The peroxisome proliferator-activated receptors (PPARs) are nuclear receptors involved in the regulation of the metabolic homeostasis and therefore represent valuable therapeutic targets for the treatment of metabolic diseases. The development of more balanced drugs interacting with PPARs, devoid of the side-effects showed by the currently marketed PPARγ full agonists, is considered the major challenge for the pharmaceutical companies. Here we present a structure-based virtual screening approach that let us identify a novel PPAR pan-agonist with a very attractive activity profile and its crystal structure in the complex with PPARα and PPARγ, respectively. In PPARα this ligand occupies a new pocket whose filling is allowed by the ligand-induced switching of the F273 side chain from a closed to an open conformation. The comparison between this pocket and the corresponding cavity in PPARγ provides a rationale for the different activation of the ligand towards PPARα and PPARγ, suggesting a novel basis for ligand design.
Intersubunit Ionic Interactions Stabilize the Nucleoside Diphosphate Kinase of Mycobacterium tuberculosis
Most nucleoside diphosphate kinases (NDPKs) are hexamers. The C-terminal tail interacting with the neighboring subunits is crucial for hexamer stability. In the NDPK from Mycobacterium tuberculosis (Mt) this tail is missing. The quaternary structure of Mt-NDPK is essential for full enzymatic activity and for protein stability to thermal and chemical denaturation. We identified the intersubunit salt bridge Arg80-Asp93 as essential for hexamer stability, compensating for the decreased intersubunit contact area. Breaking the salt bridge by the mutation D93N dramatically decreased protein thermal stability. The mutation also decreased stability to denaturation by urea and guanidinium. The D93N mutant was still hexameric and retained full activity. When exposed to low concentrations of urea it dissociated into folded monomers followed by unfolding while dissociation and unfolding of the wild type simultaneously occur at higher urea concentrations. The dissociation step was not observed in guanidine hydrochloride, suggesting that low concentration of salt may stabilize the hexamer. Indeed, guanidinium and many other salts stabilized the hexamer with a half maximum effect of about 0.1 M, increasing protein thermostability. The crystal structure of the D93N mutant has been solved.
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 conserved scaffold which has evolved to preferentially interact with a partner GGDEF but which harbors different functions obtained through diversification of the active site. IMPORTANCEIn bacteria, the capability to form biofilms, responsible for increased pathogenicity and antibiotic resistance, is almost universally stimulated by the second messenger cyclic di-GMP (c-di-GMP). To design successful strategies for targeting biofilm formation, a detailed characterization of the enzymes involved in c-di-GMP metabolism is crucial. We solved the structure of the HD-GYP domain of PA4781 from Pseudomonas aeruginosa, involved in c-di-GMP degradation. This is the third structure of this class of phosphodiesterases to be solved, and with respect to its homologues, it shows significant differences both in the nature and in the binding mode of the coordinated metals, indicating that HD-GYP proteins are able to fine-tune their function, thereby increasing the chances of the microorganism to adapt to different environmental needs. The dinucleotide cyclic di-GMP (c-di-GMP) serves as a core signal in the coordinated lifestyle switch of most bacteria in response to different environmental stimuli. In particular, high levels of c-di-GMP generally flag hostile conditions and result in reduced motility, attachment, and biofilm formation, while low levels of c-di-GMP indicate that it is time to go back to virulence and cell division (1-5). The intracellular levels of c-di-GMP are fine-tuned by the opposite action of dedicated enzymes: diguanylate cyclases (DGCs) and phosphodiesterases (PDEs) (6). The first class, characterized by a GGDEF domain, synthesize c-di-GMP from two GTP molecules, while the second one hydrolyzes it. PDEs are further divided into two unrelated superfamilies of hydrolases: the more abundant EAL proteins, which degrade c-di-GMP to the linear dinucleotide pGpG, and the HD-GYP proteins, which are able to hydrolyze c-di-GMP into two molecules of GMP. Bacteria display a wide variety of genes encoding these three enzymatic domains,...
