Monique Vasseur

Direct Inhibitory Effect of Rotavirus NSP4(114-135) Peptide on the Na+-d-Glucose Symporter of Rabbit Intestinal Brush Border Membrane

ABSTRACT The direct effect of a rotavirus nonstructural glycoprotein, NSP4, and certain related peptides on the sodium-coupled transport ofd-glucose and of l-leucine was studied by using intestinal brush border membrane vesicles isolated from young rabbits. Kinetic analyses revealed that the NSP4(114-135) peptide, which causes diarrhea in young rodents, is a specific, fully noncompetitive inhibitor of the Na+-d-glucose symporter (SGLT1). This interaction involves three peptide-binding sites per carrier unit. In contrast, the Norwalk virus NV(464-483) and mNSP4(131K) peptides, neither of which causes diarrhea, both behave inertly. The NSP4(114-135) and NV(464-483) peptides inhibited Na+-l-leucine symport about equally and partially via a different transport mechanism, in that Na+behaves as a nonobligatory activator. The selective and strong inhibition caused by the NSP4(114-135) peptide on SGLT1 in vitro suggests that during rotavirus infection in vivo, NSP4 can be one effector directly causing SGLT1 inhibition. This effect, implying a concomitant inhibition of water reabsorption, is postulated to play a mechanistic role in the pathogenesis of rotavirus diarrhea.

Ionic Strength- and Temperature-Induced KCa Shifts in the Uncoating Reaction of Rotavirus Strains RF and SA11: Correlation with Membrane Permeabilization

ABSTRACT The hydrodynamic diameters of native rotavirus particles, bovine RF and simian SA11 strains, were determined by quasielastic light scattering. By using this method and agarose gel electrophoresis, the Ca2+ dissociation constant, KCa, governing the transition from triple-layer particles (TLPs) to double-layer particles (DLPs), was shown to increase, at constant pH, as the temperature and/or the ionic strength of the incubation medium increased. We report the novel observation that, under physiological conditions, KCa values for both RF and SA11 rotaviruses were well above the intracytoplasmic Ca2+ concentrations of various cells, which may explain why TLP uncoating takes place within vesicles (possibly endosomes) during the entry process. A correlation between TLP uncoating and cell membrane permeabilization was found, as shown by the release of carboxyfluorescein (CF) from CF-loaded intestinal brush-border membrane vesicles. Conditions stabilizing the virion in the TLP form inhibited CF release, whereas conditions favoring the TLP-to-DLP transformation activated this process. We conclude that membrane permeabilization must be preceded by the loss of the outer-capsid proteins from trypsinized TLP and that physiological ionic strength is required for permeabilization to take place. Finally, the paper develops an alternative explanation for the mechanism of rotavirus entry, compatible with the Ca2+-dependent endocytic pathway. We propose that there must be an iterative process involving tight coupling in time between the lowering of endosomal Ca2+ concentration, virion decapsidation, and membrane permeabilization, which would cause the transcriptionally active DLPs to enter the cytoplasm of cells.

Sodium-dependent activation of intestinal brush-border sucrase: correlation with activation by deprotonation from pH 5 to 7.

Abstract The activation of rabbit intestinal brush-border sucrase in the pH range 4.8 to 9.2 was studied as a function of sucrose concentration and temperature in a metal-free, n -butylamine universal buffer, both in the absence and in the presence of sodium. When sodium was absent, enzyme activation involved the simultaneous loss of two key protons (p K 1 of about 5.6), thus yielding a high-affinity, catalytically active enzyme conformation. Inactivation followed when a third key proton (p K 2 of about 8.4) was lost. When sodium was present, kinetic analysis in the pH range 4.8 to 7.2 revealed that sodium activation involves distinct effects on the two kinetic parameters, V m and K m . The V m parameter seemed to conform to the classical rules of pH-dependent enzyme activation and implicated the release of a single proton whose apparent p K (p K 1y , about 5.6) was little affected by sodium. On the contrary, the K m parameter was strongly influenced by sodium. Here, activation of rabbit sucrase seemed to involve release of a different proton whose apparent p K (p K 1x also of about 5.6 in the absence of sodium) was strongly shifted to more acid values by saturating sodium concentrations. The functional distinction between the above two protons explains the existence of strong affinity-type activating effects of sodium on rabbit sucrase, previously shown to be pH independent ( F. Alvarado and A. Mahmood, 1979 , J. Biol. Chem. 254 , 9534–9541).

