Cation transport in Escherichia coli. VIII. Potassium transport mutants

Analysis of K transport mutants indicates the existence of four separate K uptake systems in Escherichia coli K-12. A high affinity system called Kdp has a Km of 2 muM, and Vmax at 37 degrees C of 150 mumol/g min. This system is repressed by growth in high concentrations of K. Two constitutive systems, TrkA and TrkD, have Km's of 1.5 and 0.5 mM and Vmax's of 550 and 40 at 37 and 30 degrees C, respectively. Mutants lacking all three of these saturable systems take up K slowly by a process, called TrkF, whose rate of transport is linearly dependent on K concentration up to 105 mM. On the whole, each of these systems appears to function as an independent path for K uptake since the kinetics of uptake when two are present is the sum of each operating alone. This is not true for strains having both the TrkD and Kdp systems, where presence of the latter results in K uptake which saturates at a K concentration well below 0.1 mM. This result indicates some interaction between these systems so that uptake now has the affinity characteristic of the Kdp system. All transport systems are able to extrude Na during K uptake. The measurements of cell Na suggest that growing cells of E. coli have very low concentrations of Na, considerably lower than indicated by earlier studies.     

Slow axonal transport.

New studies provide further evidence that the neuronal cytoskeleton is the product of a dynamic interplay between axonal transport processes and locally regulated assembly mechanisms. These data confirm that the axonal cytoskeleton in mammalian systems is largely stationary and is maintained by a smaller pool of moving subunits or polymers. Slow axonal transport in certain lower species, however, may exhibit quite different features.     

Bicarbonate transport proteins.

Bicarbonate is not freely permeable to membranes. Yet, bicarbonate must be moved across membranes, as part of CO2 metabolism and to regulate cell pH. Mammalian cells ubiquitously express bicarbonate transport proteins to facilitate the transmembrane bicarbonate flux. These bicarbonate transporters, which function by different transport mechanisms, together catalyse transmembrane bicarbonate movement. Recent advances have allowed the identification of several new bicarbonate transporter genes. Bicarbonate transporters cluster into two separate families: (i) the anion exachanger (AE) family of Cl-/HCO3- exchangers is related in sequence to the NBC family of Na+/HCO3- cotransporters and the Na(+)-dependent Cl/HCO3- exchangers and (ii) some members of the SLC26a family of sulfate transporters will also transport bicarbonate but are not related in sequence to the AE/NBC family of transporters. This review summarizes our understanding of the mammalian bicarbonate transporter superfamily.     

Calcium transport in isolated bone cells. II. Calcium transport studies

Calcium transport was studied in bone cells isolated from fetal rat calvaria. ⁴⁵Ca uptake experiments revealed an active component of calcium exchange. Calcium uptake was inhibited by iodoacetamide, DNP, CCCP and oligomycin and appeared to be dependent on medium phosphate concentration. Initial influx values exhibited saturation kinetics from 0.6 mM to 1.5 mM extracellular calcium. Efflux of ⁴⁵Ca from loaded cells increased in the presence of iodoacetamide, DNP and CCCP. Incubation of the cells af 4° C inhibited both influx and efflux of calcium. Parathyroid hormone had no consistent effect on calcium uptake although characteristic increases in cyclic AMP levels were seen with the hormone. Calcitonin appeared to cause a transient increase in calcium uptake.     

Cation transport in Escherichia coli. IX. Regulation of K transport

Kinetics of K exchange in the steady state and of net K uptake after osmotic upshock are reported for the four K transport systems of Escherichia coli: Kdp, TrkA, TrkD, and TrkF. Energy requirements for K exchange are reported for the Kdp and TrkA systems. For each system, kinetics of these two modes of K transport differ from those for net K uptake by K-depleted cells (Rhoads, D. B. F.B. Walters, and W. Epstein. 1976. J. Gen. Physiol. 67:325-341). The TrkA and TrkD systems are inhibited by high intracellular K, the TrkF system is stimulated by intracellular K, whereas the Kdp system is inhibited by external K when intracellular K is high. All four systems mediate net K uptake in response to osmotic upshock. Exchange by the Kdp and TrkA systems requires ATP but is not dependent on the protonmotive force. Energy requirements for the Kdp system are thus identical whether measured as net K uptake or K exchange, whereas the TrkA system differs in that it is dependent on the protonmotive force only for net K uptake. We suggest that in both the Kpd and TrkA systems formation of a phosphorylated intermediate is necessary for all K transport, although exchange transport may not consume energy. The protonmotive-force dependence of the TrkA system is interpreted as a regulatory influence, limiting this system to exchange except when the protonmotive force is high.     

