The phosphate pool in Escherichia coli THU

The phosphate pool of Escherichia coli was determined as a fraction of the total cell phosphate. This relative pool size was found to be essentially independent of cell age.     

Molecular genetic studies of a 10.9-kb operon in Escherichia coli for phosphonate uptake and biodegradation

Bacteria that use phosphonates as a phosphorus source must be able to break the stable carbon-phosphorus bond. In Escherichia coli phosphonates are broken down by a C-P lyase that has a broad substrate specificity. Evidence for a lyase is based on in vivo studies of product formation because it has been proven difficult to detect the activity in vitro. By using molecular genetic techniques, we have studied the genes for phosphonate uptake and degradation in E. coli, which are organized in an operon of 14 genes, named phnC to phnP. As expected for genes involved in P acquisition, the phnC-phnP operon is a member of the PHO regulon and is induced many hundred-fold during phosphate limitation. Three gene products (PhnC, PhnD and PhnE) comprise a binding protein-dependent phosphonate transporter, which also transports phosphate, phosphite, and certain phosphate esters such as phosphoserine; two gene products (PhnF and PhnO) may have a role in gene regulation; and nine gene products (PhnG, PhnH, PhnI, PhnJ, PhnK, PhnL, PhnM, PhnN, and PhnP) probably comprise a membrane-associated C-P lyase enzyme complex. Although E. coli can degrade many different phosphonates, the ability to use certain phosphonates appears to be limited by the specificity of the PhnCDE transporter and not by the specificity of the C-P lyase.     

Cloning of the ethidium efflux gene from Escherichia coli

The gene specifying the ethidium efflux system of Escherichia coli has been cloned on a 3.2 kbp HindIII fragment and located on a 1.2 kbp fragment within this. Cross-resistance studies indicate that the system has a broad specificity for monovalent cations and the gene shows no hybridisation with similar genes found in Staphylococci.     

Regulation of phosphate starvation responses in higher plants

Background

Phosphorus (P) is often a limiting mineral nutrient for plant growth. Many soils worldwide are deficient in soluble inorganic phosphate (P_i), the form of P most readily absorbed and utilized by plants. A network of elaborate developmental and biochemical adaptations has evolved in plants to enhance P_i acquisition and avoid starvation.

Scope

Controlling the deployment of adaptations used by plants to avoid P_i starvation requires a sophisticated sensing and regulatory system that can integrate external and internal information regarding P_i availability. In this review, the current knowledge of the regulatory mechanisms that control P_i starvation responses and the local and long-distance signals that may trigger P_i starvation responses are discussed. Uncharacterized mutants that have P_i-related phenotypes and their potential to give us additional insights into regulatory pathways and P_i starvation-induced signalling are also highlighted and assessed.

Conclusions

An impressive list of factors that regulate P_i starvation responses is now available, as is a good deal of knowledge regarding the local and long-distance signals that allow a plant to sense and respond to P_i availability. However, we are only beginning to understand how these factors and signals are integrated with one another in a regulatory web able to control the range of responses demonstrated by plants grown in low P_i environments. Much more knowledge is needed in this agronomically important area before real gains can be made in improving P_i acquisition in crop plants.     

Differential activities of the SoxR protein of Escherichia coli: SoxS is not required for gene activation under iron deprivation

When Escherichia coli cells are under superoxide stress, proteins SoxR and SoxS, acting sequentially, control the expression of a set of repair and defense genes. One of these genes, fumC, encoding fumarase C, was reported to be also activated by iron deprivation in a soxRS-dependent manner. However, the same condition failed to induce the expression of a soxS'::lacZ fusion. The expression of acnA (aconitase A) is also activated by SoxR alone when under iron deprivation, but not of sodA (Mn-superoxide-dismutase). SoxR completely inhibited the migration of a DNA fragment containing the promoter region of fumC, in gel-shift experiments. SoxR might bind to a different region than SoxS within the fumC promoter, or an unknown intermediate other than SoxS might be acting. It is possible that the regulatory role of SoxR is more complex than previously considered.     

Chromosome replication in Escherichia coli induced by oversupply of DnaA

Summary Overexpression of DnaA protein from a multicopy plasmid accompanied by a shift to 42°C causes initiation of one extra round of replication in a dnaA ⁺ strain grown in glycerol minimal medium. This extra round of replication does not lead to an extra cell division, such that cells contain twice the normal number of chromosomes.     

