GIL,a new c‐di‐GMP‐binding protein domain involved in regulation of cellulose synthesis in enterobacteria

In contrast to numerous enzymes involved in c‐di‐GMP synthesis and degradation in enterobacteria, only a handful of c‐di‐GMP receptors/effectors have been identified. In search of new c‐di‐GMP receptors, we screened the Escherichia coli ASKA overexpression gene library using the Differential Radial Capillary Action of Ligand Assay (DRaCALA) with fluorescently and radioisotope‐labelled c‐di‐GMP. We uncovered three new candidate c‐di‐GMP receptors in E. coli and characterized one of them, BcsE. The bcsE gene is encoded in cellulose synthase operons in representatives of Gammaproteobacteria and Betaproteobacteria. The purified BcsE proteins from E. coli, Salmonella enterica and Klebsiella pneumoniae bind c‐di‐GMP via the domain of unknown function, DUF2819, which is hereby designated GIL, G GDEF I ‐site l ike domain. The RxGD motif of the GIL domain is required for c‐di‐GMP binding, similar to the c‐di‐GMP‐binding I‐site of the diguanylate cyclase GGDEF domain. Thus, GIL is the second protein domain, after PilZ, dedicated to c‐di‐GMP‐binding. We show that in S. enterica, BcsE is not essential for cellulose synthesis but is required for maximal cellulose production, and that c‐di‐GMP binding is critical for BcsE function. It appears that cellulose production in enterobacteria is controlled by a two‐tiered c‐di‐GMP‐dependent system involving BcsE and the PilZ domain containing glycosyltransferase BcsA.     

A post‐translational,c‐di‐GMP‐dependent mechanism regulating flagellar motility

Elevated levels of the second messenger cyclic dimeric GMP, c‐di‐GMP, promote transition of bacteria from single motile cells to surface‐attached multicellular communities. Here we describe a post‐translational mechanism by which c‐di‐GMP initiates this transition in enteric bacteria. High levels of c‐di‐GMP induce the counterclockwise bias in Escherichia coli flagellar rotation, which results in smooth swimming. Based on co‐immunoprecipitation, two‐hybrid and mutational analyses, the E. coli c‐di‐GMP receptor YcgR binds to the FliG subunit of the flagellum switch complex, and the YcgR–FliG interaction is strengthened by c‐di‐GMP. The central fragment of FliG binds to YcgR as well as to FliM, suggesting that YcgR–c‐di‐GMP biases flagellum rotation by altering FliG‐FliM interactions. The c‐di‐GMP‐induced smooth swimming promotes trapping of motile bacteria in semi‐solid media and attachment of liquid‐grown bacteria to solid surfaces, whereas c‐di‐GMP‐dependent mechanisms not involving YcgR further facilitate surface attachment. The YcgR–FliG interaction is conserved in the enteric bacteria, and the N‐terminal YcgR/PilZN domain of YcgR is required for this interaction. YcgR joins a growing list of proteins that regulate motility via the FliG subunit of the flagellum switch complex, which suggests that FliG is a common regulatory entryway that operates in parallel with the chemotaxis that utilizes the FliM‐entryway.     

The PilZ domain is a receptor for the second messenger c-di-GMP: the PilZ domain protein YcgR controls motility in enterobacteria

