemistry is a valuable technique for investigating topology and dynamics of membrane molecules.     

A new dynamic model system for the study of capture reactions for diffusable compounds in cytochemistry. II. Effect of the composition of the incubation medium on the trapping of phosphate ions in acid phosphatase cytochemistry

Synopsis A model system developed for the study of the dynamics of capture reactions for diffusable compounds in cytochemistry served as a basis for the experiments reported in the present paper. The model was used to study the effect of the composition of the cytochemical medium on the trapping of phosphate ions by lead (II) ions in acid phosphatase cytochemistry. In this system a phosphate-containing solution and a lead-containing solution (cytochemical medium) are pumped along opposite sides of a polyacrylamide film. The phosphate concentration at which measurable precipitation starts in the film (critical phosphate concentration) was taken as a measure of the trapping efficiency of the cytochemical medium. The addition of -glycerophosphate and cytidine-5-monophosphate to a buffered lead-containing solution resulted in a higher critical phosphate concentration. Both substrates had an effect on the crystal form of lead phosphate. The addition of chloride ions and acetone, as well as decreasing the molarity of the acetate buffer of the cytochemical medium, were found to lower the critical phosphate concentration, whereas the addition of fluoride ions, glucose, and sucrose had no effect. From the effect of variations in the composition of the cytochemical medium on the trapping efficiency and the turnover number of acid phosphatase in the medium, it was possible to predict which cytochemical medium would be the most suitable for the demonstration of acid phosphatase activity in guinea-pig peritoneal exudate cells. The results were in accordance with the localization of acid phosphatase activity: the higher the trapping efficiency and the turnover number, the higher the amount of precipitate and the number of positive enzymatic sites. In this way an improved cytochemical medium for acid phosphatase was developed.     

Prospects for microscopical cytochemistry

Synopsis This review is devoted mainly to an evaluation of the status of microscopical cytochemistry seen as a discipline aiming at both the localization and the quantification of molecular processes in cells. Its relationships to ultramicrochemistry, as well as, in a broader sense, to biochemistry and cell biology, are discussed from both the historical and the methodological points of view. Recent developments in quantitative cytophysical techniques, such as automated cytophotometry using microscopes fitted with flying spot systems, TV cameras, or scanning stages, and the development of rapid flow cytometers are discussed. Analytical electron microscopy is touched upon too.The main part of the review is devoted to recent trends that strengthen the analytical basis of cytochemical staining methods. The special character of staining procedures as a kind of matrix chemistry is discussed and the potentialities of the use of matrixincorporated compounds for the fundamental study and calibration of microscopical staining procedures are elaborated. Parallel developments in the theory and practice of matrix chemistry in biochemistry are stressed. Growing interrelations between microscopical cytochemistry and related fields of investigation, such as the controlled fragmentation of cells, and methods like ultramicroanalysis of individual cells are indicated.     

Cytochemical and biochemical microanalysis of carcinogenesis

Conclusions While the understanding of early cellular changes gleaned from conventional histopathology alone has been rather limited, modern cytochemical methods at the light and electron microscope level have revealed in a number of experimental models and in some human tumour types important results which indicate that a sequence of qualitatively different cell populations is followed during carcinogenesis Some of the cytochemical and electron microscope findings can be correlated with specific cytopathological phenomena which are readily detectable in routine H & E sections. Thus the evaluation of animal experiments concerned with the testing of chemical compounds for carcinogenicity has been improved. The use of simple cytochemical techniques may considerably increase the reliability of the results. With respect to the further elucidation of the mechanism of neoplastic cell transformation, cytochemistry has broadened research horizons. The identification of putative preneoplastic and early neoplastic cell populations by cytochemical methods allows for the first time the microdissection and subsequent detailed investigation of target cells of the carcinogen which are at a high risk of becoming cancer cells. The combination of cytochemical and biochemical microanalysis seems to be the most useful tool for clarifying a number of important problems of carcinogenesis at present.Dedicated to Professor Ekkehard Grundmann on the occasion of his sixtieth birthday.     

