HD-[HD-GYP] Phosphodiesterases: Activities and Evolutionary Diversification within the HD-GYP Family (original) (raw)
Related papers
Journal of Bacteriology, 2015
ABSTRACTThe intracellular level of the bacterial secondary messenger cyclic di-3′,5′-GMP (c-di-GMP) is determined by a balance between its biosynthesis and degradation, the latter achieved via dedicated phosphodiesterases (PDEs) bearing a characteristic EAL or HD-GYP domain. We here report the crystal structure of PA4781, one of the threePseudomonas aeruginosaHD-GYP proteins, which we have previously characterizedin vitro. The structure shows a bimetallic active site whose metal binding mode is different from those of both HD-GYP PDEs characterized so far. Purified PA4781 does not contain iron in the active site as for other HD-GYPs, and we show that it binds to a wide range of transition metals with similar affinities. Moreover, the structural features of PA4781 indicate that this is preferentially a pGpG binding protein, as we previously suggested. Our results point out that the structural features of HD-GYPs are more complex than predicted so far and identify the HD-GYP domain as...
The HD-GYP domain, named after two of its conserved sequence motifs, was first described in 1999 as a specialized version of the widespread HD phosphohydrolase domain that had additional highly conserved amino acid residues. Domain associations of HD-GYP indicated its involvement in bacterial signal transduction and distribution patterns of this domain suggested that it could serve as a hydrolase of the bacterial second messenger c-di-GMP, in addition to or instead of the EAL domain. Subsequent studies confirmed the ability of various HD-GYP domains to hydrolyze c-di-GMP to linear pGpG and/or GMP. Certain HD-GYP-containing proteins hydrolyze another second messenger, cGAMP, and some HD-GYP domains participate in regulatory protein-protein interactions. The recently solved structures of HD-GYP domains from four distinct organisms clarified the mechanisms of c-di-GMP binding and metal-assisted hydrolysis. However, the HD-GYP domain is poorly represented in public domain databases, which causes certain confusion about its phylogenetic distribution, functions, and domain architectures. Here, we present a refined sequence model for the HD-GYP domain and describe the roles of its most conserved residues in metal and/or substrate binding. We also calculate the numbers of HD-GYPs encoded in various genomes and list the most common domain combinations involving HD-GYP, such as the RpfG (REC-HD-GYP), Bd1817 (DUF3391-HD-GYP), and PmGH (GAF-HD-GYP) protein families. We also provide the descriptions of six HD-GYP-associated domains, including four novel integral membrane sensor domains. This work is expected to stimulate studies of diverse HD-GYP-containing proteins, their N-terminal sensor domains and the signals to which they respond.
Journal of Bacteriology, 2015
The intracellular level of the bacterial secondary messenger cyclic di-3′,5′-GMP (c-di-GMP) is determined by a balance between its biosynthesis and degradation, the latter achieved via dedicated phosphodiesterases (PDEs) bearing a characteristic EAL or HD-GYP domain. We here report the crystal structure of PA4781, one of the three Pseudomonas aeruginosa HD-GYP proteins, which we have previously characterized in vitro . The structure shows a bimetallic active site whose metal binding mode is different from those of both HD-GYP PDEs characterized so far. Purified PA4781 does not contain iron in the active site as for other HD-GYPs, and we show that it binds to a wide range of transition metals with similar affinities. Moreover, the structural features of PA4781 indicate that this is preferentially a pGpG binding protein, as we previously suggested. Our results point out that the structural features of HD-GYPs are more complex than predicted so far and identify the HD-GYP domain as a c...
