Preventing Neurodegeneration by Controlling Oxidative Stress: The Role of OXR1

Parkinson’s disease, diabetic retinopathy, hyperoxia induced retinopathy, and neuronal damage resulting from ischemia are among the notable neurodegenerative diseases in which oxidative stress occurs shortly before the onset of neurodegeneration. A shared feature of these diseases is the depletion of OXR1 (oxidation resistance 1) gene products shortly before the onset of neurodegeneration. In animal models of these diseases, restoration of OXR1 has been shown to reduce or eliminate the deleterious effects of oxidative stress induced cell death, delay the onset of symptoms, and reduce overall severity. Moreover, increasing OXR1 expression in cells further increases oxidative stress resistance and delays onset of disease while showing no detectable side effects. Thus, restoring or increasing OXR1 function shows promise as a therapeutic for multiple neurodegenerative diseases. This review examines the role of OXR1 in oxidative stress resistance and its impact on neurodegenerative diseases. We describe the potential of OXR1 as a therapeutic in light of our current understanding of its function at the cellular and molecular level and propose a possible cascade of molecular events linked to OXR1’s regulatory functions.

Molecular Assessment of Epiretinal Membrane: Activated Microglia, Oxidative Stress and Inflammation

Fibrocellular membrane or epiretinal membrane (ERM) forms on the surface of the inner limiting membrane (ILM) in the inner retina and alters the structure and function of the retina. ERM formation is frequently observed in ocular inflammatory conditions, such as proliferative diabetic retinopathy (PDR) and retinal detachment (RD). Although peeling of the ERM is used as a surgical intervention, it can inadvertently distort the retina. Our goal is to design alternative strategies to tackle ERMs. As a first step, we sought to determine the composition of the ERMs by identifying the constituent cell-types and gene expression signature in patient samples. Using ultrastructural microscopy and immunofluorescence analyses, we found activated microglia, astrocytes, and Müller glia in the ERMs from PDR and RD patients. Moreover, oxidative stress and inflammation associated gene expression was significantly higher in the RD and PDR membranes as compared to the macular hole samples, which are not associated with inflammation. We specifically detected differential expression of hypoxia inducible factor 1-α (HIF1-α), proinflammatory cytokines, and Notch, Wnt, and ERK signaling pathway-associated genes in the RD and PDR samples. Taken together, our results provide new information to potentially develop methods to tackle ERM formation.

RNA polymerase II depletion promotes transcription of alternative mRNA species

BACKGROUND

Cells respond to numerous internal and external stresses, such as heat, cold, oxidative stress, DNA damage, and osmotic pressure changes. In most cases, the primary response to stress is transcriptional induction of genes that assist the cells in tolerating the stress and facilitate the repair of the cellular damage. However, when the transcription machinery itself is stressed, responding by such standard mechanisms may not be possible.

RESULTS

In this study, we demonstrate that depletion or inactivation of RNA polymerase II (RNAPII) changes the preferred polyadenylation site usage for several transcripts, and leads to increased transcription of a specific subset of genes. Surprisingly, depletion of RNA polymerase I (RNAPI) also promotes altered polyadenylation site usage, while depletion of RNA polymerase III (RNAPIII) does not appear to have an impact.

CONCLUSIONS

Our results demonstrate that stressing the transcription machinery by depleting either RNAPI or RNAPII leads to a novel transcriptional response that results in induction of specific mRNAs and altered polyadenylation of many of the induced transcripts.

Induction of a unique isoform of the NCOA7 oxidation resistance gene by interferon β-1b

We demonstrate that interferon (IFN)-β-1b induces an alternative-start transcript containing the C-terminal TLDc domain of nuclear receptor coactivator protein 7 (NCOA7), a member of the OXR family of oxidation resistance proteins. IFN-β-1b induces NCOA7-AS (alternative start) expression in peripheral blood mononuclear cells (PBMCs) obtained from healthy individuals and multiple sclerosis patients and human fetal brain cells, astrocytoma, neuroblastoma, and fibrosarcoma cells. NCOA7-AS is a previously undocumented IFN-β-inducible gene that contains only the last 5 exons of full-length NCOA7 plus a unique first exon (exon 10a) that is not found in longer forms of NCOA7. This exon encodes a domain closely related to an important class of bacterial aldo-keto oxido-reductase proteins that play a critical role in regulating redox activity. We demonstrate that NCOA7-AS is induced by IFN and LPS, but not by oxidative stress and exhibits, independently, oxidation resistance activity. We further demonstrate that induction of NCOA7-AS by IFN is dependent on IFN-receptor activation, the Janus kinase-signal transducers and activators of transcription (JAK-STAT) signaling pathway, and a canonical IFN-stimulated response element regulatory sequence upstream of exon 10a. We describe a new role for IFN-βs involving a mechanism of action that leads to an increase in resistance to inflammation-mediated oxidative stress.

UV damage regulates alternative polyadenylation of the RPB2 gene in yeast

Alternative polyadenylation (APA) is conserved in all eukaryotic cells. Selective use of polyadenylation sites appears to be a highly regulated process and contributes to human pathogenesis. In this article we report that the yeast RPB2 gene is alternatively polyadenylated, producing two mRNAs with different lengths of 3′UTR. In normally growing wild-type cells, polyadenylation preferentially uses the promoter-proximal poly(A) site. After UV damage transcription of RPB2 is initially inhibited. As transcription recovers, the promoter-distal poly(A) site is preferentially used instead, producing more of a longer form of RPB2 mRNA. We show that the relative increase in the long RPB2 mRNA is not caused by increased mRNA stability, supporting the preferential usage of the distal poly(A) site during transcription recovery. We demonstrate that the 3′UTR of RPB2 is sufficient for this UV-induced regulation of APA. We present evidence that while transcription initiation rates do not seem to influence selection of the poly(A) sites of RPB2, the rate of transcription elongation is an important determinant.

