c Clostridium difficile-associated disease is increasing in incidence and is costly to treat. Our understanding of how this organism senses its entry into the host and adapts for growth in the large bowel is limited. The small-molecule second messenger cyclic diguanylate (c-di-GMP) has been extensively studied in Gram-negative bacteria and has been shown to modulate motility, biofilm formation, and other processes in response to environmental signals, yet little is known about the functions of this signaling molecule in Gram-positive bacteria or in C. difficile specifically. In the current study, we investigated the function of the second messenger c-di-GMP in C. difficile. To determine the role of c-di-GMP in C. difficile, we ectopically expressed genes encoding a diguanylate cyclase enzyme, which synthesizes c-di-GMP, or a phosphodiesterase enzyme, which degrades c-di-GMP. This strategy allowed us to artificially elevate or deplete intracellular c-di-GMP, respectively, and determine that c-di-GMP represses motility in C. difficile, consistent with previous studies in Gram-negative bacteria, in which c-di-GMP has a negative effect on myriad modes of bacterial motility. Elevated c-di-GMP levels also induced clumping of C. difficile cells, which may signify that C. difficile is capable of forming biofilms in the host. In addition, we directly quantified, for the first time, c-di-GMP production in a Gram-positive bacterium. This work demonstrates the effect of c-di-GMP on the motility of a Gram-positive bacterium and on aggregation of C. difficile, which may be relevant to the function of this signaling molecule during infection. C yclic diguanylate (3=,5=-cyclic diguanylic acid) (c-di-GMP) is a second messenger utilized exclusively by prokaryotes to effect global changes in cellular physiology (45). c-di-GMP has been implicated in changes to the cellular envelope in multiple species and mediates the transition from planktonic growth to biofilm formation in many Gram-negative bacteria. c-di-GMP augments biofilm formation by increasing the production of adhesins and extracellular matrix components through altered gene regulation (21,36,37,56,67,68) and posttranslational modifications (10, 73). Conversely, c-di-GMP inhibits motility by reducing the transcription or translation of flagellar genes (1,2,26,29,35), impeding pilus assembly (24, 28), or inhibiting the rotation of assembled flagella (4,8,40,49). In addition to regulating biofilm formation and motility, c-di-GMP coordinates cell-wide responses to lifestyle transitions such as entry into stationary phase (60), expression of virulence genes (22,30,64,69), resistance to antibiotics and host immune responses (22, 33), and cell developmental shifts (13,41,70).The level of c-di-GMP in the cell is controlled by three types of enzymes. c-di-GMP is synthesized from two molecules of GTP by diguanylate cyclases (DGCs) containing a GGDEF domain, named for a conserved motif in the active site (46,50,56). c-di-GMP is hydrolyzed by two distinct families of phosphodiestera...
NifL is a multidomain sensor protein responsible for the transcriptional regulation of genes involved in response to changes in cellular redox state and ADP concentration. Cellular redox is monitored by the N-terminal PAS domain of NifL which contains an FAD cofactor. Flavin-based PAS domains of this type have also been referred to as LOV domains. To explore the mechanism of signal recognition and transduction in NifL, we determined the crystal structure of the FAD-bound PAS domain of NifL from Azotobacter vinelandii to 1.04 A resolution. The structure reveals a novel cavity within the PAS domain which contains two water molecules directly coordinated to the FAD. This cavity is connected to solvent by multiple access channels which may facilitate the oxidation of the FAD by molecular oxygen and the release of hydrogen peroxide. The structure contains a dimer of the NifL PAS domain that is structurally very similar to those described in other crystal structures of PAS domains and identifies a conserved dimerization motif. An N-terminal amphipathic helix constitutes part of the dimerization interface, and similar N-terminal helices are identified in other PAS domain proteins. The structure suggests a model for redox-mediated signaling in which a conformational change is initiated by redox-dependent changes in protonation at the N5 atom of FAD that lead to reorganization of hydrogen bonds within the flavin binding pocket. A structural signal is subsequently transmitted to the beta-sheet interface between the monomers of the PAS domain.
