Low-affinity potassium uptake system in Bacillus acidocaldarius.

Cells of Bacillus acidocaldarius that were grown with 2.7 mM K+ expressed a low-affinity K+ uptake system. The following observations indicate that its properties closely resemble those of the Escherichia coli Trk and Streptococcus faecalis KtrI systems: (i) the B. acidocaldarius system took up K+ with a Km of 1 mM; (ii) it accepted Rb+ (Km of 6 mM; same Vmax as for K+); (iii) it was still active in the presence of low concentrations of sodium; (iv) the observed accumulation ratio of K+ maintained by metabolizing cells was consistent with K+ being taken up via a K+-H+ symporter; and (v) K+ uptake did not occur in cells in which the ATP level was low. Under the latter conditions, the cells still took up methylammonium ions via a system that was derepressed by growth with low levels of ammonium ions, indicating that in the acidophile ammonium (methylammonium) uptake requires a high transmembrane proton motive force rather than ATP.     

Rapid inactivation of the Escherichia coli Kdp K+ uptake system by high potassium concentrations

The Kdp K+ uptake system of Escherichia coli is induced by limitation for K+ and/or high osmolarity. In the present study, the regulation of the activity of the Kdp system has been investigated in E. coli mutants possessing only the Kdp system as the mechanism of K+ accumulation. Cells grown in the presence of low K+ (0.1-1 mM) exhibit normal growth. However, growth inhibition results from exposure of cells to moderate levels of external K+ (> 5 mM). Measurement of the cytoplasmic pH, of K+ pools and of transport via the Kdp system demonstrates that the Kdp system is rapidly and irreversibly inhibited by moderate external K+. Concentrations of K+ greater than 2 mM are sufficient to cause inhibition of Kdp. At pH 6, this results in rapid lowering of the capacity for pH homeostasis, but at pH 7 the intracellular pH is unaffected. Parallel analysis of the expression of the Kdp system in a Kdp+/kdpFABC-lacZ strain shows that levels of K+ that are sufficient to inhibit Kdp activity also repress expression. As a result, growth inhibition of strains solely possessing Kdp arises jointly from inhibition of Kdp activity and repression of Kdp gene expression. These data identify an important aspect of the regulation of potassium transport via the Kdp system and also provide support for a model of regulation of Kdp expression via at least two mechanisms: sensing of both turgor and external K+ concentration.     

Futile cycling of ammonium ions via the high affinity potassium uptake system (Kdp) of Escherichia coli

Escherichia coli Frag1 was grown under various nutrient limitations in chemostat culture at a fixed temperature, dilution rate and pH both in the presence and the absence of a high concentration of ammonium ions by using either ammonium chloride or dl-alanine as the sole nitrogen source. The presence of high concentrations of ammonium ions in the extracellular fluids of potassium-limited cultures of E. coli Frag1 caused an increase of the specific rate of oxygen consumption of these cultures. In contrast, under phosphate-, sulphate- or magnesium-limited growth conditions no such increase could be observed. The presence of high concentrations of ammonium ions in potassium-limited cultures of E. coli Frag5, a mutant strain of E. coli Frag1 which lacks the high affinity potassium uptake system (Kdp), did not increase the specific rate of oxygen consumption.These results indicate that ammonium ions, very similar to potassium ions both in charge and size, are transported via the K dp leading to a futile cycle of ammonium ions and ammonia molecules (plus protons) across the cytoplasmic membrane. Both the uptake of ammonium ions and the extrusion of protons would increase the energy requirement of the cells and therefore increase their specific rate of oxygen consumption. The involvement of a (methyl)ammonium transport system in this futile cycle could be excluded.     

The activity of the high-affinity K+ uptake system Kdp sensitizes cells of Escherichia coli to methylglyoxal.

Expression of the Kdp system sensitizes cells to methylglyoxal (MG) whether this electrophile is added externally or is synthesized endogenously. The basis of this enhanced sensitivity is the maintenance of a higher cytoplasmic pH (pHi) in cells expressing Kdp. In such cells, MG elicits rapid cytoplasmic acidification via KefB and KefC, but the steady-state pHi attained is still too high to confer protection Lowering pHi further by incubation with acetate increases the sensitivity of cells to MG.     