Structural/functional analysis of the human OXR1 protein: identification of exon 8 as the anti-oxidant encoding function

Background

The human OXR1 gene belongs to a class of genes with conserved functions that protect cells from reactive oxygen species (ROS). The gene was found using a screen of a human cDNA library by its ability to suppress the spontaneous mutator phenotype of an E. coli mutH nth strain. The function of OXR1 is unknown. The human and yeast genes are induced by oxidative stress and targeted to the mitochondria; the yeast gene is required for resistance to hydrogen peroxide. Multiple spliced isoforms are expressed in a variety of human tissues, including brain.

Results

In this report, we use a papillation assay that measures spontaneous mutagenesis of an E. coli mutM mutY strain, a host defective for oxidative DNA repair. Papillation frequencies with this strain are dependent upon a G→T transversion in the lacZ gene (a mutation known to occur as a result of oxidative damage) and are suppressed by in vivo expression of human OXR1. N-terminal, C-terminal and internal deletions of the OXR1 gene were constructed and tested for suppression of the mutagenic phenotype of the mutM mutY strain. We find that the TLDc domain, encoded by the final four exons of the OXR1 gene, is not required for papillation suppression in E. coli. Instead, we show that the protein segment encoded by exon 8 of OXR1 is responsible for the suppression of oxidative damage in E. coli.

Conclusion

The protein segment encoded by OXR1 exon 8 plays an important role in the anti-oxidative function of the human OXR1 protein. This result suggests that the TLDc domain, found in OXR1 exons 12–16 and common in many proteins with nuclear function, has an alternate (undefined) role other than oxidative repair.

Preferential DNA damage prevention by the E. coli AidB gene: A new mechanism for the protection of specific genes

aidB is one of the four genes of E. coli that is induced by alkylating agents and regulated by Ada protein. Three genes (ada, alkA, and alkB) encode DNA repair proteins that remove or repair alkylated bases. However, the role of AidB remains unclear despite extensive efforts to determine its function in cells exposed to alkylating agents. The E. coli AidB protein was identified as a component of the protein complex that assembles at strong promoters. We demonstrate that AidB protein preferentially binds to UP elements, AT rich transcription enhancer sequences found upstream of many highly expressed genes, several DNA repair genes, and housekeeping genes. AidB allows efficient transcription from promoters containing an UP element upon exposure to a DNA methylating agent and protects downstream genes from DNA damage. The DNA binding domain is required to target AidB to specific genes preferentially protecting them from alkylation damage. However, deletion of AidB's DNA binding domain does not prevent its antimutagenic activity, instead this deletion appears to allow AidB to function as a cytoplasmic alkylation resistance protein. Our studies identify the role of AidB in alkylating agent exposed cells and suggest a new cellular strategy in which a subset of the genome is preferentially protected from damage by alkylating agents.

Base excision repair sensitizes cells to sulfur mustard and chloroethyl ethyl sulfide

DNA repair generally functions to improve survival and reduce mutagenesis of cells that have suffered DNA damage. In this study we examine the role of nucleotide excision repair (NER) and base excision repair (BER) in recovery, mutagenesis and DNA repair in response to DNA damage inflicted by the mustard compounds, sulfur mustard (SM) and chloroethyl ethyl sulfide (CEES) in bacteria and mammalian cells. SM and CEES are compared because SM produces cross-links and monoadducts, whereas CEES produces only monoadducts that are similar to those produced by SM, thus allowing the examination of which types of lesions may be responsible for the effects seen. We find that the presence of a functional NER pathway increases survival and reduces mutagenesis, whereas the presence of a functional BER pathway reduces survival, increases mutagenesis, and decreases repair. The deleterious effects of BER appear to be due to an interaction between the DNA glycosylases and the lesions produced by SM and CEES. Possible mechanisms for BER-mediated sensitization by glycosylase action on mustard lesions are discussed.

Deregulation of DNA damage signal transduction by herpesvirus latency-associated M2

Infected cells recognize viral replication as a DNA damage stress and elicit a DNA damage response that ultimately induces apoptosis as part of host immune surveillance. Here, we demonstrate a novel mechanism where the murine gamma herpesvirus 68 (gammaHV68) latency-associated, anti-interferon M2 protein inhibits DNA damage-induced apoptosis by interacting with the DDB1/COP9/cullin repair complex and the ATM DNA damage signal transducer. M2 expression constitutively induced DDB1 nuclear localization and ATM kinase activation in the absence of DNA damage. Activated ATM subsequently induced Chk activation and p53 phosphorylation and stabilization without eliciting H2AX phosphorylation and MRN recruitment to foci upon DNA damage. Consequently, M2 expression inhibited DNA repair, rendered cells resistant to DNA damage-induced apoptosis, and induced a G(1) cell cycle arrest. Our results suggest that gammaHV68 M2 blocks apoptosis-mediated intracellular innate immunity, which might ultimately contribute to its role in latent infection.

The single-strand DNA binding activity of human PC4 prevents mutagenesis and killing by oxidative DNA damage

Human positive cofactor 4 (PC4) is a transcriptional coactivator with a highly conserved single-strand DNA (ssDNA) binding domain of unknown function. We identified PC4 as a suppressor of the oxidative mutator phenotype of the Escherichia coli fpg mutY mutant and demonstrate that this suppression requires its ssDNA binding activity. Saccharomyces cerevisiae mutants lacking their PC4 ortholog Sub1 are sensitive to hydrogen peroxide and exhibit spontaneous and peroxide-induced hypermutability. PC4 expression suppresses the peroxide sensitivity of the yeast sub1Delta mutant, suggesting that the human protein has a similar function. A role for yeast and human proteins in DNA repair is suggested by the demonstration that Sub1 acts in a peroxide resistance pathway involving Rad2 and by the physical interaction of PC4 with the human Rad2 homolog XPG. We show that XPG recruits PC4 to a bubble-containing DNA substrate with a resulting displacement of XPG and formation of a PC4-DNA complex. We discuss the possible requirement for PC4 in either global or transcription-coupled repair of oxidative DNA damage to mediate the release of XPG bound to its substrate.