The ubiquitous bacterial second messenger c-di-GMP controls exopolysaccharide synthesis, flagella- and pili-based motility, gene expression, and interactions of bacteria with eukaryotic hosts. With the exception of bacterial cellulose synthases, the identities of c-di-GMP receptors and end targets have remained unknown. Recently, Amikam and Galperin (Amikam, D., and Galperin, M. (2006) Bioinformatics 22, 3-6) hypothesized that the PilZ domains present in the BcsA subunits of bacterial cellulose synthases function in c-di-GMP binding. This hypothesis has been tested here using the Escherichia coli PilZ domain protein YcgR, its individual PilZ domain and the PilZ domain from Gluconacetobacter xylinus BcsA. YcgR was purified and found to bind c-di-GMP tightly and specifically, Kd 0.84 microm. Individual PilZ domains from YcgR and BcsA also bound c-di-GMP, albeit with lesser affinity, indicating that PilZ is sufficient for binding. The site-directed mutagenesis performed on YcgR implicated the most conserved residues in the PilZ domain directly in c-di-GMP binding. It is suggested that c-di-GMP binding to PilZ brings about conformational changes in the protein that stabilize the bound ligand and initiate the downstream signal transduction cascade. While the identity of the downstream partner(s) of YcgR remains unknown, it is shown that YcgR regulates flagellum-based motility in a c-di-GMP-dependent manner. The inactivation of ycgR improves swimming and swarming motility of the poorly motile yhjH mutants of Salmonella enterica serovar Typhimurium UMR1. Therefore, biochemical and genetic evidence presented here establishes PilZ as a long sought after c-di-GMP-binding domain and YcgR as a c-di-GMP receptor affecting motility in enterobacteria.     

XC1028 from Xanthomonas campestris adopts a PilZ domain‐like structure without a c‐di‐GMP switch

The crystal structure of XC1028 from Xanthomonas campestris has been determined to a resolution of 2.15 Å using the multiple anomalous dispersion approach. It bears significant sequence identity and similarity values of 64.10% and 70.09%, respectively, with PA2960, a protein indispensable for type IV pilus‐mediated twitching motility, after which the PilZ motif was first named. However, both XC1028 and PA2960 lack detectable c‐di‐GMP binding capability. Although XC1028 adopts a structure comprising a five‐stranded β‐barrel core similar to other canonical PilZ domains with robust c‐di‐GMP binding ability, considerable differences are observed in the N‐terminal motif; XC1028 assumes a compact five‐stranded β‐barrel without an extra long N‐terminal motif, whereas other canonical PilZ domains contain a long N‐terminal sequence embedded with an essential “c‐di‐GMP switch” motif. In addition, a β‐strand (β1) in the N‐terminal motif, running in exactly opposite polarity to that of XC1028, is found inserted into the parallel β3/β1′ strands, forming a completely antiparallel β4↓β3↑β1↓β1′↑ sheet in the canonical PilZ domains. Such dramatic structural differences at the N‐terminus may account for the diminished c‐di‐GMP binding capability of XC1028, and suggest that interactions with additional proteins are necessary to bind c‐di‐GMP for type IV fimbriae assembly. Proteins 2009. © 2008 Wiley‐Liss, Inc.     

The role of PilZ domain proteins in the virulence of Xanthomonas campestris pv. campestris

Cyclic di‐GMP [(bis‐(3′–5′)‐cyclic di‐guanosine monophosphate)] is an almost ubiquitous second messenger in bacteria that is implicated in the regulation of a range of functions that include developmental transitions, aggregative behaviour, adhesion, biofilm formation and virulence. Comparatively little is known about the mechanism(s) by which cyclic di‐GMP exerts these various regulatory effects. PilZ has been identified as a cyclic di‐GMP binding protein domain; proteins with this domain are involved in regulation of specific cellular processes, including the virulence of animal pathogens. Here we have examined the role of PilZ domain proteins in virulence and the regulation of virulence factor synthesis in Xanthomonas campestris pv. campestris (Xcc), the causal agent of black rot of crucifers. The Xcc genome encodes four proteins (XC0965, XC2249, XC2317 and XC3221) that have a PilZ domain. Mutation of XC0965, XC2249 and XC3221 led to a significant reduction of virulence in Chinese radish. Mutation of XC2249 and XC3221 led to a reduction in motility whereas mutation of XC2249 and XC0965 affected extracellular enzyme production. All mutant strains were unaffected in biofilm formation in vitro. The reduction of virulence following mutation of XC3221 could not be wholly attributed to an effect on motility as mutation of pilA, which abolishes motility, has a lesser effect on virulence.     

