Lenin Domínguez-Ramírez

Different regions of Mlc and NagC, homologous transcriptional repressors controlling expression of the glucose and N-acetylglucosamine phosphotransferase systems in Escherichia coli, are required for inducer signal recognition

Mlc and NagC are two homologous transcription factors which bind to similar DNA targets but for which the inducing signals and mechanisms of activation are very different. Displacing Mlc from its DNA binding sites necessitates its sequestration to the inner membrane via an interaction with PtsG (EIICBGlc), while NagC is displaced from its DNA targets by interacting with GlcNAc6P. We have isolated mutations in both proteins which prevent the inactivation of the repressors by growth on glucose or GlcNAc. These mutations are located in different and specific regions of each protein. For Mlc changes at the C‐terminal make it a constitutive repressor and also prevent it from binding to EIIBGlc. Mutations in NagC, at positions which form a structural motif resembling a glucose binding site in Mlc, produce permanently repressing forms of NagC, suggesting that this motif forms a GlcNAc6P binding site in NagC. The pattern of repression by chimeric proteins of NagC and Mlc confirms the importance of the C‐terminal region of Mlc for both repression and inducer binding and demonstrate that the helix–turn–helix DNA‐binding motif is not sufficient to determine the specificity of interaction of the repressor with DNA.

Conformational dynamics of L-lysine, L-arginine, L-ornithine binding protein reveals ligand-dependent plasticity.

The molecular basis of multiple ligand binding affinity for amino acids in periplasmic binding proteins (PBPs) and in the homologous domain for class C G‐protein coupled receptors is an unsolved question. Here, using unrestrained molecular dynamic simulations, we studied the ligand binding mechanism present in the L‐lysine, L‐arginine, L‐ornithine binding protein. We developed an analysis based on dihedral angles for the description of the conformational changes upon ligand binding. This analysis has an excellent correlation with each of the two main movements described by principal component analysis (PCA) and its more convenient than RMSD measurements to describe the differences in the conformational ensembles observed. Furthermore, an analysis of hydrogen bonds showed specific interactions for each ligand studied as well as the ligand interaction with the aromatic residues Tyr‐14 and Phe‐52. Using uncharged histidine tautomers, these interactions are not observed. On the basis of these results, we propose a model in which hydrogen bond interactions place the ligand in the correct orientation to induce a cation–π interaction with Tyr‐14 and Phe‐52 thereby stabilizing the closed state. Our results also show that this protein adopts slightly different closed conformations to make available specific hydrogen bond interactions for each ligand thus, allowing a single mechanism to attain multiple ligand specificity. These results shed light on the experimental evidence for ligand‐dependent conformational plasticity not explained by the previous crystallographic data. Proteins 2011.

Interactions of subunits Asa2, Asa4 and Asa7 in the peripheral stalk of the mitochondrial ATP synthase of the chlorophycean alga Polytomella sp.

Mitochondrial F1FO-ATP synthase of chlorophycean algae is a complex partially embedded in the inner mitochondrial membrane that is isolated as a highly stable dimer of 1600kDa. It comprises 17 polypeptides, nine of which (subunits Asa1 to 9) are not present in classical mitochondrial ATP synthases and appear to be exclusive of the chlorophycean lineage. In particular, subunits Asa2, Asa4 and Asa7 seem to constitute a section of the peripheral stalk of the enzyme. Here, we over-expressed and purified subunits Asa2, Asa4 and Asa7 and the corresponding amino-terminal and carboxy-terminal halves of Asa4 and Asa7 in order to explore their interactions in vitro, using immunochemical techniques, blue native electrophoresis and affinity chromatography. Asa4 and Asa7 interact strongly, mainly through their carboxy-terminal halves. Asa2 interacts with both Asa7 and Asa4, and also with subunit α in the F1 sector. The three Asa proteins form an Asa2/Asa4/Asa7 subcomplex. The entire Asa7 and the carboxy-terminal half of Asa4 seem to be instrumental in the interaction with Asa2. Based on these results and on computer-generated structural models of the three subunits, we propose a model for the Asa2/Asa4/Asa7 subcomplex and for its disposition in the peripheral stalk of the algal ATP synthase.