To investigate the structural/functional role of the dimeric structure in Cu,Zn superoxide dismutases, we have studied the stability to a variety of agents of the Escherichia coli enzyme, the only monomeric variant of this class so far isolated. Differential scanning calorimetry of the native enzyme showed the presence of two well defined peaks identified as the metal free and holoprotein. Unlike dimeric Cu,Zn superoxide dismutases, the unfolding of the monomeric enzyme was found to be highly reversible, a behavior that may be explained by the absence of free cysteines and the highly polar nature of its molecular surface. The melting temperature of the E. coli enzyme was found to be pH-dependent with the holoenzyme transition centered at 66°C at pH 7.8 and at 79.3°C at pH 6.0. The active-site metals, which were easily displaced from the active site by EDTA, were found to enhance the thermal stability of the monomeric apoprotein but to a lower extent than in the dimeric enzymes from eukaryotic sources. Apo-superoxide dismutase from E. coli was shown to be nearly as stable as the bovine apoenzyme, whose holo form is much more stable and less sensitive to pH variations. The remarkable pH susceptibility of the E. coli enzyme structure was paralleled by the slow decrease in activity of the enzyme incubated at alkaline pH and by modification of the EPR spectrum at lower pH values than in the case of dimeric enzymes. Unlike eukaryotic Cu,Zn superoxide dismutases, the active-site structure of the E. coli enzyme was shown to be reversibly perturbed by urea. These observations suggest that the conformational stability of Cu,Zn superoxide dismutases is largely due to the intrinsic stability of the -barrel fold rather than to the dimeric structure and that pH sensitivity and weak metal binding of the E. coli enzyme are due to higher flexibility and accessibility to the solvent of its activesite region.
Bis-(3'-5')-cyclic diguanylic acid (c-di-GMP) belongs to the class of cyclic dinucleotides, key carriers of cellular information in prokaryotic and eukaryotic signal transduction pathways. In bacteria, the intracellular levels of c-di-GMP and their complex physiological outputs are dynamically regulated by environmental and internal stimuli, which control the antagonistic activities of diguanylate cyclases (DGCs) and c-di-GMP specific phosphodiesterases (PDEs). Allostery is one of the major modulators of the c-di-GMP-dependent response. Both the c-di-GMP molecule and the proteins interacting with this second messenger are characterized by an extraordinary structural plasticity, which has to be taken into account when defining and possibly predicting c-di-GMP-related processes. Here, we report a structure-function relationship study on the catalytic portion of the PA0575 protein from Pseudomonas aeruginosa, bearing both putative DGC and PDE domains. The kinetic and structural studies indicate that the GGDEF-EAL portion is a GTP-dependent PDE. Moreover, the crystal structure confirms the high degree of conformational flexibility of this module. We combined structural analysis and protein engineering studies to propose the possible molecular mechanism guiding the nucleotide-dependent allosteric control of catalysis; we propose that the role exerted by GTP via the GGDEF domain is to allow the two EAL domains to form a dimer, the species competent to enter PDE catalysis.
