Membrane electrogenesis and sodium transport in filamentous nitrogen-fixing cyanobacteria

Transport of Na+ and its relationship with membrane potential (delta psi m) was examined in Anabaena L-31 (a fresh water cyanobacterium) and Anabaena torulosa (a brackish water cyanobacterium) which require Na+ for diazotrophic growth. The data on the effect of N,N'-dicyclohexylcarbodiimide indicated that delta psi m was generated by electrogenic proton extrusion predominantly mediated by ATPase(s). In addition, operation of a plasmalemmabound, non-ATP-requiring, H+-pumping terminal oxidase was suggested by the sensitivity of delta psi m to anaerobiosis, cyanide and azide, all of which inhibit aerobic respiration. The response of delta psi m to external pH and external Na+ or K+ concentrations indicated that a diffusion potential of Na+ or K+ may not contribute significantly to delta psi m. Kinetic studies showed that Na+ influx was unlikely to be a result of Na+/NA+ exchange but was a carrier-mediated secondary active transport insensitive to low concentrations (less than 10 mM) of external K+. There was a close correspondence between changes in delta psi m and Na+ influx; all the treatments which caused depolarisation (such as low temperature, dark, cyanide, azide, anaerobiosis, ATPase inhibitors) lowered Na+ influx whereas treatments which caused hyperpolarisation (such as 2,4-dinitrophenol, nigericin) enhanced Na+ influx. Remarkably low intracellular Na+ concentrations were maintained by these cyanobacteria by means of active efflux of the cation. The basic mechanism of Na+ transport in the fresh water and the brackish water cyanobacterium was similar but the latter demonstrated less influx, more efficient efflux, more affinity of carriers for Na+ and less accumulation of Na+, all attributes favouring salt tolerance.     

Cation transport and membrane morphology

Summary Freeze-fracture electron-microscopy has been used to study membrane ultrastructure in (1) red cells from five species of mammals which have naturally occurring differences in cation transport and (2) red cells which have been treated with various drugs known to affect transport. A reproducible method for estimation of the intramembrane particle density is described. Considerable differences in the densities of intramembrane particles on the A-fracture faces were noted in five species of red cells studied. Such differences were not noted on the B-fracture faces. The differences correlated with species differences in active potassium transport and membrane phospholipid composition. Ouabain and trinitrocresolate-treated red cell membranes were found to have small but reproducible reductions in intra-membrane particle densities on the B-fracture faces, but such differences were not seen in valinomycin and amphotericin B-treated red cells. It was found that dimethylsulfoxide (DMSO) and glycerol drastically reduced intra-membrane particle densities. However, over the range of glycerol and DMSO concentrations in which membrane morphology was altered, no effects on either passive or active potassium transport were observed. It appears that the particles which are altered by DMSO and glycerol are not involved in cation transport.     

Cation transport in nanopores

Using periodic boundary conditions and external electric potential field, we have simulated an ion current flow through a flexible nanopore using cations and an explicit extended simple point charge (SPC/E) water with molecular dynamics simulation. The simulation voltages range goes beyond the usual ionic channel measurements ( ± 1 V) and yields useful information about density profiles, current density distribution and current–voltage (I–V) characteristics.     

Cation transport in yeast

1. The distribution of azide added to suspensions of bakers' yeast was studied under various conditions. The recovery of azide was estimated in the volume of water into which low concentrations of electrolytes can readily diffuse (anion space). Considerable azide disappeared from this anion space. 2. The incomplete recovery of azide in the anion space is due to its uptake by the cells. This uptake occurs against a concentration gradient at 0 degrees C., and is attributed to binding of azide by cell constituents. 3. Confirmatory evidence is presented that one such constituent is the K carrier in the cell membrane. The azide inhibition of K transport is not mediated by inhibition of cytochrome oxidase in the mitochondria. 4. From the amount of combined azide and the experimentally determined dissociation constant of the K carrier-inhibitor complex, the maximum value for the concentration of this carrier is calculated as 0.1 microM/gm. yeast. 5. The addition of glucose and PO(4) causes a secondary K uptake which is not azide-sensitive and is clearly distinct from the primary, azide-sensitive mechanism. 6. The existence of a separate carrier responsible for Na extrusion is reconsidered. It is concluded that present evidence does not necessitate the assumption that such a carrier is active in yeast.     

