Role of tol genes in cloacin DF13 susceptibility of Escherichia coli K-12 strains expressing the cloacin DF13-aerobactin receptor IutA.

IutA is the outer membrane protein receptor for ferric aerobactin and the bacteriocin cloacin DF13. Although the same receptor is shared, ferric aerobactin transport across the outer membrane in Escherichia coli is TonB dependent, whereas cloacin DF13 transport is not. We have recently observed that tolQ is required for cloacin DF13 susceptibility (J.A. Thomas and M.A. Valvano, FEMS Microbiol. Lett. 91:107-112, 1992). In this study, we demonstrate that the genes tolQ, tolR, and tolA, but not tolB, tolC, and ompF, are required for the internalization of cloacin DF13 and they are not involved in the transport of ferric aerobactin.     

Regulation of the ColV plasmid-determined iron (III)-aerobactin transport system in Escherichia coli.

Regulation by iron was studied in Escherichia coli strains whose iron supply was entirely dependent on the iron(III)-aerobactin system determined by the ColV plasmid. By the insertion of phage Mu (Ap lac) into the ColV plasmid, mutants were selected that could no longer grow in iron-limited media. The inserted Mu (Ap lac) strongly reduced the amount of aerobactin and he cloacin receptor protein formed by the cells. Their production was no longer subject to regulation by iron. The Mu (Ap lac) insertion apparently led to a polar effect on the expression of the presumably closely linked genes that control the synthesis of aerobactin and the cloacin receptor protein. The expression of the beta-galactosidase gene on the inserted phage genome came under the control of the iron state of the cells. Under iron-limited growth conditions, the amount of beta-galactosidase synthesized was, depending on the strain studied, 6 to 30 times higher than under iron-sufficient growth conditions. In fur mutants with an impaired iron regulation of ll iron supply systems studied so far, high amounts of beta-galactosidase were synthesized independent of the cells' iron supply. The results demonstrate an iron-controlled promoter on the ColV plasmid which is subject to regulation by the chromosomal fur gene.     

tolQ is required for cloacin DF13 susceptibility in Escherichia coli expressing the aerobactin/cloacin DF13 receptor IutA

We investigated the role of the tolQ gene in the import of cloacin DF13 across the outer membrane of Escherichia coli strains expressing the IutA receptor. The IutA outer-membrane protein is the receptor for the siderophore ferric aerobactin and also binds cloacin DF13, a bacteriocin produced by strains of Enterobacter aerogenes. In this report we present evidence that tolQ is required for the internalization of cloacin DF13 upon binding to IutA but it is not involved in the transport of ferric aerobactin.     

Chromosomal genes for ColV plasmid-determined iron(III)-aerobactin transport in Escherichia coli.

Four chromosomal genes, tonA (fhuA), fhuB, tonB, and exbB, were required for the transport of iron(III)-aerobactin specified by the plasmids ColV-K311, ColV-K229, ColV-K328, and ColV-K30. These genes also determine the transport system in Escherichia coli for the iron ionophore ferrichrome. Aerobactin and ferrichrome are both iron ligands of the hydroxamate type, but they are of different structure. The ColV plasmids determine an outer membrane protein that serves as a receptor for cloacin. Cloacin-resistant mutants were devoid of iron(III)-aerobactin transport but were unimpaired in ferrichrome transport. We conclude that for iron(III)-aerobactin transport two outer membrane proteins, the TonA and the cloacin receptor protein, have to interact functionally or structurally or both.     

Regulation of ugp, the sn-glycerol-3-phosphate transport system of Escherichia coli K-12 that is part of the pho regulon.

The expression of the ugp-dependent sn-glycerol-3-phosphate transport system that is part of the pho regulon was studied in mutants of Escherichia coli K-12 containing regulatory mutations of the pho regulon. The phoR and phoST gene products exerted a negative control on the expression of ugp. Induction of the system was positively controlled by the phoB, phoM, and phoR gene products. Using a ugp-lacZ operon fusion, we showed that the ugp and phoA genes were coordinately derepressed and repressed.     

Role of Na+ and Li+ in thiomethylgalactoside transport by the melibiose transport system of Escherichia coli.

