Catalase and superoxide dismutase in Escherichia coli

We assessed the roles of intrabacterial catalase and superoxide dismutase in the resistance of Escherichia coli to killing by neutrophils. E. coli in which the synthesis of superoxide dismutase and catalase were induced by paraquat 10-fold and 5-fold, respectively, did not resist killing by neutrophils. When bacteria were allowed to recover from the toxicity of paraquat for 1 h on ice and for 30 min at 37 degrees C, they still failed to resist killing by neutrophils. Induction of the synthesis of catalase 9-fold by growth in the presence of phenazine methosulfate did not render E. coli resistant to killing by either neutrophils or by H2O2 itself. The lack of protection by intrabacterial catalase from killing by neutrophils could not be attributed to an impermeable bacterial membrane; the evolution of O2 from H2O2 was no less rapid in suspensions of E. coli than in lysates. The failure of intrabacterial catalase or superoxide dismutase to protect bacteria from killing by neutrophils might indicate either that the flux of O-2 and H2O2 in the phagosome is too great for the intrabacterial enzymes to alter or that the site of injury is at the bacterial surface.     

Secretion expression of recombinant glucagon in Escherichia coli

A novel approach for the preparation of recombinant human glucagon was described. An expression vector pAGluT, containing phoA promoter, phoA signal peptide and glucagon gene, was constructed by means of genetic engineering. Escherichia coli strain YK537 was transformed with pAGluT. High-level secretory expression of recombinant human glucagon was achieved. The expression yield of recombinant human glucagon was found to be 80 mg/L, approximately 30% of the total proteins in supernatant. The biological activities and the physicochemical properties of the purified recombinant human glucagon were found to be the same as that of native glucagon. In addition, our results suggested that phoA expression system may be suitable for the expression of other small peptides.     

应用PCR重组技术构建大肠杆菌分泌型表达载体

应用ＰＣＲ重组技术,对大肠杆菌分泌型表达载体ｐＩＮ－ⅢｏｍｐＡ进行改建,除去原载体的ＨｉｎｄⅢ位点,将信号肽序列末端两个密码子ＣＡＧＧＣＣ改为ＣＡＡＧＣＴ,从而引入一个新的ＨｉｎｄⅢ位点,并在其下游接上一段多克隆位点序列。改建后的载体可用于直接插入外源ＤＮＡ编码序列,表达产物在分泌过程中被切除信号肽而成为天然有活性的蛋白质,操作十分简便。     

新月柄杆菌RsaA分泌系统用于大肠杆菌胞外递送重组蛋白的初步研究

目的：构建基于新月柄杆菌RsaA外运机制的以大肠杆菌为宿主的原核胞外分泌表达载体系统。方法：利用分子克隆手段,按RsaA分泌系统操纵子组织方式,将RsaA系统外运功能基因配合以异源调控序列克隆至pQE30骨架质粒。以绿色荧光蛋白（GFP）为报告分子、大肠杆菌M15为宿主茵,诱导表达后通过Western Blotting检测培养上清中GFP的表达。结果：获得了与设计完全一致的pQABPS载体,利用该载体系统,在培养上清中报告分子GFP的表达明显增加,且是通过特异的RsaA外运机制被分泌至胞外的,而非渗漏表达或简单的信号肽引导。结论：在大肠杆菌中重现了RsaA分泌系统的外运功能,为该系统在基因工程领域的应用研究打下了良好基础。     

High-level expression of human extracellular superoxide dismutase in Escherichia coli and insect cells.

Much is known about the physical properties of the Cu,Zn- and Mn-superoxide dismutases (SODs). However, the biochemical characteristics and pharmacological properties of extracellular (EC)-SOD have been severely limited due to difficulties in obtaining and purifying the enzyme. The EC-SOD cDNA was inserted into the Escherichia coli expression plasmid pET-28a(+) which contains the T7 promoter and transformed into the E. coli BL21(DE3). After induction with 1 mmol/L isopropyl beta-D-thiogalactoside, the recombinant human EC-SOD was highly expressed as inclusion bodies. SDS-PAGE analysis revealed that recombinant EC-SOD accumulated up to 26% of the total soluble protein of E. coli cells. The expression product was purified by a Ni(2+)-IDA-Sepharose 6B column. After the denaturing and refolding processes, the recombinant human EC-SOD retains the specific enzymatic activity of 920 U/mg of the purified product. The gene encoding human EC-SOD mature peptide was also inserted into the donor plasmid pFastBacHTb. After transposition, transfection, and amplification were performed, the recombinant baculoviruses infected the Tn-5B1-4 cells and EC-SOD was highly expressed in Tn-5B1-4 cells. SDS-PAGE and Western blot analysis revealed that the subunit molecular weight of the expression product is 28 kDa. Furthermore, recombinant human EC-SOD retains the enzymatic specific activity of 200 U/mg of the Tn-5B1-4 cell lysates.     