Streptococcus faecalis proton gradients and tetracycline transport.

The transport of chlortetracycline by Streptococcus faecalis is energy dependent. Addition of glucose to energy-depleted cells enhances both the transport rates and accumulation levels. Transport rates can be altered independently of glucose by treating cells with ionophores that increase or decrease the proton gradient. The transport of the antibiotic is linked only to the transmembrane pH difference, delta pH, and not the transmembrane electrical potential, delta psi. This conclusion was verified by quantitative measurements of delta pH, delta psi, and tetracycline accumulation levels. A linear correlation between delta pH and the tetracycline electrochemical potential was observed. Tetracycline most likely accumulates by the symport of protons in which the protons are bound to an anionic form of the antibiotic to form an uncharged molecule.     

Cation transport in vascular endothelial cells and aging

Summary To understand the generation and maintenance of Na and K gradients in cultured vascular endothelial cells, net Na and K movements were studied. Ouabain-sensitive (OS) net Na gain and K loss were estimated as the difference between the cation content in the presence of ouabain and that in the control. Ouabain-and furosemide-resistant (OFR) fluxes were determined in the presence of the two inhibitors. When the normal medium bicarbonate and phosphate buffers were replaced by N-2-hydroxyethylpiperazine-N'-2-ethane sulfonic acid both the OS ans OFR fluxes decreased more than 50%. Ouabain-sensitive and ouabain-and furosemide-resistant fluxes decreased with increasing cellular age (passage number) an effect not observed when the cation movements were studied in the absence of bicarbonate and phosphate. These results suggest that cultured vascular endothelial cells possess bicarbonate-and phosphate-dependent Na and K pathways which account for a significant portion of their passive movements. Furthermore, the behavior of cation permeabilities with passage number suggests that these modulations may be related to the cellular aging process.     

Cation transport in Serratia marcescens and Serratia marinorubra

The sodium, potassium, and magnesium ion contents of Serratia marcescens and those of its salt-tolerant relative, S. marinoruba, were determined by atomic-absorption spectrometry. The intracellular K(+) and Mg(2+) contents of both microorganisms were found to be dependent on the ionic strength of the growth or suspending medium. The Mg(2+) content of S. marinoruba was generally greater than that of S. marcescens. The Na(+) content of the cells was normally low and did not increase as the cells aged or when the cells were grown in media of high ionic strength. The transport of K(+) by resting cells suspended in hypertonic solution was studied by chemical and light-scattering techniques and was found to be more rapid in S. marcescens than in S. marinorubra. The slower rate of K(+) transport in S. marinorubra is probably related to the lower glycogen reserves found in resting cells of this microorganism. K(+) transport was found to have a pH optimum of 5.5 to 6.1 for S. marcescens, and the K(m) for K(+) was approximately 1.6 mm. Na(+) and Mg(2+) were not taken up by the cells, although the presence of Mg(2+) tended to decrease rates of K(+) uptake. Tris-(hydroxymethyl)aminomethane, routinely used for resuspending the cells, was apparently taken up by the cells at pH >7.     

Exocellular polysaccharide production byStreptococcus thermophilus

Summary Streptococcus thermophilus strains grown on skim milk produce exocellular polysaccharide, essentially composed of galactose and glucose. Small amounts of xylose, arabinose, rhamnose and mannose are identified also. A relationship exists between viscosity of the culture medium and the amount of polymer produced. However, the thickness producing trait in the strains studied is highly unstable.