Model film studies in enzyme histochemistry with special reference to glucose-6-phosphate dehydrogenase

Summary This paper deals with the progress made over the last few years in our understanding of enzyme cytochemical staining methods as studied using a fundamental approach with the aid of a model system of thin gel films. Although model films with a matrix of polyacrylamide have been mostly used, the properties and possible applications of other matrices are also reviewed. The chemical aspects of the entrapment of enzyme molecules into a matrix are summarized. Special attention has been paid in model film studies to the principles of the trapping reaction of a diffusable precursor resulting from the enzymatic conversion of a substrate. They are considered here as they concern the cytochemical demonstration of acid phosphatase activity with a lead salt. The effect of fixatives on different enzyme activities, the diffusion rate of substrates and chromogenic compounds to the enzyme site, and enzyme kinetics under cytochemical conditions are also discussed, since they are factors which influence the final results of the staining procedures. The advantage of model film studies in enabling the direct correlation of cytochemical and biochemical results is outlined with special reference to the cytochemical determination of glucose-6-phosphate dehydrogenase with Tetra Nitro BT. A method for determining enzyme activities in the soluble fraction of isolated cells after incorporation in model films is described for the first time. This method has proved to be highly appropriate for microscopical observations of glucose-6-phosphate dehydrogenase activity in single cells, because it results in a good morphology and no formazan precipitaties outside the cells. On the other hand, this type of model film forms a bridge between fundamental model film studies using purified enzyme and quantitative enzyme cytochemistry performedin situ.     

ULTRASTRUCTURAL LOCALIZATION OF COMPLEX CARBOHYDRATES AND PHOSPHATASES IN DIGESTIVE GLAND CELLS OF FEEDING AND HIBERNATING SNAILS, HELIX LUCORUM (GASTROPODA: HELICIDAE)

The digestive gland of normally-fed snails Helix lucorum, aswell as that of snails which had hibernated for 4 months wereexamined by the use of cytochemical techniques for detectionof acid and alkaline phos-phatase, as well as of periodate-reactive(PA-TCH-SP technique), sulfated (HID-TCH-SP technique) and carboxylatedcarbohydrates (LID-TCH-SP technique). The cytochemical resultssupport the hypothesis of intracellular digestion via lysosomalactivity of material taken up by endocytotic processes by thecells of the digestive gland. Four months hibernation did notaffect the intracellular distribution of polysac-charides andphosphatases in the cells of the digestive gland of H. lucorumcompared to that in the control snails. In addition, hibernationaffected the percentage of the calcium cells which significantlyincreased compared to the non-hibernating snails, whiie thepercentages of the digestive and excretory cells remained almoststable. However, the periodate-reactive sulfated and carboxylatedpolysaccharides of the digestive gland cells decreased in thehibernated snails compared to the controls. The results suggestthat the cytochemistry of periodate-reactive, sulfated and carboxylatedpolysaccharides used in the present study could, also, be appliedto the study of lysosomal activities. (Received 1 October 1991; accepted 4 December 1991)     

Relationship between peroxisomes and endoplasmic reticulum investigated by combined catalase and glucose-6-phosphatase cytochemistry

The theoretical advantages of electron microscopic cytochemistry were utilized to look for evidence of possible connections between peroxisomes and the endoplasmic reticulum in rat liver. Established cytochemical procedures for catalase (peroxisomes) and glucose-6-phosphatase (endoplasmic reticulum) were carried out, and evidence was sought of diffusion of reaction products between the organelles. No such diffusion was observed: lead phosphate was found in the endoplasmic reticulum and in the nuclear envelope but not in peroxisomes; oxidized diaminobenzidine (DAB) was seen only in peroxisomes. In addition, both types of cytochemistry were carried out on the same tissue. The two kinds of reaction product could be distinguished by virtue of their different electron opacities. No mixing of the two reaction products was observed. These results do not support the hypothesis that peroxisomes and endoplasmic reticulum may be connected; rather, they support the idea that the two organelles exist as separate cellular compartments.     

Autoradiography-based cytochemical detection of ecto-ATPase, ecto-ADPase, 5′-nucleotidase, and extracellular adenosine production, employing 141Ce3+ as a capturing agent

Summary A method for the visualization of the ecto-nucleotidase enzyme activities present on the cell surface, employing¹⁴¹Ce³⁺ as a capturing and labelling agent, is described. Phosphate ions precipitated at the cell surface can be detected by coating the cells with an autoradiographic emulsion, followed by light microscopical inspection of the formed silver grains. The activities of ecto-ATPase, ecto-ADPase and 5′-nucleotidase were detected by this approach in four different cell lines. Parallel biochemical measurements of the activities of the corresponding enzymes were carried out in order to validate, evaluate, and optimize the cytochemical detection. The finding that Ce³⁺ ions are inhibitory to ecto-ATPase provided evidence for the necessity of carefully establishing appropriate reaction conditions for the cytochemical determination of ecto-nucleotidases. The application of this method to the indirect detection of extracellular adenosine production from substrates like ATP has also been documented. It allows a cytochemical determination of adenosine formed through cascade nucleotide dephosphorylation. This newly described method is of high sensitivity and potentially of value for a variety of applications, including not only cytochemistry but also cell biology, and molecular biology studies.     