Thiomethyl-beta-galactoside (TMG) accumulation via the melibiose transport system was studied in lactose transport-negative strains of Escherichia coli. TMG uptake by either intact cells or membrane vesicles was markedly stimulated by Na+ or Li+ between pH 5.5 and 8. The Km for uptake of TMG was approximately 0.2 mM at an external Na+ concentration of 5 mM (pH 7). The alpha-galactosides, melibiose, methyl-alpha-galactoside, and o-nitrophenyl-alpha-galactoside had a high affinity for this system whereas lactose, maltose and glucose had none. Evidence is presented for Li+-TMG or Na+-TMG cotransport.     

Specificity of the Escherichia coli proline transport system.

The presence of both the carbonyl portion of the carboxyl group at position 2 of the pyrrolidine ring and a secondary amine was essential for uptake of a compound by the proline permease of Escherichia coli. The permease possessed a high affinity for azetidine-2-carboxylic acid and for compounds with ring structures smaller than the pyrrolidine ring. Pipecolic acid, the higher homologue of proline, and its derivatives were not transported. Cis- and trans-3,4-methano-prolines, also six-membered ring structures, behaved anomolously in that they possessed a high affinity for the permease. The difference between the methano-prolines and other six-membered ring structures probably resides in the fact that the former exist in the "boat" configuration whereas the latter possess the "chair" configuration. In general, substituted prolines in the cis configuration displayed a higher affinity for the permease than did corresponding trans isomers, though the affinity for substituted prolines was influenced by the position, size, and polar or nonpolar nature of the substituent group. At O C many analogues with affinity for proline permease exchanged with intracellular proline, but some analogues, notably trans-3-methyl- and trans-4-methyl-L-prolines, though possessing high affinity for the permease, showed an almost complete inability to exchange with intracellular proline.     

PstB protein of the phosphate-specific transport system of Escherichia coli is an ATPase.

The PstB protein of the phosphate-specific transport (Pst) system of Escherichia coli bound and hydrolyzed ATP, producing ADP. Urea-treated denatured PstB did not bind ATP. The N-terminal amino acid sequence of the immune serum-precipitable PstB protein was determined, and it corresponded to that deduced from the DNA sequence.     

A K+ transport ATPase in Escherichia coli.

A K+ -stimulated ATPase in membranes of Escherichia coli has been identified as an activity of the Kdp system, and ATP-driven K+ transport system. Three characteristics support association of the ATPase with the Kdp system: (i) ATPase and Kdp transport are both repressed by growth in media containing high concentrations of K+; (ii) the ATPase and Kdp system accept only K+ as substrate, neither requires Na+ nor accepts Rb+ as a substrate; (iii) the affinity of the ATPase and that of th Kdp system for K+ is similar and is altered by mutations in the structural genes of the Kdp system. Discovery of an ATPase associated with a bacterial transport system suggests functional similarities with the ATP-driven transport systems of animal cells.     

Specialized peptide transport system in Escherichia coli.

Trileucine is utilized as a source of leucine for growth of strains of Escherichia coli K-12 that are deficient in the oligopeptide transport system (Opp). Trithreonine is toxic to E. coli K-12. Opp- mutants of E. coli K-12 retain complete sensitivity to this tripeptide. Moreover, E. coli W, which is resistant to trithreonine, can utlize this tripeptide as a threonine source and this capability is fully maintained in E. coli W (Opp-). A spontaneous trithreonine-resistant mutant of E. coli K-12 (Opp-) has been isolated that has an impaired growth response to trileucine and is resistant to trithreonine. Trileucine competes with the uptake of trithreonine as measured by its ability to relieve trithreonine toxicity in E. coli K-12. It is concluded that trileucine as well as trithreonine are transported into E. coli K-12 or W by a common uptake system that is distinct from the Opp system. Trimethionine can act as a competitor of trileucine or trithreonine-supported growth and as an antagonist of trithreonine toxicity in Opp- mutants. It is concluded that trimethionine is recognized by the trileucine-trithreonine transport system. Trithreonine, trimethionine, and trileucine are also transported by the Opp system, as they all relieve triornithine toxicity towards E. coli W and compete with tetralysine utilization as lysine source for growth of a lysine auxotroph of this strain.     

A second transport system for sn-glycerol-3-phosphate in Escherichia coli.

