Bacteria and archaea encode members of the large multiple antibiotic resistance regulator (MarR) family of transcriptional regulators. Generally, MarR homologs regulate activity of genes involved in antibiotic resistance, stress responses, virulence or catabolism of aromatic compounds. They constitute a diverse group of transcriptional regulators that includes both repressors and activators, and the conventional mode of regulation entails a genetic locus in which the MarR homolog and a gene under its regulation are encoded divergently; binding of the MarR homolog to the intergenic region typically represses transcription of both genes, while binding of a specific ligand to the transcription factor results in attenuated DNA binding and hence activated gene expression. For many homologs, the natural ligand is unknown. Crystal structures reveal a common architecture with a characteristic winged helix domain for DNA binding, and recent structural information of homologs solved both in the absence and presence of their respective ligands, as well as biochemical data, is finally converging to illuminate the mechanisms by which ligand-binding causes attenuated DNA binding. As MarR homologs regulate pathways that are critical to bacterial physiology, including virulence, a molecular understanding of mechanisms by which ligands affect a regulation of gene activity is essential. Specifying the position of ligand-binding pockets further has the potential to aid in identifying the ligands for MarR homologs for which the ligand remains unknown.
The MarR family of transcriptional regulators comprises a subset of winged helix DNA-binding proteins and includes numerous members that function in environmental surveillance of aromatic compounds. We describe the characterization of HucR, a novel MarR homolog from Deinococcus radiodurans that demonstrates phenolic sensing capabilities. HucR binds as a homodimer to a single site within its promoter/operator region with K d ؍ 0.29 ؎ 0.02 nM. The HucR binding site contains a pseudopalindromic sequence, composed of 8-bp half-sites separated by 2 bp. The location of the HucR binding site in the intergenic region between hucR and a putative uricase suggests a mechanism of simultaneous co-repression of these two genes. The substrate of uricase, uric acid, is an efficient antagonist of DNA binding, reducing HucR-DNA complex formation to 50% at 0.26 mM ligand, compared with 5.2 and 46 mM for the aromatic compounds salicylate and acetylsalicylate, respectively. Enhanced levels in vivo of hucR and uricase transcript and increased uricase activity under conditions of excess uric acid further indicate a novel regulatory mechanism of aromatic catabolism in D. radiodurans. Since uric acid is a scavenger of reactive oxygen species, we hypothesize that HucR is a participant in the intrinsic resistance of D. radiodurans to high levels of oxidative stress.
Members of the multiple antibiotic resistance regulator (MarR) family of transcription factors are critical for bacterial cells to respond to chemical signals and to convert such signals into changes in gene activity. Obligate dimers belonging to the winged helix-turn-helix protein family, they are critical for regulation of a variety of functions, including degradation of organic compounds and control of virulence gene expression. The conventional regulatory paradigm is based on a genomic locus in which the gene encoding the MarR protein is divergently oriented from a gene under its control; MarR binding to the intergenic region controls expression of both genes by changing the interaction of RNA polymerase with gene promoters. MarR protein oxidation or binding of a small molecule ligand adversely affects DNA binding, resulting in altered expression of the divergent genes. The generality of this simple paradigm, including the regulation of Escherichia coli MarR by direct binding of antibiotics, has been challenged by reports published in recent years. In addition, structural and biochemical analyses of ligand binding to numerous MarR homologs are converging to identify a shared ligand-binding "hot-spot". This review highlights recent research advances that point to shared features, yet at the same time highlights the remarkable flexibility with which members of this protein family implement responses to inducing signals. A more comprehensive understanding of protein function will pave the way towards the development of both antibacterial agents and biosensors that are based on MarR family proteins.
marR gene and prevents excessive protein accumulation. The advantage of this mechanism is that the MarR protein concentration fluctuates within a narrow range that allows a more sensitive response to ligands. MarR family transcription factors Anne Grove What are MarR proteins? Members of the Multiple Antibiotic Resistance Regulator (MarR) family of transcriptional regulators are named for Escherichia coli MarR. In E. coli, MarR regulates an operon that encodes a drug efflux pump, and mutations in proteins that participate in this system lead to a multiple antibiotic resistance phenotype, hence the name. MarR proteins are members of the winged helix-turnhelix family of transcription factors.
