Electron transfer from quinohemoprotein alcohol dehydrogenase to blue copper protein azurin in the alcohol oxidase respiratory chain of Pseudomonas putida HK5.

A blue copper protein was purified together with a type II quinohemoprotein alcohol dehydrogenase (ADH IIB) from the soluble fraction of Pseudomonas putida HK5 grown on n-butanol. The purified blue copper protein was shown to be azurin, on the basis of several properties such as its absorption maximum (623 nm), its low molecular mass (17 500 Da), its acidic nature (pI of 4.1), its relatively high redox potential (306 mV), the presence of an intramolecular disulfide bond, and N-terminal amino acid sequence homology with respect to azurins from other sources, especially from P. putida NCIB 9869 and Pseudomonas fluorescens. Direct electron transfer from ADH IIB to azurin was shown to occur at a rate of 48-70 s-1. The apparent Km value of ADH IIB for azurin, determined by steady-state kinetics, was decreased several-fold by increasing the ionic strength. Furthermore, the extent of fluorescence quenching of ADH IIB due to the interaction with azurin was increased by increasing the ionic strength, but the binding constant for binding between ADH IIB and azurin was unchanged. The redox potential of azurin was increased 12 mV by incubation with ADH but not vice versa. Furthermore, the redox potential gap between ADH and azurin was increased from 102 to 126 mV by increasing the ionic strength. It is conceivable that a hydrophobic interaction is involved in the electron transfer between both proteins, and it is also suggested that the electron transfer may occur by a freely reversible on and off binding process but may not be related to the global binding process of both proteins. Thus, the results presented here strongly suggest that azurin works as an electron-transfer mediator in a PQQ-dependent alcohol oxidase respiratory chain in P. putida HK5.     

Conformational heterogeneity of the copper binding site in azurin. A time-resolved fluorescence study.

Comparison of the fluorescence spectra and the effect of temperature on the quantum yields of fluorescence of Azurin (from Pseudomonas fluorescens ATCC-13525-2) and 3-methylindole (in methylcyclohexane solution) provides substantive evidence that the tryptophan residue in azurin is completely inaccessible to solvent molecules. The quantum yields of azurin (CuII), azurin (CuI), and apoazurin (lambda ex = 291 nm) were 0.052, 0.054, and 0.31, respectively. Other evidence indicates that there is no energy transfer from tyrosine to tryptophan in any of these proteins. The fluorescence decay behavior of each of the azurin samples was found to be invariant with emission wavelength. The fluorescences of azurin (CuII) and azurin (CuI) decay with dual exponential kinetics (tau 1 = 4.80 ns, tau 2 = 0.18 ns) while that of apoazurin obeys single exponential decay kinetics (tau = 4.90). The ratio of pre-exponentials of azurin (CuII), alpha 1/alpha 2, is found to be 0.25, and this ratio increases to 0.36 on reduction to azurin (CuI). The results are interpreted as originating from different interactions of the tryptophan with two conformers of the copper-ligand complex in azurin.     

Global Gene Expression Analysis of Long-Term Stationary Phase Effects in E. coli K12 MG1655

Global gene expression was monitored in long-term stationary phase (LSP) cells of E. coli K12 MG1655 and compared with stationary phase (SP) cells that were sub-cultured without prolonged delay to get an insight into the survival strategies of LSP cells. The experiments were carried out using both LB medium and LB supplemented with 10% of glycerol. In both the media the LSP cells showed decreased growth rate compared to SP cells. DNA microarray analysis of LSP cells in both the media resulted in the up- and down-regulation of several genes in LSP cells compared to their respective SP cells in the corresponding media. In LSP cells grown in LB 204 genes whereas cells grown in LB plus glycerol 321 genes were differentially regulated compared to the SP cells. Comparison of these differentially regulated genes indicated that irrespective of the medium used for growth in LSP cells expression of 95 genes (22 genes up-regulated and 73 down-regulated) were differentially regulated. These 95 genes could be associated with LSP status of the cells and are likely to influence survival and growth characteristics of LSP cells. This is indeed so since the up- and down-regulated genes include genes that protect E. coli LSP cells from stationary phase stress and genes that would help to recover from stress when transferred into fresh medium. The growth phenotype in LSP cells could be attributed to up-regulation of genes coding for insertion sequences that confer beneficial effects during starvation, genes coding for putative transposases and simultaneous down-regulation of genes coding for ribosomal protein synthesis, transport-related genes, non-coding RNA genes and metabolic genes. As yet we still do not know the role of several unknown genes and genes coding for hypothetical proteins which are either up- or down-regulated in LSP cells compared to SP cells.     

