Evolution of permease diversity and energy-coupling mechanisms with special reference to the bacterial phosphotransferase system

Different classes of apparently unrelated permeases couple different forms of energy to solute transport. While the energy coupling mechanisms utilized by the different permease classes are clearly distinct, it is proposed, based on structural comparisons, that many of these permeases possess transmembrane, hydrophobic domains which are evolutionarily related. Carriers may have arisen from transmembrane pore-forming proteins, and the protein constituents or domains which are specifically responsible for energy coupling may have had distinct origins. Thus, complex permeases may possess mosaic structures. This suggestion is substantiated by recent findings regarding the evolutionary origins of the bacterial phosphoenolpyruvate-dependent phosphotransferase system (PTS). Mechanistic implications of this proposal are presented.     

(Na+,K+)-cotransport in the Madin-Darby canine kidney cell line. Kinetic characterization of the interaction between Na+ and K+

Confluent monolayer cultures of the differentiated kidney epithelial cell line, Madin-Darby canine kidney cells (MDCK), have been used to study ion transport mechanisms involved in transepithelial transport. We have investigated the previously reported K+-stimulation of 22Na+ uptake by confluent monolayers of Na+ depleted cells (Rindler, M. J., Taub, M., and Saier, M. H., Jr. (1979) J. Biol. Chem. 254, 11431-11439). This component of Na+ uptake was insensitive to ouabain and amiloride, but was strongly inhibited by furosemide or bumetanide. Ouabain-insensitive 86Rb+ uptake was also inhibitable by furosemide or bumetanide and stimulated by extracellular Na+. The synergistic effect of Na+ and 86Rb+ uptake and K+ on 22Na+ uptake was reflected by an increase in the apparent Vmax and a decrease in the apparent Km as the concentration of the other cation was increased. The extrapolated Km for either 86Rb+ or 22Na+ uptake in the absence of the other cation was 30 mM while the Km in the presence of a saturating concentration of the other cation was 9 mM. The absolute Vmax values for 22Na+ and 86Rb+ uptake suggest a cotransport system with a stoichiometry of 2Na+:3K+. However, because of the experimental design, the actual ratio may be closer to 1:1. Competition with, and stimulation by, a variety of unlabeled cations indicated that Na+ could be partially replaced by Li+, while K+ could be fully replaced by Rb+ and partially replaced by NH4+ and CS+. Uptake by this system was dependent upon cellular ATP. Reduction of intracellular ATP to 3% of normal abolished both K+-stimulated 22Na+ uptake and Na+-stimulated 86Rb+ uptake.     

Vectorial and nonvectorial transphosphorylation catalyzed by enzymes II of the bacterial phosphotransferase system

The plasmolytic response of Bacillus licheniformis 749/C cells to the increasing osmolarity of the surrounding medium was quantitated with stereological techniques. Plasmolysis was defined as the area (in square micrometers) of the inside surface of the bacterial wall not in association with bacterial membrane per unit volume (in cubic micrometers) of bacteria. This plasmolyzed surface area was zero when the cells were suspended in a concentration of sucrose solution lower than 0.5 M, but increased linearly when the sucrose molarity rose above 0.5 M, reaching a plateau value of 3.61 micrometers2/micrometers3 in 2 M sucrose. In contrast, when the bacterial cells were treated with lysozyme plasmolysis increased abruptly from 0.06 micrometers2/micrometers3 in 0.75 M sucrose to 4.09 micrometers2/micrometers3 in 1 M sucrose. When the time of exposure was prolonged, the degree of plasmolysis increased gradually for the duration of the experiment (30 min) after exposure to 1 M sucrose without lysozyme, whereas with lysozyme plasmolysis reached a maximum (4.09 micrograms2/micrometers3) in 2 to 5 min. The examination of ultrastructure showed that the protoplast bodies of lysozyme-treated cells in 1 M sucrose and untreated cells in 2 M sucrose are maximally retracted from the intact wall of the bacteria; hardly any retraction of protoplasts could be seen for untreated cells in 1 M sucrose. The data suggest that the B. licheniformis cells are isoosmotic to 800 to 1,100 mosM solutions, but are able to withstand much greater osmotic pressure with no signs of plasmolysis because the cell wall and the plasma membrane are held in close association, perhaps by a covalent bond. It is likely that lysozyme weakens this bond by degradation of the peptidoglycan layer. Cellular autolysis also weakens this wall-membrane association.     

Fine control of adenylate cyclase by the phosphoenolpyruvate:sugar phosphotransferase systems in Escherichia coli and Salmonella typhimurium.

Inhibition of cellular adenylate cyclase activity by sugar substrates of the phosphoenolpyruvate-dependent phosphotransferase system was reliant on the activities of the protein components of this enzyme system and on a gene designated crrA. In bacterial strains containing very low enzyme I activity, inhibition could be elicited by nanomolar concentrations of sugar. An antagonistic effect between methyl alpha-glucoside and phosphoenolpyruvate was observed in permeabilized Escherichia coli cells containing normal activities of the phosphotransferase system enzymes. In contrast, phosphoenolpyruvate could not overcome the inhibitory effect of this sugar in strains deficient for enzyme I or HPr. Although the in vivo sensitivity of adenylate cyclase to inhibition correlated with sensitivity of carbohydrate permease function to inhibition in most strains studied, a few mutant strains were isolated in which sensitivity of carbohydrate uptake to inhibition was lost and sensitivity of adenylate cyclase to regulation was retained. These results are consistent with the conclusions that adenylate cyclase and the carbohydrate permeases were regulated by a common mechanism involving phosphorylation of a cellular constituent by the phosphotransferase system, but that bacterial cells possess mechanisms for selectively uncoupling carbohydrate transport from regulation.     

