Genetic responses against nitric oxide toxicity

The threat of free radical damage is opposed by coordinated responses that modulate expression of sets of gene products. In mammalian cells, 12 proteins are induced by exposure to nitric oxide (NO) levels that are sub-toxic but exceed the level needed to activate guanylate cyclase. Heme oxygenase 1 (HO-1) synthesis increases substantially, due to a 30- to 70-fold increase in the level of HO-1 mRNA. HO-1 induction is cGMP-independent and occurs mainly through increased mRNA stability, which therefore indicates a new NO-signaling pathway. HO-1 induction contributes to dramatically increased NO resistance and, together with the other inducible functions, constitutes an adaptive resistance pathway that also defends against oxidants such as H2O2. In E. coli, an oxidative stress response, the soxRS regulon, is activated by direct exposure of E. coli to NO, or by NO generated in murine macrophages after phagocytosis of the bacteria. This response is governed by the SoxR protein, a homodimeric transcription factor (17-kDa subunits) containing [2Fe-2S] clusters essential for its activity. SoxR responds to superoxide stress through one-electron oxidation of the iron-sulfur centers, but such oxidation is not observed in reactions of NO with SoxR. Instead, NO nitrosylates the iron-sulfur centers of SoxR both in vitro and in intact cells, which yields a form of the protein with maximal transcriptional activity. Although nitrosylated SoxR is very stable in purified form, the spectroscopic signals for the nitrosylated iron-sulfur centers disappear rapidly in vivo, indicating an active process to reverse or eliminate them.

Role for the oxyS gene in regulation of intracellular hydrogen peroxide in Escherichia coli

Intracellular hydrogen peroxide is regulated in Escherichia coli by OxyR in response to the metabolic production of H2O2. Here, we show that the untranslated oxyS RNA controlled by OxyR has a role in this regulation. The oxyS transcript appears to affect the metabolic output of H2O2 rather than the removal of H2O2 by catalases-hydroperoxidases.

Transcriptional regulation via redox-sensitive iron-sulphur centres in an oxidative stress response

Genetic responses to oxidative stress are triggered by excessive levels of agents such as superoxide. The soxRS regulon of Escherichia coli includes at least a dozen oxidative-stress and antibiotic-resistance genes that are activated by the SoxS protein, the synthesis of which is controlled by the redox-sensing SoxR protein. SoxR is a homodimer of 17 kDa subunits, each of which contains a [2Fe-2S] cluster. Transcriptional activation by SoxR is controlled by the oxidation state of these metal centres. In the absence of oxidative stress, the [2Fe-2S] centres are in the reduced form and the protein is inactive, although it still binds the soxS promoter. Agents that generate superoxide in the cell (e.g. paraquat) cause rapid oxidation of the metal centres, which triggers the transcriptional activity of SoxR; removal of the oxidative stress is followed by rapid re-reduction of the [2Fe-2S] centres. This facile mechanism links oxidation state to control of protein activity and may be used widely to allow cells to respond to oxidative stress.

Adaptive resistance to nitric oxide in motor neurons

Nitric oxide (NO) is a free radical produced actively by mammalian cells, including neurons. Low levels of NO can function in intercellular signaling, but high levels are cytotoxic. This cytotoxic potential suggests that cells at risk for NO damage, such as neurons, might have NO resistance mechanisms to prevent cell death, and adaptive resistance to NO-releasing compounds has been reported for some non-neuronal cell types. Here we show that immortalized mouse motor neurons (NSC34 cells) respond to sub-lethal fluxes of pure NO by activating adaptive resistance mechanisms that counteract cytotoxic NO exposure. This adaptive NO resistance is reversible and is paralleled by the induction of the oxidative stress enzyme heme oxygenase 1 (HO-1). An inhibitor of both HO-1 and heme-dependent guanylate cyclase (tin-protoporphyrin IX) greatly sensitized NO-pretreated NSC34 cells to the NO challenge. However, readdition of cyclic GMP (in the form of the 8-bromo derivative) restored rather little resistance, and a more selective guanylate cyclase inhibitor, 1H-[1,2,4]oxadiazolo[4,3-alpha]quinoxaline-1-one (at 10 microM), did not have the sensitizing effect. Therefore, the inducible HO-1 pathway contributes substantially to adaptive NO resistance, while cyclic GMP seems to play at most a small role. A similar adaptive resistance to NO was observed in primary rat spinal chord motor neurons. The activation of NO resistance in motor neurons may counteract age- or disease-related neurodegeneration.

