Basic Amino Acid Transport in Escherichia coli: Properties of Canavanine-Resistant Mutants

A mutant of Escherichia coli strain CanR 22 has been isolated which is resistant to growth inhibition by canavanine, an analogue of arginine. The properties of this strain and of another canavanine-resistant mutant, JC182-5 (isolated by Celis et al. [5]), were studied. The mutation is pleiotropic in that it results in a reduction in the activity of two distinct permeases, the arginine-specific and lysine-arginine-ornithine transport systems. The lesion maps at min 56 of the E. coli linkage map, at or near the argP locus. Although strain CanR 22 excretes arginine, this excretion appears to result from reduced ability to concentrate arginine, rather than the loss of transport ability being the result of excretion. This conclusion is based on findings with a canavanine-resistant strain auxotrophic for arginine, which exhibits transport properties similar to those of the prototrophic strains. Additionally, growth in the presence of arginine or ornithine results in a repression of the activity of the two basic amino acid transport systems. Neither the arginine-specific nor the lysine-arginine-ornithine binding proteins of the mutant cells show significant alterations in terms of amount, physical properties, or kinetic parameters. These observations lead to the proposal of a model for the two basic amino acid transport systems in which two carrier proteins with different specificities interact with a common energy coupling mechanism. A lesion in the gene (or one of the genes) for this coupling mechanism can confer canavanine resistance.     

Properties of an Escherichia coli K-12 mutant defective in the transport of arginine and ornithine.

A canavanine-resistant mutant strain, defective in the transport of arginine and ornithine, was isolated and characterized. Experiments presented show that both the kinetics of influx and the steady state of accumulation of arginine and ornithine are affected by the mutation, whereas the activity of other related transport systems remains unchanged. On the basis of competitive studies, it is concluded that L-canavanine can inhibit efficiently the arginine-specific uptake system. D-Arginine appears to be a moderate inhibitor. None of the basic amino acid-binding proteins of the mutant strain showed detectable alterations in terms of quantity, physical properties, or affinity constants. Studies on the relationship between the number of transport carriers and the steady state of accumulation of arginine suggested the presence of a reduced number of membrane carriers in the mutant strain. It is proposed that the mutation affects a regulatory gene concerned with controlling the amount of membrane carriers produced, which are components of the arginine- and ornithine-specific uptake systems. The mutation maps at min 62 on the recalibrated linkage map of Escherichia coli K-12, in a locus closely linked or identical to argP.     

Characterization of PitA and PitB from Escherichia coli

Escherichia coli contains two major systems for transporting inorganic phosphate (P(i)). The low-affinity P(i) transporter (pitA) is expressed constitutively and is dependent on the proton motive force, while the high-affinity Pst system (pstSCAB) is induced at low external P(i) concentrations by the pho regulon and is an ABC transporter. We isolated a third putative P(i) transport gene, pitB, from E. coli K-12 and present evidence that pitB encodes a functional P(i) transporter that may be repressed at low P(i) levels by the pho regulon. While a pitB(+) cosmid clone allowed growth on medium containing 500 microM P(i), E. coli with wild-type genomic pitB (pitA Delta pstC345 double mutant) was unable to grow under these conditions, making it indistinguishable from a pitA pitB Delta pstC345 triple mutant. The mutation Delta pstC345 constitutively activates the pho regulon, which is normally induced by phosphate starvation. Removal of pho regulation by deleting the phoB-phoR operon allowed the pitB(+) pitA Delta pstC345 strain to utilize P(i), with P(i) uptake rates significantly higher than background levels. In addition, the apparent K(m) of PitB decreased with increased levels of protein expression, suggesting that there is also regulation of the PitB protein. Strain K-10 contains a nonfunctional pitA gene and lacks Pit activity when the Pst system is mutated. The pitA mutation was identified as a single base change, causing an aspartic acid to replace glycine 220. This mutation greatly decreased the amount of PitA protein present in cell membranes, indicating that the aspartic acid substitution disrupts protein structure.     

