Two fep genes are required for ferrienterochelin uptake in Escherichia coli K-12

Escherichia coli mutants defective in the assimilation of iron from ferrienterochelin were isolated and characterized. One mutant was able to bind ferrienterochelin to its outer membrane but could not transport it into the cell. Complementation tests with lambda hybrid phage were employed to distinguish the defective gene, which we term fepB, from fepA, the structural gene for the outer membrane ferrienterochelin receptor protein. These same physiological and genetic tests were employed to tentatively classify several previously described fep mutants as carrying either fepA or fepB. The data demonstrate the existence of fepB and provide an explanation for previous difficulties in identifying fepB mutants.     

Cation gradient dependence of the steps in thrombin stimulation of human platelets

Thrombin causes a dose-dependent depolarization of the transmembrane potential of normal human platelets which can be continuously measured by the fluorescent probe, 3,3'-dipropylthiodicarbocyanine, whose distribution across the plasma membrane has been shown to be dependent upon the membrane potential. The dose-dependent depolarization of the platelet's negative membrane potential by thrombin is in large part due to a rapid uptake of sodium. Both the membrane potential change and the rapid sodium influx can be inhibited by a fast acting analog of amiloride, a sodium channel blocker, while valinomycin, a potassium ionophore, has no effect on the potential change nor on the sodium uptake, suggesting that the transmembrane potassium gradient is not important in the thrombin-induced depolarization. Neither the secretion of serotonin nor that of lysosomal enzymes nor the secondary release of the fluorescent probe which correlates with the lysosomal enzyme secretion occur if treatment with valinomycin precedes activation by thrombin. It is thus apparent that: 1) the change in the membrane potential induced by thrombin is directly dependent upon the transmembrane sodium gradient and is primarily due to a dose-dependent sodium uptake by the platelets; and 2) the thrombin-induced secretory processes are dependent upon maintenance of the transmembrane potassium gradients.     

Suppression of iron uptake deficiency in Escherichia coli K-12 by loss of two major outer membrane proteins.

A novel iron uptake system was observed in pseudorevertants of $\text{Escherichia}$,$\text{coli}$ strains defective in ferrienterochelin transport. The new system is unique in that it is an active transport system that does not utilize any known siderophore. Acquisition of the new uptake system occurs concomitantly with the loss of two major outer membrane proteins (b and c) believed to function as structural components of transmembrane pores.     

Distinct mechanisms of clathrin-independent endocytosis have unique sphingolipid requirements

Sphingolipids (SLs) play important roles in membrane structure and cell function. Here, we examine the SL requirements of various endocytic mechanisms using a mutant cell line and pharmacological inhibitors to disrupt SL biosynthesis. First, we demonstrated that in Chinese hamster ovary cells we could distinguish three distinct mechanisms of clathrin-independent endocytosis (caveolar, RhoA, and Cdc42 dependent) which differed in cargo, sensitivity to pharmacological agents, and dominant negative proteins. General depletion of SLs inhibited endocytosis by each clathrin-independent mechanism, whereas clathrin-dependent uptake was unaffected. Depletion of glycosphingolipids (GSLs; a subgroup of SLs) selectively blocked caveolar endocytosis and decreased caveolin-1 and caveolae at the plasma membrane. Caveolar endocytosis and PM caveolae could be restored in GSL-depleted cells by acute addition of exogenous GSLs. Disruption of RhoA- and Cdc42-regulated endocytosis by SL depletion was shown to be related to decreased targeting of these Rho proteins to the plasma membrane and could be partially restored by exogenous sphingomyelin but not GSLs. Both the in vivo membrane targeting and in vitro binding to artificial lipid vesicles of RhoA and Cdc42 were shown to be dependent upon sphingomyelin. These results provide the first evidence that SLs are differentially required for distinct mechanisms of clathrin-independent endocytosis.     

Cloning and physical characterization of chromosomal conjugative elements in streptococci.