Purification of the rabbit small intestinal sucrase-isomaltase complex: Separation from other maltases

The rabbit intestinal sucrase-isomaltase complex has been purified to homogeneity after solubilization with Triton X 100 followed by chromatography on DEAE Sepharose CL 6B and a second solubilization with papain. After hydrophobic chromatography on Octyl Sepharose CL 6B, separation from other contaminating maltases was achieved by gel filtration on Ultrogel ACA 22. The final enzyme was purified 390 fold, with a specific activity of about 10 units per mg protein.

pH-Dependent Inhibitory Effects of Tris and Lithium Ion on Intestinal Brush-Border Sucrase

Tris and two of its hydroxylated amine analogs were examined in a metal-free, universal n-butylamine buffer, for their interaction with intestinal brush border sucrase. Our recent three-proton-families model (Vasseur, van Melle, Frangne and Alvarado (1988) Biochem. J., 251, 667-675) has provided the sucrase pK values necessary to interpret the present work. At pH 5.2, 2-amino-2-methyl-l-propanol (PM) causes activation whereas Tris has a concentration-dependent biphasic effect, first causing activation, then fully competitive inhibition. The amine species causing activation is the protonated, cationic form. The difference between the two amines is related to the fact that Tris has a much lower pKa value than PM (respectively, 8.2 and 9.8). Even at pH 5.2, Tris (but not PM) exists as a significant proportion of the free base which, by inhibiting the enzyme fully competitively, overshadows the activating effect of the cationic, protonated amine. Above pH 6.8, both Tris and PM act as fully competitive inhibitors. These inhibitions increase monotonically between pH 6.5 and 8.0 but, above pH 8, inhibition by 2.5 mM Tris tends to diminish whereas inhibition by 40 mM PM increases abruptly to be essentially complete at pH 9.3 and above. As pH increases from 7.6 to 9.0, the apparent affinity of the free amine bases decreases whereas that of the cationic, protonated amines, increases. In this way, the protonated amines replace their corresponding free bases as the most potent inhibitors at high pH. The pH-dependent inhibition by 300 mM Li+ is essentially complete at pH 8, independent of the presence or absence of either 2.5 mM Tris or 40 mM PM. Even at pH 7.6, an excess (300 mM) of Li+ causes significant increases in the apparent Ki value of each Tris, PD (2-amino-2-methyl-1-3-propanediol) and PM, suggesting the possibility of a relation between the effects of Li+ and those of the hydroxylated amines which in fact are mutually exclusive inhibitors. The inhibitory results are interpreted in terms of a mechanistic model in which the free bases bind at two distinct sites in the enzymes active center. Binding at the glucosyl sub-site occurs through the amines free hydroxyl groups. This positioning facilitates the interaction between the lone electron pair of the deprotonated amino group with a proton donor in the enzymes active center, characterized by a pK0 around 8.1. When this same group deprotonates, then the protonated amines acting as proton donors replace the free bases as the species giving fully competitive inhibition of sucrase.

Trans-potassium effects on the chloride/proton symporter activity of guinea-pig ileal brush-border membrane vesicles.