Stress induction and mitochondrial localization of Oxr1 proteins in yeast and humans

Reactive oxygen species (ROS) are critical molecules produced as a consequence of aerobic respiration. It is essential for cells to control the production and activity of such molecules in order to protect the genome and regulate cellular processes such as stress response and apoptosis. Mitochondria are the major source of ROS within the cell, and as a result, numerous proteins have evolved to prevent or repair oxidative damage in this organelle. The recently discovered OXR1 gene family represents a set of conserved eukaryotic genes. Previous studies of the yeast OXR1 gene indicate that it functions to protect cells from oxidative damage. In this report, we show that human and yeast OXR1 genes are induced by heat and oxidative stress and that their proteins localize to the mitochondria and function to protect against oxidative damage. We also demonstrate that mitochondrial localization is required for Oxr1 protein to prevent oxidative damage.

The Escherichia coli methyl-directed mismatch repair system repairs base pairs containing oxidative lesions

A major role of the methyl-directed mismatch repair (MMR) system of Escherichia coli is to repair postreplicative errors. In this report, we provide evidence that MMR also acts on oxidized DNA, preventing mutagenesis. When cells deficient in MMR are grown anaerobically, spontaneous mutation frequencies are reduced compared with those of the same cells grown aerobically. In addition, we show that a dam mutant has an increased sensitivity to hydrogen peroxide treatment that can be suppressed by mutations that inactivate MMR. In a dam mutant, MMR is not targeted to newly replicated DNA strands and therefore mismatches are converted to single- and double-strand DNA breaks. Thus, base pairs containing oxidized bases will be converted to strand breaks if they are repaired by MMR. This is demonstrated by the increased peroxide sensitivity of a dam mutant and the finding that the sensitivity can be suppressed by mutations inactivating MMR. We demonstrate further that this repair activity results from MMR recognition of base pairs containing 8-oxoguanine (8-oxoG) based on the finding that overexpression of the MutM oxidative repair protein, which repairs 8-oxoG, can suppress the mutH-dependent increase in transversion mutations. These findings demonstrate that MMR has the ability to prevent oxidative mutagenesis either by removing 8-oxoG directly or by removing adenine misincorporated opposite 8-oxoG or both.

The role of human alkyladenine glycosylase in cellular resistance to the chloroethylnitrosoureas

To investigate the possible role of glycosylase action in causing tumor resistance, a full-length, histidine-tagged human alkyladenine glycosylase has been purified from the cloned human gene contained in a pTrc99A vector propagated in a tag alkA mutant Escherichia coli. This human enzyme releases both 3-methyladenine and 7-methylguanine from methylated DNA but in contrast to previous studies of the bacterial AlkA glycosylase, it does not release any adducts from [(3)H]chloroethylnitrosourea-modified DNA. This finding suggests that the alkyladenine DNA glycosylase-dependent resistance to the toxic effects of the chloroethylnitrosoureas reported previously in the literature may occur by a mechanism other than through direct glycosylase action.

Alkylation resistance of E. coli cells expressing different isoforms of human alkyladenine DNA glycosylase (hAAG)

The alkyladenine DNA glycosylase (AAG) has been cloned from mouse and humans. AAG knock out mouse cells are sensitized to a variety of alkylating and cross-linking agents suggesting AAG is active on a variety of substrates. In humans, two isoforms have been characterized that are generated by alternative splicing and contain either exon 1a or 1b (hAAG1 or hAAG2). In this study, we examine the ability of the both known isoforms of human AAG (hAAG) to contribute to survival of Escherichia coli from treatments with simple alkylating agents and cross-linking alkylating agents. Our results show that hAAG is effective at repairing methyl lesions when expressed in E. coli, but is unable to afford increased resistance to alkylating agents producing larger alkyl lesions such as ethyl lesions or lesions produced by the cross-linking alkylating agents N,N'-bis-chloroethyl-N-nitrosourea (BCNU), N-(2-chloroethyl)-N-nitrosourea (CNU) or mitomycin C. In the case of CNU, expression of hAAG causes increased sensitivity rather than resistance, suggesting deleterious effects of hAAG activity. We also demonstrate that there are no apparent differences between the two isoforms of hAAG when recovery from damage produced by all alkylating agents is tested.

Transcriptional responses to DNA damage

In Escherichia coli, DNA repair and protective responses are regulated at the transcriptional level. Regulatory mechanisms have evolved that allow cells to respond to DNA damage by mounting the appropriate responses. The regulatory proteins controlling these responses are activated when they recognize the presence of a specific DNA damaging agent, the production of specific DNA lesions, or the production of damage intermediates resulting from replication of lesions containing DNA. Transcription of the responses to DNA damage are induced when the activated regulatory proteins stimulate transcription of the genes they control by a variety of complex and unique molecular mechanisms.

Functional genomics reveals a family of eukaryotic oxidation protection genes

Reactive oxygen species (ROS) are toxic compounds produced by normal metabolic processes. Their reactivity with cellular components is a major stress for aerobic cells that results in lipid, protein, and DNA damage. ROS-mediated DNA damage contributes to spontaneous mutagenesis, and cells deficient in repair and protective mechanisms have elevated levels of spontaneous mutations. In Escherichia coli a large number of genes are involved in the repair of oxidative DNA damage and its prevention by detoxification of ROS. In humans, the genes required for these processes are not well defined. In this report we describe the human OXR1 (oxidation resistance) gene discovered in a search for human genes that function in protection against oxidative damage. OXR1 is a member of a conserved family of genes found in eukaryotes but not in prokaryotes. We also outline the procedures developed to identify human genes involved in the prevention and repair of oxidative damage that were used to identify the human OXR1 gene. This procedure makes use of the spontaneous mutator phenotype of E. coli oxidative repair-deficient mutants and identifies genes of interest by screening for antimutator activity resulting from cDNA expression.