Induction of a global stress response during the first step of Escherichia coli plate growth

We have investigated the first events that occur when exponentially grown cells are transferred from a liquid medium (Luria-Bertani [LB]) to a solid medium (LB agar [LBA]). We observed an initial lag phase of 180 min for the wild type MG1655 without any apparent growth. This lack of growth was independent of the bacterial physiological state (either the stationary or the exponential phase), the solid medium composition, or the number of cells on the plate, but it was dependent on the bacterial genotype. Using lacZ-reporter fusions and two-dimensional electrophoresis analysis, we observed that when cells from exponential-phase cultures were plated on LBA, several global regulons, like heat shock regulons (RpoH, RpoE, CpxAR) and oxidative-stress regulons (SoxRS, OxyR, Fur), were immediately induced. Our results indicate that in order to grow on plates, bacteria must not only adapt to new conditions but also perceive a real stress.     

Induction of a Global Stress Response during the First Step of Escherichia coli Plate Growth

We have investigated the first events that occur when exponentially grown cells are transferred from a liquid medium (Luria-Bertani [LB]) to a solid medium (LB agar [LBA]). We observed an initial lag phase of 180 min for the wild type MG1655 without any apparent growth. This lack of growth was independent of the bacterial physiological state (either the stationary or the exponential phase), the solid medium composition, or the number of cells on the plate, but it was dependent on the bacterial genotype. Using lacZ-reporter fusions and two-dimensional electrophoresis analysis, we observed that when cells from exponential-phase cultures were plated on LBA, several global regulons, like heat shock regulons (RpoH, RpoE, CpxAR) and oxidative-stress regulons (SoxRS, OxyR, Fur), were immediately induced. Our results indicate that in order to grow on plates, bacteria must not only adapt to new conditions but also perceive a real stress.     

Effects of growth medium selection on plasmid DNA production and initial processing steps

Cultures of recombinant Escherichia coli containing the plasmid pSVbeta were grown in three medium formulations to assess their effects on the characteristics of supercoiled plasmid DNA production for plasmid-based gene therapy. A semi-defined medium containing casamino acids (SDCAS) was found to support higher cell densities and higher plasmid stability than a similar medium containing soya amino acids (SDSOY) or Luria-Bertani medium (LB). Differences were observed in the cell harvest characteristics, plasmid DNA primary recovery, plasmid DNA yield and quality between cells grown on LB and on SDCAS medium. Cells grown on SDCAS medium were more difficult to resuspend after harvest than those grown in LB medium and were less susceptible to alkaline lysis. The plasmid DNA content from SDCAS was predominantly supercoiled and was less contaminated by chromosomal DNA than plasmid DNA extracts derived from cells grown on LB medium. It was hypothesised that the different carbon:nitrogen ratio (C:N) of the medium may have been responsible for changing the cell wall polysaccharide composition resulting in the change in cell harvest and lysis characteristics. Results indicated that changing the C:N ratio of SDCAS medium between 1.21:1 and 12.08:1 resulted in no alteration in cell wall polysaccharide composition or in cell susceptibility to chemical lysis or physical breakage. Plasmid DNA yields increased ten-fold with ten-fold increase in the C:N ratio of SDCAS medium.     

