In vivo reversibility of the jejunal glucose and cation transport alteration caused by intraluminal surfactants in the rat

Tied jejunal loops in anaesthetized rats were under standardized conditions pre-exposed for 30 min. with Tyrode solution containing surfactants. 5, 20 or 150 min. after wash out of bulk surfactant, the loops were re-instilled with Tyrode containing glucose at 5--15 mmol/l. Net glucose, sodium and potassium transport were studied for 15 min. by changes in intraluminal amounts, and compared with results obtained in control rats. The surfactants (mmol/l) tested were the anionics dioctylsulphosuccinate (5.6) and dodecylsulphate (8.5--17), the cationics cetrimonium bromide (2.1--4.1) and benzalkonium chloride (2.1), the nonionics Triton X100 (0.25%) and Lubrol WX (0.25--0.5%) plus cholic acid (4.9) and desoxycholic acid (1.3--2.5). In most cases, the glucose transport was normal or fairly normal after 150 min., most of the restoration taking place shortly after surfactant removal. However, Lubrol in particular caused more irreversible effects. Generally, the changes in net cation transport tended to be less easily reversible than the alteration in glucose transport. In so far as a normal or near to normal glucose transport is unlikely to occur unless both functional and structural integrity of the epithelium is preserved, the results indicate that in most cases there is but insignificant epithelial damage under the experimental conditions. Since, furthermore, these surfactants can interact with glucose transport in the same technique even at lower concentration and shorter incubation time than used here, it is concluded that the interaction of surfactants with intestinal transport is not neccessarily linked to gross histo-pathological changes.

The stimulus-secretion coupling of glucose-induced insulin release. Metabolic and functional effects of NH4+ in rat islets

NH4+ caused a dose-related, rapid, and reversible inhibition of glucose-stimulated insulin release by isolated rat islets. It also inhibited glyceraldehyde-, Ba2+-, and sulfonylurea-stimulated insulun secretion. NH4+ failed to affect glucose utilization and oxidation, glucose-stimulated proinsulin biosynthesis, the concentration of ATP, AD, and AMP, and the intracellular pH. NH4+ also failed to affect the ability of theophylline and cytochalasin B to augment glucose-induced insulin release. However, in the presence and absence of glucose, accumulation of NH4+ in islet cells was associated with a fall in the concentration of NADH and HADPH and a concomitant alteration of 86Rb+ and 45Ca2+ (or 133Ba2+) handling. These findings suggest that reduced pyridine nucleotides, generated by the metabolism of endogenous of exogenous nutrients, may modulate ionophoretic processes in the islet cells and by doing so, affect the net uptake of Ca2+ and subsequent release of insulin.

Studies on the ionophorous antibiotics. XV The monovalent cation selective ionophorous activities of carriomycin, lonomycin and etheromycin

The cations selectivity profiles of the carboxylic ionophores, carriomycin, lonomycin and etheromycin, have been investigated by measuring the complexation affinities for metal cations and the cation transport activity through an organic barrier. In a two-phase partition study, carriomycin and lonomycin formed complexes more readily with K+ than with NH4+, Rb+ or Na+, but not with Li+ or Cs+. On the other hand, etheromycin exhibited a great preference for K+ or NH4+ over Na+, Li+ or Rb+, but displayed no binding affinity for Cs+. The alklaine degradation product of lonomycin exhibited a preference for K+ or Na+, but its complexation affinities were much lower than those of the parent compound. Carriomycin, lonomycin and etheromycin efficiently transported K+, Rb+ and Na+ through a CCl4 barrier. But did not carry Ca2+. These antibiotics caused a massive release of K+, Rb+ or Na+, but not of Li+ and Cs+, from mitochondria previously loaded with these cations by valinomycin or monazomycin. Thus, it is concluded that carriomycin, lonomycin and etheromycin are monovalent cation selective ionophores.

[Effect of inductors of alkali cation permeability on cytochrome c bound to mitochondrial membrane]

The effect of inductors of alkali cation permeability--valinomycin, gramicidin A, gramicidin S and its N,N'-diacetyl derivative--on rat liver mitochondria during respiration has been studied. It is shown that valinomycin, gramycidin A and diacetylgramicidin S at optimal concentration for uncoupling cause two-phase activation of mitochondrial respiration and that this effect results from cytochrome c solubilization. Gramicidin S at optimal concentration cannot remove cytochrome c from the respirating mitochondria. It is suggested that this property of gramicidin S is owned to cytochrome c immobilisation in membrane, due to the effect of this compound.

Maleate induced change in the kidney binding of mercury in rats pretreated with cadmium

The kidney uptake of Hg2+ was increased by Cd2+-pretreatment when Hg2+ was given intraperitoneally but not subcutaneously. Subsequent s.c. administration of maleate increased Hg2+ release from the kidneys only if Hg2+ was given subcutaneously. Neither the effect of Cd2+, nor that of maleate, on the distribution of Hg2+ among the renal soluble protein fractions was affected by the route of Hg2+ administration. The protective effect of Cd2+-pretreatment against the nephrotoxic effect of Hg2+ was also independent of the route of Hg2+ administration. Maleate given in nephrotoxic doses removed Hg2+ and copper, but not Cd2+ from the renal metallothionein fraction. Mercury in the urine, however, was not complexed by proteins with the molecular weight of thionein, but was bound to high molecular weight proteins and diffusible molecules. These findings are discussed in relation to the role of metallothionein in the interaction between Cd2+ and Hg2+.