Removal by human apurinic/apyrimidinic endonuclease 1 (Ape 1) and Escherichia coli exonuclease III of 3'-phosphoglycolates from DNA treated with neocarzinostatin, calicheamicin, and gamma-radiation

DNA strand breaks with terminal 3'-phosphoglycolate groups are produced by agents that can abstract the hydrogen atom from the 4'-carbon of DNA deoxyribose groups. Included among these agents are gamma-radiation (via the OH radical) and enediyne compounds, such as neocarzinostatin and calicheamicin. However, while the majority of radiation-induced phosphoglycolates are found at single-strand breaks, most of the phosphoglycolates generated by these two enediynes are found at bistranded lesions, including double-strand breaks. Using a 32P-post-labelling assay, we have compared the enzyme-catalyzed removal of phosphoglycolates induced by each of these agents. Both human apurinic/apyrimidinic endonuclease 1 (Ape 1) and its Escherichia coli homolog exonuclease III rapidly removed over 80% of phosphoglycolates from gamma-irradiated DNA, although there appeared to be a small resistant subpopulation. The neocarzinostatin-induced phosphoglycolates were removed more slowly, though not to completion, while the calicheamicin-induced phosphoglycolates were extremely refractory to both enzymes. These data suggest that unless other enzymes are capable of acting upon the phosphoglycolate termini at enediyne-induced double-strand breaks, such termini will be resistant to end rejoining repair pathways.

Radical ideas: genetic responses to oxidative stress

1. Complex genetic systems counteract different types of 'oxidative stress' caused by reactive derivatives of oxygen. 2. The bacterial oxyR system responds to peroxide stress and is governed by OxyR, a transcription factor activated by the formation of an intramolecular disulphide bond in H2O2-treated cells. Activated OxyR switches on several genes encoding antioxidant functions, such as catalase. During aerobic growth, oxyR acts homeostatically to regulate cellular H2O2 levels. 3. The bacterial soxRS system responds to superoxide or nitric oxide (NO) stress and is activated in two transcriptional stages. The SoxR protein is activated by oxidation of its [2Fe-2S] centres in cells exposed to superoxide-generating agents, such as paraquat, or to No. Activated SoxR stimulates the soxS gene and SoxS protein then induces at least 15 genes encoding antioxidant functions, such as superoxide dismutase, metabolic functions, such as fumarase, and antibiotic resistance by activation of efflux pumps. The soxRS system may function in resistance to NO-generating immune cells and may contribute to clinical antibiotic resistance. 4. Human cells respond to subtoxic levels of NO by inducing 12 proteins and down-regulating others. A key induced activity is haem oxygenase 1, which is controlled post-transcriptionally. 5. Motor neurons exhibit adaptive resistance to NO, triggered by exposure to subtoxic NO levels, and providing resistance to usually cytotoxic levels of this agent or H2O2. Adaptive resistance to NO depends strongly on the inducible heam oxygenase activity.

Thiol-mediated disassembly and reassembly of [2Fe-2S] clusters in the redox-regulated transcription factor SoxR

SoxR, a transcription factor containing [2Fe-2S] clusters, governs the cellular response to oxidative stress in Escherichia coli. The oxidation state of the iron-sulfur clusters regulates the SoxR transcriptional activity. When the reduced iron-sulfur clusters become oxidized ([2Fe-2S]2+ state), SoxR is activated to stimulate transcription of the soxS gene, whose product in turn switches on a group of genes encoding various proteins that defend against oxidative stress and antibiotics. A previous study showed that the oxidized [2Fe-2S] clusters of SoxR are destroyed by a free-radical-dependent process in vitro during aerobic exposure to the biological thiol glutathione. Here, we show that different thiols have differing effects on the SoxR [2Fe-2S] clusters. Like reduced glutathione, N-acetyl-L-cysteine, L-cysteine methyl ester, and L-cysteine ethyl ester disrupted the SoxR [2Fe-2S] clusters in aerobic solution. This disruption was blocked by L-cysteine, which was effective at concentrations 100-fold lower (1-10 microM) than the disrupting thiols (1 mM). In view of a previous observation that superoxide dismutase and catalase block the disruption process, this result suggests that L-cysteine may quench reactive SoxR or thiol intermediates involved in the cluster disruption reaction, the detailed mechanism of which remains unknown. In contrast, bifunctional thiols such as dithiothreitol or dithioerythritol promoted the aerobic assembly of the functional [2Fe-2S] clusters into apo-SoxR in the presence of Fe2+ and inorganic sulfide. The dithiol protein thioredoxin-A of E. coli acted catalytically in vitro in the presence of thioredoxin reductase and NADPH to promote [2Fe-2S] cluster assembly into apo-SoxR. The regulatory activity of SoxR in vivo, assessed by monitoring the paraquat-mediated induction of a soxS'::lacZ reporter fusion, was significantly lower in a strain lacking both thioredoxin-A and glutathione reductase, which maintains reduced glutaredoxins. Thus, cellular monothiols and dithiol proteins may contribute to SoxR regulation by affecting the disassembly and reassembly of the [2Fe-2S] clusters.