Crystal structure of an HD‐GYP domain cyclic‐di‐GMP phosphodiesterase reveals an enzyme with a novel trinuclear catalytic iron centre

Bis‐(3′,5′) cyclic di‐guanylate (c‐di‐GMP) is a key bacterial second messenger that is implicated in the regulation of many crucial processes that include biofilm formation, motility and virulence. Cellular levels of c‐di‐GMP are controlled through synthesis by GGDEF domain diguanylate cyclases and degradation by two classes of phosphodiesterase with EAL or HD‐GYP domains. Here, we have determined the structure of an enzymatically active HD‐GYP domain protein from Persephonella marina (PmGH) alone, in complex with substrate (c‐di‐GMP) and final reaction product (GMP). The structures reveal a novel trinuclear iron binding site, which is implicated in catalysis and identify residues involved in recognition of c‐di‐GMP. This structure completes the picture of all domains involved in c‐di‐GMP metabolism and reveals that the HD‐GYP family splits into two distinct subgroups containing bi‐ and trinuclear metal centres.     

Finally! The structural secrets of a HD‐GYP phosphodiesterase revealed

The major sessility‐motility lifestyle change and additional fundamental aspects of bacterial physiology, behaviour and morphology are regulated by the secondary messenger cyclic di‐GMP (c‐di‐GMP). Although the c‐di‐GMP metabolizing enzymes and many receptors have been readily characterized upon discovery, the HD‐GYP domain c‐di‐GMP phosphodiesterase family remained underinvestigated. In this issue of Molecular Microbiology, Bellini et al. provide an important step towards functional and structural characterization of the previously neglected HD‐GYP domain family by resolving the crystal structure of PmGH, a catalytically active family member from the thermophilic bacterium Persephonella marina. The crystal structure revealed a novel tri‐nuclear catalytic iron centre involved in c‐di‐GMP binding and catalysis and provides the structural basis to subsequently characterize in detail the catalytic mechanism of hydrolysis of c‐di‐GMP to GMP by HD‐GYP domains.     

Allosteric activation of exopolysaccharide synthesis through cyclic di‐GMP‐stimulated protein–protein interaction

In many bacterial pathogens, the second messenger c‐di‐GMP stimulates the production of an exopolysaccharide (EPS) matrix to shield bacteria from assaults of the immune system. How c‐di‐GMP induces EPS biogenesis is largely unknown. Here, we show that c‐di‐GMP allosterically activates the synthesis of poly‐β‐1,6‐N‐acetylglucosamine (poly‐GlcNAc), a major extracellular matrix component of Escherichia coli biofilms. C‐di‐GMP binds directly to both PgaC and PgaD, the two inner membrane components of the poly‐GlcNAc synthesis machinery to stimulate their glycosyltransferase activity. We demonstrate that the PgaCD machinery is a novel type c‐di‐GMP receptor, where ligand binding to two proteins stabilizes their interaction and promotes enzyme activity. This is the first example of a c‐di‐GMP‐mediated process that relies on protein–protein interaction. At low c‐di‐GMP concentrations, PgaD fails to interact with PgaC and is rapidly degraded. Thus, when cells experience a c‐di‐GMP trough, PgaD turnover facilitates the irreversible inactivation of the Pga machinery, thereby temporarily uncoupling it from c‐di‐GMP signalling. These data uncover a mechanism of c‐di‐GMP‐mediated EPS control and provide a frame for c‐di‐GMP signalling specificity in pathogenic bacteria.     

Cellulose production,activated by cyclic di‐GMP through BcsA and BcsZ,is a virulence factor and an essential determinant of the three‐dimensional architectures of biofilms formed by Erwinia amylovora Ea1189

