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.     

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.     

Analysis of proton wires in the enzyme active site suggests a mechanism of c‐di‐GMP hydrolysis by the EAL domain phosphodiesterases

We report for the first time a hydrolysis mechanism of the cyclic dimeric guanosine monophosphate (c‐di‐GMP) by the EAL domain phosphodiesterases as revealed by molecular simulations. A model system for the enzyme‐substrate complex was prepared on the base of the crystal structure of the EAL domain from the BlrP1 protein complexed with c‐di‐GMP. The nucleophilic hydroxide generated from the bridging water molecule appeared in a favorable position for attack on the phosphorus atom of c‐di‐GMP. The most difficult task was to find a pathway for a proton transfer to the O3' atom of c‐di‐GMP to promote the O3'? P bond cleavage. We show that the hydrogen bond network extended over the chain of water molecules in the enzyme active site and the Glu359 and Asp303 side chains provides the relevant proton wires. The suggested mechanism is consistent with the structural, mutagenesis, and kinetic experimental studies on the EAL domain phosphodiesterases. Proteins 2016; 84:1670–1680. © 2016 Wiley Periodicals, Inc.     

The EAL domain containing protein STM2215 (rtn) is needed during Salmonella infection and has cyclic di‐GMP phosphodiesterase activity

Salmonella Typhimurium gene STM2215 (rtn) is conserved among many enterobacteriaceae. Mutants lacking STM2215 poorly colonized the liver and spleen in intraperitoneal infection of mice and poorly colonized the intestine and deeper tissues in oral infection. These phenotypes were complemented by a wild‐type copy of STM2215 provided in trans. STM2215 deletion mutants grew normally in J774A.1 murine macrophages but were unable to invade Caco‐2 colonic epithelial cells. Consistent with this finding, mutants in STM2215 produced lower levels of effectors of the TTSS‐1. STM2215 is a predicted c‐di‐GMP phosphodiesterase, but lacks identifiable sensor domains. Biochemical analysis of STM2215 determined that it is located in the inner membrane and has c‐di‐GMP phosphodiesterase activity in vitro dependent on an intact EAL motif. Unlike some previously identified members of this family, STM2215 did not affect motility, was expressed on plates, and in liquid media at late exponential and early stationary phase during growth. Defined mutations in STM2215 revealed that neither the predicted periplasmic domain nor the anchoring of the protein to the inner membrane is necessary for the activity of this protein during infection. However, the EAL domain of STM2215 is required during infection, suggesting that its phosphodiesterase activity is necessary during infection.     

Biofilm dispersal: deciding when it is better to travel

Bacteria live predominantly in biofilms, and the internal signal cyclic diguanylate (c‐di‐GMP) is a universal signal that governs the formation and the dispersal of these communities. Pseudomonas aeruginosa is one of the most important reference systems for studying bacterial biofilms and contains numerous diguanylate cyclases (DGCs) for synthesizing c‐di‐GMP and phosphodiesterases (PDEs) for degrading c‐di‐GMP. However, few studies have discerned how cells in biofilms respond to their environment to regulate c‐di‐GMP concentrations through this sophisticated network of enzymes. Basu Roy and Sauer (2014) provide insights on how cells disperse in response to an increase in nutrient levels. Their results show that the inner membrane protein NicD is a DGC that controls dispersal by sensing nutrient levels: when glutamate concentrations are increased, NicD is dephosphorylated, which increases c‐di‐GMP levels and leads to phosphorylation and processing of dispersal regulator BdlA. Processing of BdlA leads to activation of PDE DipA, which results in a net reduction of c‐di‐GMP and biofilm dispersal. These results suggest biofilm dispersal relies on surprisingly dynamic c‐di‐GMP concentrations as a result of a sophisticated interaction between DGCs and PDEs.     

Genetic analysis of two phosphodiesterases reveals cyclic diguanylate regulation of virulence factors in Dickeya dadantii

Cyclic diguanylate (c‐di‐GMP) is a second messenger implicated in the regulation of various cellular properties in several bacterial species. However, its function in phytopathogenic bacteria is not yet understood. In this study we investigated a panel of GGDEF/EAL domain proteins which have the potential to regulate c‐di‐GMP levels in the phytopathogen Dickeya dadantii 3937. Two proteins, EcpB (contains GGDEF and EAL domains) and EcpC (contains an EAL domain) were shown to regulate multiple cellular behaviours and virulence gene expression. Deletion of ecpB and/or ecpC enhanced biofilm formation but repressed swimming/swarming motility. In addition, the ecpB and ecpC mutants displayed a significant reduction in pectate lyase production, a virulence factor of this bacterium. Gene expression analysis showed that deletion of ecpB and ecpC significantly reduced expression of the type III secretion system (T3SS) and its virulence effector proteins. Expression of the T3SS genes is regulated by HrpL and possibly RpoN, two alternative sigma factors. In vitro biochemical assays showed that EcpC has phosphodiesterase activity to hydrolyse c‐di‐GMP into linear pGpG. Most of the enterobacterial pathogens encode at least one T3SS, a major virulence factor which functions to subvert host defences. The current study broadens our understanding of the interplay between c‐di‐GMP, RpoN and T3SS and the potential role of c‐di‐GMP in T3SS regulation among a wide range of bacterial pathogens.     

