Obg, an essential GTP binding protein of Bacillus subtilis, is necessary for stress activation of transcription factor sigma(B).

sigma(B), the general stress response sigma factor of Bacillus subtilis, is activated when intracellular ATP levels fall or the bacterium experiences environmental stress. Stress activates sigma(B) by means of a collection of regulatory kinases and phosphatases (the Rsb proteins), which catalyze the release of sigma(B) from an anti-sigma factor inhibitor. By using the yeast dihybrid selection system to identify B. subtilis proteins that could interact with Rsb proteins and act as mediators of stress signaling, we isolated the GTP binding protein, Obg, as an interactor with several of these regulators (RsbT, RsbW, and RsbX). B. subtilis depleted of Obg no longer activated sigma(B) in response to environmental stress, but it retained the ability to activate sigma(B) by the ATP responsive pathway. Stress pathway components activated sigma(B) in the absence of Obg if the pathway's most upstream effector (RsbT) was synthesized in excess to the inhibitor (RsbS) from which it is normally released after stress. Thus, the Rsb proteins can function in the absence of Obg but fail to be triggered by stress. The data demonstrate that Obg, or a process under its control, is necessary to induce the stress-dependent activation of sigma(B) and suggest that Obg may directly communicate with one or more sigma(B) regulators.     

Stress activation of Bacillus subtilis sigma B can occur in the absence of the sigma B negative regulator RsbX.

Environmental stress activates sigma B, the general stress response sigma factor of Bacillus subtilis, by a pathway that is negatively controlled by the RsbX protein. To determine whether stress activation of sigma B occurs by a direct effect of stress on RsbX, we constructed B. subtilis strains which synthesized various amounts of RsbX or lacked RsbX entirely and subjected these strains to ethanol stress. Based on the induction of a sigma B-dependent promoter, stress activation of sigma B can occur in the absence of RsbX. Higher levels of RsbX failed to detectably influence stress induction, but reduced levels of RsbX resulted in greater and longer-lived sigma B activation. The data suggest that RsbX is not a direct participant in the sigma B stress induction process but rather serves as a device to limit the magnitude of the stress response.     

Reactivation of the Bacillus subtilis anti-sigma B antagonist, RsbV, by stress- or starvation-induced phosphatase activities.

sigma B is a secondary sigma factor that controls the general stress regulon in Bacillus subtilis. The regulon is activated when sigma B is released from a complex with an anti-sigma B protein (RsbW) and becomes free to associate with RNA polymerase. Two separate mechanisms cause sigma B release: an ATP-responsive mechanism that correlates with nutritional stress and an ATP-independent mechanism that responds to environmental insult (e.g., heat shock and ethanol treatment). ATP levels are thought to directly affect RsbW's binding preference. Low levels of ATP cause RsbW to release sigma B and bind to an alternative protein (RsbV), while high levels of ATP favor RsbW-sigma B complex formation and inactivation of RsbV by an RsbW-dependent phosphorylation. During growth, most of the RsbV is phosphorylated (RsbV-P) and inactive. Environmental stress induces the release of sigma B and the formation of the RsbW-RsbV complex, regardless of ATP levels. This pathway requires the products of additional genes encoded within the eight-gene operon (sigB) that includes the genes for sigma B, RsbW, and RsbV. By using isoelectric focusing techniques to distinguish RsbV from RsbV-P and chloramphenicol treatment or pulse-chase labeling to identify preexisting RsbV-P, we have now determined that stress induces the dephosphorylation of RsbV-P to reactivate RsbV. RsbV-P was also found to be dephosphorylated upon a drop in intracellular ATP levels. The stress-dependent and ATP-responsive dephosphorylations of RsbV-P differed in their requirements for the products of the first four genes (rsbR, -S, -T, and -U) of the sigB operon. Both dephosphorylation reactions required at least one of the genes included in a deletion that removed rsbR, -S, and -T; however, only an environmental insult required RsbU to reactivate RsbV.     

Protein-protein interactions that regulate the energy stress activation of sigma(B) in Bacillus subtilis

Sigma(B) is an alternative sigma factor that controls the general stress response in Bacillus subtilis. In the absence of stress, sigma(B) is negatively regulated by anti-sigma factor RsbW. RsbW is also a protein kinase which can phosphorylate RsbV. When cells are stressed, RsbW binds to unphosphorylated RsbV, produced from the phosphorylated form of RsbV by two phosphatases (RsbU and RsbP) which are activated by stress. We now report the values of the K(m) for ATP and the K(i) for ADP of RsbW (0.9 and 0.19 mM, respectively), which reinforce the idea that the kinase activity of RsbW is directly regulated in vivo by the ratio of these nucleotides. RsbW, purified as a dimer, forms complexes with RsbV and sigma(B) with different stoichiometries, i.e., RsbW(2)-RsbV(2) and RsbW(2)-sigma(B)(1). As determined by surface plasmon resonance, the dissociation constants of the RsbW-RsbV and RsbW-sigma(B) interactions were found to be similar (63 and 92 nM, respectively). Nonetheless, an analysis of the complexes by nondenaturing polyacrylamide gel electrophoresis in competition assays suggested that the affinity of RsbW(2) for RsbV is much higher than that for sigma(B). The intracellular concentrations of RsbV, RsbW (as a monomer), and sigma(B) measured before stress were similar (1.5, 2.6, and 0.9 micro M, respectively). After ethanol stress they all increased. The increase was greatest for RsbV, whose concentration reached 13 micro M, while those of RsbW (as a monomer) and sigma(B) reached 11.8 and 4.9 micro M, respectively. We conclude that the higher affinity of RsbW for RsbV than for sigma(B), rather than a difference in the concentrations of RsbV and sigma(B), is the driving force that is responsible for the switch of RsbW to unphosphorylated RsbV.     