The formation and cytochemical characterization of cortical granules in ovarian oocytes of the golden hamster (Mesocricetus auratus).

The formation and cytochemical characterization of cortical granules in the ovarian oocytes of the golden hamster have been investigated by use of light and electron microscopical techniques. Particular emphasis is given to the changing population of organelles associated with cortical granule formation. Our observations indicate that cortical granules are produced by the participation of both the Golgi complex and the rough endoplasmic reticulum. Ultrastructural cytochemistry reveals that the cortical granules are composed of glycoprotein. The cortical granules are released at fertilization by a merocrine-type of secretory process.     

Freeze-fracture cytochemistry: a new method combining immunocytochemistry and enzyme cytochemistry on replicas.

We describe a new freeze-fracture cytochemical technique consisting of combined immunocytochemistry and enzyme cytochemistry. This technique reveals the relationship between molecules in biological membranes by double labeling with two different cytochemical markers (i.e., immunogold probes and cerium). In this method, antigens were detected with specific primary antibodies and appropriate secondary immunoprobes. Subsequently, alkaline phosphates activity was detected with cerium as the capture agent on the same replicas. Octyl-glucoside (OG) digestion before the cytochemical reactions was crucial to the success of this combined method. OG is an efficient detergent and OG digestion can preserve both immunocytochemical antigenicity and enzyme activity on replicas. As an initial examination, we applied this technique to the study of glycosyl-phosphatidyl-inositol-anchored proteins and adhesion molecules in human neutrophils. The method described here should serve as a unique additional approach for the study of topology and dynamics of molecules in biomembranes.     

Effects of polycyclic aromatic hydrocarbons on molluscan lysosomes and endoplasmic reticulum

Summary Some effects of two isomeric polycyclic aromatic hydrocarbons, anthracene and phenanthrene, on the fine structure and cytochemistry of digestive cells in the marine musselMytilus edulis have been investigated. The cytochemical results show that increasing concentrations of anthracene and phenanthrene have different effects on the acid labilization time for laten -glucuronidase which is used to measure the stability of lysosomal membranes. At the ultrastructural level the limiting membranes of secondary lysosomes appear multilayered, with discontinuities and overlaps. Under the conditions of the experiment, only phenanthrene produces changes in this configuration. Both macroautophagic and microautophagic processes occur in the control and hydrocarbon treatments, and complementary data from other studies indicate that autophagic processes are enhanced by polycyclic aromatic hydrocarbons. Phenanthrene also causes proliferation of the smooth endoplasmic reticulum in the digestive cells, although cytochemical measurements of smooth endoplasmic reticulum-associated NADPH-ferrihemoprotein reductase show that anthracene stimulates activity over a greater range of concentrations than phenanthrene. The different effects of the two isomers is taken as evidence that the molecular configuration of the compound determines its reactivity with membranes and its subsequent effect on the physiology of the cells.     

Direct flow cytometric quantification of alkaline phosphatase activity in rat bone marrow stromal cells.

Cell preparations in cytochemistry are conventionally analyzed with transmitted light after fixation and reaction with agents such as azo-coupling dyes. With cell suspensions stained with fluorescent cytochemical dyes, cells can also be analyzed and sorted by flow cytometry. We have exploited the intense red fluorescence of Fast Red Violet LB generated in cytochemical reactions to perform flow cytometric analyses of alkaline phosphatase (AP) expression in rat bone marrow stromal cells. By modifying staining protocols of single-cell suspensions, we demonstrate that in comparison to staining with Fast Red TR, the method is specific, can distinguish among various levels of enzyme expression within the whole population, and permits enzyme kinetic studies of heterogeneous cell populations. The method was applied to study the effect of the glucocorticoid dexamethasone (Dx) on cell proliferation and AP expression. In low AP-expressing cells, Dx treatment at 10(-8) M increased the [3H]-thymidine labeling index from 3.85% to 5.24% (p less than 0.01). In contrast, high AP-expressing cells were unlabeled by [3H]-thymidine. The staining and analytical methods reported here facilitate the detection, isolation, and quantification of subpopulations of bone marrow stromal cells that express alkaline phosphatase activity. These experiments demonstrate the value of flow cytometry as an adjunct to conventional cytochemical methods.     

