Role of ςB in Heat, Ethanol, Acid, and Oxidative Stress Resistance and during Carbon Starvation in Listeria monocytogenes

To determine the contribution of sigma B (ς^B) to survival of stationary-phase Listeria monocytogenes cells following exposure to environmental stresses, we compared the viability of strain 10403S with that of an isogenic nonpolar sigB null mutant strain after exposure to heat (50°C), ethanol (16.5%), or acid (pH 2.5). Strain viabilities were also determined under the same conditions in cultures that had been previously exposed to sublethal levels of the same stresses (45°C, 5% ethanol, or pH 4.5). The ΔsigB and wild-type strains had similar viabilities following exposure to ethanol and heat, but the ΔsigB strain was almost 10,000-fold more susceptible to lethal acid stress than its parent strain. However, a 1-h preexposure to pH 4.5 yielded a 1,000-fold improvement in viability for the ΔsigB strain. These results suggest the existence in L. monocytogenes of both a ς^B-dependent mechanism and a pH-dependent mechanism for acid resistance in the stationary phase. ς^B contributed to resistance to both oxidative stress and carbon starvation in L. monocytogenes. The ΔsigB strain was 100-fold more sensitive to 13.8 mM cumene hydroperoxide than the wild-type strain. Following glucose depletion, the ΔsigB strain lost viability more rapidly than the parent strain. ς^B contributions to viability during carbon starvation and to acid resistance and oxidative stress resistance support the hypothesis that ς^B plays a role in protecting L. monocytogenes against environmental adversities.     

Polyamines Stimulate the Level of the σ38 Subunit (RpoS) of Escherichia coli RNA Polymerase,Resulting in the Induction of the Glutamate Decarboxylase-dependent Acid Response System via the gadE Regulon

To study the physiological roles of polyamines, we carried out a global microarray analysis on the effect of adding polyamines to an Escherichia coli mutant that lacks polyamines because of deletions in the genes in the polyamine biosynthetic pathway. Previously, we have reported that the earliest response to polyamine addition is the increased expression of the genes for the glutamate-dependent acid resistance system (GDAR). We also presented preliminary evidence for the involvement of rpoS and gadE regulators. In the current study, further confirmation of the regulatory roles of rpoS and gadE is shown by a comparison of genome-wide expression profiling data from a series of microarrays comparing the genes induced by polyamine addition to polyamine-free rpoS⁺/gadE⁺ cells with genes induced by polyamine addition to polyamine-free ΔrpoS/gadE⁺ and rpoS⁺/ΔgadE cells. The results indicate that most of the genes in the E. coli GDAR system that are induced by polyamines require rpoS and gadE. Our data also show that gadE is the main regulator of GDAR and other acid fitness island genes. Both polyamines and rpoS are necessary for the expression of gadE gene from the three promoters of gadE (P1, P2, and P3). The most important effect of polyamine addition is the very rapid increase in the level of RpoS sigma factor. Our current hypothesis is that polyamines increase the level of RpoS protein and that this increased RpoS level is responsible for the stimulation of gadE expression, which in turn induces the GDAR system in E. coli.     

Role of Listeria monocytogenes σB in Survival of Lethal Acidic Conditions and in the Acquired Acid Tolerance Response

The food-borne pathogen Listeria monocytogenes can acquire enhanced resistance to lethal acid conditions through multiple mechanisms. We investigated contributions of the stress-responsive alternative sigma factor, σ^B, which is encoded by sigB, to growth phase-dependent acid resistance (AR) and to the adaptive acid tolerance response in L. monocytogenes. At various points throughout growth, we compared the relative survival of L. monocytogenes wild-type and ΔsigB strains that had been exposed to either brain heart infusion (pH 2.5) or synthetic gastric fluid (pH 2.5) with and without prior acid adaptation. Under these conditions, survival of the ΔsigB strain was consistently lower than that of the wild-type strain throughout all phases of growth, ranging from 4 orders of magnitude less in mid-log phase to 2 orders of magnitude less in stationary phase. Survival of both ΔsigB and wild-type L. monocytogenes strains increased by 6 orders of magnitude upon entry into stationary phase, demonstrating that the L. monocytogenes growth phase-dependent AR mechanism is σ^B independent. σ^B-mediated contributions to acquired acid tolerance appear to be greatest in early logarithmic growth. Loss of a functional σ^B reduced the survival of L. monocytogenes at pH 2.5 to a greater extent in the presence of organic acid (100 mM acetic acid) than in the presence of inorganic acid alone (HCl), suggesting that L. monocytogenes protection against organic and inorganic acid may be mediated through different mechanisms. σ^B does not appear to contribute to pH_i homeostasis through regulation of net proton movement across the cell membrane or by regulation of pH_i buffering by the GAD system under the conditions examined in this study. In summary, a functional σ^B protein is necessary for full resistance of L. monocytogenes to lethal acid treatments.     