Escherichia coli cells defective for the recN gene display constitutive elevation of mutagenesis at 3,N(4)-ethenocytosine via an SOS-induced mechanism

The Escherichia coli UVM (UV Modulation of mutagenesis) response is a DNA damage-inducible mutagenic pathway detected as significantly increased mutagenesis at 3,N4-ethenocytosine (epsilon C) lesions borne on transfected single-stranded M13 vector DNA. All major classes of DNA-damaging agents can induce UVM, and the phenomenon is independent of previously characterized mutagenic responses in E. coli. To understand this phenomenon further, we set out to identify and characterize mutants in the UVM response. Screening a mutant bank of cells defective for 1-methyl-3-nitro-1-nitrosoguanidine-inducible genes revealed that defects in the recN gene cause a constitutive elevation of mutagenesis at epsilon C residues. In contrast to normal cells that show approximately 6% mutagenesis at epsilon C lesions, but approximately 60% upon UVM induction, recN-defective strains display approximately 50% mutagenesis at epsilon C lesion sites in untreated cells. However, the recN-mediated mutagenesis response was found to require the recA gene and the umuDC genes, and could be suppressed in the presence of a plasmid harbouring the SOS transcriptional repressor LexA. These results imply that recN cells are constitutively active for SOS mutagenesis functions. The observation that epsilonC mutagenesis is enhanced in recN cells confirms previous findings that mutagenesis at epsilonC can also be independently elevated by the SOS pathway.

Ada protein-RNA polymerase sigma subunit interaction and alpha subunit-promoter DNA interaction are necessary at different steps in transcription initiation at the Escherichia coli Ada and aidB promoters

The methylated form of the Ada protein (meAda) binds the ada and aidB promoters between 60 and 40 base pairs upstream from the transcription start and activates transcription of the Escherichia coli ada and aidB genes. This region is also a binding site for the alpha subunit of RNA polymerase and resembles the rrnB P1 UP element in A/T content and location relative to the core promoter. In this report, we show that deletion of the C-terminal domain of the alpha subunit severely decreases meAda-independent binding of RNA polymerase to ada and aidB, affecting transcription initiation at these promoters. We provide evidence that meAda activates transcription by direct interaction with the C-terminal domain of RNA polymerase sigma70 subunit (amino acids 574-613). Several negatively charged residues in the sigma70 C-terminal domain are important for transcription activation by meAda; in particular, a glutamic acid to valine substitution at position 575 has a dramatic effect on meAda-dependent transcription. Based on these observations, we propose that the role of the alpha subunit at ada and aidB is to allow initial binding of RNA polymerase to the promoters. However, transcription initiation is dependent on meAda-sigma70 interaction.

Cytochrome c biogenesis is involved in the transposon Tn5-mediated bleomycin resistance and the associated fitness effect in Escherichia coli

The transposon Tn5 ble gene and the Escherichia coli alkylation-inducible aidC locus are co-operatively involved in the resistance to the anti-cancer drug and DNA-cleaving agent bleomycin and enhance fitness of bacteria in the absence of the drug. In this report, we demonstrate that the aidC locus is identical to nrfG, the last gene of the nrf operon involved in the periplasmic formate-dependent nitrite reduction. In the presence of Ble, NrfG expression is specifically induced and restores both bleomycin resistance and its associated beneficial growth effect in an aidC- strain. In vitro DNA protection assays reveal that purified Ble prevents bleomycin-mediated DNA breakage, as do bleomycin-binding proteins. Similarities between haems of the cytochrome c biogenesis nrf pathway and iron bleomycin suggest a DNA repair-independent molecular mechanism for both bleomycin resistance and increased viability. The Ble protein binds bleomycin and prevents DNA breakage. It also induces the nrf locus that may assimilate bleomycin into haem for extracellular transport or inactivate bleomycin. Inactivation of potent DNA oxidants confers a better fitness to the bacterium carrying the transposon, suggesting a symbiotic relationship between host and transposon.

The RNA polymerase alpha subunit carboxyl-terminal domain is required for both basal and activated transcription from the alkA promoter

Expression of the Escherichia coli adaptive response genes (ada, aidB, and alkA) is regulated by the transcriptional activator, Ada. However, the interactions of RNA polymerase and Ada with these promoters differ. In this report we characterize the interactions of Ada, methylated Ada (meAda), and RNA polymerase at the alkA promoter and contrast these interactions with those characterized previously for the ada and aidB promoters. At the alkA promoter, we do not detect the RNA polymerase alpha subunit-mediated binary complex detected at the ada and aidB promoters. In the presence of either of these two activators, RNA polymerase protects the alkA core promoter, including the elements at -35 and -10, and is more efficient in transcription initiation in vitro. RNA polymerase holoenzyme containing the alpha subunit mutation R265A is severely impaired in Ada-independent basal alkA transcription, shows no activation by Ada or meAda, and fails to bind the alkA promoter in vitro. Binding of the purified wild type alpha subunit to alkA was not detected, but a complex of promoter DNA, Ada or meAda, and alpha was observed in gel shift assays. These observations suggest that both forms of Ada protein activate alkA transcription by enhancing RNA polymerase holoenzyme and alpha subunit binding.