Biochemistry, 2004
The 2-haloalkanoic acid dehalogenase (HAD) family, which contains both carbon and phosphoryl transferases, is one of the largest known enzyme superfamilies. HAD members conserve an R, -core domain that frames the four-loop active-site platform. Each loop contributes one or more catalytic groups, which function in mediating the core chemistry (i.e., group transfer). In this paper, we provide evidence that the number of carboxylate residues on loop 4 and their positions (stations) on the loop are determinants, and therefore reliable sequence markers, for metal ion activation among HAD family members. Using this predictor, we conclude that the vast majority of the HAD members utilize a metal cofactor. Analysis of the minimum requirements for metal cofactor binding was carried out using Mg-(II)-activated Bacillus cereus phosphonoacetaldehyde hydrolase (phosphonatase) as an experimental model for metal-activated HAD members. Mg(II) binding occurs via ligation to the loop 1 Asp12 carboxylate and Thr14 backbone carbonyl and to the loop 4 Asp186 carboxylate. The loop 4 Asp190 forms a hydrogen bond to the Mg(II) water ligand. X-ray structure determination of the D12A mutant in the presence of the substrate phosphonoacetaldehyde showed that replacement of the loop 1 Asp, common to all HAD family members, with Ala shifts the position of Mg(II), thereby allowing innersphere coordination to Asp190 and causing a shift in the position of the substrate. Kinetic analysis of the loop 4 mutants showed that Asp186 is essential to cofactor binding while Asp190 simply enhances it. Within the phosphonatase subfamily, Asp186 is stringently conserved, while either position 185 or position 190 is used to position the second loop 4 Asp residue. Retention of a high level of catalytic activity in the G185D/D190G phosphonatase mutant demonstrated the plasticity of the metal binding loop, reflected in the variety of combinations in positioning of two or three Asp residues along the seven-residue motif of the 2700 potential HAD sequences that were examined.
Molego-based definition of the architecture and specificity of metal-binding sites
Proteins: Structure, Function, and Bioinformatics, 2004
Decomposing proteins into "molegos," building blocks that are conserved in sequence and 3D-structure, can identify functional elements. To demonstrate the specificity of the decomposition method, the PCPMer program suite was used to numerically define physical chemical property motifs corresponding to the molegos that make up the metal-containing active sites of three distinct enzyme families, from the dimetallic phosphatases, DNase 1 related nucleases/phosphatases, and dioxygenases. All three superfamilies bind metal ions in a -strand core region but differ in the number and type of ions needed for activity. The motifs were then used to automatically identify proteins in the ASTRAL40 database that contained similar motifs. The proteins with the highest PCPMer score in the database were primarily metal-binding enzymes that were related in function to those in the alignment used to generate the PCPMer motif lists. The proteins that contained motifs similar to the dioxygenases differed from those found with PCP-motifs for phosphatases and nucleases. Relatively few metal-binding enzymes were detected when the search was done with PCP-motifs defined for interleukin-1 related proteins, which have a -strand core but do not bind metal ions. While the box architecture was constant in each superfamily, the specificity for the metal ion preferred for enzymatic activity is determined by the pattern of carbonyl, hydroxyl or imadazole groups in key positions in the molegos. These results have implications for the design of metal-binding enzymes, and illustrate the ability of the PCPMer approach to distinguish, at the sequence level, structural and functional elements. Proteins 2005;58:200 -210.
Biochemistry, 2011
The explosion of protein sequence information requires that current strategies for function assignment must evolve to complement experimental approaches with computationally-based function prediction. This necessitates the development of strategies based on the identification of sequence markers in the form of specificity determinants and a more informed definition of orthologues. Herein, we have undertaken the function assignment of the unknown Haloalkanoate Dehalogenase superfamily member BT2127 (Uniprot accession # Q8A5V9) from Bacteroides thetaiotaomicron using an integrated bioinformatics/structure/mechanism approach. The substrate specificity profile and steady-state rate constants of BT2127 (with k cat /K m value for pyrophosphate of ∼1 × 10 5 M −1 s −1 ), together with the gene context, supports the assigned in vivo function as an inorganic pyrophosphatase. The X-ray structural analysis of the wild-type BT2127 and several variants generated by site-directed mutagenesis shows that substrate discrimination is based, in part, on active site space restrictions imposed by the cap domain (specifically by residues Tyr76 and Glu47). Structure guided site directed mutagenesis coupled with kinetic analysis of the mutant enzymes identified the residues required for catalysis, substrate binding, and domaindomain association. Based on this structure-function analysis, the catalytic residues Asp11, Asp13, Thr113, and Lys147 as well the metal binding residues Asp171, Asn172 and Glu47 were used as + This work was supported by NIH grants U54 GM093342 (K.N.A., D.D.-M., and S. A.), N.I.H. grant GM61099 * To whom correspondence should be addressed regarding X-ray structure determination (S.A. or K.N.A.) or kinetic analyses (