Dynamics of the interaction of human apurinic endonuclease (Ape1) with its substrate and product

We investigated the interaction dynamics of human abasic endonuclease, the Ape1 protein (also called Ref1, Hap1, or Apex), with its DNA substrate and incised product using electrophoretic assays and site-specific amino acid substitutions. Changing aspartate 283 to alanine (D283A) left 10% residual activity, contrary to a previous report, but complementation of repair-deficient bacteria by the D283A Ape1 protein was consistent with its activity in vitro. The D308A, D283/D308A double mutant, and histidine 309 to asparagine proteins had 22, 1, and approximately 0. 02% of wild-type Ape1 activity, respectively. Despite this range of enzymatic activities, all the mutant proteins had near-wild-type binding affinity specific for DNA containing a synthetic abasic site. Thus, substrate recognition and cleavage are genetically separable steps. Both the wild-type and mutant Ape1 proteins bound strongly to the enzyme incision product, an incised abasic site, which suggested that Ape1 might exhibit product inhibition. The use of human DNA polymerase beta to increase Ape1 activity by eliminating the incision product supports this conclusion. Notably, the complexes of the D283A, D308A, and D283A/D308A double mutant proteins with both intact and incised abasic DNA were significantly more stable than complexes containing wild-type Ape1, which may contribute to the lower turnover numbers of the mutant enzymes. Wild-type Ape1 protein bound tightly to DNA containing a one-nucleotide gap but not to DNA with a nick, consistent with the proposal that substrate recognition by Ape1 involves a space bracketed by duplex DNA, rather than mere flexibility of the DNA.

Rapid dissociation of human apurinic endonuclease (Ape1) from incised DNA induced by magnesium

Repair of apurinic/apyrimidinic (AP) sites is initiated by AP endonucleases, such as the human Ape1 protein (also called Hap1, Apex, and Ref1). This and related enzymes show strong dependence on divalent cations, particularly magnesium. Here we explore the role of this metal in different stages of the Ape1 reaction: substrate binding, cleavage, and product release. We examined DNA binding using an electrophoretic approach and DNA cleavage in single-turnover and steady-state reactions. Magnesium at low to moderate concentrations accelerated both substrate and product release by wild-type Ape1 protein. For a mutant Ape1 protein with an aspartate to alanine substitution at residue 308, substrate in preformed protein-DNA complexes was more efficiently cleaved before release in contrast to wild-type Ape1, whereas product release was accelerated dramatically. The magnesium dependence of steady-state AP endonuclease reactions was sigmoidal for both wild-type and the aspartate 308 to alanine protein but was not sigmoidal for an aspartate 283 to alanine derivative of Ape1. These results show that magnesium affects both DNA interactions with and phosphodiester cleavage by Ape1 and can change the rate-limiting step of the reaction. Structural studies will need to be interpreted in the context of these diverse effects of the metal.