The leucine-responsive regulatory protein (Lrp) acts as a specific repressor for sigma s-dependent transcription of the Escherichia coli aidB gene

The product of the Escherichia coli aidB gene is homologous to human isovaleryl-coenzyme A dehydrogenase (IVD), an enzyme involved in the breakdown of the amino acid leucine. The aidB gene is not expressed constitutively, but its transcription is induced via distinct mechanisms in response to: (i) exposure to alkylating agents; (ii) acetate at a slightly acidic pH; and (iii) anoxia. Induction by alkylating agents is mediated by the transcriptional activator Ada, in its methylated form (meAda); the other forms of induction are Ada independent and require sigma s, the alternative sigma factor mainly expressed during the stationary phase of bacterial growth. In this report we show that, in the absence of any transcriptional factor, aidB is efficiently transcribed in vitro by the sigma s, but not by the sigma 70, form of RNA polymerase holoenzyme. In the presence of meAda, levels of transcription by both forms of RNA polymerase are significantly increased. However, sigma s-dependent transcription of aidB is inhibited both in vitro and in vivo by binding of the transcriptional regulator Lrp (leucine responsive protein) to the aidB promoter region (PaidB). Lrp acts as a specific repressor for sigma s-dependent transcription of aidB. Leucine counteracts Lrp binding to P aidB, as does binding to P aidB of me Ada, which causes Lrp to dissociate from the promoter. The physiological significance of aidB transcription regulation is discussed.

RNA polymerase alpha subunit binding site in positively controlled promoters: a new model for RNA polymerase-promoter interaction and transcriptional activation in the Escherichia coli ada and aidB genes

The ada and aidB genes are part of the adaptive response to DNA methylation damage in Escherichia coli. Transcription of the ada and the aidB genes is triggered by binding of the methylated Ada protein (meAda) to a specific sequence located 40-60 base pairs upstream of the transcriptional start, which is internal to an A/T-rich region. In this report we demonstrate that the Ada binding site is also a binding site for RNA polymerase. RNA polymerase is able to bind the -40 to -60 region of the ada and the aidB promoters in the absence of meAda, and its binding is mediated by the alpha subunit. This region resembles the UP element of the rrnB P1 promoter in location, sequence and mechanism of interaction with RNA polymerase. We discuss the function of UP-like elements in positively controlled promoters and provide evidence that Ada does not act by enhancing RNA polymerase binding affinity to the promoter region. Instead, Ada stimulates transcription by modifying the nature of the RNA polymerase-promoter interaction, allowing RNA polymerase to recognize the core promoter -35 and -10 elements in addition to the UP-like element.

Transcriptional activation of the Escherichia coli adaptive response gene aidB is mediated by binding of methylated Ada protein. Evidence for a new consensus sequence for Ada-binding sites

The Escherichia coli aidB gene is part of the adaptive response to DNA methylation damage. Genes belonging to the adaptive response are positively regulated by the ada gene; the Ada protein acts as a transcriptional activator when methylated in one of its cysteine residues at position 69. Through DNaseI protection assays, we show that methylated Ada (meAda) is able to bind a DNA sequence between 40 and 60 base pairs upstream of the aidB transcriptional startpoint. Binding of meAda is necessary to activate transcription of the adaptive response genes; accordingly, in vitro transcription of aidB is dependent on the presence of meAda. Unmethylated Ada protein shows no protection against DNaseI digestion in the aidB promoter region nor does it promote aidB in vitro transcription. The aidB Ada-binding site shows only weak homology to the proposed consensus sequences for Ada-binding sites in E. coli (AAANNAA and AAAGCGCA) but shares a higher degree of similarity with the Ada-binding regions from other bacterial species, such as Salmonella typhimurium and Bacillus subtilis. Based on the comparison of five different Ada-dependent promoter regions, we suggest that a possible recognition sequence for meAda might be AATnnnnnnG-CAA. Higher concentrations of Ada are required for the binding of aidB than for the ada promoter, suggesting lower affinity of the protein for the aidB Ada-binding site. Common features in the Ada-binding regions of ada and aidB are a high A/T content, the presence of an inverted repeat structure, and their position relative to the transcriptional start site. We propose that these elements, in addition to the proposed recognition sequence, are important for binding of the Ada protein.

Induction of the Escherichia coli aidB gene under oxygen-limiting conditions requires a functional rpoS (katF) gene

The Escherichia coli aidB gene is regulated by two different mechanisms, an ada-dependent pathway triggered by methyl damage to DNA and an ada-independent pathway triggered when cells are grown without aeration. In this report we describe our search for mutations affecting the ada-independent aidB induction pathway. The mutant strain identified carries two mutations affecting aidB expression. These mutations are named abrB (aidB regulator) and abrD. The abrB mutation is presently poorly characterized because of instability of the phenotype it imparts. The second mutation, abrD1, reduces the expression of aidB observed when aeration is ceased and oxygen becomes limiting. Genetic and phenotypic analysis of the abrD1 mutation demonstrates that it is an allele of rpoS. Thus, aidB is a member of the family of genes that are transcribed by a sigma S-directed RNA polymerase holoenzyme. Examination of aidB expression in an rpoS insertion mutant strain indicates that both rpoS13::Tn10 and abrD1 mutations reduce aidB expression under oxygen-limiting conditions that prevail in unaerated cultures, reduce aidB induction by acetate at a low pH, but have little or no effect on the ada-dependent alkylation induction of aidB.

Structure and transcriptional regulation of the Escherichia coli adaptive response gene aidB

Expression of the Escherichia coli aidB gene is induced in vivo by alkylation damage in an ada-dependent pathway and by anaerobiosis or by acetate at pH 6.5 in an ada-independent fashion. In this report, we present data on aidB gene structure, function, and regulation. The aidB gene encodes a protein of ca. 60 kDa that is homologous to several mammalian acyl coenzyme A dehydrogenases. Accordingly, crude extracts from an aidB-overexpressing strain showed isovaleryl coenzyme A dehydrogenase activity. aidB overexpression also reduced N-methyl-N'-nitro-N-nitrosoguanidine-induced mutagenesis. Both ada- and acetate/pH-dependent induction of aidB are regulated at the transcriptional level, and the same transcriptional start point is used for both kinds of induction. Ada protein plays a direct role in aidB regulation: methylated Ada is able to bind to the aidB promoter region and to activate transcription from aidB in an in vitro transcription-translation system using crude E. coli extracts.