Bacterial iron storage proteins such as ferritin serve as intracellular iron reserves. Members of the DNA protection during starvation (Dps) family of proteins are structurally related to ferritins, and their function is to protect the genome from iron-induced free radical damage. Some members of the Dps family bind DNA and are thought to do so only as fully assembled dodecamers. We present the cloning and characterization of a Dps homolog encoded by the radiation-resistant eubacterium Deinococcus radiodurans and show that DNA binding does not require its assembly into a dodecamer. D.radiodurans Dps-1, the product of gene DR2263, adopts a stably folded conformation, as demonstrated by circular dichroism spectroscopy, and undergoes a transition to a disordered state with a melting temperature of 69.2(+/-0.1) degrees C. While a dimeric form of Dps-1 is observed under low-salt conditions, a dodecameric assembly is highly favored at higher concentrations of salt. Both oligomeric forms of Dps-1 exhibit ferroxidase activity, and Fe(II) oxidation/mineralization is seen for dodecameric Dps-1. Notably, addition of Ca(2+) (to millimolar concentrations) to dodecameric Dps-1 can result in the reduction of bound Fe(III). Dimeric Dps-1 protects DNA from both hydroxyl radical cleavage and from DNase I-mediated cleavage; however, dodecameric Dps-1 is unable to provide efficient protection against hydroxyl radical-mediated DNA cleavage. While dodecameric Dps-1 does bind DNA, resulting in formation of large aggregates, cooperative DNA binding by dimeric Dps-1 leads to formation of protein-DNA complexes of finite stoichiometry.
High mobility group box (HMGB) proteins are architectural proteins whose HMG DNA binding domains confer significant preference for distorted DNA, such as 4-way junctions. HMO1 is one of 10 Saccharomyces cerevisiae HMGB proteins, and it is required for normal growth and plasmid maintenance and for regulating the susceptibility of yeast chromatin to nuclease. Using electrophoretic mobility shift assays, we have shown here that HMO1 binds 26-bp duplex DNA with K d ؍ 39.6 ؎ 5.0 nM and that its divergent box A domain participates in DNA interactions, albeit with low affinity. HMO1 has only modest preference for DNA with altered conformations, including DNA with nicks, gaps, overhangs, or loops, as well as for 4-way junction structures and supercoiled DNA. HMO1 binds 4-way junctions with half-maximal saturation of 19.6 ؎ 2.2 nM, with only a modest increase in affinity in the absence of magnesium ions (half-maximal saturation 6.1 ؎ 1.1 nM). Whereas the box A domain contributes modest structure-specific binding, the box B domain is required for high affinity binding. HMO1 bends DNA, as measured by DNA cyclization assays, facilitating cyclization of 136-, 105-, and 87-bp DNA, but not 75-bp DNA, and it has a significantly longer residence time on DNA minicircles compared with linear duplex DNA. The unique DNA binding properties of HMO1 are consistent with global roles in the maintenance of chromatin structure. High mobility group (HMG)1 proteins constitute a significant proportion of non-histone proteins of eukaryotic chromatin. They are abundant proteins that are grouped, in part based on their DNA binding characteristics, into three major classes, HMGA, HMGB, and HMGN (1-4). HMGB proteins contain one or more homologous repeats of the ϳ80-amino acid sequence HMG box and are classified into two families based on the abundance, function, and DNA specificity of this conserved region (1, 5, 6). The moderately sequence-specific family is typified by transcription factors such as sex-determining factor SRY and lymphoid enhancer factor LEF-1 (7, 8), whereas the non-sequence-specific family is represented by so-called architectural factors HMGB1/2 and the Saccharomyces cerevisiae non-histone chromosomal proteins 6A and 6B (NHP6A/B) (9).The tertiary structures of HMG boxes from sequence-specific and non-sequence-specific proteins have revealed an evolutionarily conserved, common global fold consisting of an L-shaped structure composed of three ␣-helices (10 -19). The HMG DNA binding domain, which interacts with ϳ10 bp of duplex, binds to the minor groove of DNA by partial intercalation of one or two surface-exposed, conserved hydrophobic residues into the base pair stack. Consequently, the DNA is greatly distorted, resulting in a sharp bend and helical underwinding (4,8,14,16,20). SRY and LEF-1 cause bending by insertion of helix I hydrophobic residues Ile and Met, respectively, into the base pair stack (Fig. 1) (8, 17). HMGB1 contains tandem HMG box domains referred to as box A and box B; DNA-intercalating residues are located...
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