Strains containing phage Mucts inserted into glpT were isolated as fosfomycin-resistant clones. These mutants did not transport sn-glycerol-3-phosphate, and they lacked GLPT, a protein previously shown to be a product of the glpT operon. By plating these mutants on sn-glycerol-3-phosphate at 43 degrees C, we isolated revertants that regained the capacity to grow on G3P. Most of these revertants did not map in glpT and did not regain GLPT. These revertants exhibited a highly efficient uptake system for sn-glycerol-3-phosphate within an apparent Km of 5 micron. In addition, three new proteins (GP 1, 2, and 3) appeared in the periplasm of these revertants. None of these proteins were antigentically related to GLPT. However, like GLPT, GP1 exhibits abnormal behavior on sodium dodecyl sulfate-polyacrylamide gels. GP 2 is an efficient binding protein. The new uptake system showed different characteristics than the system that is coded for by the glpT operon. It was inhibited neither by phosphate nor fosfomycin. So far, none of the systems that transport organic acids in Escherichia coli could be implicated in the new sn-glycerol-3-phosphate uptake activity. The mutation ugp+, which was responsible for the appearance of the new transport system and the appearance of GP 1, 2, and 3 in the periplasm was cotransducible with araD by phage P1 transduction and was recessive in merodiploids.     

Periplasmic protein related to the sn-glycerol-3-phosphate transport system of Escherichia coli.

Two-dimensional gel electrophoresis of shock fluids of Escherichia coli K-12 revealed the presence of a periplasmic protein related to sn-glycerol-3-phosphate transport (GLPT) that is under the regulation of glpR, the regulatory gene of the glp regulon. Mutants selected for their resistance to phosphonomycin and found to be defective in sn-glycerol-3-phosphate transport either did not produce GLPT or produced it in reduced amounts. Other mutations exhibited no apparent effect of GLPT. Transductions of glpT+ nalA phage P1 into these mutants and selection for growth on sn-glycerol-3-phosphate revealed a 50% cotransduction frequency to nalA. Reversion of mutants taht did not produce GLPT to growth on sn-glycerol-3-phosphate resulted in strains that produce GLPT. This suggests a close relationship of GLPT to the glpT gene and to sn-glycerol-3-phosphate transport. Attempts to demonstrate binding activity of GLPT in crude shock fluid towards sn-glycerol-3-phosphate have failed so far. However, all shock fluids, independent of their GLPT content, exhibited an enzymatic activity that hydrolyzes under the conditions of the binding assay, 30 to 60% of the sn-glycerol-3-phosphate to glycerol and inorganic orthophosphate.     

Genetics of the glutamine transport system in Escherichia coli.

The active transport of glutamine by Escherichia coli occurs via a single osmotic shock-sensitive transport system which is known to be dependent upon a periplasmic binding protein specific for glutamine. We obtained a mutant that had elevated levels of glutamine transport and overproduced the glutamine binding protein. From this strain many point mutants and deletion-carrying strains defective in glutamine transport were isolated by a variety of techniques. The genetic locus coding for the glutamine transport system, glnP, and the regulatory mutation which causes overproduction of the transport system were both shown to map at 17.7 min on the E. coli chromosome, and it was demonstrated that the glnP locus contains the structural gene for the glutamine binding protein. Evidence was also obtained that the glutamine transport system, by an unknown mechanism, plays a direct role in the catabolism of glutamate and, hence, of glutamine and proline as well.     

Co-transport of Na+ and methul-beta-D-thiogalactopyranoside mediated by the melibiose transport system of Escherichia coli.

Na⁺-dependent transport of methyl-β-D-thiogalactopyranoside (TMG) mediated by the melibiose transport system was investigated in $\text{Escherichia coli}$ mutants lacking the lactose transport system. When an inwardly-directed electro-chemical potential difference of Na⁺ was imposed across the membrane of energy depleted cells, transient uptake of TMG was observed. Addition of TMG to cell suspensions under anaerobic conditions caused a transient acidification of the medium. This acidification was observed only in the presence of Na⁺ or Li⁺. These results support the idea that TMG is taken up by a mechanism of Na⁺-TMG co-transport via the melibiose transport system in $\text{Escherichia coli}$.     