The delta (argF-lacZ)205(U169) deletion greatly enhances resistance to hydrogen peroxide in stationary-phase Escherichia coli

In this study, we demonstrate that a strain bearing the delta (argF-lacZ)205(U169) deletion exhibits a high level of resistance to hydrogen peroxide compared with its undeleted parent. Our initial investigation of the mechanism behind the observed differences in peroxide resistance when parent and mutant strains are compared indicates that the parent strain carries a region near argF that is responsible for the H2O2-sensitive phenotype, which we have named katC. The H2O2 resistance phenotype of the delta katC [delta (argF-lacZ)205(U169)] mutant strain can be duplicated by Tn9 insertion in a specific locus (katC5::Tn9) which maps near argF. The increased H2O2 resistance of the delta katC and katC5::Tn9 mutant strains can be seen only when cells are grown to stationary phase; exponential-phase cells are unaffected by the presence or absence of katC. This H2O2 resistance mechanism requires functional katE and katF genes, which suggests that the mechanism of H2O2 resistance may involve the activity of the stationary-phase-specific catalase HPII. Cloning, DNA sequencing, and analysis of the katC5::Tn9 insertion allele in comparison with its parent allele implicate two insertion elements, IS1B and IS30B, and suggest that their presence sensitizes parent cells to H2O2.

Anaerobic induction of the alkylation-inducible Escherichia coli aidB gene involves genes of the cysteine biosynthetic pathway

The Escherichia coli aidB gene is a component of the adaptive response to alkylation damage. This gene is subject to two different forms of induction: an ada-dependent alkylation induction and an ada-independent induction that occurs when cells are grown anaerobically (M. R. Volkert, L. I. Hajec, and D. C. Nguyen, J. Bacteriol. 171:1196-1198, 1989; M. R. Volkert, and D. C. Nguyen, Proc. Natl. Acad. Sci. USA 81:4110-4114, 1984). In this study, we isolated and characterized strains bearing mutations that specifically affect the anaerobic induction pathway. This pathway requires a functional cysA operon, which encodes sulfate permease. Mutations in cysA block this pathway of aidB induction. In contrast, mutations in either cysH, cysD, cysN, or cysC result in elevated levels of aidB expression during aerobic growth. These results indicate that the sulfate transport genes perform a role in anaerobic induction of the aidB gene and suggest that growth under anaerobic conditions may modify either the function or the expression of gene products encoded by the cysA operon.

Molecular analysis of the aidD6::Mu d1 (bla lac) fusion mutation of Escherichia coli K12

In this report we present genetic and biochemical evidence indicating that the aidD6::Mu d1 (bla lac) fusion is an insertion of Mu d1 (bla lac) into the alkB coding sequence. We describe the phenotypic effects resulting from this mutation and compare them with the effects of alkB22, alkA and ada mutations. We also constructed an alkA alkB double mutant and compared its phenotype with that of the single mutant strains. The observation that the methyl methanesulfonate (MMS) and N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) resistance of the double mutant is approximately at the level predicted from the additive sensitivity of each of the single mutants suggests that these two gene products act in different pathways of DNA repair.

Expression of DNA damage-inducible genes of Escherichia coli upon treatment with methylating, ethylating and propylating agents

Several alkylation-inducible genes have been identified by construction of Mu-d1 (Apr lac) fusions to genes whose expression is increased in response to alkylation treatment, but not UV treatment. We have examined the induction of 4 different alkylation-inducible genes by treatment with a variety of methylating and ethylating agents, and a propylating agent. We have compared the induction of the alkylation-inducible genes with the induction of the sulA gene, which is a component of the SOS response to DNA damage. We find that the Ada-regulated adaptive response genes (ada-alkB, alkA and aidB) are induced primarily in response to methylation treatment. The ada-independent aidC gene is induced upon treatment with agents that alkylate predominantly by SN1 nucleophilic attack. aidC induction occurs only when cells are not aerated during treatment. The SOS response, as indicated by sulA induction, is strongly induced by all types of alkylating agents used.

Induction of the alkylation-inducible aidB gene of Escherichia coli by anaerobiosis

Induction of the adaptive response to alkylation damage results in the expression of four genes arranged in three transcriptional units: the ada-alkB operon and the alkA and aidB genes. Adaptive-response induction requires the ada gene product and occurs when cells are treated with methylating agents. In previous studies we noted that aidB, but not alkA or ada-alkB, was induced in the absence of alkylation damage as cells were grown to stationary phase. In this note we present evidence that aidB is induced by anaerobiosis. Thus, aidB is subject to dual regulation by ada-dependent alkylation induction and ada-independent anaerobic induction.

Altered induction of the adaptive response to alkylation damage in Escherichia coli recF mutants

Escherichia coli recF mutants are hypermutable when treated with methyl methanesulfonate (G. C. Walker, Mol. Gen. Genet. 152:93-103, 1977). In this study, methylation hypermutability of recF mutant strains was examined, and it was found that recF+ is required for normal induction of the adaptive response to alkylation damage. Although this regulatory effect of recF mutations results in reduced levels of enzymes that specifically repair methyl lesions in DNA, it only partially explains the hypermutability. Further examination showed that methylation hypermutability of recF mutant strains required a functional umuDC operon, a component of the SOS response. These results lead to the hypothesis that methylation hypermutability results from the effects of recF mutations on the induction of both the SOS response and the adaptive response.

Gene expression caused by alkylating agents and cis-diamminedichloroplatinum(II) in Escherichia coli

Previous work has demonstrated heterogeneous effects of methylating agents on induction of DNA damage inducible genes in Escherichia coli. These studies employed E. coli mutants that have fusions of the lac operon to genes induced by treatment with sublethal levels of alkylating agents. These mutants were selected from random insertions of the Mu-dl (Apr lac) phage by screening for induction of beta-galactosidase activity in the presence of methylmethanesulfonate or N-methyl-N'-nitro-N-nitrosoguanidine. The current report extends these findings by analyzing gene expression caused by mechlorethamine, chloroethylnitrosoureas and cis-diamminedichloroplatinum(II) (cis-DDP). The results demonstrate heterogeneous effects by these agents on gene expression. While 1-(2-chloroethyl)-3-cyclohexyl-1-nitrosourea induces alkA, other nitrosoureas, mechlorethamine, and cis-DDP do not cause expression of this gene. Further, while all nitrosoureas caused expression of aidC, mechlorethamine and cis-DDP did not. Lastly, cis-DDP caused marked expression of a sulA fusion mutant while not inducing any of the other E. coli fusion mutants.

