Studies on 5'-nucleotidase histochemistry. III. 5'-Nucleotidase activity in smooth muscle cells of the rat's gastrointestinal tube.

The distribution pattern of histochemically detectable 5'-nucleotidase (5'-Nase) activity is described in smooth muscle cells of the rat's gastrointestinal tube (esophagus, stomach, small intestine, large intestine). Both, light and electron microscopic methods are used. Faint positive 5'-Nase activity is observed on smooth muscle cells of the lamina muscularis mucosae in the thoracal esophagus whereas it is completely absent from smooth muscle cells of the abdominal esophagus and the stomach. In the small and large intestine strong positive 5'-Nase reaction is found on smooth muscle cells of the lamina muscularis mucosae and the innermost part of the lamina muscularis externa. In the circular and longitudinal layer of the lamina muscularis externa a slight increase in 5'-Nase activity is observed from the proximal to the distal segments. The reaction product is restricted to the outer cell surface of smooth muscle cells. In the small intestine the strong enzymatic activity in the innermost part of the muscularis externa is found to be localized at small and dense muscle cells (sd-cells). Common morphological and histochemical characteristics of sd-cells and smooth muscle cells of the lamina muscularis mucosae are emphasized. Hypothetical functions e.g. uptake of precursors of nucleosidephosphates, possible functional connection to a high glycogen content, correlation between 5'-Nase activity and proliferation capacity and local vasodilatory effect are discussed.     

5'-nucleotidase activity in developing chick pectoral muscle.

The activity of the plasma membrane enzyme 5′-nucleotidase varies dramatically during the embryonic development of chick pectoral muscle. The specific activity is greatest at early stages of differentiation (8-day embryos), falls to a minimum on days 12–14, then rises again in older embryos. In cultured muscle cells obtained from embryonic chick muscle the 5′-nucleotidase activity is essentially absent. Muscle cells grown in the presence of bromodeoxyuridine, an inhibitor of muscle differentiation, contain enhanced levels of 5′-nucleotidase activity. These results indicate that 5′-nucleotidase may be absent in muscle fibers, but present in other cells of muscle tissue.     

Danazol action on 5'-nucleotidase activity in mouse peritoneal macrophages]

The paper reports the results of danazol action in vivo and in vitro on 5'-nucleotidase activity of mouse peritoneal macrophages. The results showed, that danazol at a concentration of 10 M (the pharmacologic level in women taking 600 mg/day) significantly stimulated the enzyme activity.     

Surface localization of 5'-nucleotidase on the mouse lymphocyte.

The optimal conditions for the cytochemical localization of 5'-nucleotidase (AMPase) in the mouse lymphocyte have been established. Quantitative monitoring of the effects of fixation and the components of the cytochemical medium showed that the cytochemistry can be performed under conditions that do not lead to loss of AMPase activity, and also under conditions where penetration of the substrate into the cell has occurred. The cytochemical reaction product was seen only on the surface of a proportion of splenic lymphocytes, regardless of the fixative used. Biochemical data confirmed that AMPase is an ectoenzyme and is the only protein in splenic lymphocytes capable of catalysing the hydrolysis of AMP. The activity of 5'-nucleotidase was studied also by harvesting cells either from thymus or spleen of A/ST or Cd-1 mouse strains. The enzymatic activity in splenic lymphocytes was more than six time higher than the activity of intact thymus cells. Cytochemically it was evident that within splenic lymphocytes there was a distinct population of lymphocytes with readily demonstrable AMPase activity, and another with no cytochemically demonstrable AMPase activity. It was concluded that murine lymphocytes vary in their activity of AMPase, and that the enzyme is exclusively confined to the cell surface.     

Freeze substituted tissue in 5'-nucleotidase histochemistry. Comparative histochemical and biochemical investigations

The suitability of freeze-substitution in n-butanol and paraffin embedding of tissues for the histochemical demonstration of 5'-nucleotidase was investigated and compared with commonly used preparation techniques, such as fresh frozen sections and cryostate sections of cold formalin and glutaraldehyde-fixed rat liver. The influences of each step of the preparation techniques on the enzyme activity were controlled by a quantitative radiochemical assay. Freeze substitution was revealed to be superior to the commonly used preparation techniques with respect to: 1) high sensitivity and specificity of the histochemical 5'-nucleotidase reaction (this is based on the fact that incubation media with very low lead concentrations (0,6 mM/1) can be used); 2) excellent morphological appearance of the tissues showing cytological details of enzyme localization; 3) unlimited storage of the tissue materials and ease of sectioning.     

5'-Nucleotidase activity and adenosine production in rat liver mitochondria.