Excision of C-4'-oxidized deoxyribose lesions from double-stranded DNA by human apurinic/apyrimidinic endonuclease (Ape1 protein) and DNA polymerase beta

Oxidative damage to DNA deoxyribose generates oxidized abasic sites (OAS) that may constitute one-third of ionizing radiation damage. The antitumor drug bleomycin produces exclusively OAS in the form of C-4-keto-C-1-aldehydes in unbroken DNA strands and 3'-phosphoglycolate esters terminating strand breaks. We investigated whether two human DNA repair enzymes can mediate OAS excision in vitro: Ape1 protein (the main human abasic endonuclease (also called Hap1, Apex, or Ref1)) and DNA polymerase beta, which carries out both the abasic excision and the resynthesis steps. We used a duplex oligonucleotide substrate with one main target for bleomycin-induced damage. Ape1 catalyzed effective incision at the C-4-keto-C-1-aldehyde sites at a rate that may be only a few-fold lower than incision of hydrolytic abasic sites at the same location. Consistent with several previous studies, Ape1 hydrolyzed 3'-phosphoglycolates 25-fold more slowly than C-4-keto-C-1-aldehydes. DNA polymerase beta excised the 5'-terminal OAS formed by Ape1 incision at a rate similar to its removal of unmodified abasic residues. Polymerase beta-mediated excision of 5'-terminal OAS was stimulated by Ape1 as it is for unmodified abasic sites. Escherichia coli Fpg (MutM) protein also excised 5'-terminal OAS, but in our hands, the RecJ protein did not. These observations help define mammalian pathways of OAS repair, point to interactions that might coordinate functional steps, and suggest that still unknown factors may contribute to removal of 3'-phosphoglycolate esters.

Complex genetic response of human cells to sublethal levels of pure nitric oxide

NO is a biologically generated free radical that serves diverse roles in mammalian cell signaling and immune-mediated cell killing. Because mammalian cells might be exposed to varying levels of NO, we tested for possible defense genes and proteins induced upon treatment of cells with sublethal fluxes of pure NO. Two-dimensional gel analysis was performed for human embryonic lung fibroblasts (IMR-90) exposed for 90 min to pure NO at approximately 280 nM/s, which revealed the reproducible induction of at least 12 proteins. Among these, a prominent polypeptide had Mr approximately 32,000, similar to the well-known oxidative stress protein heme oxygenase-1 (HO-1). Northern blot analysis of IMR-90 and HeLa cells demonstrated the NO-mediated induction of HO-1 mRNA up to 70-fold over the levels in untreated cells. HO-1 induction depended on the NO dose and subsequent expression time and was maximal 3-5 h after a 1-h exposure to NO at a constant flux of approximately 280 nM/s. The mRNA encoding a tyrosine/threonine phosphatase (CL100/MKP-1) was also NO inducible (approximately 20 fold), whereas there was no increase in expression of the mRNA encoding manganese-containing superoxide dismutase. Induction of HO-1 mRNA was independent of the guanylate cyclase signaling pathway; addition of the analogue 8-bromo-cyclic GMP did not induce the HO-1 transcript, and the soluble guanylate cyclase inhibitor LY-83583 did not block HO-1 induction by NO in IMR-90 cells. Luciferase reporter constructs containing up to 4.7 kb of DNA upstream of the HO-1 transcription start site showed < or = 2.5-fold induction in IMR-90 or HeLa cells exposed to NO. However, HO-1 mRNA was dramatically stabilized after exposure of IMR-90 cells to NO. Even a transient NO exposure produced elevated levels of HO-1 protein for > or = 10 h, whereas continuous low-level NO treatment (35 nM/s) maintained elevated HO-1 mRNA expression for > or = 8 h. These results reveal a complex mammalian response to NO that involves a new level of posttranscriptional control in response to this radical.

The redox-regulated SoxR protein acts from a single DNA site as a repressor and an allosteric activator

The SoxR protein of Escherichia coli responds to redox signals by activating the transcription of soxS, which encodes another transcription activator that directly stimulates oxidative stress genes. We show here that transcription of the soxR gene, which is positioned head-to-head with soxS in the chromosome, initiates in the intergenic region and is itself repressed by SoxR protein in in vitro transcription experiments. Analysis of single-copy operon fusions to soxR, combined with the results of Northern blotting experiments, verified this regulation and the transcription start site in vivo. The structure of the overlapping promoters is such that the single SoxR-binding site is located in the -10/-35 spacer of the soxS promoter, but just downstream of the -10 element of the soxR promoter. Activated and non-activated SoxR bind this site equally well, exerting nearly constant repression of soxR; activated SoxR simultaneously stimulates the soxS promoter >/=30-fold. The functional soxR promoter depresses soxS transcription when SoxR is not activated and enhances soxS transcription when SoxR is activated, as shown by comparing the expression of soxS'::lacZ fusions with and without the soxR -35 element (induction ratio only approximately 7-fold). SoxR thus represents a highly polar, redox-regulated transcriptional switch that maximizes the change in expression of soxS.