The development of the sinusoids of fetal rat liver: localization of endogenous peroxidase in fetal Kupffer cells.

Endogenous peroxidase is the cytochemical marker used to identify Kupffer cells in the adult liver. In this study, we show by ultrastructural cytochemistry that Kupffer cells of the fetal rat liver are endogenous peroxidase positive. The reaction product is localized in the endoplasmic reticulum including the perinuclear cisternae and in a few lysosome-like dense bodies. Serial sections of Golgi regions suggest that GERL and not the Golgi stacks, is peroxidase positive. As in the adult liver, peroxidase is not localized in endothelial cells. Kupffer cells do not appear to transform from endothelial or extravascular developing monocytic cells and are present prior to bone marrow formation. The relevance of these observations with respect to the possible origin of the Kupffer cell is discussed.     

Methods of simultaneous visualization of cytoplasmic enzyme reactivity and cell surface antigens (by cytochemistry combined with immunocytochemistry) in individual hematopoietic and lymphoid cells

Enzyme cytochemistry alone, and more recently, immunocytohistochemistry have been satisfactorily used by hematologists and hematopathologists for the study, diagnosis and classification of human hematological and lymphoproliferative disorders. To enhance the potential of these techniques, the possibility of combining immunocytohistochemical techniques with enzyme cytohistochemistry with simultaneous visualization of both reaction products has been examined by some investigators. This approach has been applied to normal, reactive and neoplastic material using mainly cell suspensions and frozen sections, with the aim of improving cell identification in specimens containing different cell types, of determining the cytochemical profiles of well-defined lymphocyte subpopulations and of establishing the cell surface phenotypes of cells that are positive for certain enzymes. In this paper, published reports on this subject are reviewed and compared with the experience of our study group.     

Ultrastructure and cytochemical localization of acid phosphatase of laticifers in Euphorbia kansui Liou

Acid phosphatase (AcPase) activities are involved in the degeneration process of cytoplasm in plants. In this study, acid phosphatase was detected by the method of lead nitrate and cytochemical electron microscopy during the development of nonarticulated laticifers in Euphorbia kansui Liou. The most important feature in the differentiation of the laticifers in E. kansui is that the development of small vacuoles arises from endoplasmic reticulum (ER). The mature laticifers possess a thin layer of electron-dense peripheral cytoplasm in which the organelle cannot be distinguished and a large central vacuole filled with latex particles. AcPase cytochemistry studies show AcPase reaction products congregated into heaps are distributed along the tonoplast of central vacuole and around the mitochondria and plastids. Some small vacuoles which develop at later developmental stages of laticifers contain AcPase reaction products. As a result, the central vacuole is formed by cellular autophagy and fusion of small vacuoles which apparently arises from ER.     

Peroxisomes in regenerating human skeletal myofibers

Peroxisomes of the human regenerating skeletal myofibers were studied qualitatively and quantitatively by electron cytochemistry and were compared with those of the mature normal human skeletal muscle fibers. Peroxisomes visualized by electron cytochemistry with 3,3'-diaminobenzidine (DAB) were small round or oval bodies delimited by a single membrane and contained the electron-opaque, coarsely granular matrix. Muscle grafts of the regenerating normal human quadriceps obtained from 4 orthopedic patients were analyzed 2 weeks after transplantation into nude mice; they contained peroxisomes with a mean diameter of 0.25 microns, ranging from 0.12 to 0.67 microns. The group mean density of peroxisomes per 100 microns2 was 2.0 +/- 0.4 (SE), while that of histochemically normal mature human quadriceps femoris myofibers was 0. The cytochemical controls without DAB or with the presence of 3-amino 1,2,4-triazole in the solution containing DAB lacked the electron-opaque reaction, indicating that these reactions were on an enzymatic basis. The results of this study showed clearly that the regenerating normal human skeletal myofibers contained numerous peroxisomes differing from the mature normal human muscle fibers in which the peroxisomes were not observed.