Use of glucose starvation to limit growth and induce protein production in Escherichia coli

The use of glucose starvation to uncouple the production of recombinant beta-galactosidase from cell growth in Escherichia coli was investigated. A lacZ operon fusion to the carbon starvation-inducible cst-1 locus was used to control beta-galactosidase synthesis. beta-Galactosidase induction was observed only under aerobic starvation conditions, and its expression continued for 6 h following the onset of glucose starvation. The cessation of beta-galactosidase expression closely correlated with the exhaustion of acetate, an overflow metabolite of glucose, from the culture medium. Our results suggest the primary role of acetate in cst-1-controlled protein expression is that of an energy source. Using this information, we metered acetate to a glucose-starved culture and produced a metabolically sluggish state, where growth was limited to a low linear rate and production of recombiant beta-galactosidase occurred continuously throughout the experiment. The cst-1 controlled beta-galactosidase synthesis was also induced at low dilution rates in a glucose-limited chemostat, suggesting possible applications to high-density cell systems such as glucose-limited recycle reactors. This work demonstrates that by using an appropriate promoter system and nutrient limitation, growth can be restrained while recombinant protein production is induced and maintained.     

Effect of oxygen limitation and starvation on the benzalkonium chloride susceptibility of Escherichia coli

Aims: To investigate the effect of oxygen limitation, glucose-starvation and temperature on the susceptibility of Escherichia coli towards the quaternary ammonium biocide benzalkonium chloride (BAC). Methods and Results: The effect of BAC on planktonic and sessile cells were investigated using the gfp-tagged E. coli K-12 strain MG1655[pOX38Km]. Increasing temperature from 10°C to 30°C increased the bactericidal effect of BAC for both starved and nonstarved E. coli under aerobic and anaerobic conditions. The lowest minimum bactericidal concentration was observed for cells in anaerobic media at 30°C (30 mg l⁻¹ BAC). Decreasing cell densities increased the decay rate for BAC-exposed cells for both starved and nonstarved E. coli. Biofilms of E. coli exposed to BAC in anaerobic medium showed a greater percentage of membrane-compromised cells than biofilms grown in aerobic medium. Image analyses of BAC-exposed biofilms showed that membrane-compromised cells were occasionally located in the interior structure of the biofilm microcolonies. Conclusions: Increasing temperatures and the absence of oxygen, and energy substrates increased the antimicrobial effect of BAC towards E. coli. Significance and Impact of the Study: The results are relevant for understanding the disinfection efficacy of quaternary ammonium compounds towards planktonic and sessile bacteria.     

外源基因在大肠杆菌中的高效表达

为了提高外源蛋白在大杨杆菌中的表达量,人们对大肠杆菌表达系统进行了许多研究。作者综述了有关外源基因在大肠杆菌中高效表达的研究进展。     

The role of exogenous iron in the activation of ribonucleotide reductase from Escherichia coli

 Protein R2, the small component of ribonucleotide reductase from Escherichia coli, contains a diferric center and a catalytically essential tyrosyl radical. In vitro, this radical can be produced in the protein from two inactive forms, metR2, containing an intact diiron center and lacking the tyrosyl radical, and apoR2, lacking both iron and the radical. While activation of apoR2 requires only a source of ferrous iron and exposure to O₂, activation of metR2 was achieved using a multienzymatic system consisting of an NAD(P)H:flavin oxidoreductase, superoxide dismutase and a poorly defined protein fraction, named fraction b (Fontecave M, Eliasson R, Reichard P (1987) J Biol Chem 262 : 12325–12331). In both reactions, reduced R2, containing a diferrous center, is a key intermediate which is subsequently converted to active R2 during reaction with O₂. By in vivo labeling of E. coli with radioactive ⁵⁹Fe, we show that fraction b contains iron. Depletion of the iron in fraction b inactivates it, and fraction b can be substituted for by ferric citrate solutions. Furthermore, aqueous Fe²⁺ in the presence of dithiothreitol is able to convert metR2 into reduced R2. Therefore we propose that the function of fraction b is to provide, in association with the flavin reductase, ferrous iron for reduction of the endogenous diiron center. Since fraction b is not a single well-defined protein, it remains to be shown whether, in vivo, that function resides in a specific protein. Exogenous iron can thus participate in activation of both apoR2 and metR2, but it is incorporated into R2 only in the former case. A unifying mechanism is proposed. Received: 13 November 1996 / Accepted: 3 April 1997     

一种用质粒DNA转化大肠杆菌感受态细胞的实用操作技巧

目的是建立一种简化、实用的用质粒DNA转化大肠杆菌的操作方法.采用氯化钙法制备大肠杆菌感受态细胞.以质粒pUC18,pCSN44,pAN52-1Not,pETts,pANth和植物双元表达栽体pCAMBIA1301分别转化用于质粒扩增与保存的常用大肠杆菌菌株Top10和DH5α以及用于原核表达的常用大肠杆菌菌株BL21(DE3)和TB1.质粒与感受态细胞的混合液置冰上作用一定时间后,直接涂布含有筛选抗生素的LB平板,于37℃培养12～16h.结果表明,用不同大小的质粒DNA转化不同的大肠杆菌菌株,都可以获得满足实验要求,转化效率可高达103～4阳性克隆/μg.该方法较标准的转化流程更加简便、省时、实用.