A transport system for polyamines was studied with both intact cells and membrane vesicles of an Escherichia coli polyamine-deficient mutant. Polyamine uptake by intact cells and membrane vesicles was inhibited by various protonophores, and polyamines accumulated in membrane vesicles when D-lactate was added as an energy source or when a membrane potential was imposed artificially by the addition of valinomycin to K+-loaded vesicles. These results show that the uptake was dependent on proton motive force. Transported [14C]putrescine and [14C]spermidine were not excreted by intact cells upon the addition either of carbonyl cyanide m-chlorophenylhydrazone, A23187, and Ca2+ or of an excess amount of nonlabeled polyamine. However, they were excreted by membrane vesicles, although the degree of spermidine efflux was much lower than that of putrescine efflux. These results suggest that the apparent unidirectionality in intact cells has arisen from polyamine binding to nucleic acids, thus giving rise to a negligible free intracellular concentration of polyamines. Polyamine uptake, especially putrescine uptake, was inhibited strongly by monovalent cations. The Mg2+ ion inhibited spermidine and spermine uptake but not putrescine uptake.     

Transport of cyclic adenosine 3'',5''-monophosphate across Escherichia coli vesicle membranes.

The uptake and efflux of cyclic adenosine 3',5'-monophosphate (3',5'-cAMP) by Escherichia coli membrane vesicles were studied. Metabolic energy was not required for the uptake process and was found to actually decrease the amount of 3',5'-cAMP found in the vesicles. 3',5'-cAMP uptake exhibits saturation kinetics (Km = 10 mM, Vmax = 2.8 nmol/mg of protein per min) and was competitively inhibited by a number of 3',5'-cAMP analogs. The uptake of 3',5'-cAMP was found to be sharply affected by a membrane phase transition. The excretion of 3',5'-cAMP was studied by using everted membrane vesicles. Efflux in this system was dependent upon metabolic energy and was reduced or abolished by uncouplers. Different energy sources powered efflux at different rates, showing a relationship between the degree of membrane energization and rate of excretion of 3',5'-cAMP. The efflux process also displayed saturation kinetics (Km = 10.0 mM, Vmax = 0.98 nmol/mg of protein per min) and was competitively inhibited by the same 3',5'-cAMP analogs and to the same degree as was the uptake process. 3',5'-cAMP was found to be chemically unaltered by both the uptake and excretion processes. These data are interpreted as showing that the uptake and excretion of 3',5'-cAMP in E. coli membrane vesicles are carrier-mediated phenomena, possibly employing the same carrier system. Uptake is by facilitated diffusion whereas efflux is via an energy-dependent, active transport process. Evidence is presented showing that cells can regulate the number of 3',5'-cAMP transport carriers. The rate of 3',5'-cAMP excretion is possibly regulated by both the degree of membrane energization and the number of carriers present per cells.     

Characteristics of copper-induced streptomycin transport in Escherichia coli

Copper dependent uptake of streptomycin by resting E. coli cells was studied. It was shown that copper stimulates the aminoglycoside uptake only when bacteria possess endogenic energy sources. Additional accumulation of positive charged molecules of the antibiotic is accompanied by partial depolarisation of the membrane, its steady state distribution between cells and the medium corresponding to the resulted value of the membrane potential. On the basis of the data obtained it was suggested that under the influence of copper membrane permeability for streptomycin increases.     

Glucose transport in Acholeplasma laidlawii B: dependence on the fluidity and physical state of membrane lipids.

The uptake of D-glucose by Acholeplasma laidlawii B occurs via a mediated transport process, as shown by the following observations: (i) glucose permeates A. laidlawii B cells at a rate at least 100 times greater than would be expected if its entry occurred only by simple passive diffusion; (ii) the apparent activation energy for glucose uptake in A. laidlawii is significantly lower than that expected and observed for the passive permeation of this sugar; (iii) glucose uptake appears to be a saturable process; (iv) glucose uptake can be completely inhibited by low concentrations of phloretin and phlorizin; and (v) glucose uptake is markedly inhibited at temperatures above 45 C, whereas the passive entry of erythritol continues to increase logarithmically until at least 60 C. The metabolism of D-glucose by this organism is rapid and, at low glucose concentrations, the intracellular radioactivity derived from D-[14-C]glucose is at any given time a reflection of the net effect of glucose transport, glucose metabolism, and loss from the cell of radioactive metabolic products. Care must thus be taken when attempting to determine the rate of glucose transport by measuring the accumulation by the cells of the total radioactivity derived from D-[14-C]glucose. The rate of uptake of D-glucose by A. laidlawii B cells is markedly dependent on the fatty acid composition and cholesterol content of the plasma membrane and exhibits a direct dependence on the fluidity of the membrane lipids as measured by their reversible, thermotropic gel to liquie-crystalline phase transition temperatures. In contrast to the transport rates, the apparent activation energy for glucose uptake above the phase transition temperature is not dependent on membrane lipid composition. At the temperature range within the membrane lipid phase transition region, the apparent activation energy of glucose uptake is different from the activation energy observed at temperatures above the phase transition. This may reflect the superimposed operation within the phase transition region of more than one temperature-dependent process.     