High-affinity calcium-binding proteins in Escherichia coli

Crude extracts of Escherichia coli contain at least three heat stable proteins of Mr, 33,000, 47,000, and 60,000, which bind 45Ca2+ in buffers containing micromolar calcium and physiological salt concentrations. Fractions containing these proteins neither activated the calmodulin-dependent enzyme, NAD kinase, nor inhibited the activity of this enzyme in the presence of brain calmodulin. Radioimmunoassay of crude extracts for calmodulin indicated the presence of a calmodulin-like antigen. Crude extracts also contain proteins that interact with 2-trifluoromethyl-10H-(3'-aminopropyl)phenothiazine-Sepharose in a calcium-dependent manner, but proteins eluted from this resin did not bind calcium with high affinity.     

Mutations affecting the citrate-dependent iron uptake system in Escherichia coli.

Isolation of six strains of Escherichia coli K-12 carrying mutations affecting the citrate-dependent iron uptake system is described. Genetic analysis of these mutants showed that the mutation affecting the citrate system are cluster together at about min 6 on the E. coli chromosome.     

L-asparagine uptake in Escherichia coli.

The uptake of L-asparagine by Escherichia coli K-12 is characterized by two kinetic components with apparent Km values of 3.5 muM and 80 muM. The 3.5 muM Km system displays a maximum velocity of 1.1 nmol/min per mg of protein, which is a low value when compared with derepressed levels of other amino acid transport systems but is relatively specific for L-asparagine. Compounds providing effective competition for L-asparagine uptake were 4-carbon analogues of the L-isomer with alterations at the beta-amide position, i.e., 5-diazo-4-oxo-L-norvaline (Ki = 4.6 muM), beta-hydroxyamyl-L-aspartic acid (Ki = 10 muM), and L-aspartic acid (Ki = 50 muM). Asparagine uptake is energy dependent and is inhibited by a number of metabolic inhibitors. In a derived strain of E. coli deficient in cytoplasmic asparaginase activity asparagine can be accumulated several-fold above the apparent biosynthetic pool of the amino acid and 100-fold above the external medium. The high affinity system is repressed by culture of cells with L-asparagine supplements in excess of 1 mM and is suggested to be necessary for growth of E. coli asparagine auxotrophs with lower supplement concentrations.     

Potassium transport in Escherichia coli: sodium is not a substrate of the potassium uptake system TrkA

Abstract In Escherichia coli cells depleted of both sodium and potassium, the potassium uptake system TrkA mediated a slow, electrogenic uptake of potassium. Electroneutrality was maintained by the extrusion of protons. Internal, but not external sodium stimulated potassium uptake. This extra uptake was coupled to a stoichiometric extrusion of sodium. Triethanolamine also stimulated potassium uptake, presumably by increasing the cytoplasmic buffer capacity. These results are taken to mean that sodium is not a substrate of the TrkA system, but stimulates TrkA activity by facilitating the reentry of protons through the sodium-proton antiporter, and thereby preventing a prohibitive increase in cytoplasmic pH.     

嗜酸热硫化叶菌麦芽寡粉基海藻糖合酶基因的克隆和表达

The gene of MTSase (maltooligosyltrehalose synthase) from Sulfolobus acidocaldarius ATCC49426 was amplified by PCR. The primers were designed according to the published sequence of homologous gene from Sulfolobus acidocaldarius ATCC33909. This gene was inserted into the plasmid pBV220 and the resultant recombinant plasmid pBV220-GT was transformed to E. coli DH5 alpha. The activity of recombinant enzyme was about 10 u/g(wet cell). In order to improve the expression level of target protein, some nucleotides in the 3' and 5' of the gene were modified to optimize the second structure of mRNA by PCR amplification using the new primers devised according to the biosoftware GOLDKEY2.0. As a result, the activity of recombinant enzyme increase to 19.8 u/g(wet cell). Then, the helping plasmid pUBS520 which carried the gene encoding the tRNA of rare codons AGG and AGA was transformed to the recombinant strain. But it took little effect.     

Characterization of the ferrous iron uptake system of Escherichia coli.