Inorganic Chemistry, 2010
The glycerophosphodiesterase (GpdQ) from Enterobacter aerogenes is a promiscuous, dinuclear metallohydrolase that has potential application in the remediation of organophosphate nerve agents and pesticides. GpdQ employs an unusual reaction mechanism in which the enzyme is predominantly mononuclear in the resting state, and substrate binding induces the formation of the catalytically competent dinuclear center (Hadler et al. J. Am. Chem. Soc. 2008, 130, 14129). Reactivity is further modulated by the coordination flexibility of Asn80, a ligand that binds to the second, loosely bound metal ion (Hadler et al. J. Am. Chem. Soc. 2009, 131, 11900). It is proposed that hydrolysis is initiated by a terminal, metal-bound hydroxide molecule which is activated at unusually low pH by electrostatic/hydrogen bonding interactions with a bridging hydroxide species. In this study, electronic structure analysis of the dinuclear center is employed to study the coordination environment of the dinuclear center at the resting and product-bound stage of catalysis. This is achieved through the use of variable temperature, variable field magnetic circular dichroism experiments involving the Co(II)-substituted wild type enzyme and its Asn80Asp variant. The data support the above model for the catalytic mechanism whereby the metal ion-bridging hydroxide molecule activates a terminally bound hydroxide nucleophile. Replacement of Asn80 by an aspartate residue does prevent coordination flexibility but also leads to cleavage of the μ-hydroxide bridge and reduced reactivity. This is the first study to investigate the electronic structure of an enzyme with a μ-1,1-carboxylate bridged dicobalt(II) center.
The Internet Journal of Genomics and Proteomics, 2010
2CQZ, a hypothetical protein from Pyrococcus horikoshii OT3 was selected to study the presence of domain regions based on similarity search using BLASTp (Basic Local Alignment Search Tool for protein) server against non-redundant databases of NCBI (National Centre for Biotechnology Information). Similarity analysis revealed matches with oxetanocin-like protein, metal dependent phosphohydrolases and HD domain containing proteins, respectively. Further multiple alignments were constructed to recognize the regions of conserved residues. From our analysis and Pfam entry PF01966 it was identified that this protein is known to contain a HD domain motif. 2CQZ showed highest similarity with oxetanocin-like protein and moderate similarities with metal-dependent phosphohydrolases and HD domain proteins. Finally, it was observed that the metal-coordinating HD motif (H33, H68, D69, and D137) and other conserved residues (R18, E72, and D77), important for activity are retained in 2CQZ and the protein thus belongs to the superfamily of metal-dependent phosphohydrolases.
History of biological metal utilization inferred through phylogenomic analysis of protein structures
2010
The fundamental chemistry of trace elements dictates the molecular speciation and reactivity both within cells and the environment at large. Using protein structure and comparative genomics, we elucidate several major influences this chemistry has had upon biology. All of life exhibits the same proteome size-dependent scaling for the number of metal-binding proteins within a proteome. This fundamental evolutionary constant shows that the selection of one element occurs at the exclusion of another, with the eschewal of Fe for Zn and Ca being a defining feature of eukaryotic proteomes. Early life lacked both the structures required to control intracellular metal concentrations and the metal-binding proteins that catalyze electron transport and redox transformations. The development of protein structures for metal homeostasis coincided with the emergence of metal-specific structures, which predominantly bound metals abundant in the Archean ocean. Potentially, this promoted the diversification of emerging lineages of Archaea and Bacteria through the establishment of biogeochemical cycles. In contrast, structures binding Cu and Zn evolved much later, providing further evidence that environmental availability influenced the selection of the elements. The late evolving Zn-binding proteins are fundamental to eukaryotic cellular biology, and Zn bioavailability may have been a limiting factor in eukaryotic evolution. The results presented here provide an evolutionary timeline based on genomic characteristics, and key hypotheses can be tested by alternative geochemical methods.