Azaserine resistance in Escherichia coli: chromosomal location of multiple genes.

Resistance to azaserine in Escherichia coli is the result of mutations in at least three different loci. All spontaneously arising azaserine-resistant mutants harbor a lesion in the aroP gene. However, a lesion in this gene is not solely responsible for resistance. All spontaneously arising intermediate-level azaserine-resistant mutants also harbor a lesion in a gene designated azaA, which lies near min 43 on the chromosome. High-level resistant mutants harbor lesions in the aroP and azaA genes and in a third gene designated azaB, which lies near min 69 on the chromosome. Transport studies demonstrate that mutants harboring lesions in the azaA gene are not defective in the transport of the aromatic amino acids, but that mutants which harbor lesions in the azaB gene are defective in phenylalanine transport but not in tyrosine or tryptophan transport.     

The LIV-I/LS system as a determinant of azaserine sensitivity of Escherichia coli K-12

The growth of Escherichia coli is inhibited by an antibiotic compound, azaserine (O-diazoacetyl-L-serine). Previous studies revealed the biochemical properties of azaserine, which involves inhibition of various enzymatic reactions as well as introduction of DNA breakage. However, genetically, nothing has been elucidated except that all the azaserine-resistant strains isolated so far carry lesions in the aroP gene as a primary determinant. Here, we demonstrate that, in addition to AroP, the LIV-I/LS system, an ATP-binding cassette type transporter, is involved in azaserine sensitivity of E. coli, by genetic analysis and transport studies, in which Ki value for azaserine was determined to be approximately 10(-3) M.     

The function of gamma-glutamyl transpeptidase as a determinant in cell sensitivity to azaserine toxicity

The enzyme gamma-glutamyl transpeptidase (GGT) is characteristically present at high levels in mammalian cells that are vulnerable in vivo to the selectively toxic and carcinogenic effects of the naturally occurring diazo amino acid L-azaserine. The possible role of GGT as a determinant of cellular sensitivity to azaserine toxicity was investigated. No correlation was found between GGT activity and the abilities of different cell lines or GGT-deficient cell strains of TuWi, a human nephroblastoma-derived line high in GGT, to accumulate azaserine. However, the thiols glutathione and cysteine were found to inhibit the toxicity of azaserine in cultures of TuWi. In addition, maleate lowered both intracellular and extracellular glutathione levels and enhanced sensitivity of TuWi cells to azaserine, while serine-borate, a potent inhibitor of GGT, increased extracellular glutathione levels and inhibited azaserine toxicity. Since extracellular glutathione accumulation, which may reflect the rate of cellular glutathione turnover, is increased in cultures of azaserine-resistant, GGT-deficient strains of TuWi, we propose that GGT enhances cellular sensitivity to azaserine primarily by increasing the rate of glutathione turnover, thus removing the glutathione from detoxification pathways.     

The effect of azaserine on glutamine uptake by rat renal brush-border membranes.

Azaserine added directly to isolated rat renal brush-border membrane vesicles inhibits uptake of L-glutamine. Azaserine acts as a non-competitive inhibitor of the low-Km system for glutamine transport, but has no effect on the high-Km system. Preincubation of the vesicles with azaserine at 37 degrees C min is not required for transport inhibition to occur, although it is a requirement for gamma-glutamyl transpeptidase inhibition. Removal of azaserine from the vesicle preparation by repeated resuspensions in buffer results in a reversal of the transport inhibition but not in reversal of enzyme inhibition. Azaserine also inhibits vesicle uptake of L-proline and alpha-methyl D-glucoside, indicating a generalized effect on membrane transport systems. The data cast doubt on the postulate that gamma-glutamyl transpeptidase might act as the carrier mechanism for glutamine reabsorption by renal cortical cells.     

大肠杆菌色氨酸转运系统多基因敲除对色氨酸生产的影响

大肠杆菌中色氨酸向胞内的转运主要是由mtr、tnaB和aroP 3个基因编码的通透酶进行调控.利用Red重组技术,在mtr单基因敲除菌的基础上,成功构建了mtr.tnaB和mtr.aroP双基因敲除菌以及mtr.tnaB.aroP三基因敲除菌,并通过发酵实验首次考察了色氨酸转运系统多基因缺失对大肠杆菌合成色氨酸的影响.发酵结果表明,mtr.tnaB和mtr.aroP双基因缺失后,色氨酸产量分别达到1.38 g/L和1.27 g/L,与出发菌株相比分别提高了17％和9％,而mtr.tnaB.aroP三基因缺失后,菌体生长受到了明显抑制,发酵后色氨酸产量仅为0.63 g/L.在补料分批发酵实验中,mtr.tnaB双基因敲除菌的色氨酸产量进一步提高至12.2 g/L,与出发菌株相比色氨酸产量提高了27％.     