A photosensory two-component system regulates bacterial cell attachment
Flavin-binding LOV domains are blue-light photosensory modules that are conserved in a number of developmental and circadian regulatory proteins in plants, algae, and fungi. LOV domains are also present in bacterial genomes, and are commonly located at the amino termini of sensor histidine kinases. Genes predicted to encode LOV-histidine kinases are conserved across a broad range of bacterial taxa, from aquatic oligotrophs to plant and mammalian pathogens. However, the function of these putative prokaryotic photoreceptors remains largely undefined. The differentiating bacterium, Caulobacter crescentus, contains an operon encoding a two-component signaling system consisting of a LOV-histidine kinase, LovK, and a single-domain response regulator, LovR. LovK binds a flavin cofactor, undergoes a reversible photocycle, and displays increased ATPase and autophosphorylation activity in response to visible light. Deletion of the response regulator gene, lovR, results in severe attenuation of cell attachment to a glass surface under laminar flow, whereas coordinate, low-level overexpression of lovK and lovR results in a light-independent increase in cell-cell attachment, a response that requires both the conserved histidine phosphorylation site in LovK and aspartate phosphorylation site in LovR. Growing C. crescentus in the presence of blue light dramatically enhances cell-cell attachment in the lovKlovR overexpression background. A conserved cysteine residue in the LOV domain of LovK, which forms a covalent adduct with the flavin cofactor upon absorption of visible light, is necessary for the light-dependent regulation of LovK enzyme activity and is required for the light-dependent enhancement of intercellular attachment.Caulobacter ͉ LOV domain ͉ photoreceptor ͉ signal transduction ͉ histidine kinase P roteins that serve as detectors of environmental signals are often modular, containing conserved sensory domains that control diverse signaling outputs (1, 2). One such sensory module is the PAS (Per-ARNT-Sim) domain, which is conserved across all kingdoms of life and is capable of specifically binding a wide range of ligands including heme, flavins, p-coumaric acid, citrate, and other small molecules (3). A subclass of PAS domains, known as LOV domains for their role as sensors of light, oxygen, or voltage, commonly bind a flavin cofactor and function to regulate a number of blue light-dependent processes in plants and fungi (4). These photosensory LOV domains signal by means of a unique photocycle in which photon absorption drives the reversible formation of a covalent adduct between the 4a carbon of the flavin isoalloxazine ring and a conserved cysteine residue (5, 6). Adduct formation is followed by a large structural change at the C terminus of the LOV domain that leads to cell signaling (7,8). Beyond plants and fungi, dozens of proteins containing LOV photosensory domains have been identified in bacterial species (4, 9). Examples of bacterial LOV photosensors include LOV-phosphodiesterases, LOV-HTH transcription fa...
The Gram-positive obligate anaerobe Clostridium difficile causes potentially fatal intestinal diseases. How this organism regulates virulence gene expression is poorly understood. In many bacterial species, the second messenger cyclic di-GMP (c-di-GMP) negatively regulates flagellar motility and, in some cases, virulence. c-di-GMP was previously shown to repress motility of C. difficile. Recent evidence indicates that flagellar gene expression is tightly linked with expression of the genes encoding the two C. difficile toxins TcdA and TcdB, which are key virulence factors for this pathogen. Here, the effect of c-di-GMP on expression of the toxin genes tcdA and tcdB was determined, and the mechanism connecting flagellar and toxin gene expressions was examined. In C. difficile, increasing c-di-GMP levels reduced the expression levels of tcdA and tcdB, as well as that of tcdR, which encodes an alternative sigma factor that activates tcdA and tcdB expression. We hypothesized that the C. difficile orthologue of the flagellar alternative sigma factor SigD (FliA; 28 ) mediates regulation of toxin gene expression in response to c-di-GMP. Indeed, ectopic expression of sigD in C. difficile resulted in increased expression levels of tcdR, tcdA, and tcdB. Furthermore, sigD expression enhanced toxin production and increased the cytopathic effect of C. difficile on cultured fibroblasts. Finally, evidence is provided that SigD directly activates tcdR expression and that SigD cannot activate tcdA or tcdB expression independent of TcdR. Taken together, these data suggest that SigD positively regulates toxin genes in C. difficile and that c-di-GMP can inhibit both motility and toxin production via SigD, making this signaling molecule a key virulence gene regulator in C. difficile.
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