Bacterial biofilms are multicellular aggregates encased in an extracellular matrix mainly composed of exopolysaccharides (EPSs), protein and nucleic acids, which determines the architecture of the biofilm. Erwinia amylovora Ea1189 forms a biofilm inside the xylem of its host, which results in vessel plugging and water transport impairment. The production of the EPSs amylovoran and levan is critical for the formation of a mature biofilm. In addition, cyclic dimeric GMP (c‐di‐GMP) has been reported to positively regulate amylovoran biosynthesis and biofilm formation in E. amylovora Ea1189. In this study, we demonstrate that cellulose is synthesized by E. amylovora Ea1189 and is a major modulator of the three‐dimensional characteristics of biofilms formed by this bacterium, and also contributes to virulence during systemic host invasion. In addition, we demonstrate that the activation of cellulose biosynthesis in E. amylovora is a c‐di‐GMP‐dependent process, through allosteric binding to the cellulose catalytic subunit BcsA. We also report that the endoglucanase BcsZ is a key player in c‐di‐GMP activation of cellulose biosynthesis. Our results provide evidence of the complex composition of the extracellular matrix produced by E. amylovora and the implications of cellulose biosynthesis in shaping the architecture of the biofilm and in the expression of one of the main virulence phenotypes of this pathogen.     

The extremophile Acidithiobacillus ferrooxidans possesses a c-di-GMP signalling pathway that could play a significant role during bioleaching of minerals

Aims: The primary goal of this study was to characterize the existence of a functional c‐di‐GMP pathway in the bioleaching bacterium Acidithiobacillus ferrooxidans. Methods and Results: A bioinformatic search revealed that the genome sequence of At. ferrooxidans ATCC 23270 codes for several proteins involved in the c‐di‐GMP pathway, including diguanylate cyclases (DGC), phosphodiesterases and PilZ effector proteins. Overexpression in Escherichia coli demonstrated that four At. ferrooxidans genes code for proteins containing GGDEF/EAL domains with functional DGC activity. MS/MS analysis allowed the identification of c‐di‐GMP in nucleotide preparations obtained from At. ferrooxidans cells. In addition, c‐di‐GMP levels in cells grown on the surface of solid energetic substrates such as sulfur prills or pyrite were higher than those measured in ferrous iron planktonic cells. Conclusions: At. ferrooxidans possesses a functional c‐di‐GMP pathway that could play a key role in At. ferrooxidans biofilm formation during bioleaching processes. Significance and Impact of the Study: This is the first global study about the c‐di‐GMP pathway in an acidophilic bacterium of great interest for the biomining industry. It opens a new way to explore the regulation of biofilm formation by biomining micro‐organisms during the bioleaching process.     

Activation and polar sequestration of PopA,a c‐di‐GMP effector protein involved in Caulobacter crescentus cell cycle control

When Caulobacter crescentus enters S‐phase the replication initiation inhibitor CtrA dynamically positions to the old cell pole to be degraded by the polar ClpXP protease. Polar delivery of CtrA requires PopA and the diguanylate cyclase PleD that positions to the same pole. Here we present evidence that PopA originated through gene duplication from its paralogue response regulator PleD and subsequent co‐option as c‐di‐GMP effector protein. While the C‐terminal catalytic domain (GGDEF) of PleD is activated by phosphorylation of the N‐terminal receiver domain, functional adaptation has reversed signal transduction in PopA with the GGDEF domain adopting input function and the receiver domain serving as regulatory output. We show that the N‐terminal receiver domain of PopA specifically interacts with RcdA, a component required for CtrA degradation. In contrast, the GGDEF domain serves to target PopA to the cell pole in response to c‐di‐GMP binding. In agreement with the divergent activation and targeting mechanisms, distinct markers sequester PleD and PopA to the old cell pole upon S‐phase entry. Together these data indicate that PopA adopted a novel role as topology specificity factor to help recruit components of the CtrA degradation pathway to the protease specific old cell pole of C. crescentus.     