Properties of cysK mutants of Escherichia coli K12.

Triazole and azaserine resistant mutants of E. coli K12 affecting cysK gene coding for O-acetylserine sulphydrylase were isolated. The cysK gene in E. coli is located in the same region of chromosome as the cycK gene in Salmonella typhimurium. All azaserine and some triazole resistant mutants require cysteine for growth at a normal rate. The cysK mutants have reduced sulphate uptake. Stability and transfer by conjugation of triazole resistant phenotype were checked. Differences in sulphate metabolism between closely related organisms E. coli and S. typhimurium are discussed.     

Mutator Gene of Escherichia coli B

An azaserine-resistant derivative of Escherichia coli B/UV, AZA/R(1), was found to carry a mutator gene. This gene, designated mutS1, was mapped by means of conjugation and P1kc-mediated transduction. The mutS1 gene was cotransduced with argB at a frequency of 2.4%; the gene order in this region of the chromosome is thy argB mutS1. To determine whether a relationship commonly exists between azaserine resistance and the mutator property, 12 additional azaserine-resistant derivatives of B/UV were developed and tested for the mutator phenotype. None of the twelve was a mutator strain. The level of azaserine resistance was not increased over that of the recipient parent when mutS1 was transduced to an azaserine-susceptible strain. Reversion studies indicated that mutS1 induced adenosine-ribosylthymine to guanosine-cytidine and guanosine-cytidine to adenosine-ribosylthymine transitions. Because such mutational changes are suppressible with deoxynucleosides when induced by base analogues, an attempt was made to suppress the mutator activity of mutS1 by the addition of deoxyribonucleosides to the medium. No suppression was found. Recombinants were prepared containing mutS1 and the Treffers mutator gene of E. coli K-12. The effect of the mutator genes appears to be additive.     

Transport of L-4-azaleucine in Escherichia coli.

The uptake of L-4-azaleucine was examined in Escherichia coli K-12 strains to determine the systems that serve for its accumulation. L-4=Azaleucine in radio-labeled form was synthesized and resolved by the action of hog kidney N-acylamino-acid amidohydrolase (EC 3.5.1.B) on the racemic alpha-N-acetyl derivative of DL-[dimethyl-14C]4-azaleucine. L-4-Azaleucine is taken up in E. coli by energy-dependent processes that are sensitive to changes in the pH and to inhibition by leucine and the aromatic amino acids. Although a single set of kinetic parameters was obtained by kinetic experiments, other evidence indicates that transport systems for both the aromatic and the branched-chain amino acids serve for azaleucine. Azaleucine uptake in strain EO317, with a mutation leading to derepression and constitutive expression of branched-chain amino acid (LIV) transport and binding proteins, was not repressed by growth with leucine as it was in parental strain EO300. Lesions in the aromatic amino acid transport system, aroP, also led to changes in the regulation of azaleucine uptake activity when cells were grown on phenylalanine. Experiments on the specificity of azaleucine uptake and exchange experiments with leucine and phenylalanine support the hypothesis that both LIV and aroP systems transport azaleucine. The ability of external azaleucine to exchange rapidly with intracellular leucine may be an important contributor to azaleucine toxicity. We conclude from these and other studies that at least four other process may affect azaleucine sensitivity: the level of branched-chain amino acid biosynthetic enzymes; the level of leucine, isoleucine, and valine transport systems; the level of the aromatic amino acid, aroP, uptake system; and, possibly, the ability of the cell to racemize D and L amino acids. The relative importance of these processes in azaleucine sensitivity under various conditions is not known precisely.     

Inhibition of the growth of mammalian cells in cuture by amino acids and the isolation and characterization of L-phenylalanine transport.

Raising the concentration of phenylalanine and other amino acids in MEM leads to the inhibition of growth and in some cases to death of A9. Balb 3T3 , SV40 Balb 3T3 (SVT2), CHO, and WI38. All cells tested exhibited some similar senstivities to certain of the amino acids. but there were some unique differences. Phenylalanine-resistant mutants (Pher) of A9 were isolated that had modified phenylalanine-transport properties. These mutants can be isolated by a single-step selection procedure. A Lineweaver-Burk plot of initial rates of phenylalanine uptake by A9 and mutants showed a biphasic curve suggesting two transport systems. The Pher mutants had altered properties of both systems. It is suggested that the selection of clones resistant to high concentration of several of the natural amino acid may be used as a general method for the isolation of mutants affecting the various amino acid transport systems in mammalian cells.     