Calcium-mediated effects of carbachol on cation pumping and Na uptake in rat parotid gland

Carbachol (10(-4) M), a cholinergic secretagogue, significantly increased the ouabain-sensitive uptake of 86Rb by rat parotid gland slices. This effect was blocked by the omission of Ca from the bathing medium. When extracellular Na was decreased from 125 to 5 mM, the effect of carbachol was reversed (86Rb uptake was significantly decreased). Increasing intracellular Na (by incubation in medium lacking K) produced a significant stimulation of 86Rb influx. A role for Na in the response was suspected, and so the metabolism, of 22Na by the slices was characterized. The 60-minute distribution of 22Na could be described by three kinetic components; one extracellular (0.315 ml/g, tau = 1.94 minutes) and two intracellular (0.075 ml/g, tau = 7.63 minutes and 0.017 ml/g, tau = 58.4 minutes). Carbachol enhanced the uptake of 22Na into the intracellular components (primarily the 7.63-minute component). The increased uptake of 22Na required Ca in the bathing medium. These observations could be explained by assuming that cholinergic receptor activation stimulates Ca influx which in turn enhances Na uptake. The resulting elevated intracellular Na acts to stimulate activity of the Na,K pump.

Isolation of a low molecular weight Ca2+ carrier from calf heart inner mitochondrial membrane

A protein was isolated from calf heart inner mitochondrial membrane with the aid of an electron paramagnetic resonance assay based on the relative binding properties of Ca2+, Mn2+, and Mg2+ to the protein. The molecular weight of this protein has been estimated to be about 3000 by urea/sodium dodecyl sulfate gel electrophoresis and amino acid analysis. The protein is shown to have two classes of binding sites for Ca2+ by flow dialysis studies and can extract Ca2+ into an organic phase. The selectivity sequence of this protein determined from the organic solvent extraction experiments shows that it favors divalent cations over monovalent cations. Also, the relative selectivity sequence for divalent cations is Ca2+, Sr2+ greater than Mn2+ greater than Mg2+. Ruthenium red and La3+ are shown to inhibit the protein-mediated extraction of Ca2+ into the organic solvent. The calcium translocation in a Pressman cell by this protein is selectively driven by a hydrogen ion gradient. Control experiments indicate that the Ca2+ trnsport properties of the protein are not due to the contaminating phospholipids. It appears that we have isolated from the inner mitochondrial membrane a calcium carrier, which we have named "calciphorin."

Structural similarities and differences among metal ion complexes of phosphoglucomutase by solvent perturbation and ultraviolet difference spectroscopy

Although the binding of bivalent metal-ion activators to phosphoglucomutase produces substantial changes in the near ultraviolet spectrum of the enzyme, the extent to which aromatic residues are exposed to the aqueous environment, as assessed by means of solvent perturbation spectroscopy (using D2O), does not appear to be significantly altered by the binding process. Other ways in which the spectral effects induced by activation might arise are considered by making comparisons with those changes induced by various nonactivating monovalent and bivalent cations. The observed differences are most easily interpreted in terms of an electrostatic perturbation of (at least) two different tryptophan residues. This interpretation is supported by using cationic vs, neutral (zwitterionic) tryptophan in various solvent systems to generate difference spectra that are similar either to the observed metal-ion induced spectral differences or to the differences in the spectral changes produced by various pairs of metal ions. Although a rationale for the striking similarity in the spectral changes produced by Mg2+ and by Li+ (which elicits less than 2 X 10(-8) of the enzymic activity induced by Mg2+) cannot be ascribed to a simple electrostatic effect, alone, the involvement of an additional, negatively charged group in the binding of Mg2+ (but not Li+) could reduce the effective charge of bound Mg2+ to a value close to that of bound Li+.

Effect of SITS on organic anion transport in the rabbit kidney cortical slice

The effect of SITS (4-acetamido-4'-isothiocyano-2,2'-disulfonic stilbene) on the transport of organic ions in the rabbit kidney cortical slice was studied. SITS at a concentration of 10(-4) to 10(-3) M significantly decreased the slice-to-medium (S/M) concentration ratio of the organic anions p-aminohippurate (PAH), and 2,4,5-trichlorophenoxyacetate, but had no significant effect on that of the organic cation tetraethylammonium. The S/M ratio of PAH decreased to 0.52 +/- 0.03 (SE) in the presence of 10(-3) M SITS. The inhibition of PAH uptake caused by SITS was reversed in the presence of 0.5% bovine serum albumin in the medium. SITS at a concentration of 10(-4) M had no significant effect on the efflux of PAH. However, there was a small increase in PAH efflux at a concentration of 10(-3) M SITS. A Lineweaver-Burk analysis of the data indicates that SITS competitively inhibits PAH uptake and that SITS has a Ki value of 2.3 X 10(-4) M. SITS had no effect on the tissue water content, [14C]inulin space, or intracellular Na and K concentrations. It is suggested that the primary effect of SITS is to inhibit the entry of organic anions from the medium into the cell across the basolateral membrane.