Iron uptake in pseudorevertants of Escherichia coli K-12 mutants with multiple defects in the enterochelin system

Iron uptake in pseudorevertants of Escherichia coli K-12 strains which lack the ability to synthesize enterochelin, 2,3-dihydroxybenzoate, and the ferrienterochelin receptor protein was characterized. In four independent pseudorevertants, the suppressor mutations which permitted growth in iron-poor environments appeared to be located in ompB, the regulatory locus for the porin proteins. Unlike wild-type cells, the pseudorevertants were unable to utilize ferrienterochelin and could acquire iron from citrate without induction by prior growth in citrate. The energy requirements of the pseudorevertant system appeared to be identical to those of the enterochelin system. Evidence that loss of the porin proteins results in the secretion by the pseudorevertants of a molecule with siderophore activity is presented; this siderophore is able to remove iron from the non-biological iron chelators nitrilotriacetic acid and , -dipyridyl but not from the siderophores ferrichrome and enterochelin.     

Defective growth functions in mutants of Escherichia coli K12 lacking a major outer membrane protein.

Various properties of mutants of Escherichia coli K12 lacking specific outer membrane proteins have been studied. ompA mutants are shown to grow less well than their parent strains under a variety of growth conditions, and after completion of growth to enter a decline phase in which viability is lost and the cells become heavily piliated and clump. They are defective in the uptake of amino acids, whereas the uptakes of the larger transport substrates ferrienterochelin and cyanocobalamin (vitamin B12) are normal. These ompA mutants also grow poorly at 42 °C. The implications of these results are discussed in terms of the function of the ompA. gene product. No growth or uptake defects were observed for ompB or tsx mutants.     

Interaction of renin inhibitors with the intestinal uptake system for oligopeptides and beta-lactam antibiotics

The interaction of two renin inhibitors, S 86,2033 and S 86,3390, with the uptake system for beta-lactam antibiotics and small peptides in the brush border membrane of enterocytes from rabbit small intestine was investigated using brush border membrane vesicles. Both renin inhibitors inhibited the uptake of the orally active cephalosporin cephalexin into brush border membrane vesicles from rabbit small intestine in a concentration-dependent manner. 1.1 mM of S 86,3390 and 2.5 mM of S 86,2033 led to a half-maximal inhibition of the H(+)-dependent uptake of cephalexin. Both renin inhibitors were stable against peptidases of the brush border membrane. The uptake of cephalexin into brush border membrane vesicles (1 min of incubation) was competitively inhibited by S 86,2033 and S 86,3390 suggesting a direct interaction of these compounds with the intestinal peptide uptake system. The renin inhibitors are transported across the brush border membrane into the intravesicular space as was shown by equilibrium uptake studies dependent upon the medium osmolarity. The uptake of S 86,3390 was stimulated by an inwardly directed H(+)-gradient and occurred with a transient accumulation against a concentration gradient (overshoot phenomenon). The renin inhibitors S 86,2033 and 86,3390 also caused a concentration-dependent inhibition in the extent of photoaffinity labeling of the putative peptide transport protein of apparent Mr 127,000 in the brush border membrane of small intestinal enterocytes. In conclusion, these studies show that renin inhibitors specifically interact with the intestinal uptake system shared by small peptides and beta-lactam antibiotics.     

Characterization of the active transport of chlorotetracycline in Staphylococcus aureus by a florescence technique

