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. 2003 Nov 11;100(23):13603-8.
doi: 10.1073/pnas.2235180100. Epub 2003 Nov 3.

Spx-dependent global transcriptional control is induced by thiol-specific oxidative stress in Bacillus subtilis

Shunji Nakano  1 Elke Küster-SchöckAlan D GrossmanPeter Zuber
Affiliations

Spx-dependent global transcriptional control is induced by thiol-specific oxidative stress in Bacillus subtilis

Shunji Nakano et al. Proc Natl Acad Sci U S A. .

Abstract

The Spx protein of Bacillus subtilis represses activator-stimulated transcription by interacting with the C-terminal domain of RNA polymerase (RNAP) alpha subunit. Its concentration increases in cells lacking the ATP-dependent protease, ClpXP, resulting in severe effects on growth and developmental processes. Microarray analysis was undertaken to identify genes that are induced or repressed when Spx interacts with RNAP. The induced genes included those encoding products known to function in maintaining thiol homeostasis. Two genes, thioredoxin (trxA) and thioredoxin reductase (trxB), are transcriptionally induced under conditions of thiol-specific oxidative (disulfide) stress by a mechanism involving Spx-RNAP interaction. Disulfide stress also results in an increase in Spx-dependent transcriptional repression. The increase in Spx activity in cells encountering disulfide stress is due in part to a posttranscriptional mechanism of spx control resulting in an increase in Spx concentration. An spx null mutant and a strain bearing an allele of rpoA that prevents Spx-RNAP interaction show hypersensitivity to disulfide stress. From these results, it is proposed that Spx is an activator that mobilizes the operations necessary to reverse the effects of oxidative damage, but it also serves as a negative regulator that causes the postponement of developmental programs and energy-consuming growth-related functions while the cell copes with the period of stress.

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Figures

Fig. 1.
Fig. 1.
Protease-resistant SpxDD and its effect on srf-lacZ expression. (A) Amino acid sequence of Spx showing the location of the 2-Asp (DD) substitution at the C terminus. The CXXC motif is underlined. (B) Coomasssie-stained SDS-polyacrylamide gel of ClpXP proteolysis reactions containing either WT Spx protein or mutant SpxDD. Time of incubation is shown at the bottom. (C) Western blot analysis of whole-cell extracts obtained from cultures of the following strains: ORB4271 (amyE::pMMN521 [Pspank-hy-spx]), lanes marked spx; ORB4342 (amyE::pSN56 [Pspank-hy-spxDD]), lanes marked spxDD; ORB4343 (amyE::pSN56 rpoAcxs-1), lanes marked spxDD rpoAcxs-1. Marker (M) band is lysozyme (20.8 kDa). (D) Expression of transcriptional srf-lacZ over time in ORB4349 (srfA-lacZ [pMMN84] amyE::pSN56, circle) and ORB4353 (srfA-lacZ [pMMN84] amyE::pSN56, rpoAcxs-1, square) grown in DSM. The cultures were split at OD 600 = 0.5 at time 0 and grown in the absence (open symbols) or presence (filled symbols) of 1 mM IPTG. The x axis represents the time (h) of incubation after the addition of IPTG.
Fig. 2.
Fig. 2.
Effects of diamide, spx, and rpoAcxs-1 on the levels of trxA, trxB, srf, and yocJ transcripts. (A) Primer extension analysis of trxA, trxB, srf, and yocJ transcripts in RNA from cultures grown in TSS and treated with 1 mM diamide after midlogarithm phase. RNA was purified from strains JH642 (WT), ORB3834 (spx::neo), and ORB3621 (rpoAcxs-1). Time after diamide addition in minutes is shown at the bottom. The left lanes show gel profile of A and T specific sequencing reactions. (B) Western analysis, by using anti-Spx antiserum, of Spx protein concentration in cells of strains JH642 (WT) and ORB3621 (rpoAcxs-1) treated with diamide as described in A. Marker (M) band is lysozyme (20.8 kDa). (C) Primer extension analysis of trxA, trxB, srf, and yocJ transcripts in RNA from cultures of strain ORB4533 (spx::neo amyE::pMMN521 [Pspank-hy-spx]) grown in TSS with and without 0.1 mM IPTG and treated with 1 mM diamide at midlogarithm phase. Time after diamide treatment in minutes is indicated at the bottom. Left lanes show gel profiles of A and T specific sequencing reactions. (D) Western blot analysis of Spx protein from cultures of strain ORB4533 grown in TSS with or without IPTG and treated with diamide. Time after diamide treatment in minutes is indicated at bottom.
Fig. 3.
Fig. 3.
Localization of the transcriptional start sites of trxB and yocJ. Cells of JH642 were grown in TSS medium to midlogarithm, and the cultures were split. Diamide was added to one culture. Cells were harvested after 30 min, and RNA was purified for primer extension reaction. Primer extension products by using the primer specifying the trxB transcript and the yocJ transcript, respectively, are shown. Lane 1, -diamide; lane 2, +diamide. Four lanes on the left in A and B are the gel profiles of sequencing reactions A, G, C, and T.
Fig. 4.
Fig. 4.
Sensitivity of spx and rpoAcxs-1 cells to diamide. Cells of strains JH642 (WT), ORB3834 (spx::neo), and ORB3621(rpoAcxs-1) were streaked onto DSM plates with (top) or without (bottom) 50 μM diamide.
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