<i>Escherichia coli</i>
            HdeB Is an Acid Stress Chaperone

Kern, Renée; Malki, Abderrahim; Abdallah, Jad; Tagourti, Jihen; Richarme, Gilbert

doi:10.1128/jb.01522-06

Cited by 112 publications

(142 citation statements)

References 28 publications

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“…Both chaperones are only active below pH 3 and prevent irreversible aggregation of acid-denatured periplasmic proteins (14,21,23,28). HdeA seems to play a major role at pH 2, whereas HdeB is more active at pH 3 (23). The determined HdeA crystal structure and the model HdeB structure are similar (14,45), in agreement with their genetic and functional similarities.…”

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confidence: 64%

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Role of the Multidrug Resistance Regulator MarA in Global Regulation of the hdeAB Acid Resistance Operon in Escherichia coli

2008

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MarA, a transcriptional regulator in Escherichia coli, affects functions such as multiple-antibiotic resistance (Mar) and virulence. Usually an activator, MarA is a repressor of hdeAB and other acid resistance genes. We found that, in wild-type cells grown in LB medium at pH 7.0 or pH 5.5, repression of hdeAB by MarA occurred only in stationary phase and was reduced in the absence of H-NS and GadE, the main regulators of hdeAB. Moreover, repression of hdeAB by MarA was greater in the absence of GadX or Lrp in exponential phase at pH 7.0 and in the absence of GadW or RpoS in stationary phase at pH 5.5. In turn, MarA enhanced repression of hdeAB by H-NS and hindered activation by GadE in stationary phase and also reduced the activity of GadX, GadW, RpoS, and Lrp on hdeAB under some conditions. As a result of its direct and indirect effects, overexpression of MarA prevented most of the induction of hdeAB expression as cells entered stationary phase and made the cells sevenfold more sensitive to acid challenge at pH 2.5. These findings show that repression of hdeAB by MarA depends on pH, growth phase, and other regulators of hdeAB and is associated with reduced resistance to acid conditions.

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confidence: 64%

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confidence: 99%

Role of the Multidrug Resistance Regulator MarA in Global Regulation of the hdeAB Acid Resistance Operon in Escherichia coli

2008

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“…This stress-specific unfolding mechanism enables the exposure of these monomers' hydrophobic surfaces to interact with an array of client proteins in a promiscuous fashion (13-15); however, this unique disorder-triggered interaction between chaperones and clients makes direct characterization of the recognition mechanism very challenging, especially within native cellular contexts. HdeA has been recognized as the major acid chaperone, whereas HdeB has a smaller hydrophobic surface with weaker chaperoning activity in vitro (6). In particular, although HdeB has been suggested to have certain functions together with HdeA at pH 3, no distinct HdeB clients have been identified to date.…”

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confidence: 99%

Comparative proteomics reveal distinct chaperone–client interactions in supporting bacterial acid resistance

Zhang

Yang

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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HdeA and HdeB constitute the essential chaperone system that functions in the unique periplasmic space of Gram-negative enteric bacteria to confer acid resistance. How this two-chaperone machinery cooperates to protect a broad range of client proteins from acid denaturation while avoiding nonspecific binding during bacterial passage through the highly acidic human stomach remains unclear. We have developed a comparative proteomic strategy that combines the genetically encoded releasable protein photocross-linker with 2D difference gel electrophoresis, which allows an unbiased side-by-side comparison of the entire client pools from these two acid-activated chaperones in Escherichia coli. Our results reveal distinct client specificities between HdeA and HdeB in vivo that are determined mainly by their different responses to pH stimulus. The intracellular acidity serves as an environmental cue to determine the folding status of both chaperones and their clients, enabling specific chaperone-client binding and release under defined pH conditions. This cooperative and synergistic mode of action provides an efficient, economical, flexible, and finely tuned protein quality control strategy for coping with acid stress.comparative proteomics | conditionally disordered chaperones | bacteria acid resistance | 2D-DIGE | photocross-linking

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“…Some of the best-characterized systems involve amino acid decarboxylases, which consume protons during amino acid decarboxylation, and antiporters that exchange product for substrate (29). Finally, DNA repair systems (10,81,82) and chaperones (8,31,41,46,50) appear to be important for the reparation of cellular material damaged by exposure to acid.…”

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confidence: 99%

Identification of Campylobacter jejuni Genes Contributing to Acid Adaptation by Transcriptional Profiling and Genome-Wide Mutagenesis

Reid

Pandey

Palyada

et al. 2008

Appl Environ Microbiol

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In order to cause disease, the food-and waterborne pathogen Campylobacter jejuni must face the extreme acidity of the host stomach as well as cope with pH fluctuations in the intestine. In the present study, C. jejuni NCTC 11168 was grown under mildly acidic conditions mimicking those encountered in the intestine. The resulting transcriptional profiles revealed how this bacterium fine-tunes gene expression in response to acid stress. This adaptation involves the differential expression of respiratory pathways, the induction of genes for phosphate transport, and the repression of energy generation and intermediary metabolism genes. We also generated and screened a transposon-based mutant library to identify genes required for wild-type levels of growth under mildly acidic conditions. This screen highlighted the important role played by cell surface components (flagella, the outer membrane, capsular polysaccharides, and lipooligosaccharides) in the acid stress response of C. jejuni. Our data also revealed that a limited correlation exists between genes required for growth under acidic conditions and genes differentially expressed in response to acid. To gain a comprehensive picture of the acid stress response of C. jejuni, we merged transcriptional profiles obtained from acid-adapted cells and cells subjected to acid shock. Genes encoding the transcriptional regulator PerR and putative oxidoreductase subunits Cj0414 and Cj0415 were among the few up-regulated under both acid stress conditions. As a Cj0415 mutant was acid sensitive, it is likely that these genes are crucial to the acid stress response of C. jejuni and consequently are important for host colonization.

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Escherichia coli HdeB Is an Acid Stress Chaperone

Cited by 112 publications

References 28 publications

Role of the Multidrug Resistance Regulator MarA in Global Regulation of the hdeAB Acid Resistance Operon in Escherichia coli

Role of the Multidrug Resistance Regulator MarA in Global Regulation of the hdeAB Acid Resistance Operon in Escherichia coli

Comparative proteomics reveal distinct chaperone–client interactions in supporting bacterial acid resistance

Identification of Campylobacter jejuni Genes Contributing to Acid Adaptation by Transcriptional Profiling and Genome-Wide Mutagenesis

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