[en] Short communication

[en] Carbachol (CCH), serotonin (5HT), divalent ionophore A23187, cAMP, and certain neuropeptides, i.e. substance P (SP), inhibit the initial rate of uptake (influx) of ²²Na into isolated chicken villus enterocytes. All these agents also increase cytosolic Ca. However, the increases stimulated by CCH, 5HT, and cAMP are not blocked by chelation of extracellular Ca, whereas those of A23187 and SP are. Only CCH and 5HT stimulate hydrolysis of membrane phosphoinositides to form inositol phosphates. CCH and 5HT also stimulate incorporation of [³²P]-PO₄ into membrane polyphosphoinositides. These studies suggest that at least three mechanisms exist to increase cytosolic Ca in chicken enterocytes and thereby inhibit Na influx. Certain neurohumoral agents such as SP open a plasma membrane permeability for Ca, permitting extracellular Ca to enter the cell down its electrochemical gradient. These agents do not stimulate phosphadidylinositol breakdown. CCH and 5HT stimulate phosphatidylinositol breakdown and via the formation of inositol trisphosphate release Ca from intracellular stores. A third mechanism exists for cAMP which mobilizes Ca from intracellular stores, but does not involve the metabolism of membrane phosphatidylinositols

[en] MC9 mast cells stimulated by a soluble (calcium ionophore A23187) or by an Fc epsilon-receptor agonist (IgE plus hapten) produce platelet activating factor (PAF). MC9 cells incorporate either exogenous [³H]acetic acid or [³H]lyso-PAF into PAF. PAF was identified by mobility on thin layer chromatography, platelet aggregatory activity inhibitable by known PAF antagonists, and by enzymatic modification. Quantified by aggregation of rabbit platelets, MC9 cells produce 6 pmoles PAF/10(6) cells. MC9 cells express acetyltransferase activity of 0.19 nmole/5 min-mg protein. Analysis of MC9 phospholipids by HPLC showed that MC9 cells contain large amounts of phosphatidylcholine (82 nmoles/10(7) cells) but contain little ether-linked phosphatidylcholine (4 nmoles/10(7) cells)

[en] Prostaglandins (PG's) increase short-circuit current (I/sub sc/), inhibit NaCl absorption, and stimulate Cl secretion in rabbit ileum. These changes occur with the following PGs; E₃, E₁, nitrilo-I₂ and, to a lesser extent, with A₂, D₂, and F/sub 2α/. Arachidonic acid (AA) also stimulates secretion. The PG- or AA-stimulated I/sub sc/ does not persist, however, and on prolonged exposure tachyphylaxis develops. Resensitization of the I/sub sc/ response to PGE₂ is rapid, being essentially complete in 15 min after the PG is removed. Desensitization to AA is not reflected by diminished PG generation. PGE₂ release from the mucosa after AA addition is constant, although the AA-stimulated I/sub sc/ decreases. I/sub sc/ measurements indicate that PGE₂ at slightly below its EC₅₀ partially desensitizes and a near-maximal concentration completely desensitizes to PGE₂ but does not, however, inhibit the subsequent change in I/sub sc/ caused by theophylline or vasoactive intestinal peptide (VIP). Adenosine 3',5'-cyclic monophosphate (cAMP) measurements suggest that desensitization applies to cAMP production. PGE₂ (10^-5 M) increases mucosal cAMP three- to sevenfold, but this elevation is transient; a second challenge dose, which fails to elicit a I/sub sc/ change, also fails to increase mucosal cAMP. Adenylate cyclase measurements from untreated and PGE₂-treated enterocytes demonstrate a decrease in stimulation by PGE₂ but not in stimulation by VIP, fluoride, or 5-guanylylimidodiphosphate

[en] Effects of HgCl2 (100 microM) para-chloromercuribenzene sulfonate (PCMBS) (1 mM), and oxophenylarsine (OPA) (250 microM) were determined on (a) the rate of Na pump activity in intact winter flounder intestine; (b) activity of Na-K-ATPase in tissue homogenates; and (c) Na-dependent and Na-independent uptake of tyrosine in brush border membrane vesicles. Initial rate of uptake (influx) of 86Rb from the serosal solution of tissues mounted in Ussing chambers, a measure of Na-K-ATPase activity in the intact cell, was inhibited by all three agents with differing time courses. Rapidly permeating HgCl2 inhibited influx to the same degree as ouabain at 30 min, whereas the effects of PCMBS and OPA required 90 min. Cell potassium was also measured as an indirect indicator of ATPase activity and cell membrane permeability. All three agents decreased cell K, although effects on cell K lagged behind those for inhibition of the ATPase. At the concentrations used in the Ussing chamber (or at one-tenth concentration), all agents completely inhibited Na-K-ATPase activity in enzyme assays performed with tissue homogenates. In contrast, only HgCl2 decreased Na-dependent uptake of tyrosine by brush border membrane vesicles. These results suggest that mercurial and arsenical effects on tyrosine absorption are due to inhibition of the Na-K-ATPase thus decreasing the driving force for the cellular uptake by the Na-tyrosine cotransport system. Direct effects on Na-tyrosine cotransport may play a role in the inhibition observed with HgCl2, but not for PCMBS or OPA

[en] Tyrosine absorption across the brush border of the intestinal epithelium of the winter flounder Pseudopleuronectes americanus was studied in Ussing chambers modified to determine early rates of uptake. At 0.1 mM tyrosine, the 4-min rate of uptake (influx) of tyrosine across the brush border averaged 37.5 nmol·cm^-2·h^-1. Omission of Na decreased influx by 60%, indicting that tyrosine influx occurs, at least in part, by a Na-coupled process. Ouabain inhibited influx by 80%. Inhibition of brush border Na⁺-K⁺-2Cl^- cotransport by bumetanide, 8-bromo-cyclic GMP, or Cl replacement stimulated tyrosine influx 2.5- to 4-fold. However, atriopeptin III, which also inhibits Na⁺-K⁺-2Cl^- cotransport, did not stimulate tyrosine influx. Cyclic AMP, which does not appear to inhibit ion cotransport, did not stimulate tyrosine influx. Both cyclic GMP and bumetanide also stimulated the net mucosa-to-serosa tyrosine flux (43 and 29%, respectively) and increased the cellular concentration of tyrosine by 50%. Thus tyrosine's influx is increased to a greater extent than is its transmural flux or its cellular concentration, suggesting that the main change occurs at the brush border and represents large increases in both influx and efflux of tyrosine across this membrane