Fine structural localization of alkaline phosphatase in rat ovum during cleavage

On a submicroscopic level alkaline phosphatase activity was demonstrated by cytochemical methods in all stages of segmenting rat ova under survey, i.e. in the unfertilized and fertilized ovum, in the two-, four- and eight-cell stages and in the blastocyst. The reaction product was present in some cytoplasmic organelles as well as on cell membranes. A considerable number of cytoplasmic organelles with alkaline phosphatase activity was found in all stages from the one-cell up to the eight-cell stage. The reaction product was deposited in the tubules and vesicles of the smooth endoplasmic reticulum, in the nuclear envelope and in the Golgi complex as well. Some multivesicular bodies, autophagic vacuoles and majority of residual bodies out of the secondary lysosomes showed enzymatic activity. In the multicellular stages no significant differences were observed between the individual blastomeres in the incidence and distribution of the alkaline phosphatase activity. On the blastocyst-stage was found a low incidence of enzymatically active cytoplasmic organelles. Alkaline phosphatase activity was demonstrated in some minute vesicles below the cell membrane and in some secondary lysosomes. No essential differences were found between the cells of the embryoblast and the cells of the trophoblast in the incidence of enzymatically active structures. In the one-cell stage the activity of alkaline phosphatase was present on the cell membrane only sporadically, in the two- and four-cell stages enzymatic activity was found in this localization in a third of all specimen. In the eight-cell stage alkaline phosphatase activity was demonstrated on the cell membranes of all blastomeres. In the blastocyst the reaction product was deposited regularly on the membranes of the trophoblastic cells turned towards the zone pellucida, frequently on membranes of mutual tactile cells of the trophoblast and the embryoblast and only sporadically on cell membranes limiting the blastocyst cavity.     

Fine structural localization of thiamine pyrophosphatase and acid phosphatase activities in the mouse pancreatic acinar cell

Summary The fine structural localization of thiamine pyrophosphatase (TPPase) and acid phosphatase (AcPase) was examined in pancreatic acinar cells of fasting and fed mice. The results were not affected by these conditions. TPPase activity was positive in two and sometimes three cisternae of the inner Golgi lamellae as well as in the condensing vacuoles of the trans area, but negative in the rigid lamellae and small vesicles of the trans area. AcPase activity was demonstrated in two and sometimes three cisternae of inner Golgi lamellae, condensing vacuoles, rigid lamellae, lysosomes and smooth or coated vesicles in the trans area. The inner Golgi lamellae and the condensing vacuoles were positive for both enzyme activities. From these facts, the lysosome is considered to be formed not only in the GERL system but also through the rough endoplasmic reticulum-Golgi apparatus route. It is reasonable to consider that Novikoff's GERL is not independent from the Golgi apparatus but represents a part of this organelle.This study was supported by a grant from the Japan Educational Ministry     

Fine structural localization of thiamine pyrophosphatase and acid phosphatase activities in the mouse pancreatic acinar cell

The fine structural localization of thiamine pyrophosphatase (TPPase) and acid phosphatase (AcPase) was examined in pancreatic acinar cells of fasting and fed mice. The results were not affected by these conditions. TPPase activity was positive in two and sometimes three cisternae of the inner Golgi lamellae as well as in the condensing vacuoles of the trans area, but negative in the rigid lamellae and small vesicles of the trans area. AcPase activity was demonstrated in two and sometimes three cisternae of inner Golgi lamellae, condensing vacuoles, rigid lamellae, lysosomes and smooth or coated vesicles in the trans area. The inner Golgi lamellae and the condensing vacuoles were positive for both enzyme activities. From these facts, the lysosome is considered to be formed not only in the GERL system but also through the rough endoplasmic reticulum-Golgi apparatus route. It is reasonable to consider that Novikoff's GERL is not independent from the Golgi apparatus but represents a part of this organelle.     

Fine structural localization of alkaline phosphatase in the fracture callus of the rat

Summary The fine structural localization of nonspecific alkaline phosphomonoesterase in the different cells constituting the fracture callus in the rat was studied by incubating sections of glutaraldehyde-fixed callus tissue of variable age in media containing -glycerophosphate and either lead or calcium ions. The specificity of the reactions were tested by exposing the tissues to inhibitors of alkaline phosphatase.The results showed presence of final product on the plasma membranes and associated structures (subplasmalemmal endocytotic vesicles) of fibroblasts, pre-osteoblasts, osteoblasts, and cartilaginous cells in the callus. With the calcium method, reaction product was demonstrated in vesicular elements of the Golgi apparatus in osteoblasts and chondrocytes. Precipitates indicating presence of alkaline phosphatase activity were also observed on the membranes bordering cytoplasmic projections and fragments of cytoplasm located adjacent to enzyme-containing cells. Furthermore, the globule-shaped bodies in the matrix (Bonucci-bodies) showed evidence of alkaline phosphatase activity.The evidence obtained supported the view that alkaline phosphatase plays a role in calcification. It is suggested that transfer of cellular alkaline phosphatase to the sites of initial calcification in the extracellular matrix occurs by way of pinched off vesicular fragments of the cytoplasm and plasma membrane of osteogenic enzyme-producing cells; these structures appear to move awy from their cells of origin to form the Bonucci bodies in the matrix.     