The controversial subject of mitochondrial 5'-nucleotidase in the liver was studied employing density gradient fractionation combined with a method for analyzing the distribution profiles of marker enzymes based on multiple regression analysis. Triton WR-1339 was used to improve the separation of mitochondria from lysosomes by the gradient centrifugation technique. Adenosine production was examined further using acetate to increase intramitochondrial AMP, and thus adenosine production, in incubations with gradient centrifugation-purified mitochondria. Distribution analysis of the crude homogenate showed that 5'-nucleotidase activity exists in the mitochondrial fraction. To increase the resolution of this approach with respect to mitochondria, a crude mitochondrial fraction was also studied. In this case the relative mitochondrial activity decreased but 5'-nucleotidase activity was still clearly detectable. The mitochondrial 5'-nucleotidase exhibited a Km of 94 microM and a Vmax of 31 nmol/min per mg protein for AMP. The kinetic data for the Mg2+, ATP, ADP and AOPCP sensitivity of the enzyme showed that it differs from the plasma membrane, lysosome and cytosol 5'-nucleotidases. AOPCP was only a moderate inhibitor, and ATP was a more potent inhibitor than ADP at a 1 mM concentration. The enzyme also showed a requirement of Mg2+. Acetate caused the conversion of intramitochondrial adenylates to AMP and the formation of adenosine. Adenosine concentration increased in the extramitochondrial space in a time-dependent manner, but only trace amounts of nucleotides were detected. The data show that 5'-nucleotidase activity producing adenosine exists in rat liver mitochondria and a concentration-dependent adenosine output from mitochondria by diffusion or facilitated diffusion is also suggested.     

Heterogeneity in 5'-nucleotidase activity of mouse peritoneal macrophages. An EM-cytochemical and biochemical study

After stimulation of the mouse peritoneal cavity with newborn calf serum (NBCS), four types of monocyte and macrophage were distinguished on the basis of peroxidase (PO) patterns. Cytochemically, these cells showed strong heterogeneity in 5'-nucleotidase (5'N) activity. Monocytes and monocyte-derived macrophages with PO activity in granules lacked 5'N activity. Resident macrophages (with PO activity in RER and nuclear envelope) generally had significant 5'N activity on the plasma membrane, the pattern showing close correlation with the biochemical findings. The group of PO-negative macrophages comprised both 5'N-negative and 5'N-positive cells. These findings suggest two possibilities, i.e., that monocytes (5'N-)transform via PO-negative cells (5'N -/+) into resident macrophages (5'N +), or that the monocytes and monocyte-derived macrophages and the resident macrophages represent separate lineages. The fourth type of macrophage, the exudate-resident cell (with PO activity both in granules and in the RER and nuclear envelope), occurred only in low numbers and very late after NBCS stimulation, and is therefore considered not to be a transitional cell between monocytes and resident macrophages.     

Morphogenesis and histochemistry of the developing mouse kidney

A morphological and histochemical investigation was conducted on the pronephros and mesonephros of the mouse embryo from 8.5 through 16.5 days. The pronephros appeared between days 8.5 and 9.5 as a thickening of the somatic layer of the intermediate cell mass. It consisted of three small clusters of cells on either side of the midline dorsally between the somite and the coelom, at the level of somites 8 and 9. The mesonephros arose during day 9 and persisted until day 16. In the male the anterior three tubules were incorporated into the testis at 15.5–16.5 days. The mesonephros consisted of approximately 11 tubules located between somites 10–17. The tubules possessed lumina and connected with the Wolffian duct. Indications of internal and external glomeruli were noted on day 11. The Wolffian duct reached the cloaca at ten days. Strong alkaline phosphatase activity was noted in the differentiating tubules. Cytoplasmic and luminal enzyme activity was observed between 9.3 and 12.5 days indicating possible function at this time. Acid phosphatase was demonstrable in the tubules and duct only on day 11. Ribonucleic acid was observed in the nuclei and cytoplasm of the mesodermal cells as they differentiated into tubules and duct. A decrease in RNA was noted after differentiation was complete. Periodic acid-Schiff material (diastase-stable) was localized in the basement membrane of the tubule and duct cells. A faint positive reaction was also found at the luminal border of the tubules. The strongest reaction was noted in the luminal border at 11.5–12.5 days. Those tubules being incorporated into the genital system in the male were also PAS positive. Morphological and histochemical evidence suggested that the mouse mesonephros, though quasi vestigial, may function for a short time.     

Studies on the alkaline phosphatase and 5'-nucleotidase of Dictyostelium discoideum.

The alkaline phosphatase and 5′-nucleotidase activities of Dictyostelium discoideum are due to two distinct enzymes. Both enzymes are membrane bound, but over 90% of the 5′-nucleotidase activity is solubilized when the crude membrane fraction of the cell is treated with phospholipase C under conditions that release only 10% of the alkaline phosphatase.Part of the alkaline phosphatase activity can be detected in whole cells, suggesting that some of the enzyme molecules are located on the exterior surface of the plasma membrane. In contrast very low 5′-nucleotidase activity can be detected in whole cells. When membrane preparations, isolated from cells that had been surface labeled with ¹²⁵I, were subjected to sedimentation equilibrium on sucrose density gradients, the majority of the ¹²⁵I-radioactivity cosedimented with the alkaline phosphatase and 5′-nucleotidase activites, suggesting that both enzymes are plasma membrane components.The two enzymes have distinctly different pH optima, but otherwise their properties are remarkably similar. Both enzymes are inhibited by cyanide, sulfhydryl inhibitors and sulfhydryl reagents, although in each case the 5′-nucleotidase is slightly more susceptible. Both enzymes are inhibited by the levamisole analogue, R 8231, but the alkaline phosphatase is inhibited to a somewhat greater extent. Both enzymes are activated by incubation at 50 °C but inactivated by higher temperatures.The two enzymes increase in activity at identical times during differentiation, suggesting that they are under coordinate developmental control.