Purification and characterization of a non-reconstitutable azurin, obtained by heterologous expression of the Pseudomonas aeruginosa azu gene in Escherichia coli

The azurin-encoding azu gene from Pseudomonas aeruginosa was cloned and expressed in Escherichia coli. A purification procedure was developed to isolate the azurin obtained from the E. coli cells. No differences were observed between azurins isolated from P. aeruginosa and E. coli. A non-reconstitutable azurin-like protein, azurin*, with a spectral ratio (A625/A280) less than 0.01 could be separated from holo-azurin with a spectral ratio of 0.58 (+/- 0.01). The properties of azurin* were examined by electrophoretic (SDS-PAGE and IEF) and spectroscopic (UV/vis, 1H-NMR, static and dynamic fluorescence) techniques, and compared to the properties of holo-azurin and apo-azurin. Azurin* resembles apo-azurin (same pKa* values of His-35 and His-117, same fluorescence characteristics). However, it has lost the ability to bind Cu-ions. It is tentatively concluded that azurin* is a chemically modified form of azurin, the modification possibly being due to oxidation of the ligand residue Cys-112 or the formation of a chemical bond between the ligand residues Cys-112 and His-117. In agreement with previous results from Hutnik and Szabo (Biochemistry (1989) 28, 3923-3934), fluorescence experiments show that the heterogeneous fluorescence decay observed for holo-azurin is not due to the presence of azurin*, but most likely originates from conformational heterogeneity of the holo-azurin.     

Identification,Source, and Metabolism of N-Ethylglutamate in Escherichia coli

N-Ethylglutamate (NEG) was detected in Escherichia coli BL21 cells grown on LB broth, and it was found to occur at a concentration of ∼4 mM in these cells under these conditions. The same cells grown on M9 glucose medium contained no detectable amount of NEG. Analysis of the LB broth showed the presence of NEG, a compound never before reported as a natural product. Isotope dilution analysis showed that it occurred at a concentration of 160 μM in LB broth. Analyses of yeast extract and tryptone, the organic components of LB broth, both showed the presence NEG. It was demonstrated that NEG can be generated during the autolysis of the yeast used in the preparation of the yeast extract. Growth of these E. coli cells in LB broth prepared in deuterated water showed no incorporation of deuterium into NEG, demonstrating that E. coli cells did not generate the NEG. Cell growth rates were not affected by the addition of 5 mM NEG to either LB or M9 glucose medium. l-[ethyl-²H₄]NEG was found to be readily incorporated into the cells and metabolized by the cells. From these results, it was concluded that all of the NEG present in the cells was taken up from the medium. NEG could serve as the sole nitrogen source for E. coli when grown on M9 glucose medium in the presence of glucose but could not serve as the sole carbon source on M9 medium in the absence of glucose.During work on developing methods for the analysis of the amino acids generated by recombinant archaeal mutases, I developed procedures for the recovery and analysis of the free amino acids present in cell extracts of Escherichia coli. When these methods were applied to analysis of E. coli grown on LB broth, I always found a large amount of an unknown amino acid. Here I report on the identification of this amino acid as N-ethylglutamate (NEG). NEG has never been reported as a natural product. I demonstrate that NEG is readily taken up by E. coli and can serve as the sole source of nitrogen when the cells are grown on M9 glucose medium.     