Aggregation of ALS mutant superoxide dismutase expressed in Escherichia coli

Although large amounts of wild-type human Cu,Zn superoxide dismutase (SOD) are easily expressed in Escherichia coli, the amyotrophic lateral sclerosis-associated mutants have a strong propensity to aggregate into inclusion bodies. The alanine to valine mutation at the fourth codon (A4V) is responsible for a rapidly progressive disease course and is particularly prone to aggregation when expressed in E. coli. We found that A4V SOD remained soluble when expressed at 18 degrees C, but >95% A4V SOD aggregated in inclusion bodies when expressed at 23 degrees C or above. The SOD aggregates dissolved with 4 M urea, suggesting that intermolecular hydrophobic interactions were predominantly responsible for making SOD insoluble. Many of the urea-solubilized subunits were cross-linked via disulfide bridges. Fully active mutant SOD could be produced by dialyzing urea away in the presence of beta-mercaptoethanol and subsequently adding copper plus zinc, providing a fast procedure for purifying hundreds of milligrams of protein. Extensive rinsing removed most contaminating E. coli proteins from A4V SOD inclusion bodies except for a 37 kDa protein identified as outer membrane protein F using MALDI ToF/ToF mass spectrometry. Our results indicate that metal-deficient ALS-mutant SOD folds into stable apo conformation able to rebind metals. At high protein concentrations, SOD forms aggregates through hydrophobic interactions between subunits that seem to act as a kinetic snare to entrap additional proteins.     

Periplasmic Secretion of Functional Ovotransferrin N-Lobe in Escherichia coli

The cytoplasmic and periplasmic production systems of ovotransferrin N-lobe in Escherichia coli were constructed. The periplasmic, but not cytoplasmic product, was found to have the ironbinding function.     

Regulation of the manganese-containing superoxide dismutase is independent of the inducible DNA repair system in Escherichia coli

Studies on the induction of the manganese-containing superoxide dismutase in several strains of Escherichia coli with different mutations in recA and lexA revealed that the inductions of the Mn-isozyme and of the SOS system by oxygen free radicals are not coregulated. We also studied the synthesis of the manganese-superoxide dismutase in the temperature-dependent, protease-constitutive strain recA441(tif-1) that also contained a lac fusion in an SOS gene. A shift to the temperature at which recA441 has constitutive protease activity did not induce Mn-superoxide dismutase but did induce beta-galactosidase. The data clearly demonstrate that induction of the Mn-superoxide dismutase is independent of the SOS system.     

Mutations by near-ultraviolet radiation in Escherichia coli strains lacking superoxide dismutase

Om wild-type Escherichia coli, near-ultraviolet radiation (NUV) was only weakly mutagenic. However, in an allelic mutant strain (sodA sodB) that lacks both Mn- and Fe-superoxide dismutase (SOD) and assumed to have excess superoxide anion (O₂⁻), NUV induced a 9-fold increase in mutation above the level that normally occurs in this double mutant. When a sodA sodB double mutant contained a plasmid carrying katG⁺ HP-I catalase), mutation by NUV was reduced to wild-type (sodA⁺ sodB⁺) levels. Also, in the sodA sodB xthA triple mutant, which lacks exonuclease III (exoIII) in addition to SOD, the mutations frequency by NUV was reduced to wild-type levels. This synergistic action of NUV and O₂⁻ suggested that pre-mutational lesions occur, with exoIII converting these lesions to stable mutants. Exposure to H₂O₂ induced a 2.8 fold increase in mutations in sodA sodB double mutants, but was reduced to control levels when a plasmid carrying katG⁺ was introduced. These results suggest that NUV, in addition to its other effects on cells, increases mutations indirectly by increasing the flux of OH^. radicals, possibly by generating excess H₂O₂.     

Secretion of extracellular superoxide dismutase in neonatal lungs

Extracellular superoxide dismutase (EC-SOD), the only known enzymatic scavenger of extracellular superoxide, may modulate reactions of nitric oxide (NO) in the lungs by preventing reactions between superoxide and NO. The regulation of EC-SOD has not been examined in developing lungs. We hypothesize that EC-SOD plays a pivotal role in the response to increased oxygen tension and NO in the neonatal lung. This study characterizes rabbit EC-SOD and investigates the developmental regulation of EC-SOD activity, protein expression, and localization. Purified rabbit EC-SOD was found to have several unique biochemical attributes distinct from EC-SOD in other species. Rabbit lung EC-SOD contains predominantly uncleaved subunits that do not form disulfide-linked dimers. The lack of intersubunit disulfide bonds may contribute to the decreased heparin affinity and lower EC-SOD content in rabbit lung. EC-SOD activity in rabbit lungs is low before birth and increases soon after gestation. In addition, the enzyme is localized intracellularly in preterm and term rabbit lungs. Secretion of active EC-SOD into the extracellular compartment increases with age. The changes in EC-SOD localization and activity have implications for the neonatal pulmonary response to oxidative stress and the biological activity of NO at birth.     