NF kappa B-independent transcriptional induction of the human manganous superoxide dismutase gene

Numerous conditions induce expression of manganese-containing superoxide dismutase (MnSOD) in mammalian cells. The reported inducers of MnSOD are all agents that activate two transcription factors, AP-1 and NF kappa B, but several reports have suggested that MnSOD induction relies solely on NF kappa B. We investigated the contribution of the individual transcription factors by using antioxidants and metal chelators to modulate MnSOD transcriptional activation in response to phorbol esters or hydrogen peroxide. The results indicate substantial transcriptional induction of the MnSOD gene independent of NF kappa B. The metal chelator and antioxidant pyrrolidine dithiocarbamate (PDTC) at 60 or 100 microM induced the MnSOD transcript in HeLa cells while diminishing expression of the NF kappa B-responsive transcript I kappa B-alpha. Induction of the MnSOD mRNA by phorbol-12-myristate-13-acetate (PMA) was only slightly diminished in the presence of PDTC, which in contrast virtually eliminated induction of the NF kappa B-dependent transcript I kappa B-alpha by PMA. MnSOD RNA induction by H2O2 was only approximately 1.5-fold, compared to a ca. 3-fold activation of I kappa B-alpha expression. Two other antioxidants, N-acetyl-L-cysteine and butylated hydroxyanisole, failed to block induction of the MnSOD transcript by PMA, which is consistent with a role for AP-1. In vitro DNA binding studies confirmed strong AP-1 activation under conditions where NF kappa B is blocked but the MnSOD transcript is strongly induced (e.g., PMA treatment in the presence of PDTC).

Comparison of the promoters of the mouse (APEX) and human (APE) apurinic endonuclease genes

We investigated the minimal promoter of APEX, which encodes mouse apurinic DNA repair endonuclease. A 1.85-kb fragment with APEX upstream sequences and approximately 290 bp of the transcribed region linked to a chloramphenicol acetyltransferase (CAT) reporter gene was assayed by transient transfection in NIH-3T3 cells. The minimal APEX promoter was comprised of approximately 190 bp of upstream and approximately 170 bp of transcribed DNA (exon 1 and most of intron 1). This approximately 360-bp region contains two CCAAT boxes and other consensus protein binding sites, but no TATA box. Deletion of the 5'-most CCAAT box decreased activity approximately 5-fold. The second CCAAT box (situated in exon 1) may play an independent role in APEX expression. Transcription start sites have been identified downstream of the second CCAAT box, and DNase I footprinting demonstrated NIH-3T3 nuclear proteins binding this region, including an Spl site located between the CCAAT boxes. Electrophoretic mobility-shift assays indicated binding by purified Sp1. Mouse proteins did not bind three myc-like (USF) sites in the APEX promoter, in contrast to the APE promoter. The APEX and APE promoter had similar activity in Hela cells, but in mouse cells, the murine promoter had approximately 5-fold higher activity than did the human promoter. Both the APEX and APE promoters exhibited bidirectional activity in their cognate cells.

Transcriptional regulation of the Escherichia coli oxyR gene as a function of cell growth

The oxyR regulon plays a central role in the defense of Escherichia coli against the endogenous oxidative damage associated with active aerobic growth. Here we have studied the transcriptional regulation of oxyR in E. coli growing aerobically in rich medium. Expression of a single-copy oxyR'::lacZ reporter construct varied sixfold along the growth curve, with the highest value at 4 to 6 h of growth (approximately 14 x 10(8) cells x ml(-1)). Direct measurements of oxyR mRNA by primer extension showed the same biphasic expression but with a peak somewhat earlier in cell growth (2 to 3 h; approximately 3.5 x 10(8) cells x ml(-1)). The results of immunoblotting experiments demonstrated that the level of OxyR protein exhibits the same biphasic expression. Mutant strains lacking adenylate cyclase (cya) or Crp protein (crp) failed to increase oxyR expression during exponential growth. On the other hand, an rpoS mutation allowed oxyR expression to continue increasing as the cells entered stationary phase. Consistent with a biological role for increased levels of OxyR during exponential growth, the crp cya strain had lower activities of catalase hydroperoxidase I and glutathione reductase and an increased sensitivity to exogenously added hydrogen peroxide. These results suggest that the Crp-dependent upregulation of oxyR in exponential phase is a component of a multistep strategy to counteract endogenous oxidative stress in actively growing E. coli cells.