Escherichia coli has an iron(II) transport system (feo) which may make an important contribution to the iron supply of the cell under anaerobic conditions. Cloning and sequencing of the iron(II) transport genes revealed an open reading frame (feoA) possibly coding for a small protein with 75 amino acids and a membrane protein with 773 amino acids (feoB). The upstream region of feoAB contained a binding site for the regulatory protein Fur, which acts with iron(II) as a corepressor in all known iron transport systems of E. coli. In addition, a Fnr binding site was identified in the promoter region. The FeoB protein had an apparent molecular mass of 70 kDa in sodium dodecyl sulfate-polyacrylamide gel electrophoresis and was localized in the cytoplasmic membrane. The sequence revealed regions of homology to ATPases, which indicates that ferrous iron uptake may be ATP driven. FeoA or FeoB mutants could be complemented by clones with the feoA or feoB gene, respectively.     

Aerobactin-mediated iron uptake system in intestinal Escherichia coli

Abstract Escherichia coli strains isolated from children with diarrhea were studied to determine the incidence of the components of the aerobactin system. The production of aerobactin and the presence of the aerobactin receptor were demonstrated using bioassay techniques. The presence and location of the genes for the aerobactin system was determined by colony and Southern DNA-DNA hydridization. It was found that aerobactin and the aerobactin receptor could be coded by either chromosomal or plasmid genes. A high percentage of strains expressed the receptor in the absence of aerobactin. Of 19 enterotoxin-producing strains one was found to have the complete aerobactin system, while 11 expressed only the aerobactin receptor which was most frequently coded by a plasmid.     

嗜酸热硫化叶菌麦芽寡糖基海藻糖合酶基因的克隆和表达

麦芽寡糖基海藻糖合酶( Maltodigosyltrehalose synthase;MTSase)是近年来在一些微生物中发现的新型分子内糖苷转移酶,能将淀粉或淀粉部分水解物(大于3个葡糖基)的糖链还原末端的α-1,4糖苷键转化为α-1,1糖苷键,生成具海藻糖末端结构的产物[1],如下所示: Gn为聚合度n(n＞3)的麦芽寡糖,Gn-2-T为麦芽寡糖基海藻糖,-T为海藻糖基.     

Functional expression of the glutamate uptake system from Corynebacterium glutamicum in Escherichia coli

Abstract Glutamate uptake in the Gram-positive Corynebacterium glutamicum is mediated via a binding protein-dependent transport system, which is encoded by the gluABCD gene cluster. Cloning of these genes in an expression vector and subsequent transformation of the resulting plasmid allows different strains of the Gram-negative bacterium Escherichia coli to grow on glutamate as sole carbon and nitrogen source. However, overexpression of the glutamate uptake system results in growth inhibitory effects, probably due to the particular topology of the binding protein.     

Anaerobic fumarate transport in Escherichia coli by an fnr-dependent dicarboxylate uptake system which is different from the aerobic dicarboxylate uptake system.

Escherichia coli grown anaerobically with fumarate as electron acceptor is able to take up C4-dicarboxylates by a specific transport system. The system differs in all tested parameters from the known aerobic C4-dicarboxylate transporter. The anaerobic transport system shows higher transport rates (95 mumol/g [dry weight] per min versus 30 mumol/g/min) and higher Kms (400 versus 30 microM) for fumarate than for the aerobic system. Mutants lacking the aerobic dicarboxylate uptake system are able to grow anaerobically at the expense of fumarate respiration and transport dicarboxylates with wild-type rates after anaerobic but not after aerobic growth. Transport by the anaerobic system is stimulated by preloading the bacteria with dicarboxylates. The anaerobic transport system catalyzes homologous and heterologous antiport of dicarboxylates, whereas the aerobic system operates only in the unidirectional mode. The anaerobic antiport is measurable only in anaerobically grown bacteria with fnr+ backgrounds. Additionally, the system is inhibited by incubation of resting bacteria with physiological electron acceptors such as O2, nitrate, dimethyl sulfoxide, and fumarate. The inhibition is reversed by the presence of reducing agents. It is suggested that the physiological role of the system is a fumarate/succinate antiport under conditions of fumarate respiration.     

Stable, inducible thermoacidophilic alpha-amylase from Bacillus acidocaldarius.