Probing copper ligands in denatured <Emphasis Type="Italic">Pseudomonas aeruginosa</Emphasis> azurin: unfolding His117Gly and His46Gly mutants

Azurin is a single-domain beta-barrel protein with a redox-active copper cofactor. Upon Pseudomonas aeruginosa azurin unfolding, the cofactor remains bound to the polypeptide, coordinating three ligands: cysteine-112, one histidine imidazole, and a third, unknown ligand. In order to identify which histidine (histidine-117 and histidine-46 both coordinate copper in native azurin) is involved in copper coordination in denatured azurin, two single-site (histidine to glycine) mutants, His117Gly and His46Gly azurin, are investigated here. Equilibrium denaturation experiments of His46Gly azurin loaded with copper demonstrate that copper remains bound to this mutant in high urea concentrations where the protein's secondary structure is lost. In contrast, for copper-loaded His117Gly azurin, copper does not stay coordinated upon polypeptide unfolding. The copper absorption at 370 nm in denatured His46Gly azurin agrees with that for copper in complex with a peptide corresponding to residues 111-123 in azurin, suggesting similar metal coordination. We conclude that histidine-117 (and not histidine-46) is the histidine copper ligand in denatured azurin. This is also in accord with the proximity of histidine-117 to cysteine-112 in the primary sequence.     

Chromate resistance and reduction in Pseudomonas fluorescens strain LB300

Pseudomonas fluorescens LB300 is a chromateresistant strain isolated from chromium-contaminated river sediment. Chromate resistance is conferred by the plasmid pLHB1. Strain LB300 grew in minimal salts medium with as much as 1000 g of K₂CrO₄ ml^–1, and actively reduced chromate to Cr(III) while growing aerobically on a variety of substrates. Chromate was also reduced during anaerobic growth on acetate, the chromate serving as terminal electron acceptor. P. fluorescens LB303, a plasmidless, chromatesensitive variant of P. fluorescens LB300, did not grow in minimal salts medium with more than 10 g of K₂CrO₄ ml^–1. However, resting cells of strain LB303 grown without chromate reduced chromate as well as strain LB300 cells grown under the same conditions. Furthermore, resting cells of chromate-sensitive Pseudomonas putida strain AC10, also catalyzed chromate reduction. Evidently chromate resistance and chromate reduction in these organisms are unrelated. Comparison of the rates of chromate reduction by chromate grown cells and cells grown without chromate indicated that the chromate reductase activity is constitutive. Studies with cell-free extracts show that the reductase is membrane-associated and can mediate the transfer of electrons from NADH to chromate.     

Comparative analysis of 2,4,6-trinitrotoluene (TNT)-induced cellular responses and proteomes in <Emphasis Type="Italic">Pseudomonas</Emphasis> sp. HK-6 in two types of media

TNT-induced cellular responses and proteomes in Pseudomonas sp. HK-6 were comparatively analyzed in two different media: basal salts (BS) and Luria broth (LB). HK-6 cells could not degrade more than 0.5 mM TNT with BS medium, while in LB medium, they exhibited the enhanced capability to degrade as much as 3.0 mM TNT. Analysis of total cellular fatty acids in HK-6 cells suggested that the relative abundance of several saturated or unsaturated fatty acids is altered under TNT-mediated stress conditions. Scanning electron microscopy showed the presence of perforations, irregular rod formations, and wrinkled extracellular surfaces in cells under TNT stress. Proteomic analysis of soluble protein fractions from HK-6 cultures grown with TNT as a substrate revealed 11 protein spots induced by TNT. Among these, seven proteins (including Alg8, AlgB, NirB, and the AhpC/Tsa family) were detected only in LB medium containing TNT. The proteins AspS, Tsf, and assimilatory nitrate reductase were increasingly expressed only in BS medium containing TNT. The protein dGTPase was found to be induced and expressed when cells were grown in either type of TNT-containing media. These results provide a better understanding of the cytotoxicity and survival mechanism used by Pseudomonas sp. HK-6 when placed under TNT stress conditions.     

Extracellular factors affecting the adhesion of Pseudomonas fluorescens cells to glass surface

Two factors affecting the adhesion of Pseudomonas fluorescens to glass surfaces were revealed in the culture liquid (CL) of this bacterium. One of these factors, adhesin, which is responsible for cell adhesion, was found to be a protein substance located both at the cell surface and in the CL. Bacterial cells grown in rich LB medium were less adhesive than cells grown in minimal M9 medium. The adhesive capacity of cells was independent of the growth phase. The other factor, anti-adhesion (AA), which reduces cell adhesion, was found only in the CL. AA concentration in the CL increased with the culture age.     