Role of the acrAB locus in organic solvent tolerance mediated by expression of marA, soxS, or robA in Escherichia coli

Escherichia coli K-12 strains are normally tolerant to n-hexane and susceptible to cyclohexane. Constitutive expression of marA of the multiple antibiotic resistance (mar) locus or of the soxS or robA gene product produced tolerance to cyclohexane. Inactivation of the mar locus or the robA locus, but not the soxRS locus, increased organic solvent susceptibility in the wild type and Mar mutants (to both n-hexane and cyclohexane). The organic solvent hypersusceptibility is a newly described phenotype for a robA-inactivated strain. Multicopy expression of mar, soxS, or robA induced cyclohexane tolerance in strains with a deleted or inactivated chromosomal mar, soxRS, or robA locus; thus, each transcriptional activator acts independently of the others. However, in a strain with 39 kb of chromosomal DNA, including the mar locus, deleted, only the multicopy complete mar locus, consisting of its two operons, produced cyclohexane tolerance. Deletion of acrAB from either wild-type E. coli K-12 or a Mar mutant resulted in loss of tolerance to both n-hexane and cyclohexane. Organic solvent tolerance mediated by mar, soxS, or robA was not restored in strains with acrAB deleted. These findings strongly suggest that active efflux specified by the acrAB locus is linked to intrinsic organic solvent tolerance and to tolerance mediated by the marA, soxS, or robA gene product in E. coli.

In vivo kinetics of a redox-regulated transcriptional switch

SoxR is a transcription activator governing a cellular response to superoxide and nitric oxide in Escherichia coli. SoxR protein is a homodimer, and each monomer has a redox-active [2Fe-2S] cluster. Oxidation and reduction of the [2Fe-2S] clusters can reversibly activate and inactivate SoxR transcriptional activity. Here, we use electron paramagnetic resonance spectroscopy to follow the redox-switching process of SoxR protein in vivo. SoxR [2Fe-2S] clusters were in the fully reduced state during normal aerobic growth, but were completely oxidized after only 2-min aerobic exposure of the cells to superoxide-generating agents such as paraquat. The oxidized SoxR [2Fe-2S] clusters were rapidly re-reduced in vivo once the oxidative stress was removed. The in vivo kinetics of SoxR [2Fe-2S] cluster oxidation and reduction exactly paralleled the increase and decrease of transcription of soxS, the target gene for SoxR. The kinetic analysis also revealed that an oxidative stress-linked decrease in soxS mRNA stability contributes to the rapid attainment of a new steady state after SoxR activation. Such a redox stress-related change in soxS mRNA stability may represent a new level of biological control.

Interaction of human apurinic endonuclease and DNA polymerase beta in the base excision repair pathway

Mutagenic abasic (AP) sites are generated directly by DNA-damaging agents or by DNA glycosylases acting in base excision repair. AP sites are corrected via incision by AP endonucleases, removal of deoxyribose 5-phosphate, repair synthesis, and ligation. Mammalian DNA polymerase beta (Polbeta) carries out most base excision repair synthesis and also can excise deoxyribose 5-phosphate after AP endonuclease incision. Yeast two-hybrid analysis now indicates protein-protein contact between Polbeta and human AP endonuclease (Ape protein). In vitro, binding of Ape protein to uncleaved AP sites loads Polbeta into a ternary complex with Ape and the AP-DNA. After incision by Ape, only Polbeta exhibits stable DNA binding. Kinetic experiments indicated that Ape accelerates the excision of 5'-terminal deoxyribose 5-phosphate by Polbeta. Thus, the two central players of the base excision repair pathway are coordinated in sequential reactions.

Redox signal transduction via iron-sulfur clusters in the SoxR transcription activator

Protein iron-sulfur (FeS) centers have recently been implicated in the regulation of gene expression. In the redox-sensing SoxR protein, the oxidation state of [2Fe-2S] centers controls its activity as a transcription activator independent of DNA-binding ability. Thus, FeS centers allosterically link cellular oxidative stress to the expression of defense genes.