Modulation of the interaction of regulatory 14-3-3 proteins to their physiological partners through small cell-permeant molecules is a promising strategy to control cellular processes where 14-3-3s are engaged. Here, we show that the fungal phytotoxin fusicoccin (FC), known to stabilize 14-3-3 association to the plant plasma membrane H 1 -ATPase, is able to stabilize 14-3-3 interaction to several client proteins with a mode III binding motif. Isothermal titration calorimetry analysis of the interaction between 14-3-3s and different peptides reproducing a mode III binding site demonstrated the FC ability to stimulate 14-3-3 the association. Moreover, molecular docking studies provided the structural rationale for the differential FC effect, which exclusively depends on the biochemical properties of the residue in peptide C-terminal position. Our study proposes FC as a promising tool to control cellular processes regulated by 14-3-3 proteins, opening new perspectives on its potential pharmacological applications. V C 2014 IUBMB Life, 66(1): [52][53][54][55][56][57][58][59][60][61][62] 2014
Thermal Stability of Hexameric and Tetrameric Nucleoside Diphosphate Kinases
The eukaryotic nucleoside diphosphate (NDP) kinases are hexamers, while the bacterial NDP kinases are tetramers made of small, single domain subunits. These enzymes represent an ideal model for studying the effect of subunit interaction on protein stability. The thermostability of NDP kinases of each class was studied by differential scanning calorimetry and biochemical methods. The hexameric NDP kinase from Dictyostelium discoideum displays one single, irreversible differential scanning calorimetry peak (T m 62°C) over a broad protein concentration, indicating a single step denaturation. The thermal stability of the protein was increased by ADP. The P105G substitution, which affects a loop implicated in subunit contacts, yields a protein that reversibly dissociates to folded monomers at 38°C before the irreversible denaturation occurs (T m 47°C). ADP delays the dissociation, but does not change the T m . These data indicate a "coupling" of the quaternary structure with the tertiary structure in the wild-type, but not in the mutated protein. We describe the x-ray structure of the P105G mutant at 2.2-Å resolution. It is very similar to that of the wild-type protein. Therefore, a minimal change in the structure leads to a dramatic change of protein thermostability. The NDP kinase from Escherichia coli behaves like the P105G mutant of the Dictyostelium NDP kinase. The detailed study of their thermostability is important, since biological effects of thermolabile NDP kinases have been described in several organisms.A large number of proteins are active as homo-or heterooligomers. In some cases, the quaternary structure is needed for allosteric regulation, substrate/product channeling, or signal transduction. In other cases, the biological significance of the quaternary structure is elusive. For instance, several nonallosteric enzymes are homo-oligomers (Jaenicke, 1991). One potential advantage is the contribution of the interaction energy between subunits for the global stabilization of the protein. The stability of oligomeric proteins is by far less studied as compared with monomeric proteins. It is fundamental, however, for understanding their function.Nucleoside diphosphate (NDP) 1 kinase is a suitable model for studying the effect of subunit interaction on protein stability. The high resolution x-ray structures of the NDP kinases from Dictyostelium (Moréra et al., 1994a), Myxococcus xanthus (Williams et al., 1993), Drosophila (Chiadmi et al., 1993), and of the human NDP kinase B (Webb et al., 1995;Moréra et al., 1995b) are now available. On the other hand, the structure of complexes of NDP kinases with nucleotides (Moréra et al., 1994b;Cherfils et al., 1994) as well as the structure of the phosphorylated intermediate (Moréra et al., 1995a) were determined. The subunits are small and are built of one structural domain only. The NDP kinase sequences are highly conserved throughout evolution (Ͼ60% identity between the eukaryotic enzymes, Ͼ45% identity between the procaryotic and the eukaryotic enzymes). A distinctiv...
A series of ureidofibrate-like derivatives was prepared and assayed for their PPAR functional activity. A calorimetric approach was used to characterize PPARγ-ligand interactions, and docking experiments and X-ray studies were performed to explain the observed potency and efficacy. R-1 and S-1 were selected to evaluate several aspects of their biological activity. In an adipogenic assay, both enantiomers increased the expression of PPARγ target genes and promoted the differentiation of 3T3-L1 fibroblasts to adipocytes. In vivo administration of these compounds to insulin resistant C57Bl/6J mice fed a high fat diet reduced visceral fat content and body weight. Examination of different metabolic parameters showed that R-1 and S-1 are insulin sensitizers. Notably, they also enhanced the expression of hepatic PPARα target genes indicating that their in vivo effects stemmed from an activation of both PPARα and γ. Finally, the capability of R-1 and S-1 to inhibit cellular proliferation in colon cancer cell lines was also evaluated.
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