The nature of the renal response to chronic disorders of acid-base equilibrium

The rate of acid excretion by the kidney appears to be determined by factors regulating the site and the rate of sodium reabsorption, rather than by a homeostatic mechanism that responds to systemic pH. This hypothesis, although unconventional, is supported by much experimental evidence, and it accounts for a wide variety of clinical and physiologic findings that heretofore have been difficult or impossible to explain.

Evidence for an electrogenic 3-deoxy-2-oxo-D-gluconate--proton co-transport driven by the protonmotive force in Escherichia coli K12

Evidence is presented indicating that the carrier-mediated uptake of 3-deoxy-2-oxo-D-gluconate and D-glucuronate in Escherichia coli K12 is driven by the deltapH and deltapsi components of the protonmotive force. 1. Approximately two protons enter the cells with each sugar molecule, independent of the sugar and the strain used. 2. In respiring cells, the magnitude of the pH gradient alone, as measured by distribution of [3H]acetate, appears to be insufficient to account for the chemical gradient of 3-deoxy-2-oxo-D-gluconate that is developed between pH 6.0 and 8.0. 3. If the external pH is varied between 5.5 and 8.0, 3-deoxy-2-oxo-D-gluconate uptake is gradually inhibited by valinomycin plus K+ ions, whereas the inhibition caused by nigericin is concomitantly relieved, thus reflecting the relative contribution of deltapH and deltapsi to the total protonmotive force at each external pH. 4. 3-Deoxy-2-oxo-D-gluconate can be transiently accumulated into isolated membrane vesicles in response to an artificially induced pH gradient. The process is stimulated when the membrane potential is collapsed by valinomycin in the presence of K+ ions.

An experimental model of analgesic-induced renal damage--some effects of p-aminophenol on rat kidney mitochondria

1. p-Aminophenol, a known nephrotoxin, has been studied as a model for phenacetin-induced renal damage. 2. Respiration, oxidative phosphorylation and ATPase activity were inhibited in mitochondria isolated from the kidneys of treated rats; this could not be reversed by the addition of exogenous loosely bound cofactors and bovine serum albumin to the assay medium. 3. After treatment the mitochondrial levels of sodium and calcium were increased, potassium decreased and magnesium unaltered. 4. Mitochondria isolated from treated rats showed ultrastructural damage. 5. The results are interpreted to indicate that renal tubular cell mitochondrial injury is important in triggering cortical analgesic renal damage.

Effect of cations on the temperature sensitivity of Ca2+ transport in rat-liver mitochondria and safranine uptake by liposomes

The activation energy of mitochondrial Ca2+ transport has been studied in various conditions by Arrhenius plots in the temperature range 6-20 degrees C. In the presence of Mg2+ the activation energy is decreased to 18 kJ/mole from that of 40 kJ/mole found in a sucrose medium. In the presence of the polyamine spermine the activation energy is practically 0 kJ/mole. A lanthanide Eu3+, which is a potent inhibitor of Ca2+ transport, has no significant effect on the activation energy. In a KCl medium the activation energy is increased to 70 kJ/mole. When both K+ and Mg+ are present the activation energy is nonlinear between 11 and 18 degrees C. In the presence of K+ and spermine it is about 0 kJ/mole between 6 and 13 degrees C and at higher temperatures 68 kJ/mole. Neither Mg2+ nor spermine affect the slope of the Arrhenius plot for state 4 respiration. Spermine decreases slightly the activation energy of Ca2+-stimulated respiration. Spermine also decreases the activation energy of valinomycin- or gramicidin-induced safranine uptake by liposomes from 68 to almost 0 kJ/mole between 17 and 30 degrees C. The results indicate that Ca2+ binding to the polar head groups of the phospholipids at the membrane surface is the rate-limiting step of mitochondrial Ca2+ transport, because agents that inhibit Ca2+ binding to these sites (Mg2+, spermine, K+) have the most marked effect, whereas Eu3+, which, because of the small concentration used, ought to interact mainly with the mitochondrial Ca2+ transport system, has no significant effect on the temperature sensitivity of mitochondrial Ca2+ transport.

Role of the host in the chemotherapy of infectious diseases

The use of a washed-cell system to study the factors controlling the synthesis of alkaline phosphatase and neomycin by Streptomyces fradiae has shown that calcium and magnesium salts are stimulatory, with maximal synthesis of both achieved with a combination of these salts. Among all the carbon sources studied, only arabinose induces alkaline phosphatase synthesis, whereas glucose and other carbon sources inhibit the synthesis of the enzyme. Asparagine is a very good inducer of enzyme and neomycin synthesis, with lysine and alanine having lower stimulatory effects. The appearance of alkaline phosphatase is due to de novo protein synthesis as demonstrated by the inhibition of its synthesis in the presence of chloramphenicol. There is a good correlation between the synthesis of alkaline phosphatase and neomycin biosynthesis.