β-Lactoglobulin's Conformational Requirements for Ligand Binding at the Calyx and the Dimer Interphase: a Flexible Docking Study

β-lactoglobulin (BLG) is an abundant milk protein relevant for industry and biotechnology, due significantly to its ability to bind a wide range of polar and apolar ligands. While hydrophobic ligand sites are known, sites for hydrophilic ligands such as the prevalent milk sugar, lactose, remain undetermined. Through the use of molecular docking we first, analyzed the known fatty acid binding sites in order to dissect their atomistic determinants and second, predicted the interaction sites for lactose with monomeric and dimeric BLG. We validated our approach against BLG structures co-crystallized with ligands and report a computational setup with a reduced number of flexible residues that is able to reproduce experimental results with high precision. Blind dockings with and without flexible side chains on BLG showed that: i) 13 experimentally-determined ligands fit the calyx requiring minimal movement of up to 7 residues out of the 23 that constitute this binding site. ii) Lactose does not bind the calyx despite conformational flexibility, but binds the dimer interface and an alternate Site C. iii) Results point to a probable lactolation site in the BLG dimer interface, at K141, consistent with previous biochemical findings. In contrast, no accessible lysines are found near Site C. iv) lactose forms hydrogen bonds with residues from both monomers stabilizing the dimer through a claw-like structure. Overall, these results improve our understanding of BLGs binding sites, importantly narrowing down the calyx residues that control ligand binding. Moreover, our results emphasize the importance of the dimer interface as an insufficiently explored, biologically relevant binding site of particular importance for hydrophilic ligands. Furthermore our analyses suggest that BLG is a robust scaffold for multiple ligand-binding, suitable for protein design, and advance our molecular understanding of its ligand sites to a point that allows manipulation to control binding.

Hydrophobic repacking of the dimer interface of triosephosphate isomerase by in silico design and directed evolution.

Triosephosphate isomerase from Saccharomyces cerevisiae (wt-TIM) is an obligated homodimer. The interface of wt-TIM is formed by 34 residues. In the native dimer, each monomer buries nearly 2600 A(2) of accessible surface area (ASA), and 58.4% of the interface ASA is hydrophobic. We determined the thermodynamic and functional consequences of increasing the hydrophobic character of the wt-TIM interface. Mutations were restricted to a cluster of five nonconserved residues located far from the active site. Two different approaches, in silico design and directed evolution, were employed. In both methodologies, the obtained proteins were soluble, dimeric, and compact. In silico-designed proteins are very stable dimers that bind substrate with a wild-type-like K(m); albeit, they exhibited a very low k cat. Proteins obtained from directed evolution experiments show wild-type-like catalytic activity, while their stability is decreased. Hydrophobic replacements at the interface produced a remarkable shift in the dissociation step. For wt-TIM and for TIMs obtained by directed evolution, dissociation was observed in the first transition, with C(1/2) values ranging from 0.58 to 0.024 M GdnHCl, whereas for TIMs generated by in silico design, dissociation occurred in the last transition, with C(1/2) values ranging form 3.01 to 3.65 M GdnHCl. For the latter mutants, the stabilization of the interface changed the equilibrium transitions to a novel four-state process with two dimeric intermediates. The change in the intermediate nature suggests that the relative stabilities of different folding units are similar so that subtle alterations in their stability produce a total transformation of the folding pathway.

Equilibrium between monomeric and dimeric mitochondrial F1–inhibitor protein complexes

Mg‐ATP particles from bovine heart mitochondria have more than 95% of their F1 in complex with the inhibitor protein (IF1). The F1–IF1 complex was solubilized and purified. The question addressed was if this naturally occurring complex existed as monomers or dimers. Size exclusion chromatography and electron microscopy showed that most of the purified F1–IF1 complex was a dimer of two F1–IF1. As determined by the former method, the relative concentrations of dimeric and monomeric F1–IF1 depended on the concentration of protein that was applied to the column. Apparently, there is an equilibrium between the two forms of F1–IF1.

Structural alterations and inhibition of unisite and multisite ATP hydrolysis in soluble mitochondrial F1 by guanidinium chloride.