Functional analysis of sequences adjacent to dapE of Corynebacterium glutamicum reveals the presence of aroP, which encodes the aromatic amino acid transporter.

An initially nonclonable DNA locus close to a gene of L-lysine biosynthesis in Corynebacterium glutamicum was analyzed in detail. Its stepwise cloning and its functional identification by monitoring the amino acid uptakes of defined mutants, together with mechanistic studies, identified the corresponding structure as aroP, the general aromatic amino acid uptake system.     

Photoinhibition of 2-amino-2-carboxybicyclo[2,2,1]heptane transport by O-diazoacetyl-L-serine. An initial step in identifying the L-system amino acid transporter

Neutral amino acid uptake into mammalian cells occurs predominantly through the L, A, and ASC carrier-mediated transport systems. The proteins responsible for transport by these systems have not been isolated, and the three pathways presently are defined by their amino acid specificity and physiologic parameters. We have found that the amino acid derivative, O-diazoacetyl-L-serine (azaserine), is a potentially useful probe for identification of the L-(leucine-favoring) system transporter in human T-lymphocytes. Uptake of azaserine competitively inhibits the uptake of the prototype L-system amino acid, 2-amino-2-carboxybicycloheptane (BCH). Azaserine undergoes photolytic cleavage with 365 nm incident light to yield a highly reactive carbene intermediate and free N2. Following photolysis of [14C]azaserine in a suspension of lymphocytes, the 14C label is detectable within a crude cytoplasmic membrane preparation, and this process is inhibited by a 50-fold excess of unlabeled azaserine or 2-amino-2-carboxybicycloheptane, suggesting that the 14C-product is associated with the membranes at or near the L-system transport site. Furthermore, photolysis of azaserine in the presence of lymphocytes results in specific irreversible inhibition of L-system transport. Thus, photolysis of azaserine provides an initial step toward the identification of the L-system transporter.     

大肠杆菌酪氨酸转运系统基因敲除对酪氨酸生产的影响

酪氨酸是三大芳香族氨基酸之一,广泛用于食品、医药和化工等领域。转运系统工程为代谢工程改造大肠杆菌选育酪氨酸生产菌株提供了一种重要的研究策略。大肠杆菌中酪氨酸胞内转运主要通过aroP和tyrP基因编码的通透酶进行调控。以酪氨酸生产菌株HGXP为出发菌株,利用CRISPR-Cas9技术成功构建了aroP和tyrP基因敲除菌,并通过发酵试验考察了调节转运系统对酪氨酸生产的影响。发酵结果表明,aroP和tyrP基因敲除菌酪氨酸产量分别达到3.74 g/L和3.45 g/L,较出发菌株酪氨酸产量分别提高了19%和10%。对诱导温度进行了优化,结果表明38℃为最佳诱导温度。在3 L发酵罐上进行了补料分批发酵,aroP和tyrP基因敲除菌酪氨酸产量进一步提高至44.5 g/L和35.1 g/L,较出发菌株酪氨酸产量分别提高了57%和24%。研究结果对代谢工程强化大肠杆菌生产酪氨酸具有重要的参考价值。     

Characterization of bromoethanesulfonate-resistant mutants of Methanococcus voltae: evidence of a coenzyme M transport system.

Mutants of Methanococcus voltae were isolated that were resistant to the coenzyme M (CoM; 2-mercaptoethanesulfonic acid) analog 2-bromoethanesulfonic acid (BES). The mutants displayed a reduced ability to accumulate [35S]BES relative to the sensitive parental strain. BES inhibited methane production from CH3-S-CoM in cell extracts prepared from wild-type sensitive or resistant strains. BES uptake required the presence of both CO2 and H2 and was inhibited by N-ethylmaleimide and several reagents that are known to disrupt energy metabolism. The mutants showed normal uptake of isoleucine and were not cross-resistant to either azaserine or 5-methyltryptophan and, thus, were neither defective in general energy-dependent substrate transport nor envelope permeability. Both HS-CoM and CH3-S-CoM prevented the uptake of BES and protected cells from inhibition by it. We propose that M. voltae has an energy-dependent, carrier-mediated uptake system for HS-CoM and CH3-S-CoM which can also mediate uptake of BES.     