Loss of ribosomal protein L11 blocks stress activation of the Bacillus subtilis transcription factor sigma(B)

sigma(B), the general stress response sigma factor of Bacillus subtilis, is activated when the cell's energy levels decline or the bacterium is exposed to environmental stress (e.g., heat shock, ethanol). Physical stress activates sigma(B) through a collection of regulatory kinases and phosphatases (the Rsb proteins) which catalyze the release of sigma(B) from an anti-sigma(B) factor inhibitor. The means by which diverse stresses communicate with the Rsb proteins is unknown; however, a role for the ribosome in this process was suggested when several of the upstream members of the sigma(B) stress activation cascade (RsbR, -S, and -T) were found to cofractionate with ribosomes in crude B. subtilis extracts. We now present evidence for the involvement of a ribosome-mediated process in the stress activation of sigma(B). B. subtilis strains resistant to the antibiotic thiostrepton, due to the loss of ribosomal protein L11 (RplK), were found to be blocked in the stress activation of sigma(B). Neither the energy-responsive activation of sigma(B) nor stress-dependent chaperone gene induction (a sigma(B)-independent stress response) was inhibited by the loss of L11. The Rsb proteins required for stress activation of sigma(B) are shown to be active in the RplK(-) strain but fail to be triggered by stress. The data demonstrate that the B. subtilis ribosomes provide an essential input for the stress activation of sigma(B) and suggest that the ribosomes may themselves be the sensors for stress in this system.     

Quantitative measurements of proton motive force and motility in Bacillus subtilis.

The protein motive force of metabolizing Bacillus subtilis cells was only slightly affected by changes in the external pH between 5 and 8, although the electrical component and the chemical component of the proton motive force contributed differently at different external pH. The electrical component of the proton motive force was very small at pH 5, and the chemical component was almost negligible at pH 7.5. At external pH values between 6 and 7.7, swimming speed of the cells stayed constant. Thus, either the electrical component or the chemical component of the proton motive force could drive the flagellar motor. When the proton motive force of valinomycin-treated cells was quantitatively decreased by increasing the external K+ concentration, the swimming speed of the cells changed in a unique way: the swimming speed was not affected until about--100 mV, then decreased linearly with further decrease in the proton motive force, and was almost zero at about--30 mV. The rotation rate of a flagellum, measured by a tethered cell, showed essentially the same characteristics. Thus, there are a threshold proton motive force and a saturating proton motive force for the rotation of the B. subtilis flagellar motor.     

Bacillus subtilis tolerance of moderate concentrations of rifampin involves the sigma(B)-dependent general and multiple stress response.

Low concentrations of the RNA polymerase inhibitor rifampin added to an exponentially growing culture of Bacillus subtilis led to an instant inhibition of growth. Survival experiments revealed that during the growth arrest the cells became tolerant to the antibiotic and the culture was able to resume growth some time after rifampin treatment. L-[(35)S]methionine pulse-labeled protein extracts were separated by two-dimensional polyacrylamide gel electrophoresis to investigate the change in the protein synthesis pattern in response to rifampin. The sigma(B)-dependent general stress proteins were found to be induced after treatment with the antibiotic. Part of the oxidative stress signature was induced as indicated by the catalase KatA and MrgA. The target protein of rifampin, the beta subunit (RpoB) of the DNA-dependent RNA polymerase, and the flagellin protein Hag belonging to the sigma(D) regulon were also induced. The rifampin-triggered growth arrest was extended in a sigB mutant in comparison to the wild-type strain, and the higher the concentration, the more pronounced this effect was. Activity of the RsbP energy-signaling phosphatase in the sigma(B) signal transduction network was also important for this protection against rifampin, but the RsbU environmental signaling phosphatase was not required. The sigB mutant strain was less capable of growing on rifampin-containing agar plates. When plated from a culture that had already reached stationary phase without previous exposure to the antibiotic during growth, the survival rate of the wild type exceeded that of the sigB mutant by a factor of 100. We conclude that the general stress response of B. subtilis is induced by rifampin depending on RsbP activity and that loss of SigB function causes increased sensitivity to the antibiotic.     