Transmembrane redox control and proteolysis of PdeC,a novel type of c‐di‐GMP phosphodiesterase

The nucleotide second messenger c‐di‐GMP nearly ubiquitously promotes bacterial biofilm formation, with enzymes that synthesize and degrade c‐di‐GMP being controlled by diverse N‐terminal sensor domains. Here, we describe a novel class of widely occurring c‐di‐GMP phosphodiesterases (PDE) that feature a periplasmic “CSS domain” with two highly conserved cysteines that is flanked by two transmembrane regions (TM1 and TM2) and followed by a cytoplasmic EAL domain with PDE activity. Using PdeC, one of the five CSS domain PDEs of Escherichia coli K‐12, we show that DsbA/DsbB‐promoted disulfide bond formation in the CSS domain reduces PDE activity. By contrast, the free thiol form is enzymatically highly active, with the TM2 region promoting dimerization. Moreover, this form is processed by periplasmic proteases DegP and DegQ, yielding a highly active TM2 + EAL fragment that is slowly removed by further proteolysis. Similar redox control and proteolysis was also observed for a second CSS domain PDE, PdeB. At the physiological level, CSS domain PDEs modulate production and supracellular architecture of extracellular matrix polymers in the deeper layers of mature E. coli biofilms.     

Elevated levels of the second messenger c‐di‐GMP contribute to antimicrobial resistance of Pseudomonas aeruginosa

Biofilms are highly structured, surface‐associated communities. A hallmark of biofilms is their extraordinary resistance to antimicrobial agents that is activated during early biofilm development of Pseudomonas aeruginosa and requires the regulatory hybrid SagS and BrlR, a member of the MerR family of multidrug efflux pump activators. However, little is known about the mechanism by which SagS contributes to BrlR activation or drug resistance. Here, we demonstrate that ΔsagS biofilm cells harbour the secondary messenger c‐di‐GMP at reduced levels similar to those observed in wild‐type cells grown planktonically rather than as biofilms. Restoring c‐di‐GMP levels to wild‐type biofilm‐like levels restored brlR expression, DNA binding by BrlR, and recalcitrance to killing by antimicrobial agents of ΔsagS biofilm cells. We likewise found that increasing c‐di‐GMP levels present in planktonic cells to biofilm‐like levels (≥ 55 pmol mg^?1) resulted in planktonic cells being significantly more resistant to antimicrobial agents, with increased resistance correlating with increased brlR, mexA, and mexE expression and BrlR production. In contrast, reducing cellular c‐di‐GMP levels of biofilm cells to ≤ 40 pmol mg^?1 correlated with increased susceptibility and reduced brlR expression. Our findings suggest that a signalling pathway involving a specific c‐di‐GMP pool regulated by SagS contributes to the resistance of P. aeruginosa biofilms.     

MotifAnalyzer‐PDZ: A computational program to investigate the evolution of PDZ‐binding target specificity

Recognition of short linear motifs (SLiMs) or peptides by proteins is an important component of many cellular processes. However, due to limited and degenerate binding motifs, prediction of cellular targets is challenging. In addition, many of these interactions are transient and of relatively low affinity. Here, we focus on one of the largest families of SLiM‐binding domains in the human proteome, the PDZ domain. These domains bind the extreme C‐terminus of target proteins, and are involved in many signaling and trafficking pathways. To predict endogenous targets of PDZ domains, we developed MotifAnalyzer‐PDZ, a program that filters and compares all motif‐satisfying sequences in any publicly available proteome. This approach enables us to determine possible PDZ binding targets in humans and other organisms. Using this program, we predicted and biochemically tested novel human PDZ targets by looking for strong sequence conservation in evolution. We also identified three C‐terminal sequences in choanoflagellates that bind a choanoflagellate PDZ domain, the Monsiga brevicollis SHANK1 PDZ domain (mbSHANK1), with endogenously‐relevant affinities, despite a lack of conservation with the targets of a homologous human PDZ domain, SHANK1. All three are predicted to be signaling proteins, with strong sequence homology to cytosolic and receptor tyrosine kinases. Finally, we analyzed and compared the positional amino acid enrichments in PDZ motif‐satisfying sequences from over a dozen organisms. Overall, MotifAnalyzer‐PDZ is a versatile program to investigate potential PDZ interactions. This proof‐of‐concept work is poised to enable similar types of analyses for other SLiM‐binding domains (e.g., MotifAnalyzer‐Kinase). MotifAnalyzer‐PDZ is available at http://motifAnalyzerPDZ.cs.wwu.edu .