To investigate the inhibitory effect of trans potassium on the Cl-/H+ symporter activity of brush-border membrane vesicles from guinea pig ileum, we measured both 36Cl uptake and, by the pyranine fluorescence method, proton fluxes, in the presence of appropriate H+ and K+ gradients. In the absence of valinomycin, a time-dependent inhibitory effect of chloride uptake by trans K+ was demonstrated. This inhibition was independent of the presence or absence of any K+ gradient. Electrical effects cannot be involved to explain these inhibitions because the intrinsic permeability of these vesicles to Cl- and K+ is negligibly small. Rather, our results show that, in the absence of valinomycin, the inhibitory effect of intravesicular K+ involves an acceleration of the rate of dissipation of the proton gradient through an electroneutral exchange of trans K+ for cis H+, catalyzed by the K+/H+ antiporter also present in these membranes. Valinomycin can further accelerate the rate of pH gradient dissipation by facilitating an electrically-coupled exchange between K+ and H+. To evaluate the apparent rate of pH-dissipating, downhill proton influx, we measured chloride uptake by vesicles preincubated in the presence of alkaline-inside pH gradients (pHout/pHin = 5.0/7.5), charged or not with K+. In the absence of intravesicular K+, proton influx exhibited monoexponential kinetics with a time constant k = 11 s-1. Presence of 100 mM K+ within the vesicles significantly increased the rate of pH gradient dissipation which, furthermore, became bi-exponential and revealed the appearance of an additional, faster proton influx component with k = 71 s-1. This new component we interpret as representing the sum of the electroneutral and the electrically-coupled exchange of trans K+ for cis H+, mentioned above. Finally, by using the pH-sensitive fluorophore, pyranine, we demonstrate that, independent of the absence or presence of a pH gradient, either vesicle acidification or alkalinisation can be generated by adding, respectively, Cl- or K+ to the extravesicular medium. Such results confirm the independent existence of both Cl-/H+ symporter and K+/H+ antiporter activities in our vesicle preparations, the relative activity of the former being larger under the conditions of the present experiments. The possible interplay of these two proton-transfer mechanisms in the regulation of the intracellular pH is discussed.

Quantitative analysis of the mixed activating effects of the alkali metal ions on intestinal brush-border sucrase at pH 5.2.

The activation of rabbit brush-border sucrase by the alkali metal ions, Li+, Na+ and K+, was analyzed using the equations of the random-order allosteric model previously proposed for sucrase (Mahmood, A. and Alvarado, F. (1975) Arch. Biochem. Biophys. 168, 585). The alkali metals have mixed activating effects in tert-butylamine buffers at pH 5.2, including: 1. Affinity-type activation, where the apparent Km decreases as a hyperbolic function of the metal concentration. 2. Capacity-type activation, where the apparent V increases with the metal concentration. These two effects were analyzed quantitatively: firstly, by using linear transformations that allowed us to solve each partial equation separately and secondly, by iteration of the general equation, which permits treating the mixed effects as a whole. Results are consistent with the interpretation that a single metal-binding (activator) site suffices to explain the simultaneous occurrence of the two types of kinetic effect. Nevertheless, complicating factors exist that may require the postulation of additional sites for monovalent cations. In particular, the tert-butylammonium ion appears to interface with the effects of the alkali metals, especially Li+.

PH GRADIENT EFFECTS ON CHLORIDE TRANSPORT ACROSS BASOLATERAL MEMBRANE VESICLES FROM GUINEA-PIG JEJUNUM

1. The effects of alkaline‐inside pH gradients on 36Cl‐ uptake were quantified by using brush‐border membrane (BBM) and basolateral membrane (BLM) vesicles from guinea‐pig jejunum. 2. With BBM vesicles, a pHo/pHi gradient of 5.0/7.5 yielded fast overshoots involving a random, non‐obligatory Cl(‐)‐H+ symport, strongly inhibited by CCCP. In contrast, BLM vesicles responded to similar pH gradients with much smaller, delayed overshoots, unaffected by CCCP. 3. The initial Cl‐ entry rates into BLM vesicles were a function of each pHo, pHi and delta pH value. They were stimulated by valinomycin in the presence of inward‐directed K+ gradients. Short‐circuiting the membrane potential with equilibrated K+ and valinomycin inhibited pH gradient‐dependent Cl‐ uptake, but only partially. 4. Taken together, these results indicate that guinea‐pig jejunal BLM vesicles possess both Cl‐ conductance and Cl(‐)‐H+ symport activities. 5. Even when different, the BBM and the BLM symporters are mechanistically similar. Neither of them involves a Cl(‐)‐OH‐ antiport, nor a simultaneous Cl(‐)‐anion exchange mechanism. Rather, for each membrane, all of these activities (symport, anion exchange) can be explained in terms of a single mobile carrier acting as a random, non‐obligatory Cl(‐)‐H+ symporter where exchange occurs simply by counterflow. Net Cl‐ translocation via either the ternary (Cl(‐)‐C‐H+) or the binary (Cl(‐)‐C) complexes accounts, respectively, for the existence of two, operationally distinct, electroneutral and rheogenic components. 6. The BBM symporter appears to involve an AE2 protein, but the molecular identity of the BLM one remains to be established.