The glutamate uptake regulatory protein (Grp) of Zymomonas mobilis and its relation to the global regulator Lrp of Escherichia coli.

After being expressed in Escherichia coli JC5412, which is defective in glutamate transport, a Zymomonas mobilis gene which enabled this strain to grow on glutamate was cloned. This gene encodes a protein with 33% amino acid identity to the leucine-responsive regulatory protein (Lrp) of E. coli. Although overall glutamate uptake in E. coli was increased, the protein encoded by the cloned fragment repressed the secondary H+/glutamate transport system GltP by interaction with the promoter region of the gltP gene. It also repressed the secondary, H(+)-coupled glutamate uptake system of Z. mobilis, indicating that at least one role of this protein in Z. mobilis is to regulate glutamate transport. Consequently, it was designated Grp (for glutamate uptake regulatory protein). When expressed in E. coli, Grp repressed the secondary H+/glutamate transport system GltP by binding to the regulatory regions of the gltP gene. An lrp mutation in E. coli was complemented in trans with respect to the positive expression regulation of ilvIH (coding for acetohydroxy acid synthase III) by a plasmid which carries the grp gene. The expression of grp is autoregulated, and in Z. mobilis, it depends on growth conditions. The putative presence of a homolog of Grp in E. coli is discussed.     

Arginine-agmatine antiporter in extreme acid resistance in Escherichia coli

The process of arginine-dependent extreme acid resistance (XAR) is one of several decarboxylase-antiporter systems that protects Escherichia coli and possibly other enteric bacteria from exposure to the strong acid environment of the stomach. Arginine-dependent acid resistance depends on an intracellular proton-utilizing arginine alpha-decarboxylase and a membrane transport protein necessary for delivering arginine to and removing agmatine, its decarboxylation product, from the cytoplasm. The arginine system afforded significant protection to wild-type E. coli cells in our acid shock experiments. The gene coding for the transport protein is identified here as a putative membrane protein of unknown function, YjdE, which we now name adiC. Strains from which this gene is deleted fail to mount arginine-dependent XAR, and they cannot perform coupled transport of arginine and agmatine. Homologues of this gene are found in other bacteria in close proximity to homologues of the arginine decarboxylase in a gene arrangement pattern similar to that in E coli. Evidence for a lysine-dependent XAR system in E. coli is also presented. The protection by lysine, however, is milder than that by arginine.     

三叶因子Bm-TFF2突变体在原核体系中的表达及促细胞迁移活性

大蹼铃蟾三叶因子Bm-TFF2具有较人TFF2更强的促细胞迁移和抗凋亡活性。该研究利用RT-PCR方法扩增得到野生型Bm-TFF2的基因,然后分别构建N端、C端和分子中两个精氨酸突变的突变体,最后连接表达载体产生pET32a(+)/Bm-TFF2突变型重组质粒,转入大肠杆菌中,经37℃培养,IPTG诱导,其融合蛋白主要存在于包涵体中,用组氨酸标签的亲合柱纯化溶解后的包涵体上清,进一步用RP-HPLC纯化得到硫氧还蛋白(TRX)/Bm-TFF2突变型融合蛋白。通过SDS-PAGE和Westernblotting检测分析其纯度和特异性。最终,从1L培养基中得到20mg纯度为95%的三种重组突变型融合蛋白。三种突变型重组蛋白都具有剂量依赖性的促细胞迁移活性,并且其活性无显著差异。该研究为进一步研究Bm-TFF2结构和功能的关系以及揭示其作用的分子机制奠定了基础。     

Characterization of the Escherichia coli gcvR gene encoding a negative regulator of gcv expression.