Proton Electrochemical Gradients in Washed Cells of Nitrosomonas europaea and Nitrobacter agilis

The components of the proton motive force (Δp), namely, membrane potential (Δψ) and transmembrane pH gradient (ΔpH), were determined in the nitrifying bacteria Nitrosomonas europaea and Nitrobacter agilis. In these bacteria both Δψ and ΔpH were dependent on external pH. Thus at pH 8.0, Nitrosomonas europaea and Nitrobacter agilis had Δψ values of 173 mV and 125 mV (inside negative), respectively, as determined by the distribution of the lipophilic cation [³H]tetraphenyl phosphonium. Intracellular pH was determined by the distribution of two weak acids, ¹⁴C-benzoic and ¹⁴C-acetyl salicylic, and the weak base [¹⁴C]methylamine. Nitrosomonas europaea accumulated ¹⁴C-benzoic acid and ¹⁴C-acetyl salicylic acid when the external pH was below 7.0 and [¹⁴C]methylamine at alkaline pH. Similarly, Nitrobacter agilis accumulated the two weak acids below an external pH of about 7.5 and [¹⁴C]methylamine above this pH. As these bacteria grow best between pH 7.5 and 8.0, they do not appear to have a ΔpH (inside alkaline). Thus, above pH 7.0 for Nitrosomonas europaea and pH 7.5 for Nitrobacter agilis, Δψ only contributed to Δp. In Nitrosomonas europaea the total Δp remained almost constant (145 to 135 mV) when the external pH was varied from 6 to 8.5. In Nitrobacter agilis, Δp decreased from 178 mV (inside negative) at pH 6.0 to 95 mV at pH 8.5. Intracellular pH in Nitrosomonas europaea varied from 6.3 at an external pH of 6.0 to 7.8 at external pH 8.5. In Nitrobacter agilis, however, intracellular pH was relatively constant (7.3 to 7.8) over an external pH range of 6 to 8.5. In Nitrosomonas europaea, Δp and its components (Δψ and ΔpH) remained constant in cells at various stages of growth, so that the metabolic state of cells did not affect Δp. Such an experiment was not possible with Nitrobacter agilis because of low cell yields. The effects of protonophores and ATPase inhibitors on ΔpH and Δψ in the two nitrifying bacteria are considered.     

Proteomic Analysis of the Function of Sigma Factor σ54 in Helicobacter pylori Survival with Nutrition Deficiency Stress In Vitro

H. pylori can survive under a nutrition-deficient environment. During infection and transmission, H. pylori is confronted with nutrient limitation and the bacterium requires rapid alteration in gene expression for survival under stress conditions. However, the mechanism underlining this regulation remains unknown. A previous study showed that σ⁵⁴ is an important regulation factor for H. pylori survival in the nutrition-deficient environment. Our results show that the expression of σ⁵⁴ (rpoN) is significantly induced in the stationary phase (nutrition deficiency) and the rpoN mutant showed a significantly lower viability than wild-type H. pylori in the late stationary phase. Thus, σ⁵⁴ is involved in H. pylori survival during nutrient limitation. We used comparative proteomics to analyze the protein differentiation between wild-type and rpoN mutant during the stationary phase. With depleted nutrients, σ⁵⁴ can slow the process of proliferation by negatively regulating genes involved in energy metabolism and biosynthesis and enhance stress-resistant ability by positively regulating genes involved in protein fate and redox reaction. Especially, NapA positively regulated by σ⁵⁴ plays an important function in H. pylori survival both in the stationary phase and in water, and the latter situation would be beneficial for bacterial in vitro transmission. Our investigations give new light on the adaptive regulation of H. pylori under stress conditions.     