Source of tryptone in growth medium affects oxidative stress resistance in Escherichia coli

AIMS: To investigate the influence of the source of tryptone in the growth medium on the resistance of Escherichia coli to various types of oxidative stress. METHODS AND RESULTS: Cultures of Escherichia coli MG1655 were grown in Luria-Bertani (LB) medium at 37 degrees C to stationary phase, harvested, and subsequently subjected to various types of oxidative stress. A marked difference in oxidative stress sensitivity was observed depending on the origin of the tryptone in the LB medium used to grow the cultures. Cells harvested from LB containing tryptone from source x (LBx) were more sensitive to inactivation by the superoxide generating compound plumbagin and by t-butyl peroxide, and to growth inhibition by the lactoperoxidase enzyme system, than cells harvested from LB containing tryptone from source y (LBy). By monitoring expression of a panel of stress gene promotors linked to the gfp (green fluorescent protein) gene, and using Delta2-22 alkaline phosphatase as a probe for disulphide bridge formation from protein sulphydryl groups, it was demonstrated that a greater cytoplasmic oxidative stress existed in cells during growth in LBy than in LBx. CONCLUSIONS: Depending on the source of tryptone, bacteria may experience different levels of oxidative stress in tryptone-containing nonselective growth media. Although these levels of oxidative stress are subinhibitory, they may trigger a stress response that makes the bacteria more resistant to a subsequent exposure to a lethal or inhibitory level of oxidative stress. SIGNIFICANCE AND IMPACT OF THE STUDY: This work highlights the importance of controlling very subtle differences in composition of nonselective growth media in studies on bacterial physiology.     

Extracellular factors affecting the adhesion ofPseudomonas fluorescens cells to glass surfaces

Two factors affecting the adhesionof Pseudomonas fluorescens to glass surfaces were revealed in the culture liquid (CL) of this bacterium. One of these factors, adhesin, which is responsible for cell adhesion, was found to be a protein substance located both at the cell surface and in the CL. Bacterial cells grown in rich LB medium were less adhesive than cells grown in minimal M9 medium. The adhesive capacity of cells was independent of the growth phase. The other factor, antiadhesin (AA), which reduces cell adhesion, was found only in the CL. AA concentration in the CL increased with the culture age.     

Heat-induced expression and chemically induced expression of the Escherichia coli stress protein HtpG are affected by the growth environment.

Differences in expression of the Escherichia coli stress protein HtpG were found following exposure of exponentially growing cells to heat or chemical shock when cells were grown under different environmental conditions. With an htpG::lacZ reporter system, htpG expression increased in cells grown in a complex medium (Luria-Bertani [LB] broth) following a temperature shock at 45 degrees C. In contrast, no HtpG overexpression was detected in cells grown in a glucose minimal medium, despite a decrease in the growth rate. Similarly, in pyruvate-grown cells there was no heat shock induction of HtpG expression, eliminating the possibility that repression of HtpG in glucose-grown E. coli was due to catabolite repression. When 5 mM phenol was used as a chemical stress agent for cells growing in LB broth, expression of HtpG increased. However, when LB-grown cells were subjected to stress with 10 mM phenol and when both 5 and 10 mM phenol were added to glucose-grown cultures, repression of htpG expression was observed. 2-Chlorophenol stress resulted in overexpression of HtpG when cells were grown in complex medium but repression of HtpG synthesis when cells were grown in glucose. No induction of htpG expression was seen with 2, 4-dichlorophenol in cells grown with either complex medium or glucose. The results suggest that, when a large pool of amino acids and proteins is available, as in complex medium, a much stronger stress response is observed. In contrast, when cells are grown in a simple glucose mineral medium, htpG expression either is unaffected or is even repressed by imposition of a stress condition. The results demonstrate the importance of considering differences in growth environment in order to better understand the nature of the response to an imposed stress condition.     