An assay for the detection of superoxide dismutase in individual Escherichia coli colonies

A method for detecting superoxide dismutase activity in individual colonies of Escherichia coli was developed. The assay involves the lysis of individual cells in colonies on filter papers by a series of lysozyme, chloroform, and freeze-thaw treatments. Filters are placed on agar plates to allow diffusion of cellular enzymes into a solid matrix. A nitroblue tetrazolium overlay is applied to detect superoxide dismutase activity. Colonies possessing activity produce achromatic zones against a dark Formazan background. The assay can detect the presence of superoxide dismutase and the relative amount of enzyme as well. This assay provides a method for screening a population of cells for mutants deficient in or overproducing superoxide dismutase.     

Effect of hydrogen peroxide on the iron-containing superoxide dismutase of Escherichia coli

The iron-containing superoxide dismutase from Escherichia coli is inactivated by H2O2 to a limit of approximately 90%. When corrected for the H2O2-resistant portion, this inactivation was first order with respect to residual activity and exhibited a pseudo-first-order rate constant of 0.066 min-1 at 25 degrees C in 0.24 mM H2O2 at pH 7.8. The superoxide dismutase activity remaining after treatment with H2O2 differed from the activity of the native enzyme with respect to heat stability, inhibition by azide, and inactivation by light in the presence of rose bengal and by N-bromosuccinimide. The native and the H2O2-modified enzymes were indistinguishable by electrophoresis on polyacrylamide gels. Inactivation of the enzyme by H2O2 was accompanied by loss of tryptophan and some loss of iron, but there was no detectable loss of histidine or of other amino acids. H2O2 treatment caused changes in the optical spectrum of the enzyme. Inactivation of the enzyme by H2O2 depends upon the iron at the active site. Thus, the apoenzyme and the manganese-substituted enzyme were unaffected by H2O2. We conclude that reaction of H2O2 with the iron at the active site generates a potent oxidant capable of attacking tryptophan residues. A mechanism is proposed.     

Regulation of superoxide dismutase synthesis in Escherichia coli: glucose effect.

Growth of Escherichia coli, based upon the fermentation of glucose, is associated with a low intracellular level of superoxide dismutase. Exhaustion of glucose, or depression of the pH due to accumulation of organic acids, causes these organisms to then obtain energy from the oxidative degradation of other substances present in a rich medium. This shift in metabolism is associated with a marked increase in the rate of synthesis of superoxide dismutase. Depression of the synthesis of superoxide dismutase by glucose is not due to catabolite repression since it is not eliminated by cyclic adenosine 3',5'-monophosphate and since alpha-methyl glucoside does not mimic the effect of glucose. Moreover, glucose itself no longer depresses superoxide dismutase synthesis when the pH has fallen low enough to cause a shift to a non-fermentative metabolism. It appears likely that superoxide dismutase is controlled directly or indirectly by the intracellular level of O2- and that glucose depressed the level of this enzyme because glucose metabolism is not associated with as rapid a production of O2- as is the metabolsim of many other substances. In accord with this view is the observation that paraquat, which can increase the rate of production of O2- by redox cycling, caused a rapid and marked increase in superoxide dismutase.     

Identification of copper-zinc superoxide dismutase gene from enteroaggregative Escherichia coli.

We describe here the identification of sodC gene from enteroaggregative Escherichia coli (EAggEC). A 294 bp gene-specific fragment was amplified from the organism by DNA as well as RT-PCR using primers from bacterial sodC sequences. The metal co-factor present in the protein was confirmed by running samples in native gels and inhibiting with 2 mM potassium cyanide. However, the nonpathogenic E. coli possesses the gene but does not express it. Thus, the presence of copper-zinc superoxide dismutase encoded by sodC was demonstrated for the first time in EAggEC, which means it could be a novel candidate for a virulence marker.     

Subunit dissociation and metal binding by Escherichia coli apo-manganese superoxide dismutase

Metal binding by apo-manganese superoxide dismutase (apo-MnSOD) is essential for functional maturation of the enzyme. Previous studies have demonstrated that metal binding by apo-MnSOD is conformationally gated, requiring protein reorganization for the metal to bind. We have now solved the X-ray crystal structure of apo-MnSOD at 1.9 Å resolution. The organization of active site residues is independent of the presence of the metal cofactor, demonstrating that protein itself templates the unusual metal coordination geometry. Electrophoretic analysis of mixtures of apo- and (Mn₂)-MnSOD, dye-conjugated protein, or C-terminal Strep-tag II fusion protein reveals a dynamic subunit exchange process associated with cooperative metal binding by the two subunits of the dimeric protein. In contrast, (S126C) (SS) apo-MnSOD, which contains an inter-subunit covalent disulfide-crosslink, exhibits anti-cooperative metal binding. The protein concentration dependence of metal uptake kinetics implies that protein dissociation is involved in metal binding by the wild type apo-protein, although other processes may also contribute to gating metal uptake. Protein concentration dependent small-zone size exclusion chromatography is consistent with apo-MnSOD dimer dissociation at low protein concentration (K_D = 1 × 10⁻⁶ M). Studies on metal uptake by apo-MnSOD in Escherichia coli cells show that the protein exhibits similar behavior in vivo and in vitro.     