The yhhP Gene Encoding a Small Ubiquitous Protein Is Fundamental for Normal Cell Growth of Escherichia coli

H-NS is a major constituent of the Escherichia coli nucleoid, whereas ς^S is a stress-induced sigma factor. An hns null mutation affects the cellular content of ς^S in such a way that a remarkable accumulation of ς^S is observed in the logarithmic growth phase, which results in enhanced expression of a number of ς^S-dependent genes, including the katE gene. We isolated an extragenic mutation that affects the expression of the katE-lacZ fusion gene in the Δhns background. The relevant gene was identified as yhhP, which encodes a small polypeptide of 81 amino acids. Lesion of this gene seemed to affect the stability of ς^S. A deletion analysis of yhhP revealed that this small protein plays a fundamental role in the general physiology of E. coli. The yhhP-deficient cell is not capable of growing in standard laboratory rich medium (i.e., Luria broth), resulting in the formation of filamentous cells. Homologs of this intriguing protein occur in a wide variety of bacterial species, including archaeal species.     

Interactions between the 2.4 and 4.2 regions of sigmaS, the stress-specific sigma factor of Escherichia coli, and the -10 and -35 promoter elements

The σ^s subunit of Escherichia coli RNA polymerase holoenzyme (Eσ^S) is a key factor of gene expression upon entry into stationary phase and in stressful conditions. The selectivity of promoter recognition by Eσ^S and the housekeeping Eσ⁷⁰ is as yet not clearly understood. We used a genetic approach to investigate the interaction of σ^S with its target promoters. Starting with down-promoter variants of a σ^S promoter target, osmEp, altered in the –10 or –35 elements, we isolated mutant forms of σ^S suppressing the promoter defects. The activity of these suppressors on variants of osmEp and ficp, another target of σ^S, indicated that σ^S is able to interact with the same key features within a promoter sequence as σ⁷⁰. Indeed, (i) σ^S can recognize the –35 element of some but not all its target promoters, through interactions with its 4.2 region; and (ii) amino acids within the 2.4 region participate in the recognition of the –10 element. More specifically, residues Q152 and E155 contribute to the strong preference of σ^S for a C in position –13 and residue R299 can interact with the –31 nucleotide in the –35 element of the target promoters.     

Chronic Ethanol Consumption-induced Pancreatic β-Cell Dysfunction and Apoptosis through Glucokinase Nitration and Its Down-regulation

Chronic ethanol consumption is known as an independent risk factor for type 2 diabetes, which is characterized by impaired glucose homeostasis and insulin resistance; however, there is a great deal of controversy concerning the relationships between alcohol consumption and the development of type 2 diabetes. We investigated the effects of chronic ethanol consumption on pancreatic β-cell dysfunction and whether generated peroxynitrite participates in the impaired glucose homeostasis. Here we show that chronic ethanol feeding decreases the ability of pancreatic β-cells to mediate insulin secretion and ATP production in coordination with the decrease of glucokinase, Glut2, and insulin expression. Specific blockade of ATF3 using siRNA or C-terminally deleted ATF3(ΔC) attenuated ethanol-induced pancreatic β-cell apoptosis or dysfunction and restored the down-regulation of glucokinase (GCK), insulin, and pancreatic duodenal homeobox-1 induced by ethanol. GCK inactivation and down-regulation were predominantly mediated by ethanol metabolism-generated peroxynitrite, which were suppressed by the peroxynitrite scavengers N^γ-monomethyl-l-arginine, uric acid, and deferoxamine but not by the S-nitrosylation inhibitor DTT, indicating that tyrosine nitration is the predominant modification associated with GCK down-regulation and inactivation rather than S-nitrosylation of cysteine. Tyrosine nitration of GCK prevented its association with pBad, and GCK translocation into the mitochondria results in subsequent proteasomal degradation of GCK following ubiquitination. This study identified a novel and efficient pathway by which chronic ethanol consumption may induce GCK down-regulation and inactivation by inducing tyrosine nitration of GCK, resulting in pancreatic β-cell apoptosis and dysfunction. Peroxynitrite-induced ATF3 may also serve as a potent upstream regulator of GCK down-regulation and β-cell apoptosis.     