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.     

Cytochemical localization of acid phosphatase and trimetaphosphatase activities in Kurloff cells

After stimulation of guinea pigs with estradiol to increase their Kurloff cell number, spleen imprints were prepared in order to detect non-specific acid phosphatase (AcPase) activity by light microscopic cytochemistry using naphthol AS-BI phosphate as substrate and pararosanilin or fast garnet GBC as coupler. For ultracytochemistry, Kurloff cells were prepared from spleens by filtration through a homogeneizer screen followed by repeated centrifugation. AcPase and trimetaphosphatase activities were tested using beta-glycerophosphate, cytidine-5'-monophosphate and inorganic trimetaphosphate as substrates. Significant enzymatic activities were demonstrated with all the substrates used in the cytoplasmic inclusion body of the Kurloff cells.     

Cytochemical localization of acid phosphatase and trimetaphosphatase activities in exocrine acinar cells

Acid phosphatase activity, a lysosomal marker, is commonly demonstrated using the Gomori technique with cytidine 5'-monophosphate or beta-glycerophosphate as substrate. Using this lead capture method on mouse and rat exorbital lacrimal, parotid, and pancreatic acinar cells, reaction product was localized in GERL, forming secretory granules, and secondary lysosomes. However, a different cytochemical localization was observed for inorganic trimetaphosphatase, another lysosomal enzyme. When the technique for trimetaphosphatase activity, a metal chelation method, was applied to exocrine acinar cells, reaction produce was conspicuously absent from GERL and forming secretory granules, but was present in secondary lysosomes, occasionally in Golgi saccules, and in previously unreported basal elongated lysosomes. The differences in the localization of the two enzymatic activities emphasizes the importance of employing more than one substrate where possible, and raises questions concerning the mechanism of delivery of acid hydrolases to secondary lysosomes.     

Plasma membrane localization of alkaline phosphatase in HeLa cells.

The localization of alkaline phosphatase in HeLa cells was examined by electron microscopic histochemistry and subcellular fractionation techniques. Two monophenotypic sublines of HeLa cells which respectively produced Regan and non-Regan isoenzymes of alkaline phosphatase were used for this study. The electron microscopic histochemical results showed that in both sublines the major location of alkaline phosphatase is in the plasma membrane. The enzyme reaction was occasionally observed in some of the dense body lysosomes. This result was supported by data obtained from a subcellular fractionation study which showed that the microsomal fraction rich in plasma membrane fragments had the highest activity of alkaline phosphatase. The distribution of this enzyme among the subcellular fractions closely paralleled that of the 5'-nucleotidase, a plasma membrane marker enzyme. Characterization of the alkaline phosphatase present in each subcellular fraction showed identical enzyme properties, which suggests that a single isoenzyme exists among fractions obtained from each cell line. The results, therefore, confirm the reports suggesting that plasma membrane is the major site of alkaline phosphatase localization in HeLa cells. The absence of any enzyme reaction in the perimitochondrial space in these cultured tumor cells also indicates that the mitochondrial localization of the Regan isoenzyme reported in ovarian cancer may not be a common phenomenon in Regan-producing cancer cells.     

Cytochemical localization of alkaline and acid phosphatase in human vanishing bone disease

This report is the first cytochemical investigation of vanishing bone disease "Gorham's Disease" (Gorham and Stout 1955). The ultrastructural localization of non-specific alkaline phosphatase and of specific and non-specific acid phosphatase activity was studied in slices of tissue removed from a patient with this rare disorder. Sodium beta-glycerophosphate and phosphorylcholine chloride were used as substrates. Alkaline phosphatase was present around the plasma membranes of osteoblasts and associated with extracellular matrix vesicles in new woven bone. This is consistent with the proposed role for this enzyme (Robison 1923) and for matrix vesicles (Bonucci 1967) in the mineralization of bone (Bernard and Marvaso 1981). Concentrations of specific secretory acid phosphatase reaction product in the cytoplasm of degenerating osteoblasts may contribute to the imbalance between bone formation and resorption. Osteoclasts, while few in number, showed non-specific and specific acid phosphatase activity. The Golgi apparatus and heterophagic lysosomes of mononuclear phagocytes were rich in non-specific acid phosphatase. This was also present in the Golgi lamellae and lysosomes of endothelial cells. Acid phosphatase cytochemistry suggests that mononuclear phagocytes, multinuclear osteoclasts and the vascular endothelium are involved in bone resorption in this disease.