Regulation of carbohydrate uptake in gram-positive bacteria.

Uptake of glycerol and other carbohydrates by Staphylococcus aureus cells is sensitive to regulation by sugar substrates of the phosphoenolpyruvate:sugar phosphotransferase system. Inhibition requires an intact phosphotransferase system. In contrast to results obtained with Gram-negative bacteria, it appears that intracellular sugar phosphate is the inhibiting species.     

A transport system for phosphoenolpyruvate, 2-phosphoglycerate, and 3-phosphoglycerate in Salmonella typhimurium.

Salmonella typhimurium strain LT-2 was found to utilize phosphoenolpyruvate, 2-phosphoglycerate, and 3-phosphoglycerate as sole sources of carbon and energy for growth, but Escherichia coli strains did not. The following evidence suggests that this growth difference was due to the presence in Salmonella cells of an inducible phosphoglycerate permease distinct from previously studied transport systems: (a) The ability of cells to take up 3-phospho[14-C]glycerate was induced by growth in the presence of phosphoenolpyruvate, 2-phosphoglycerate, or 3-phosphoglycerate, but not glycerate, alpha-glycerophosphate, or other carbon sources tested. (b) Uptake of 3-phospho[14-C]glycerate was strongly inhibited by the three nonradioactive inducers of 3-phosphoglycerate uptake, but not by glycerate or alpha-glycerophosphate. (c) Mutants which lost the ability to utilize and take up 3-phosphoglycerate simultaneously lost the ability to utilize 2-phosphoglycerate and phosphoenolpyruvate, but not other compounds tested. (d) Mutant strains which constitutively synthesized the phosphoglycerate transport system could use both phosphoglycerates and phosphoenolpyruvate as sole sources of phosphate at low substrate concentrations. (e) A strain lacking alkaline and acid phosphatases could still grow with 3-phosphoglycerate as sole carbon source. Maximal rates of 3-phospho[14-C]glycerate uptake occurred at pH 6 in the presence of an exogenous energy source. The apparent Km for 3-phosphoglycerate uptake under these conditions was about 10-minus 4 M. The maximal uptake rate (but not the Km) was dependent on potassium ions. Although synthesis of the phosphoglycerate transport system appeared to be under adenosine 3:5-monophosphate control, glucose repressed induction only slightly. The genes controlling synthesis of the phosphoglycerate transport system (pgt genes) appeared to map at about 74 min on the Salmonella chromosome.     

Effects of crp mutations on adenosine 3'',5''-monophosphate metabolism in Salmonella typhimurium.

Wild-type Salmonella typhimurium could not grow with exogenous cyclic adenosine 3',5'-monophosphate (AMP) as the sole source of phosphate, but mutants capable of cyclic AMP utilization could be isolated provided the parental strain contained a functional cyclic AMP phosphodiesterase.All cyclic AMP-utilizing mutants had the growth and fermentation properties of cyclic AMP receptor protein (crp) mutants, and some lacked cyclic AMP binding activity in vitro. The genetic defect in each such mutant was due to a single point mutation, which was co-transducible with cysG. crp mutants isolated by alternative procedures also exhibited the capacity to utilize cyclic AMP. crp mutants synthesized cyclic AMP at increased rates and contained enhanced cellular cyclic AMP levels relative to the parental strains, regardless of whether or not cyclic AMP phosphodiesterase was active. Moreover, adenylate cyclase activity in vivo was less sensitive to regulation by glucose, possibly because the enzyme II complexes of the phosphotransferase system, responsible for glucose transport and phosphorylation, could not be induced to maximal levels. This possibility was strengthened by the observation that enzyme II activity (measured both in vitro by sugar phosphorylation and in vivo by sugar transport and chemotaxis) was inducible in the parental strain but not in crp mutants. The results suggest that the cyclic AMP receptor protein regulates cyclic AMP metabolism as well as catabolic enzyme synthesis.     

The Transporter Classification (TC) System, 2002

The Transporter Classification (TC) system is a functional/phylogenetic system designed for the classification of all transmembrane transport proteins found in living organisms on Earth. It parallels but differs from the strictly functional EC system developed decades ago by the Enzyme Commission of the International Union of Biochemistry and Molecular Biology (IUBMB) for the classification of enzymes. Recently, the TC system has been adopted by the IUBMB as the internationally acclaimed system for the classification of transporters. Here we present the characteristics of the nearly 400 families of transport systems included in the TC system and provide statistical analyses of these families and their constituent proteins. Specifically, we analyze the transporter types for size and topological differences and analyze the families for the numbers and organismal sources of their constituent members. We show that channels and carriers exhibit distinctive structural and topological features. Bacterial-specific families outnumber eukaryotic-specific families about 2 to 1, while ubiquitous families, found in all three domains of life, are about half as numerous as eukaryotic-specific families. The results argue against appreciable horizontal transfer of genes encoding transporters between the three domains of life over the last 2 billion years.     

Multifactorial diversity sustains microbial community stability

Maintenance of a high degree of biodiversity in homogeneous environments is poorly understood. A complex cheese starter culture with a long history of use was characterized as a model system to study simple microbial communities. Eight distinct genetic lineages were identified, encompassing two species: Lactococcus lactis and Leuconostoc mesenteroides. The genetic lineages were found to be collections of strains with variable plasmid content and phage sensitivities. Kill-the-winner hypothesis explaining the suppression of the fittest strains by density-dependent phage predation was operational at the strain level. This prevents the eradication of entire genetic lineages from the community during propagation regimes (back-slopping), stabilizing the genetic heterogeneity in the starter culture against environmental uncertainty.