The antibiotic chlorotetracycline (CTC) is used as a fluorescent chelate probe to investigate its active transport in respiring Staphylococcus aureus cells. CTC chelation to magnesium or calcium leads to fluorescence enhancement. This enhancement is further increased when the polarity of its environment is decreased, as occurs when the complex moves from an aqueous environment into a membrane. Upon addition of CTC to a dispersion of S. aureus cells, a time dependent fluorescence enhancement is detected which is a monitor of the transport of the CTC-divalent cation complex into the membrane. This uptake has been shown to be energy dependent and exhibits saturation kinetics with an apparent K_m of 107 ± 20 μM by the same technique. The initial rates of antibiotic uptake are shown to have a pH optimum between 5.5 and 6.5. The effects of exogenously added EDTA and paramagnetic Mn²⁺ indicate that the CTC-divalent cation complex is transported to the inside of the membrane. Exogenously added magnesium inhibits the accumulation process. This implies that the membrane CTC binding site involves a divalent cation sequestered away from the surface of the membrane, and only free CTC is bound to that site. The uptake of CTC is also temperature dependent with a maximal rate at 40°. Arrhenius plots of the initial fluorescence enhancement rates are found to be biphasic with a 27° transition temperature. The break in the plots presumably reflects an order-disorder transition involving the fatty acids of the cell membrane. Thus, transport of the CTC involves movement through the fatty acid region of the membrane. This movement is facilitated by the more fluid state of the membrane above the transition temperature.     

The functional coupling between Ca2+-ATPase and creatine phosphokinase in heart muscle sarcoplasmic reticulum]

The functional role of creatine phosphokinase (CPK) in the process of energy supply for the Ca2+-ATPase reaction and ion transport across the membrane of heart sarcoplasmic reticulum (SR) has been studied. It has been shown that isolated and purified preparations of heart SR contain significant activity of CPK. The localization of CPK on the membrane of SR has been revealed also by an electron microscopic histochemical method. Under conditions of the Ca+-ATPase reaction in the presence of creatine phosphate the release of creatine into the reaction medium is observed, the rate of the latter process being dependent upon the MgATP concentration in accordance with the kinetic parameters of the Ca2+-ATPase reaction. CPK localized on the SR membrane is able to maintain higher rate of calcium uptake by SR vesicles, as compared to that with added ATP-regenerating system. The results obtained demonstrate the close functional coupling between CPK and Ca2+-ATPase in the membrane of SR.     

Genetic alteration in the (Na+ + K+) ATPase transport system expressed in human lymphoblasts and their isolated plasma membranes.

A series of ouabain-resistant human lymphoblastoid lines were shown to be genetically altered in the (Na+ + K+) ATPase transport system. The sensitivity to ouabain of Rb+ uptake in intact cells and (Na+ + K+) dependent ATP hydrolysis in purified plasma membrane vesicles was compared with measurement of ouabain binding to intact cells. Preliminary evidence for at least two categories of ouabain resistance was obtained.     

Proton motive force generation by citrolactic fermentation in Leuconostoc mesenteroides.

In Leuconostoc mesenteroides subsp. mesenteroides 19D, citrate is transported by a secondary citrate carrier (CitP). Previous studies of the kinetics and mechanism of CitP performed in membrane vesicles of L. mesenteroides showed that CitP catalyzes divalent citrate HCit2-/H+ symport, indicative of metabolic energy generation by citrate metabolism via a secondary mechanism (C. Marty-Teysset, J. S. Lolkema, P. Schmitt, C. Divies, and W. N. Konings, J. Biol. Chem. 270:25370-25376, 1995). This study also revealed an efficient exchange of citrate and D-lactate, a product of citrate/carbohydrate cometabolism, suggesting that under physiological conditions, CitP may function as a precursor/product exchanger rather than a symporter. In this paper, the energetic consequences of citrate metabolism were investigated in resting cells of L. mesenteroides. The generation of metabolic energy in the form of a pH gradient (delta pH) and a membrane potential (delta psi) by citrate metabolism was found to be largely dependent on cometabolism with glucose. Furthermore, in the presence of glucose, the rates of citrate utilization and of pyruvate and lactate production were strongly increased, indicating an enhancement of citrate metabolism by glucose metabolism. The rate of citrate metabolism under these conditions was slowed down by the presence of a membrane potential across the cytoplasmic membrane. The production of D-lactate inside the cell during cometabolism was shown to be responsible for the enhancement of the electrogenic uptake of citrate. Cells loaded with D-lactate generated a delta psi upon dilution in buffer containing citrate, and cells incubated with citrate built up a pH gradient upon addition of D-lactate. The results are consistent with an electrogenic citrate/D-lactate exchange generating in vivo metabolic energy in the form of a proton electrochemical gradient across the membrane. The generation of metabolic energy from citrate metabolism in L. mesenteroides may contribute significantly to the growth advantage observed during cometabolism of citrate and glucose.     