Lithium ion-sugar cotransport via the melibiose transport system in Escherichia coli. Measurement of Li+ transport and specificity

A lithium ion-selective electrode was constructed using N,N'-diheptyl-N,N'-5,5-tetramethyl-3,7-dioxanonandiamid as a Li+ ionophore. Lithium ion-sugar cotransport via the melibiose transport system was measured with this electrode. Influx of methyl-beta-D-thiogalactoside, methyl-alpha-D-galactoside, methyl-beta-D-galactoside, and D-galactose elicited uptake of Li+. This Li+ uptake was not observed when the melibiose carrier was not present in the cells or the carrier was inactivated. Melibiose caused a small amount of Li+ uptake, indicating that Li+-melibiose cotransport proceeds inefficiently. Raffinose, another substrate, did not cause detectable Li+ transport. In mutant cells which showed altered cation coupling (Niiya, S., Yamasaki, K., Wilson, T. H., and Tsuchiya, T. (1982) J. Biol. Chem. 257, 8902-8906), Li+-melibiose cotransport was clearly demonstrated. Alteration in substrate specificity was also shown in the mutants.     

Specific cesium transport via the Escherichia coli Kup (TrkD) K+ uptake system.

Escherichia coli cells which contain a functional Kup (formerly TrkD) system took up Cs+ with a moderate rate and affinity. Kup is a separate K+ uptake system with relatively little discrimination in the transport of the cations K+, Rb+, and Cs+. Regardless of the presence or absence of Kup, K+-replete cells took up Cs+ primarily by a very low affinity mode, proportional to the ratio of the Cs+ and K+ concentrations in the medium.     

Genetics of the iron dicitrate transport system of Escherichia coli.

Escherichia coli B and K-12 express a citrate-dependent iron(III) transport system for which three structural genes and their arrangement and products have been determined. The fecA gene of E. coli B consists of 2,322 nucleotides and encodes a polypeptide containing a signal sequence of 33 amino acids. The cleavage site was determined by amino acid sequence analysis of the unprocessed protein and the mature protein. For the processed form a length of 741 amino acids was calculated. The mature FecA protein in the outer membrane contains at the N terminus the "TonB box," a pentapeptide, which has hitherto been found in all receptors and colicins which functionally require the TonB protein. In addition, the dyad repeat sequence GAAAATAATTCTTATTTCG is proposed to serve as the binding site of the Fur iron repressor protein. The fecB gene was mapped downstream of fecA and encodes a protein with an apparent molecular weight of 30,000. It was synthesized as a precursor, and the mature form was found in the periplasm. The fecD gene follows fecB and was related to a membrane-bound protein with an apparent molecular weight of 28,000. In Mu d1 insertion mutants upstream of fecA, the fec genes were not inducible by iron limitation and citrate, indicating a regulatory region, termed fecI, which controls fec gene expression.     

Cation-sugar cotransport in the melibiose transport system of Escherichia coli.

The entry of Na+ or H+ into cells of Escherichia coli via the melibiose transport system was stimulated by the addition of certain galactosides. The principal cell used in these studies (W3133) was a lactose transport negative strain of E. coli possessing an inducible melibiose transport system. Such cells were grown in the presence of melibiose, washed, and incubated in the presence of 25 microM Na+. The addition of thiomethylgalactoside (TMG) resulted in a fall in Na+ concentration in the incubation medium. No TMG-stimulated Na+ movement was observed in uninduced cells. In an alpha-galactosidase negative derivative of W3133 (RA11) a sugar-stimulated Na+ uptake was observed in melibiose-induced cells on the addition of melibiose, thiodigalactoside, methyl-alpha-galactoside, methyl-beta-galactoside, and galactose, but not lactose. It was inferred from these studies that the substrates of the melibiose system enter the cell on the melibiose carrier associated with the simultaneous entry of Na+ when this cation is present in the incubation medium. Extracellular pH was measured in unbuffered suspensions of induced cells in order to study proton movement across the membrane of cells exposed to different galactosides. In the absence of external Na+ or Li+ the addition of melibiose or methyl-alpha-galactoside resulted in marked alkalinization of the external medium (consistent with H+-sugar cotransport). On the other hand TMG, thiodigalactoside, and methyl-beta-galactoside gave no proton movement under these conditions. When Na+ was present, the addition of TMG or melibiose resulted in acidification of the medium. This observation is consistent with the view that the entry of Na+ with TMG or melibiose carries into the cell a positive charge (Na+) which provides the driving force for the diffusion of protons out of the cell. It is concluded that the melibiose carrier recognition of cations differs with different substrates.