Regulation of eukaryotic abasic endonucleases and their role in genetic stability

Abasic (AP) sites in DNA arise from spontaneous reactions or the action of DNA glycosylases and represent a loss of genetic information. The AP sites can be mutagenic or cytotoxic, and their repair is initiated by class II AP endonucleases, which incise immediately 5' to AP sites. The main enzyme of S. cerevisiae. Apn1, provides cellular resistance to oxidants (e.g., H2O2) or alkylating agents, and limits the spontaneous mutation rate. AP endonucleases from other species can replace Apn1 function in yeast to different extents. We studied the main human enzyme, Ape, with respect to its incision specificity in vitro and the expression of the APE gene in vivo. The results suggest that Ape evolved to act preferentially on AP sites compared to deoxyribose fragments located at oxidative strand breaks and that the incision modes of Ape and Apn1 may be fundamentally different. We also defined the functional APE promoter, and showed that APE expression is transiently downregulated during the regeneration of epidermis after wounding. This latter effect may lead to a window of vulnerability for DNA damage and perhaps mutagenesis during the healing of epidermal and other wounds. Such unexpected effects on the expression of DNA repair enzymes need to be taken into account in analyzing the susceptibility of different tissues to carcinogens.

Cysteine-to-alanine replacements in the Escherichia coli SoxR protein and the role of the [2Fe-2S] centers in transcriptional activation

The Escherichia coli soxRS regulon activates oxidative stress and antibiotic resistance genes in two transcriptional stages. SoxR protein becomes activated in cells exposed to excess superoxide or nitric oxide and then stimulates transcription of the soxS gene, whose product in turn activates>/=10 regulon promoters. Purified SoxR protein is a homodimer containing a pair of [2Fe-2S] centers essential for soxS transcription in vitro . The [2Fe-2S] centers are thought to be anchored by a C-terminal cluster of four cysteine residues in SoxR. Here we analyze mutant SoxR derivatives with individual cysteines replaced by alanine residues (Cys-->Ala). The mutant proteins in cell-free extracts bound the soxS promoter with wild-type affinity, but upon purification lacked Fe or detectable transcriptional activity for soxS in vitro . Electron paramagnetic resonance measurements in vivo indicated that the Cys-->Ala proteins lacked the [2Fe-2S] centers seen for wild-type SoxR. The Cys-->Ala mutant proteins failed to activate soxS expression in vivo in response to paraquat, a superoxide- generating agent. However, when expressed to approximately 5% of the cell protein, the Cys-->Ala derivatives increased basal soxS transcription 2-4-fold. Overexpression of the Cys119-->Ala mutant protein strongly interfered with soxS activation by wild-type SoxR in response to paraquat. These studies demonstrate the essential role of the [2Fe-2S] centers for SoxR activation in vivo ; the data may also indicate oxidant-independent mechanisms of transcriptional activation by SoxR.

Spacing of promoter elements regulates the basal expression of the soxS gene and converts SoxR from a transcriptional activator into a repressor

SoxR protein of Escherichia coli governs a global response against superoxide-generating agents (such as paraquat) or nitric oxide, and provides broad antibiotic resistance. A redox signal activates SoxR post-translationally to trigger transcription of a second regulatory gene, soxS. Activated and non-activated SoxR bind the soxS promoter with the same high affinity, but only the activated protein stimulates soxS transcription. SoxR acts by an unusual mechanism of positive control: the protein binds the soxS promoter between near-consensus -10 and -35 elements that are separated by an unusually long 19 bp (versus the optimal 17 bp). We have constructed and analyzed site-specific deletions that alter the promoter element spacing. Reducing the spacer length to 16-18 bp dramatically elevated basal expression of soxS in vivo and in vitro, and nearly eliminated additional activation by SoxR in response to paraquat. More strikingly, shortening the spacer converted SoxR from an activator into a repressor regardless of paraquat treatment. Gel mobility-shift assays show that repression by SoxR of the promoters with 17 and 16 bp spacers is due to interference with binding by RNA polymerase. Thus, activated SoxR remodels the unusual configuration of the wild-type soxS promoter into a highly active form, probably by compensating for the suboptimal distance between the -10 and the -35 elements.