The Escherichia coli glycine cleavage enzyme system catalyzes the cleavage of glycine, generating CO2, NH3, and a one-carbon unit. Expression of the operon encoding this enzyme system (gcv) is induced in the presence of glycine and repressed in the presence of purines. In this study, a mutant with high-level constitutive expression of a gcvT-lacZ gene fusion was isolated. The mutation in this strain was designated gcvR1 and was mapped to min 53.3 on the E. coli chromosome. A single-copy plasmid carrying the wild-type gcvR gene complemented the mutation, restoring normal regulation of a gcvT-lacZ fusion, while a multicopy plasmid carrying gcvR led to superrepression under all growth conditions. Negative regulation of a gcvT-lacZ fusion by GcvR was shown to require GcvA, a LysR family protein known to both activate gcv in the presence of glycine and repress gcv in the presence of purines. Models explaining how GcvR and GcvA might interact to regulate gcv expression are proposed.     

The potential for the formation of the arginine biosynthetic enzymes and its masking during evolution

The present account spans the history of arginine regulation from its discovery in 1955 until the present. In 1957 I demonstrated that not only added arginine but also internally produced arginine represses enzyme formation and that the potential for enzyme synthesis is in excess of what is required for growth. In 1959 I located the regulatory gene argR encoding the arginine repressor. An unusual feature of this research was the finding that in E. coli B, in contrast to E. coli K12, arginine synthesis is permanently repressed, independent of arginine. This was due to a single amino acid difference between the two repressors. Recent studies showed that, in natural populations of E. coli, K12-type regulation is much more frequent than B-type regulation, and that E. coli B evolved from a strain with K12-type regulation. In competition experiments, E. coli K12 was found to be favored in the presence of arginine and E. coli B in its absence, showing that contrary to expectations permanently turned off regulation is favored over negative regulation in some environments.     

The phosphotransferase system of Streptomyces coelicolor.

We have investigated the crr gene of Streptomyces coelicolor that encodes a homologue of enzyme IIAGlucose of Escherichia coli, which, as a component of the phosphoenolpyruvate-dependent sugar phosphotransferase system (PTS) plays a key role in carbon regulation by triggering glucose transport, carbon catabolite repression, and inducer exclusion. As in E. coli, the crr gene of S. coelicolor is genetically associated with the ptsI gene that encodes the general phosphotransferase enzyme I. The gene product IIACrr was overproduced, purified, and polyclonal antibodies were obtained. Western blot analysis revealed that IIACrr is expressed in vivo. The functionality of IIACrr was demonstrated by phosphoenolpyruvate-dependent phosphorylation via enzyme I and the histidine-containing phosphoryl carrier protein HPr. Phosphorylation was abolished when His72, which corresponds to the catalytic histidine of E. coli IIAGlucose, was mutated. The capacity of IIACrr to operate in sugar transport was shown by complementation of the E. coli glucose-PTS. The striking functional resemblance between IIACrr and IIAGlucose was further demonstrated by its ability to confer inducer exclusion of maltose to E. coli. A specific interaction of IIACrr with the maltose permease subunit MalK from Salmonella typhimurium was uncovered by surface plasmon resonance. These data suggest that this IIAGlucose-like protein may be involved in carbon metabolism in S. coelicolor.     

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.     

人睫状神经营养因子突变体基因克隆及高效表达

为了提高人睫状神经营养因子（ＣＮＴＦ）的生物学活性,用ＰＣＲ方法获取Ｎ端缺失１４个氨基酸的ＣＮＴＦ基因片段,经酶切鉴定、核酸测序证实突变体的核苷酸序列,将其重组至表达质粒ｐＢＶ２２０,构建了ＣＮＴＦ突变体表达载体ｐＢＶ－ＣＮＴＦΔ．用ＳＤＳ－ＰＡＧＥ测定其表达水平,鸡胚背根节无血清培养法检测表达蛋白的生物学活性．结果表明,ｐＢＶ－ＣＮＴＦΔ能表达生物学活性高于天然ＣＮＴＦ的约２６ｋＤ蛋白质,表达水平达３０％．为今后通过基因工程方法获得ＣＮＴＦ突变体,从而制备高效的ＣＮＴＦ制剂创造了条件．