Separation of phenylalanine transport events by using selective inhibitors, and identification of a specific uncoupler activity in Yersinia pestis.

Phenylalanine transport in Yersinia pestis TJW was differentially inhibited by sulfhydryl blocking reagents, uncoupling agents, and respiratory inhibitors. Kinetic studies with potassium cyanide and sodium azide showed that these compounds have no immediate effect on the initial rate of phenylalanine transport, but have an immediate and severe inhibitory effect on the rate of oxygen uptake. Identical studies with p-chloromercuribenzoate (pCMB) and 2,4-dinitrophenol (DNP) showed that these compounds have an instantaneous and total inhibitory effect on phenylalanine transport. DNP stimulated oxygen uptake, and pCMB caused only a sluggish inhibiton of oxygen uptake. pCMB acted as a competitive inhibitor of phenylalanine transport, whereas DNP inhibitied noncompetitively. Arrenius plots of the initial rate of phenylalanine transport in pCMB- and DNP-treated cells showed that DNP alters the transition temperature of the phenylalanine transport system from 17 C for control cells to 12 C. DNP did not inhibit transport when cells were treated at temperatures of 2 to 10 C. PCMB did not alter the normal transition temperature and inhibited phenylalanine transport over a 2 to 30 C temperature range. Efflux induced by both pCMB and DNP were blocked by placing cells at low temperatures (2 to 20 C). Inhibition of adenosine 5'-triphosphate synthesis by DNP did not show any temperature sensitivity as did phenylalanine transport. These data indicate that: (i) respiration is not obligatory for active transport of phenylalanine in Y. pestis TJW; and (ii) pCMB inhibits transport activity by reacting with the sulfhydryl group(s) at the carrier binding site. The data show that the uncoupler, DNP, selectively alters a temperature-dependent property of phenylalanine transport, that is not related to uncoupling activity of DNP , and probably involves membrane lipid alterations.     

The lysP gene encodes the lysine-specific permease.

Escherichia coli transports lysine by two distinct systems, one of which is specific for lysine (LysP) and the other of which is inhibited by arginine ornithine. The activity of the lysine-specific system increases with growth in acidic medium, anaerobiosis, and high concentrations of lysine. It is inhibited by the lysine analog S-(beta-aminoethyl)-L-cysteine (thiosine). Thiosine-resistant (Tsr) mutants were isolated by using transpositional mutagenesis with TnphoA. A Tsr mutant expressing alkaline phosphatase activity in intact cells was found to lack lysine-specific transport. This lysP mutation was mapped to about 46.5 min on the E. coli chromosome. The lysP-phoA fusion was cloned and used as a probe to clone the wild-type lysP gene. The nucleotide sequence of the 2.7-kb BamHI fragment was determined. An open reading frame from nucleotides 522 to 1989 was observed. The translation product of this open reading frame is predicted to be a hydrophobic protein of 489 residues. The lysP gene product exhibits sequence similarity to a family of amino acid transport proteins found in both prokaryotes and eukaryotes, including the aromatic amino acid permease of E. coli (aroP) and the arginine permease of Saccharomyces cerevisiae (CAN1). Cells carrying a plasmid with the lysP gene exhibited a 10- to 20-fold increase in the rate of lysine uptake above wild-type levels. These results demonstrate that the lysP gene encodes the lysine-specific permease.     

Location of the gene for the low-affinity tryptophan-specific permease of Escherichia coli.

L-Tryptophan uptake was assayed under conditions in which the aroT gene had been inactivated by deletion and the product of the aroP permease was competitively inhibition. A mutant carrying a deletion from bgl through tnaA showed negligible L-tryptophan uptake, in contrast to a strain possessing an intact tna region or to strains carrying point mutations in tna. The ability to take up L-tryptophan was not restored by lysogenizing the tna-deleted strain with lambda tna+.     

Histidine and Aromatic Permeases of Salmonella typhimurim

Mutants defective either in the histidine permease (hisP) or in the aromatic permease (aroP) were isolated in Salmonella typhimurium and were characterized. The hisP locus had a 49% linkage to purF by phage transduction. The aroP locus was close to proA. Merozygotes diploid for the hisP gene were constructed by episomal transfer, and hisP(+) was dominant over hisP. The properties of merozygotes are described and discussed. A method for the selection of revertants of hisP mutants was devised. By this method, one of the hisP mutants was characterized as an amber mutant. The specificity of the aromatic permease was investigated by using as substrates analogues of the aromatic amino acids and of histidine.