Activation of recF-dependent recombination in Escherichia coli by bacteriophage lambda- and P22-encoded functions

Escherichia coli strains bearing wild-type and mutant alleles of various recombination genes, as well as plasmids that express recombination-related genes of bacteriophages lambda and P22, were tested for their proficiency as recipients in Hfr-mediated conjugation. It was found that the homologous recombination systems of both phages could promote recombination in a recB recC mutant host. In addition, the Abc function of P22, but not the Gam function of lambda, was found to inhibit recombination in a wild-type host; however, both Abc and Gam inhibited recombination in a recF mutant host. These observations are interpreted as indicating that the recombination systems of both phages, as well as the RecBCD-modulating functions Abc and Gam, all activate the RecF recombination pathway of E. coli.

Effects of the Escherichia coli recF suppressor mutation, recA801, on recF-dependent DNA-repair associated phenomena

In recb recC sbcB mutants genetic recombination is dependent upon the recF gene. recA801, recA802 and recA803 (formerly called srfA mutations) were originally isolated as mutations that suppress recombination deficiency caused by a recF mutation in a recB recC sbcB genetic background. Since the recA801 mutation also suppressed some of the UV sensitivity due to recF143, we sought to determine what DNA-repair pathways were actually being restored by the recA801 mutation in this genetic background. In this paper we show that the suppression of recF143 by recA801 does not extend to the recF143-mediated defects in induced repair of UV-damaged phages. In addition, we show that recA801 suppresses only slightly the recF143-associated defect in induced expression of the SOS-regulated muc genes of pKM101. These results suggest that recA801 suppresses primarily the RecF pathway of recombinational repair.

Escherichia coli gene induction by alkylation treatment

Searches for alkylation-inducible (aid) genes of Escherichia coli have been conducted by screening random fusions of the Mu-dl(ApR lac) phage for fusions showing increased beta-galactosidase activity after treatment with methylating agents, but not after treatments with UV-irradiation. In this report we describe gene fusions that are specifically induced by alkylation treatments. Nine new mutants are described, and their properties are compared with the five mutants described previously. The total of 14 fusion mutants map at five distinct genetic loci. They can be further subdivided on the basis of their induction by methyl methanesulfonate (MMS) and N-methyl-N' -nitro-N-nitrosoguanidine (MNNG). alkA, aidB and aidD are induced by both agents and appear to be regulated by ada. Neither aidC nor aidI is regulated by ada. Moreover, since aidC is induced only by MNNG and aidI is induced only by MMS, these two genes are likely to be individually regulated. Thus, there appear to be at least three different regulatory mechanisms controlling aid genes.

Two-component suppression of recF143 by recA441 in Escherichia coli K-12

Sensitivity to UV irradiation conferred by recF143 was partially suppressed by recA441 (also known as tif-1). A temperature-conditional component depended on uvrA function and is thought to involve thermal induction of excision repair enzymes. In a uvrA6 mutant, a temperature-independent component of suppression was seen. This is thought to indicate that recA441 also caused temperature-independent changes in recA activity. Two hypotheses are offered to explain how recA441 produced both thermosensitive and thermoindependent effects.

Induction of specific Escherichia coli genes by sublethal treatments with alkylating agents

Fusions of the lac operon to genes induced by treatment with sublethal levels of alkylating agents have been selected from random insertions of the Mu-dl(ApRlac) phage by screening for induction of beta-galactosidase activity in the presence of methyl methanesulfonate. Genetic analysis reveals that these fusions resulted from insertion of Mu-dl(ApRlac) into two regions of the chromosome. One region (aidA) is near his and, based on phenotypic effects, appears to represent insertion into the alkA gene. The other region (aidB) is in the 92.3- to 98-min region, which harbors no previously identified genes involved in repair of alkylation damage. The aidB fusions caused increased resistance to alkylating agents and caused little or no change in the biological effects of adaptation to alkylating agents. Unlike the aidA fusions, aidB fusions showed increased beta-galactosidase activity in untreated cells in a growth phase-dependent fashion. The ada-5 mutation, which blocks expression of the adaptive response, decreased induction of beta-galactosidase activity in both aidA and aidB fusions after alkylation treatments. Thus, both aidA and aidB share with adaptive response a common regulatory mechanism involving the ada gene. The growth phase-dependent control of the aidB fusions, however, is unaffected by ada, suggesting that a second regulatory mechanism exists that controls only aidB.

Suppression of Escherichia coli recF mutations by recA-linked srfA mutations

Suppressors of recF (srfA) were found by selection for resistance to mitomycin C and UV irradiation in a recB21 recC22 sbcB15 recF143 strain. srfA mutations map in recA and are dominant to srfA+. They suppress both the DNA repair and the recombination deficiencies due to recF mutations. Therefore, RecA protein which is altered by the srfA mutation can allow genetic recombination to proceed in the absence of recB, recC, and recF functions. recF is also required for induction of the SOS response after UV damage. We propose that recF+ normally functions to allow the expression of two recA activities, one that is required for the RecF pathway of recombination and another that is required for SOS induction. The two RecA activities are different and are separable by mutation since srfA mutations permit recombination to proceed but have not caused a dramatic increase in SOS induction in recF mutants. According to this hypothesis, one role for recF in DNA repair and recombination is to modulate RecA activities to allow RecA to participate in these recF-dependent processes.