The effect of guanidinium chloride (GdnHCl) on the ATPase activity and structure of soluble mitochondrial F1 was studied. At high ATP concentrations, hydrolysis is carried by the three catalytic sites of F1; this reaction was strongly inhibited by GdnHCl concentrations of <50 mM. With substoichiometric ATP concentrations, hydrolysis is catalyzed exclusively by the site with the highest affinity. Under these conditions, ATP binding and hydrolysis took place with GdnHCl concentrations of >100 mM; albeit at the latter concentration, the rate of hydrolysis of bound ATP was lower. Similar results were obtained with urea, although nearly 10-fold higher concentrations were required to inhibit multisite hydrolysis. GdnHCl inhibited multisite ATPase activity by diminishing the V(max) of the reaction without significant alterations of the Km for MgATP. GdnHCl prevented the effect of excess ATP on hydrolysis of ATP that was already bound to the high-affinity catalytic site. With and without 100 mM GdnHCl and 100 microM [3H]ATP in the medium, F1 bound 1.6 and 2 adenine nucleotides per F1, respectively. The effect of GdnHCl on some structural features of F1 was also examined. GdnHCl at concentrations that inhibit multisite ATP hydrolysis did not affect the exposure of the cysteines of F1, nor its intrinsic fluorescence. With 100 mM GdnHCl, a concentration at which unisite ATP hydrolysis was still observed, 0.7 cysteine per F1 became solvent-exposed and small changes in its intrinsic fluorescence of F1 were detected. GdnHCl concentrations on the order of 500 mM were required to induce important decreases in intrinsic fluorescence. These changes accompanied inhibition of unisite ATP hydrolysis. The overall data indicate that increasing concentrations of GdnHCl bring about distinct and sequential alterations in the function and structure of F1. With respect to the function of F1, the results show that at low GdnHCl concentrations, only the high-affinity site expresses catalytic activity, and that inhibition of multisite catalysis is due to alterations in the transmission of events between catalytic sites.

Role of cis-trans proline isomerization in the function of pathogenic enterobacterial Periplasmic Binding Proteins

Periplasmic Binding Proteins (PBPs) trap nutrients for their internalization into bacteria by ABC transporters. Ligand binding triggers PBP closure by bringing its two domains together like a Venus flytrap. The atomic determinants that control PBP opening and closure for nutrient capture and release are not known, although it is proposed that opening and ligand release occur while in contact with the ABC transporter for concurrent substrate translocation. In this paper we evaluated the effect of the isomerization of a conserved proline, located near the binding site, on the propensity of PBPs to open and close. ArgT/LAO from Salmonella typhimurium and HisJ from Escherichia coli were studied through molecular mechanics at two different temperatures: 300 and 323 K. Eight microseconds were simulated per protein to analyze protein opening and closure in the absence of the ABC transporter. We show that when the studied proline is in trans, closed empty LAO and HisJ can open. In contrast, with the proline in cis, opening transitions were much less frequent and characterized by smaller changes. The proline in trans also renders the open trap prone to close over a ligand. Our data suggest that the isomerization of this conserved proline modulates the PBP mechanism: the proline in trans allows the exploration of conformational space to produce trap opening and closure, while in cis it restricts PBP movement and could limit ligand release until in productive contact with the ABC transporter. This is the first time that a proline isomerization has been related to the control of a large conformational change like the PBP flytrap mechanism.

A hinge of the endogeneous ATP synthase inhibitor protein : The link between inhibitory and anchoring domains

The ATP synthase of bovine heart mitochondria possesses a regulatory subunit called the endogenous inhibitory protein (IF1). This subunit regulates the catalytic activity of the F1 sector in the mitochondrial inner membrane. When ΔμH+ falls, IF1 binds to the enzyme and inhibits ATP hydrolysis. On the other hand, the establishment of a ΔμH+ induces the release of the inhibitory action of IF1, allowing ATP synthesis to proceed. IF1 is also involved in the dimerization of soluble F1. Dynamic domain analysis and normal mode analysis of the reported crystallographic structure of IF1 revealed that it has an effective hinge formed by residues 46–52. Molecular dynamics data of a 27 residue fragment confirmed the existence of the hinge. The hinge may act as a regulatory region that links the inhibitory and anchoring domains of IF1. The residues assigned to the hinge are conserved between mammals, but not in other species, such as yeasts. Likewise, unlike the heart inhibitor, the yeast protein does not have the residues that allow it to form stable dimers through coiled‐coil interactions. Collectively, the data suggest that the hinge and the dimerization domain of the inhibitor protein from bovine heart are related to its ability to form stable dimers and to interact with other subunits of the ATP synthase. Proteins 2006.