Mouse and human resistins impair glucose transport in primary mouse cardiomyocytes, and oligomerization is required for this biological action

The adipocytokine resistin impairs glucose tolerance and insulin sensitivity in rodents. Here, we examined the effect of resistin on glucose uptake in isolated adult mouse cardiomyocytes. Murine resistin reduced insulin-stimulated glucose uptake, establishing the heart as a resistin target tissue. Notably, human resistin also impaired insulin action in mouse cardiomyocytes, providing the first evidence that human and mouse resistin homologs have similar functions. Resistin is a cysteine-rich molecule that circulates as a multimer of a dimeric form dependent upon a single intermolecular disulfide bond, which, in the mouse, involves Cys26; mutation of this residue to alanine (C26A) produces a monomeric molecule that appears to be bioactive in the liver. Remarkably, unlike native resistin, monomeric C26A resistin had no effect on basal or insulin-stimulated glucose uptake in mouse cardiomyocytes. Resistin impairs glucose uptake in cardiomyocytes by mechanisms that involve altered vesicle trafficking. Thus, in cardiomyocytes, both mouse and human resistins directly impair glucose transport; and in contrast to effects on the liver, these actions of resistin require oligomerization.     

Plasma membrane-mediated leakage of liposomes induced by interaction with murine thymocytic leukemia cells

The interaction of liposomes with BW 5147 murine thymocytic leukemia cells was studied using fluorescent probes (entrapped carboxyfluorescein and fluorescent phosphatidylethanolamine) in conjunction with a Ficoll-Paque discontinous gradient system for rapid separation of liposomes from cells. Reversible liposomal binding to discrete sites on the BW cell surface was found to represent the major form of interaction; uptake of intact liposomal contents by a process such as liposome-BW cell membrane fusion was found to apparently represent a minor pathway of interaction (2%). Liposomal lysis was found to be associated with the process of liposomal binding (perhaps as a result of the binding itself). Lysis was followed by release of the entrapped carboxyfluorescein into the media and its subsequent uptake by the cells. This lysis was shown to be dependent upon discrete membrane-associated sites that have some of the properties of proteins. The results of these studies suggest that liposomal binding to the cells, subsequent lysis of the liposomes and cellular uptake of their contents should be seriously considered in all studies of liposome-cell interactions as an alternate mode of interaction to the four modes (fusion, endocytosis, adsorption and lipid exchange) previously emphasized in the literature.     

The localization of glycerol-3-phosphate dehydrogenase inEscherichia coli

Summary Starved cells ofEscherichia coli are dependent on an exogenous source of energy. It was of interest to ask whether compounds that are commonly used to supply energy must themselves be transported or whether they can be utilized on the outer portion of the cytoplasmic membrane. The utilization of glycerol-3-phosphate an energy source is totally dependent on the membrane-bound glycerol-3-phosphate dehydrogenase. In the present report glycerol-3-phosphate was used as the energy source for uptake of amino acids. A mutant was constructed which is unable to transport this ester and the starved mutant could not drive the uptake of glutamine with glycerol-3-phosphate. It is concluded that the enzyme is located on the internal surface of the membrane in intactE. coli cells. Further evidence was obtained by showing that no glycerol-3-phosphate dehydrogenase activity could be measured in either intact cells or spheroplasts using ferricyanide as electron acceptor, due to its impermeability. The activity could be measured after destruction of the membrane permeability barrier by toluenization. With membrane vesicles prepared according to Kaback's procedure nearly half of the dehydrogenase activity was accessible to ferricyanide as well as to impermeable competitive inhibitors of the enzyme. Partial inversion during preparation of vesicles is the most probable explanation for the results.A protion of this work was presented at the Miami Winter Symposia on the Molecular Basis of Biological Transprot, 1972.     

Chitosan permeabilizes the plasma membrane and kills cells of Neurospora crassa in an energy dependent manner

Chitosan has been reported to inhibit spore germination and mycelial growth in plant pathogens, but its mode of antifungal action is poorly understood. Following chitosan treatment, we characterized plasma membrane permeabilization, and cell death and lysis in the experimental model, Neurospora crassa. Rhodamine-labeled chitosan was used to show that chitosan is internalized by fungal cells. Cell viability stains and the calcium reporter, aequorin, were used to monitor plasma membrane permeabilization and cell death. Chitosan permeabilization of the fungal plasma membrane and its uptake into fungal cells was found to be energy dependent but not to involve endocytosis. Different cell types (conidia, germ tubes and vegetative hyphae) exhibited differential sensitivity to chitosan with ungerminated conidia being the most sensitive.