Electrogenic transport of protons driven by the plasma membrane ATPase in membrane vesicles from radish : biochemical characterization

Mg:ATP-dependent H⁺ pumping has been studied in microsomal vesicles from 24-hour-old radish (Raphanus sativus L.) seedlings by monitoring both intravesicular acidification and the building up of an inside positive membrane potential difference (Δ ψ). ΔpH was measured as the decrease of absorbance of Acridine orange and Δ ψ as the shift of absorbance of bis(3-propyl-5-oxoisoxazol-4-yl)pentamethine oxonol. Both Mg:ATP-dependent Δ pH and Δ ψ generation are completely inhibited by vanadate and insensitive to oligomycin; moreover, Δ pH generation is not inhibited by NO₃⁻. These findings indicate that this membrane preparation is virtually devoid of mitochondrial and tonoplast H⁺-ATPases. Both intravesicular acidification and Δ ψ generation are influenced by anions: Δ pH increases and Δ ψ decreases following the sequence SO₄²⁻, Cl⁻, Br⁻, NO₃⁻. ATP-dependent H⁺ pumping strictly requires Mg²⁺. It is very specific for ATP (apparent K_m 0.76 millimolar) compared to GTP, UTP, CTP, ITP. Δ pH generation is inhibited by CuSO₄ and diethylstilbestrol as well as vanadate. Δ pH generation is specificially stimulated by K⁺ (+ 80%) and to a lesser extent by Na⁺ and choline (+28% and +14%, respectively). The characteristics of H⁺ pumping in these microsomal vesicles closely resemble those described for the plasma membrane ATPase partially purified from several plant materials.     

Influence of Transepithelial Potential Difference on the Sodium Uptake at the Outer Surface of the Isolated Frog Skin

The unidirectional uptake of sodium across the outer surface of the isolated frog skin (J₁₂^Na) was measured in the presence of transepithelial potential difference (Δ_ψ) ranging from +100 to -100 mV. With a sodium concentration of 115 mM in the bathing solutions J₁₂^Na increases significantly when the spontaneous Δ_ψ is reduced to zero by short-circuiting the skin. With an Na concentration of 6 mM a progressive increase J₁₂^Na can be observed when Δ_ψ is decreased in several steps from +100 to -100 mV (serosal side positive and negative, respectively). The observed change J₁₂^Na amounts to a fraction only of that predicted from the shift in Δ_ψ. The results suggest that under open circuit conditions the potential step across the outside surface is at most one half of Δ_ψ and that the resistance across the outside and inside barrier of the skin is ohmic. This is in agreement with measurements of intracellular potentials in the frog skin and with resistance measurements carried out in the toad skin. The data strongly support the view that the saturating component of J_ψ proceeds via a charged carrier system. Exposure to negative values of Δ_ψ of 50 mV or more for times of 24 min or more result in a marked reduction of J₁₂^Na which shows only partial or no reversibility.     

Vibrio fischeri σ54 Controls Motility, Biofilm Formation, Luminescence, and Colonization

In this study, we demonstrated that the putative Vibrio fischeri rpoN gene, which encodes σ⁵⁴, controls flagellar biogenesis, biofilm development, and bioluminescence. We also show that rpoN plays a requisite role initiating the symbiotic association of V. fischeri with juveniles of the squid Euprymna scolopes.     

Chaperone Hsp31 Contributes to Acid Resistance in Stationary-Phase Escherichia coli

Hsp31, the product of the σ^S- and σ^D-dependent hchA gene, is a heat-inducible chaperone implicated in the management of protein misfolding at high temperatures. We show here that Hsp31 plays an important role in the acid resistance of starved Escherichia coli but that it has little influence on oxidative-stress survival.