Effect of temperature and htpR on the biosynthesis of superoxide dismutase in Escherichia coli

The synthesis of Mn- and FeSODs in response to temperature changes was examined in strains of Escherichia coli with different mutations in sod and htpR genes. Growth at or shift to elevated temperatures induced FeSOD but not MnSOD. The induction of FeSOD by heat was inhibited by chloramphenicol and was independent of the heat shock (htpR-controlled) regulon. FeSOD was more stable at 42 degrees C than was MnSOD.     

Kinetic analysis of the metal binding mechanism of Escherichia coli manganese superoxide dismutase

The acquisition of a catalytic metal cofactor is an essential step in the maturation of every metalloenzyme, including manganese superoxide dismutase (MnSOD). In this study, we have taken advantage of the quenching of intrinsic protein fluorescence by bound metal ions to continuously monitor the metallation reaction of Escherichia coli MnSOD in vitro, permitting a detailed kinetic characterization of the uptake mechanism. Apo-MnSOD metallation kinetics are "gated", zero order in metal ion for both the native Mn2+ and a nonnative metal ion (Co2+) used as a spectroscopic probe to provide greater sensitivity to metal binding. Cobalt-binding time courses measured over a range of temperatures (35-50 degrees C) reveal two exponential kinetic processes (fast and slow phases) associated with metal binding. The amplitude of the fast phase increases rapidly as the temperature is raised, reflecting the fraction of Apo-MnSOD in an "open" conformation, and its temperature dependence allows thermodynamic parameters to be estimated for the "closed" to "open" conformational transition. The sensitivity of the metallated protein to exogenously added chelator decreases progressively with time, consistent with annealing of an initially formed metalloprotein complex (k anneal = 0.4 min(-1)). A domain-separation mechanism is proposed for metal uptake by apo-MnSOD.     

Physiological function of superoxide dismutase in glucose-limited chemostat cultures of Escherichia coli.

Conditions for continuous culture of Escherichia coli K-12 His- Thi- under glucose limitation were established. Both the capacity for respiration, at D greater than 0.2/h, and specific activity of superoxide dismutase increased as a function of specific growth rate, whereas peroxidase and catalase were either invariant with or inversely related to this growth rate. The abrupt increase in the availability of glucose, as a means of elevating the growth rate, was followed by an increase in superoxide dismutase, which reached a plateau before there was a significant increase in the growth rate. Thus, an increase in superoxide dismutase appeared to be a prerequisite for an increase in the rate of growth. Cells that had higher levels of superoxide dismutase, because of varying specific growth rates, were more resistant to the toxicity of hyperbaric oxygen. Superoxide dismutase thus behaved like an essential defense against the toxicity of oxygen. Sensitivity towards streptonigrin increased with specific growth rate in the range of 0.09 to 0.25/h but decreased with further increases in the growth rate. Since this antibiotic has been shown to shunt electrons to oxygen, with concomitant production of O2-, these results indicated a progressive deficiency of reducing power at growth rates below 0.25/h and a surfeit of reducing power with progressively greater protection against O2- by superoxide dismutase at growth rates greater than 0.25/h.     

Regulation of sod genes in Escherichia coli: relevance to superoxide dismutase function

This review is concerned with the effects of environmental perturbations on the expression of the two superoxide dismutase (SOD) genes in Escherichia coli (sodA, MnSOD; sodB, FeSOD). Early studies using SOD activity, showed that MnSOD levels respond to changes in oxygen tension, type of substrate, redox active compounds, iron concentration, the nature of the terminal oxidant, and the redox potential of the medium. FeSOD levels appeared nominally insensitive to these perturbations. More recent molecular genetic studies revealed that sodA expression is subject to regulation by three major regulatory systems: fur (ferric uptake regulation) and arcA arcB (aerobic respiratory control) mediate repression of sodA, while a relatively new system, soxR soxS (superoxide response), mediates activation of sodA expression. By contrast, sodB expression, which is much less studied at this time, appears to be positively activated in trans by fur. A rudimentary gene regulation model is presented which rationalizes past observations, is experimentally testable, and should serve as a guide to future research in this area.