Effects of a recA operator mutation on mutant phenotypes conferred by lexA and recF mutations

Derepression of recA by an operator mutation (recAo281) produces effects opposite to those obtained from its derepression following DNA damage. Inducible reactivation of lambda vir and S13 phages is decreased and inducible UV mutagenesis of a phi X174 amber mutant is lessened in a recAo281 strain compared to a recAo+ strain. The decreases could not be accounted for by increases in constitutive levels of these processes. Consistent with these results the UV resistance of a recAo281 strain is less than that of a recAo+ strain. This may indicate that too much recA protein immediately after irradiation interferes with derepression of the lexA regulon or functioning of its products. Effects of increasing the recAo+ and recA+ copy number on a Co1E1 plasmid are compared with the effects of recAo281. recAo281 partially suppresses UV sensitivity due to lexA102 and lexA3 in E. coli K-12. This increase in resistance is not correlated with an increase in constitutive or inducible reactivation of UV-irradiated lambda vir or S13. This is consistent with the previous suggestion that the UV resistance stems from a decrease in DNA degradation allowing an increase in DNA repair. lexA3 blocks UV mutagenesis of phi X174 as measured by reversion of amber mutations and this was not suppressed by recAo281. recF143 blocks UV mutagenesis of phi X174. recAo281 suppresses neither this effect nor the decrease in bacterial UV resistance caused by recF143.

Constitutive expression of SOS functions and modulation of mutagenesis resulting from resolution of genetic instability at or near the recA locus of Escherichia coli

Cellular activities normally inducible by DNA damage (SOS functions) are expressed, without DNA damage, in recA441 (formerly tif-1) mutants of Escherichia coli at 42 degrees C but not at 30 degrees C. We describe a strain (SC30) that expresses SOS functions (including mutator activity, prophage induction and copious synthesis of recA protein) constitutively at both temperatures. SC30 is one of four stable subclones (SC strains) derived from an unstable recombinant obtained in a conjugation between a recA441 K12 donor and a recA+ B/r-derived recipient. SC30 does not owe its SOS-constitutive phenotype to a mutation in the lexA gene (which codes the repressor of recA and other DNA damage-inducible genes), since it is lexA+. Each of the SC strains expresses SOS functions in a distinctively anomalous way. We show that the genetic basis for the differences in SOS expression among the SC strains is located at or very near the recA locus. We propose that resolution of genetic instability in this region, in the original recombinant, has altered the pattern of expression of SOS functions in the SC strains.

Evidence that rnmB is the operator of the Escherichia coli recA gene

rnmB281 leads to high constitutive levels of recA protein such that no increase after UV-inducing treatment occurs. The mutation maps in or near the portion of recA corresponding to the NH2-terminal end of the protein. Examination of the recA proteins from rnmB+ recA-/rnmB281 recA+ heterozygotes suggests that both rnmB alleles are cis-acting and codominant. This is the behavior expected from alleles of a regulatory gene such as an operator or promoter of recA. The possibility that rnmB mutations occur in the promoter of recA. The possibility that rnmB mutations occur in the promoter of recA, though not ruled out, seems unlikely based on the structure of the regulatory region of recA. This suggests that rnmB mutations are operator constitutive mutations of the recA gene and should be called recAo mutations. The UV-irradiation responses of recAo+ and recAo281 strains, both recA+, are compared and inferences are drawn about the roles of large amounts of recA protein in producing the responses.

Indirect and intragenic suppression of the lexA102 mutation in E. coli B/r

In Escherichia coli B/r the expression of UV inducible (SOS) functions is under the control of the recA and lexA genes. In this study we have characterized mutants which are altered in their ability to express SOS functions. These mutants were isolated as UV resistant UV nonmutable (Rnm) derivatives of the lexA102 uvrA155 mutant strain WP51. The UV resistance of these Rnm strains is a result of the suppression of lexA102 mediated UV sensitivity. Genetic mapping of rnm mutations shows that the two predominant classes, rnmA and rnmB, map in or very near the lexA and recA genes respectively. rnmA mutations differ from rnmB with regard to recA protein synthesis, rnmA mutations do not restore the ability to express high levels of recA protein after UV treatment whereas rnmB mutations result in constitutive expression of high levels of recA protein. However, both rnmA and rnmB mutant strains inhibit postirradiation DNA degradation. This shows that in rnmA strains, high levels of recA protein are not needed to inhibit postirradiation DNA degradation. The genetic map location and constitutive expression of recA protein synthesis resulting from rnmB mutations suggests that they are operator constitutive mutations of the recA gene. The result that the lexA+ gene is required for the expression of UV mutagenesis in rnmB mutants shows that high levels of recA protein do not circumvent the need for the lexA+ gene product in this process. Thus, while the lexA gene product is required for the induction of recA protein synthesis, lexA must have an additional role in UV induced mutagenesis.

Partial suppression of the LexA phenotype by mutations (rnm) which restore ultraviolet resistance but not ultraviolet mutability to Escherichia coli B/r uvr A lexA

In Escherichia coli, lexA mutations eliminate expression of UV-inducible functions, causing pleiotropic effects which include sensitivity to ultraviolet (UV) light and loss of UV mutability. Selection for UV resistance, after 5-bromouracil (BU) treatment of E. coli B/r uvrA lexA-102, has yielded derivatives more resistant than lexA but still refractory to UV mutagenesis. The mutation responsible for the UV-resistant UV-nonmutable phenotype (rnm) is cotransducible with malB to about the same extent as is lexA-102 and is tightly linked to lexA-102 in at least one strain. The rnm mutation may therefore be an intragenic partial suppressor of the LexA phenotype. In addition to increased UV resistance and lack of UV mutability, rnm strains show improved ability to perform postreplication repair and to control postirradiation DNA degration compared to the lexA parent. We ascribe the properties of rnm mutants to their having reacquired control of Exonuclease V activity without having reacquired UV-inducible error-prone postreplication repair. We relate our results to current interpretations of UV mutagenesis and to models of coordinate regulation of UV-inducible functions.