Sequence, identification and effect on conjugation of the rmoA gene of plasmid R100-1

The rmoA gene was recently identified from two partially overlapping sequences corresponding to a region close to the end of the tra operon of plasmid R100. Its putative amino acid sequence showed strong homology to the Hha protein of Escherichia coli and YmoA protein of Yersinia enterocolitica, which are modulators of gene expression in response to environmental stimuli. We have cloned the rmoA gene from plasmid R100-1 in pUC19 and obtained the complete nucleotide sequence, which was previously published only partially and may have contained some mistakes. The rmoA gene product has been identified in radiolabelled minicells as a protein of the predicted molecular mass. The wild-type rmoA gene of plasmid R100-1 has been mutated by gene replacement and its effect on the efficiency of conjugation has been analysed. When grown in LB medium, cells harbouring R100-1 plasmid with a disrupted copy of rmoA showed a five-fold increase in conjugation frequency compared to cells harbouring R100-1 plasmid with the wild-type rmoA gene, grown in the same conditions. When cells were grown in NaCl-free LB medium they showed a 50-fold increase in conjugation frequency.     

A phosphate-stimulated NAD(P)+-dependent glyceraldehyde-3-phosphate dehydrogenase in Bacillus cereus

Glyceraldehyde-3-phosphate dehydrogenase (GAPDH), a key enzyme of central carbon metabolism, was studied in a Bacillus cereus strain isolated from the phosphate layer from Morocco. Enzymatic assays with cell extracts demonstrated that when grown on Luria-Bertani (LB) medium, B. cereus contains a major NAD+-dependent GAPDH activity and only traces of NADP+-dependent activity, but in cells grown on Pi-supplemented LB medium a strong increase of the NADP+-dependent activity, that became predominant, occurs concurrently with a GAPDH protein increase. Our results show that B. cereus possesses two GAPDH activities, namely NAD+- and NADP+-dependent, catalyzed by two enzymes with distinct coenzyme specificity and different phosphate regulation patterns. The finding of a phosphate-stimulated NADP+-dependent GAPDH in B. cereus indicates that this bacterium can modulate its primary carbon metabolism according to phosphate availability.     

The importance of Asn47 for structure and reactivity of azurin from Alcaligenes denitrificans as studied by site-directed mutagenesis and spectroscopy.

To study the importance of a rigid copper site for the structure and function of azurin, a mutant with a reduced number of internal hydrogen bonds around the copper has been prepared and characterized. To this purpose, the previously cloned azu gene from Alcaligenes denitrificans (Hoitink, C. W. G., Woudt, L. P., Turenhout, J. C. M., Van de Kamp, M., and Canters, G. W. (1990) Gene (Amst.) 90, 15-20) was expressed in Escherichia coli and an isolation and purification procedure for the azurin was developed. The azurin obtained after heterologous expression in E. coli appears spectroscopically indistinguishable from azurin derived from A. denitrificans. The hydrogen bonding network around the copper site was altered by replacing Asn47 by a leucine by means of site-directed mutagenesis. Asn47 is a conserved residue in all blue copper proteins of which the primary structure has been reported. Characterization of the mutant protein with UV-visible, electron spin resonance, and NMR spectroscopy, and comparison with the wild type azurin revealed that the structure of the copper site as well as the overall structure of the protein have been largely retained. The redox activity as measured by the electron self-exchange rate appears not to have changed either. However, the mutant differs from the wild type azurin with respect to stability and midpoint potential. Midpoint potentials of mutant and wild type azurin amount to 396 and 286 mV, respectively. The difference is due to sizable entropic and enthalpic contributions which to a large extent cancel. Possible explanations for the outcome of these experiments are discussed.