Bacillus acidocaldarius Agnano 101 produces an inducible thermoacidophilic alpha-amylase. The enzyme production occurs during the stationary phase of growth in the presence of compounds with alpha-1,4-glucosidic linkages. The enzymatic activity is both present in the culture medium and associated with the cells; the enzymes purified from both sources show identical molecular and catalytic properties. The purified amylase has a single polypeptide chain of molecular weight 68,000 and behaves like an alpha-amylase with affinity constants for starch and related substances of 0.8 to 0.9 mg/ml. The pH and temperature optima for activity are 3.5 and 75degreesC, respectively. The amylase is stable at acidic pH (below 4.5). Its thermal stability is strictly dependent upon protein concentration; the half-life at 60degreesC of the amylase in a 70-mug/ml solution is about 5 days.     

Genetic analysis of potassium transport loci in Escherichia coli: evidence for three constitutive systems mediating uptake potassium.

The analysis of mutants of Escherichia coli that require elevated concentrations of K+ for growth has revealed two new genes, trkG, near minute 30 within the cryptic rac prophage, and trkH, near minute 87, the products of which affect constitutive K+ transport. The analysis of these and other trk mutations suggests that high rates of transport, previously considered to represent the activity of a single system, named TrkA, appear to be the sum of two systems, here named TrkG and TrkH. Each of these two is absolutely dependent on the product of the trkA gene, a cytoplasmic protein associated with the inner membrane (D. Bossemeyer, A. Borchard, D. C. Dosch, G. C. Helmer, W. Epstein, I. R. Booth, and E. P. Bakker, J. Biol. Chem. 264:16403-16410, 1989). The TrkH system is also dependent on the products of the trkH and trkE genes, while the TrkG system is also dependent on the product of the trkG gene and partially dependent on the product of the trkE gene. It is suggested that the trkH and trkG products are membrane proteins that form the transmembrane path for the K+ movement of the respective systems. Two mutations altering the trkA product reduce the affinity for K+ of both TrkG and TrkH, indicating that changes in peripheral protein can alter the conformation of the sites at which K+ is bound prior to transport. The TrkD system has a relatively modest rate of transport, is dependent solely on the product of the trkD gene, and is the sole saturable system for Cs+ uptake in this species (D. Bossemeyer, A. Schl?sser, and E. P. Bakker, J. Bacteriol. 171:2219-2221, 1989).     

Cadmium uptake in Escherichia coli K-12.

109Cd2+ uptake by Escherichia coli occurred by means of an active transport system which has a Km of 2.1 microM Cd2+ and a Vmax of 0.83 mumol/min X g (dry weight) in uptake buffer. 109Cd2+ accumulation was both energy dependent and temperature sensitive. The addition of 20 microM Cd2+ or Zn2+ (but not Mn2+) to the cell suspensions preloaded with 109Cd2+ caused the exchange of Cd2+. 109Cd2+ (0.1 microM) uptake by cells was inhibited by the addition of 20 microM Zn2+ but not Mn2+. Zn2+ was a competitive inhibitor of 109Cd2+ uptake with an apparent Ki of 4.6 microM Zn2+. Although Mn2+ did not inhibit 109Cd2+ uptake, the addition of either 20 microM Cd2+ or Zn2+ prevented the uptake of 0.1 microM 54Mn2+, which apparently occurs by a separate transport system. The inhibition of 54Mn2+ accumulation by Cd2+ or Zn2+ did not follow Michaelis-Menten kinetics and had no defined Ki values. Co2+ was a competitive inhibitor of Mn2+ uptake with an apparent Ki of 34 microM Co2+. We were unable to demonstrate an active transport system for 65Zn2+ in E. coli.     

Inhibition of L-lysine uptake by alpha-methyl lysine in Escherichia coli and Bacillus sphaericus

alpha-Methyl lysine was investigated as a potential inhibitor of lysine transport in Escherichia coli and Bacillus sphaericus. At equimolar concentrations, no inhibition was observed in either organism, but at 10X and 100X the lysine concentration, alpha-methyl lysine caused a 20-50% reduction in the initial rate of lysine uptake in both bacteria. A similar inhibitory effect was observed with epsilon-N-methyl lysine on lysine uptake in B. sphaericus, but not in E. coli. alpha-Methyl lysine had a reduced effect on ornithine uptake and no effect on arginine transport in either bacterium.