Co-transport of anions and neutral solutes with cations across charged biological membranes. Effects of surrface potential on uptake kinetics

General rate equations have been developed for the co-transport of an anion with one or two cations across a negatively charged biological membrane. The effects of surface potential on the kinetical parameters of co-transport of monovalent anions with monovalent cations have been investigated in more detail. The influence of changes in the surface potential on ion uptake kinetics appears to be markedly affected by the properties of the co-transport system. This can be shown by investigating boundary cases of the general model, namely (a) random order of binding of the ions, (b) anion binds before cations, (c) cations bind before anion. Since the effects of the surface potential are different for these three cases, these effects might serve as (additional) discrimination criteria.The effect of the surface potential on anion uptake kinetics via a co-transport system to which two cations can bind is rather complex: maxima or minima of the apparent affinity constant K_m of anion uptake may occur. Not only the magnitude of the effect of changes in the surface potential, but also its direction (stimulation, inhibition), is influenced by the co-substrate (cation) concentration. Such effects may also occur if only one cation can bind to the translocator, provided that OH^? ions compete for the anion transport site.In addition, the case of co-transport of a neutral solute with a monovalent cation has been investigated. It has been shown, that monovalent cation has been investigated. It has been shown, that also in this case, the effect of changes in the surfaces potential is affected by the order of binding of the substrates to the translocator.     

Two site-single carrier transport kinetics

Rate equations have been developed which describe the concentration dependence for ion absorption by a two site-single carrier transport system for those cases in which the ion transport can be considered to be formally equivalent with an enzymic process. Comparison of this type of transport is made with ion transport via a one site-two carrier transport system. The equations developed are also applicable to enzymic processes catalysed by an enzyme having two substrate binding sites.     

Localization and identification of the compound causing peak ‘X’ in the 31P-NMR spectrum of Saccharomyces cerevisiae

The present study is aimed at identifying the unidentified compound which gives rise to the so-called resonance ‘X’ in the ³¹P-NMR spectra of yeast cells. In addition, it is attempted to determine the localization of X (inside or outside the cell). Enzymic removal of the cell wall causes resonance ‘X’ to disappear in the spectra of the cells. This observation indicates an extracellular localization of X. The ³¹P-NMR spectrum of the phosphomannan extracted from the yeast shows a single resonance at exactly the same position as that of resonance ‘X’. Extraction of the phosphomannan from delipidized cells causes resonance ‘X’ to disappear from the ³¹P-NMR spectrum of the cells. The intensity of resonance ‘X’ in the spectrum of the intact cells can be almost quantitatively attributed to the amount of phosphomannan present in the yeast. The present results demonstrate that the resonance ‘X’ in the ³¹P-NMR spectrum of yeast cells is caused by phosphomannan in the cell wall.     

Effect of the medium pH and the cell pH upon the kinetical parameters of phosphate uptake by yeast.

1. Both the maximum rate of phosphate uptake and the Km depend upon the pH of the medium in a complex way. 2. The effect of medium pH upon the maximum rate of uptake is mainly indirect and is correlated with changes in cell pH. 3. The Km is affected by the medium pH both directly via an apparent competitive inhibition by hydroxyl anions and indirectly in a similar way as the maximum rate of uptake.     

Uptake and accumulation of Mn2+ and Sr2+ in Saccharomyces cerevisiae

Initial uptake of Mn²⁺ and Sr²⁺ in the yeast Saccharomyces cerevisiae was studied in order to investigate the selectivity of the divalent cation uptake system and the possible involvement of the plasma-membrane ATPase in this uptake. The initial uptake rates of the two ions were not significantly different. This ruled out a direct role of the plasma-membrane ATPase, since this ATPase is specific for Mn²⁺ compared to Sr²⁺. After 1 h uptake, Mn²⁺ had accumulated 10-times more than Sr²⁺. Influx of Mn²⁺ and Sr²⁺ remained unchanged during that time, however. The differences in accumulation level found for Mn²⁺ and Sr²⁺ could be ascribed to a greater efflux of Sr²⁺ as compared with Mn²⁺. Probably this greater efflux of Sr²⁺ was only apparent, since differential extraction of the yeast cells revealed that Mn²⁺ is more compartmentalised than Sr²⁺, giving rise to a lower relative cytoplasmic Mn²⁺ concentration.     

Effect of the surface potential upon ion selectivity found in competitive inhibition of divalent cation uptake. A theoretical approach

The sequence of inhibition of cation uptake caused by a series of cationic inhibitors may shift dramatically on varying the experimental conditions. This sequence depends upon the concentration of the inhibitory cation, the concentration of the substrate cation, the charge density of the cell membrane, the ionic strength of the medium and the affinity of the substrate cation for the negative groups located on the cell membrane. A shift in sequence between inhibitory cations can only occur if one of the inhibitory cations shows a greater affinity for the translocation site than the other, while the affinity for the negative groups on the cell membrane is lower.     

Cd2+ uptake, Cd2+ binding and loss of cell K+ by a Cd-sensitive and a Cd-resistant strain of Saccharomyces cerevisiae

Abstract Uptake of Cd²⁺ into Cd-resistant cells was approximately four times lower than in Cd-sensitive cells of Saccharomyces cerevisiae . Binding of Cd²⁺ to the yeast cells increased during incubation of the cells in the presence of Cd²⁺. The increase in the binding was much higher for wild-type cells than for Cd-resistant cells. This increased binding is ascribed to permeabilization of part of the cells. There is no single relation between the relative rate of K⁺ efflux and the cellular Cd content as has been found previously for wild-type cells. The rates of K⁺ efflux were much less than those found for the wild-type cells. Only with short incubation periods of the cells with Cd²⁺ was the same dependence found between the efflux of K⁺ and the cellular Cd content for both types of cell. The discrepancies found after extended incubation of the cells with Cd²⁺ are ascribed to the fact that Cd-provoked K⁺ release proceeds via an all-or-nothing process and that K⁺ released from permeabilized cells can be reaccumulated in still intact cells. The latter proceeds more efficiently in Cd-resistant cells than in wild-type cells.