Monitoring intracellular transport.

Ingested plastic scintillator spheres are shown to be a useful tool for investigating intracellular transport of material labelled by a weak beta emitter. It is found that-by numerically solving a linear integral equation with known kernel-the time evolution of the intracellular emitter density profile in the vicinity of the cell membrane is determinable from easily obtained experimental data. Applications to special biological systems are noted.     

Plant membrane transport.

Recent developments in plant membrane transport, particularly concerning the vacuolar and plasma membranes, have increased our understanding of molecular aspects of primary pumps, carrier systems and ion channels.     

Quantitative analysis of proton-linked transport systems. Glutamate transport in Staphylococcus aureus.

1. The magnitude of the protonmotive force in respiring Staphylococcus aureus was measured over the range of extracellular pH from 5.6 to 7.8. 2. The membrane potential remains constant at 150 mV, inside-negative, but the pH gradient decreases from 2.1 units, inside-alkaline, at pH 5.6 to zero at pH 7.5 and above. 3. The accumulation of glutamate in the soluble cell pool is pH-independent at a value equivalent to 100 mV. 4. The results of experiments studying co-transport of protons are consistent with a proton/glutamate stoichiometry of 2 and electrogenic transport across the pH range examined. 5. The amount of glutamate uptake is the result of a kinetic steady state between influx and efflux pathways. 6. Evidence is presented for the regulation of this kinetic steady state by the response of the initial rate of uptake to changes in the protonmotive force.     

The retrograde transport method.

After an injection of horseradish peroxidase into the brain, the enzyme product can later be found in cell bodies of neurons which project axons to the injection site. The use of the tracer has now been adapted as a means of identifying neurons on the basis of their efferent fiber projections. In this review particular attention is paid to characteristics of the phenomenon of retrograde transport, such as diffusion of the marker from the injection site and the region of effective uptake, uptake by injured axons of passage as well as by axon terminals and the preterminal portions of axons, and the anterograde movement of peroxidase. The retrograde transport method is compared to the previously available method of retrograde cell degeneration and the advantages and limitations of both techniques are considered.     

Phospholipids and electrolyte transport.

Our understanding of the role of phospholipids in ion transport processes is only beginning to be appreciated. Although the role of polyphosphoinositide and its derived second messenger molecules IP3, diacylglycerol, and arachidonic acid are well studied, we are still not certain as to how changes in the lipid bilayer structure influence the status of ion channels. This review focused on those studies which show a strong correlation with ion conductance changes and the status of the membrane phospholipids. In addition, a number of observations point to a major role of lipid second messengers that activate enzymes involved in protein phosphorylations, i.e., protein kinase C, as major regulators of a variety of ion channels and transporters. Such lipid second messengers provide a cellular mechanism whereby hormones, neurotransmitters, and pharmacologic agents functionally control the ionic environment and intracellular pH of target cells. Some of these pathways still remain to be elucidated; however, an appreciation for the participation of membrane phospholipids in these actions has been presented.     

Nucleocytoplasmic transport of macromolecules.

Nucleocytoplasmic transport is a complex process that consists of the movement of numerous macromolecules back and forth across the nuclear envelope. All macromolecules that move in and out of the nucleus do so via nuclear pore complexes that form large proteinaceous channels in the nuclear envelope. In addition to nuclear pores, nuclear transport of macromolecules requires a number of soluble factors that are found both in the cytoplasm and in the nucleus. A combination of biochemical, genetic, and cell biological approaches have been used to identify and characterize the various components of the nuclear transport machinery. Recent studies have shown that both import to and export from the nucleus are mediated by signals found within the transport substrates. Several studies have demonstrated that these signals are recognized by soluble factors that target these substrates to the nuclear pore. Once substrates have been directed to the pore, most transport events depend on a cycle of GTP hydrolysis mediated by the small Ras-like GTPase, Ran, as well as other proteins that regulate the guanine nucleotide-bound state of Ran. Many of the essential factors have been identified, and the challenge that remains is to determine the exact mechanism by which transport occurs. This review attempts to present an integrated view of our current understanding of nuclear transport while highlighting the contributions that have been made through studies with genetic organisms such as the budding yeast, Saccharomyces cerevisiae.