Chloride transport in control and cystic fibrosis human skin fibroblast membrane vesicles

Plasma membrane vesicles were isolated from either cystic fibrosis (CF) or non-CF cultured fibroblasts derived from skin biopsies of either foetus, child or adolescent human donors. The total membrane yield was essentially identical for either CF or control membranes. By using a rapid filtration technique, 36Cl uptake by these vesicles was quantitated in the absence and presence of alkali-metal ion-, electrical- and/or pH gradients. In the absence of a pH gradient (pHout = pHin = 7.5), Cl uptake took place downhill in both cases. Either cis K+, cis Na+ or an equimolar mixture of cis Na+ plus K+ caused Cl uptake activation. In the presence of an alkaline-inside pH gradient (pHout/pHin = 5.5/7.5), Cl uptake exhibited an apparent overshoot independently of the presence or absence of any metal-ion gradient. The observed potassium-, sodium- and proton-dependent Cl influx rates were all unaffected by voltage clamping, indicating the existence in these vesicles of electroneutral symport systems of the type Cl-/H+, Cl-/K+ and/or Cl-/Na+; but not 2 Cl-/Na+/K+. In the presence of an inward-directed K+ gradient, valinomycin further increased Cl uptake, both in the presence and in the absence of a pH gradient, indicating the presence of a rheogenic Cl uniport. In absolute quantitative terms, the two different modes (rheogenic and electroneutral) of Cl transport evinced in these vesicles were about 45% lower in CF than in control skin fibroblasts. However, qualitatively, there was no difference between normal and CF cells. The evidence obtained indicates that the CF defect, which is expressed in fibroblast plasma membranes, does not affect specifically either the rheogenic or the electroneutral Cl transport systems. Rather, the CF cells appear to give a smaller yield of closed, functional vesicles, reflected by a significantly smaller apparent intravesicular volume. Because it also affects the transport of D-glucose and L-alanine, this anomaly could be the consequence of a generalized membrane defect characterizing CF fibroblasts.

A method for writing enzyme rate equations: application to the estimation of the number and size of key proton families

We develop a method to derive the rate equation for enzyme models that include pH-dependent activation. Our presentation is based on a kinetic model recently described for sucrase, the three-key-proton model of Vasseur and coworkers, which considers the existence, in the acid ionization reaction, of two functionally distinct prototropic groups, respectively responsible for either V-type or K-type kinetic effects. In contrast, as concerns the basic ionization reaction, the model conforms to classical concepts of pH-dependent activation, whereby a single proton participates in either V-type or K-type effects but not in both at the same time. Enzymes with more than three key protons have been described, indicating that, rather than isolated protons, groups of protons should be considered, and therefore the model can be better described as a three-proton-family model, where a proton family is defined as one or several protons that are gained or lost as a block and perform the same kinetic function. The resulting model is treated here as a useful framework upon which other models can be built. To facilitate the writing of the rate equations, we define two new entities: (1) intralevel coefficients, which describe the various combinations of the enzyme with either the substrate(s), the allosteric effector(s), or both at a given protonation level, and (2) interlevel coefficients, which describe the interplay between the various protonation levels. The resulting rate equation can be used in a global fit procedure permitting in a single computer run the estimation of (1) the entire set of dissociation and microscopic ionization constants of the model, (2) the number and kinetic function of proton families characterizing the enzyme under consideration, and (3) the number of key protons constituting each family, which is derived from the derivatives of the kinetic parameters, Vm/Km, Vm, and Km.