Diguanylate cyclase NicD‐based signalling mechanism of nutrient‐induced dispersion by Pseudomonas aeruginosa

Dispersion enables the transition from the biofilm to the planktonic growth state in response to various cues. While several Pseudomonas aeruginosa proteins, including BdlA and the c‐di‐GMP phosphodiesterases DipA, RbdA, and NbdA, have been shown to be required for dispersion to occur, little is known about dispersion cue sensing and the signalling translating these cues into the modulation c‐di‐GMP levels to enable dispersion. Using glutamate‐induced dispersion as a model, we report that dispersion‐inducing nutrient cues are sensed via an outside‐in signalling mechanism by the diguanylate cyclase NicD belonging to a family of seven transmembrane (7TM) receptors. NicD directly interacts with BdlA and the phosphodiesterase DipA, with NicD, BdlA, and DipA being part of the same pathway required for dispersion. Glutamate sensing by NicD results in NicD dephosphorylation and increased cyclase activity. Active NicD contributes to the non‐processive proteolysis and activation of BdlA via phosphorylation and temporarily elevated c‐di‐GMP levels. BdlA, in turn, activates DipA, resulting in the overall reduction of c‐di‐GMP levels. Our results provide a basis for understanding the signalling mechanism based on NicD to induce biofilm dispersion that may be applicable to various biofilm‐forming species and may have implications for the control of biofilm‐related infections.     

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.     

The response threshold of Salmonella PilZ domain proteins is determined by their binding affinities for c‐di‐GMP

c‐di‐GMP is a bacterial second messenger that is enzymatically synthesized and degraded in response to environmental signals. Cellular processes are affected when c‐di‐GMP binds to receptors which include proteins that contain the PilZ domain. Although each c‐di‐GMP synthesis or degradation enzyme metabolizes the same molecule, many of these enzymes can be linked to specific downstream processes. Here we present evidence that c‐di‐GMP signalling specificity is achieved through differences in affinities of receptor macromolecules. We show that the PilZ domain proteins of Salmonella Typhimurium, YcgR and BcsA, demonstrate a 43‐fold difference in their affinity for c‐di‐GMP. Modulation of the affinities of these proteins altered their activities in a predictable manner in vivo. Inactivation of yhjH, which encodes a predicted c‐di‐GMP degrading enzyme, increased the fraction of the cellular population that demonstrated c‐di‐GMP levels high enough to bind to the higher‐affinity YcgR protein and inhibit motility, but not high enough to bind to the lower‐affinity BcsA protein and stimulate cellulose production. Finally, PilZ domain proteins of Pseudomonas aeruginosa demonstrated a 145‐fold difference in binding affinities, suggesting that regulation by binding affinity may be a conserved mechanism that allows organisms with many c‐di‐GMP binding macromolecules to rapidly integrate multiple environmental signals into one output.     

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.     

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.     

Characterization of starvation‐induced dispersion in Pseudomonas putida biofilms: genetic elements and molecular mechanisms

Pseudomonas putida OUS82 biofilm dispersal was previously shown to be dependent on the gene PP0164 (here designated lapG). Sequence and structural analysis has suggested that the LapG geneproduct belongs to a family of cysteine proteinases that function in the modification of bacterial surface proteins. We provide evidence that LapG is involved in P. putida OUS82 biofilm dispersal through modification of the outer membrane‐associated protein LapA. While the P. putida lapG mutant formed more biofilm than the wild‐type, P. putida lapA and P. putida lapAG mutants displayed decreased surface adhesion and were deficient in subsequent biofilm formation, suggesting that LapG affects LapA, and that the LapA protein functions both as a surface adhesin and as a biofilm matrix component. Lowering of the intracellular c‐di‐GMP level via induction of an EAL domain protein led to dispersal of P. putida wild‐type biofilm but did not disperse P. putida lapG biofilm, indicating that LapG exerts its activity on LapA in response to a decrease in the intracellular c‐di‐GMP level. In addition, evidence is provided that associated to LapA a cellulase‐degradable exopolysaccharide is part of the P. putida biofilm matrix.