Nucleotide binding properties of cytosolic components required for expression of activity of the superoxide generating NADPH oxidase

The superoxide generating NADPH oxidase was studied in an SDS-activated cell-free system. This system requires the participation of both membranal and cytosolic components. Cytosol derived from elicited peritoneal guinea pig macrophages was fractionated by several nucleotide affinity chromatography procedures. Various such fractionations led to the separation of two distinct factors, both of which are necessary for the activation and/or activity of the superoxide-forming NADPH oxidase. One factor (sigma 2), bound to octyl, 2',5'-ADP-, 5'-ATP-, 5'-GTP-agarose and carboxymethyl-Sepharose but did not bind to hexyl, 5'-AMP-, 5'-ADP- and 5'-GDP-agarose. The other factor (sigma 1) did not bind to any of the above matrices. Subsequent elution of sigma 2 from 2',5'-ADP-agarose was effected by ATP, GTP and NADPH but not by NADH. Elution from GTP-agarose was by ATP and GTP but not by NADPH. Elution from ATP-agarose was by ATP, GTP and also, albeit weakly, by NADPH. The above results suggest that sigma 2 contains a site which recognizes the phosphate group at the ribose 2' position in adenosine, and a site that recognizes purine nucleotide triphosphates.     

H Efflux and Hexose Transport under Imposed Energy Status in Maize Root Tips

The relationship between changes in H⁺ flux and sugar transport in maize Zea mays L. DEA root tips have been investigated using two methods for controlling the cellular nucleotide level: (a) incubation in the presence of a glucose analog, the 2-deoxyglucose, which decreased the ATP level to less than 15% of its initial value within 60 minutes without changing the ADP and AMP levels; (b) an hypoxic treatment which also decreased the ATP level but with a concomitant rise in ADP and AMP. In both cases the rate of hexose transport was not modified until ATP had dropped to 70% of its initial value; then it decreased with the cellular ATP level. The residual uptake rate at very low ATP concentrations still represented 50% of the maximum rate with the dGlc treatment but only the diffusion rate in anoxia. H⁺ efflux was abolished in anoxia but not by the 2-deoxyglucose treatment, in spite of a lower cellular ATP concentration. Our results are consistent with an inhibition of H⁺-ATPase activity in anoxia by the high levels of cellular ADP and AMP, and provide in vivo evidence that sugar uptake is dependent upon the proton motive force rather than cellular ATP concentration. The absence of stimulation of H⁺ extrusion by ferricyanide in either normoxic or hypoxic conditions suggests that a redox system does not appear to contribute to H⁺ secretion under the conditions of this investigation.     

Relative levels and fractionation properties of Bacillus subtilis sigma(B) and its regulators during balanced growth and stress.

sigma B is a secondary sigma factor that controls the general stress response in Bacillus subtilis. sigma B-dependent genes are activated when sigma B is released from an inhibitory complex with an anti-sigma B protein (RsbW) and becomes free to associate with RNA polymerase. Two separate pathways, responding either to a drop in intracellular ATP levels or to environmental stress (e.g., heat, ethanol, or salt), cause the release of sigma B from RsbW. rsbR, rsbS, rsbT, and rsbU are four genes now recognized as the upstream half of an operon that includes sigB (sigma B) and its principal regulators. Using reporter gene assays, we find that none of these four genes are essential for stationary-phase (i.e., ATP-dependent) activation of sigma B, but rsbU and one or more of the genes contained within an rsbR,S,T deletion are needed for stress induction of sigma B. In other experiments, Western blot (immunoblot) analyses showed that the levels of RsbR, RsbS, Rsb, and RsbU, unlike those of the sigB operon's four downstream gene products (RsbV, RsbW, RsbX and sigma B), are not elevated during sigma B activation. Gel filtration and immunoprecipitation studies did not reveal the formation of complexes between any of the four upstream sigB operon products and the products of the downstream half of the operon. Much of the detectable RsbR, RsbS, RsbT, and RsbU did, however, fractionate as a large-molecular-mass (approximately 600-kDa) aggregate which was excluded from our gel filtration matrix. The downstream sigB operon products were not present in this excluded material. The unaggregated RsbR, RsbS, and RsbU, which were retarded by the gel matrix, elated from the column earlier than expected from their molecular weights. The RsbR and RsbS fractionation profile was consistent with homodimers (60 and 30 kDa, respectively), while the RsbU appeared larger, suggesting a protein complex of approximately 90 to 100 kDa.     

The plant uncoupling protein homologues: a new family of energy-dissipating proteins in plant mitochondria.

Uncoupling proteins (UCPs) form a subfamily within the mitochondrial carrier protein family, which catalyze a free fatty acid-mediated proton recycling and can modulate the tightness of coupling between mitochondrial respiration and ATP synthesis. As in mammalian tissues, UCPs are rather ubiquitous in the plant kingdom and widespread in plant tissues in which they could have various physiological roles, such as heat production or protection against free oxygen radicals. The simultaneous occurrence in plant mitochondria of two putative energy-dissipating systems, namely UCP which dissipates the proton motive force, and alternative oxidase (AOX) which dissipates the redox potential, raises the question of their functional interactions.