Molecular rearrangements in the ligand-binding domain of cyclic nucleotide-gated channels

Cyclic nucleotide-gated (CNG) channels are activated in response to the direct binding of cyclic nucleotides to an intracellular domain. This domain is thought to contain a beta roll and two alpha helices, designated the B and C helices. To probe the conformational changes occurring in the ligand-binding domain during channel activation, we used the substituted cysteine accessibility method (SCAM). We found that a residue in the beta roll, C505, is more accessible in unliganded channels than in liganded channels, whereas a residue in the C helix, G597C, is more accessible in closed channels than in open channels. These results support a molecular mechanism for channel activation in which the ligand initially binds to the beta roll, followed by an opening allosteric transition involving the relative movement of the C helix toward the beta roll.     

Investigating the accessibility of the closed domain conformation of citrate synthase using essential dynamics sampling

A molecular dynamics study of pig heart citrate synthase is presented that aims to directly address the question of whether, for this enzyme, the ligand-induced closed domain conformation is accessible to the open unliganded enzyme. The approach utilises the technique of essential dynamics sampling, which is used in two modes. In exploring mode, the enzyme is encouraged to explore domain conformations it might not normally sample in free molecular dynamics simulation. In targeting mode, the enzyme is encouraged to adopt the domain conformation of a target structure. Using both modes extensively, it has been found that when the enzyme is prepared from a crystallographic open-domain structure and is in the unliganded state, it is unable to adopt the crystallographic closed-domain conformation of the liganded enzyme. Likewise, when the enzyme is prepared from the crystallographic closed liganded conformation with the ligands removed, it is unable to adopt the crystallographic open domain conformation. Structural investigations point to a common structural difference that is the source of this energy barrier; namely, the shift of alpha-helix 328-341 along its own axis relative to the large domain. Without this shift, the domains are unable to close or open fully. The charged substrate, oxaloacetate, binds near the base of this helix in the large domain and the interaction of Arg329 at the base of the helix with oxaloacetate is one that is consistent with the shift of this helix in going from the crystallographic open to closed structure. Therefore, the results suggest that without the substrate the enzyme remains in a partially open conformation ready to receive the substrate. In this way, the efficiency of the enzyme should be increased over one that is closed part of the time, with its binding site inaccessible to the substrate.     

Structures of the alpha L I domain and its complex with ICAM-1 reveal a shape-shifting pathway for integrin regulation

The structure of the I domain of integrin alpha L beta 2 bound to the Ig superfamily ligand ICAM-1 reveals the open ligand binding conformation and the first example of an integrin-IgSF interface. The I domain Mg2+ directly coordinates Glu-34 of ICAM-1, and a dramatic swing of I domain residue Glu-241 enables a critical salt bridge. Liganded and unliganded structures for both high- and intermediate-affinity mutant I domains reveal that ligand binding can induce conformational change in the alpha L I domain and that allosteric signals can convert the closed conformation to intermediate or open conformations without ligand binding. Pulling down on the C-terminal alpha 7 helix with introduced disulfide bonds ratchets the beta 6-alpha 7 loop into three different positions in the closed, intermediate, and open conformations, with a progressive increase in affinity.     

Investigation of the mechanism of domain closure in citrate synthase by molecular dynamics simulation

Six, 2 ns molecular dynamics simulations have been performed on the homodimeric enzyme citrate synthase. In three, both monomers were started from the open, unliganded X-ray conformation. In the remaining three, both monomers started from a closed, liganded X-ray conformation, with the ligands removed. Projecting the motion from the simulations onto the experimental domain motion revealed that the free-energy profile is rather flat around the open conformation, with steep sides. The most closed conformations correspond to hinge-bending angles of 12-14 compared to the 20 degrees that occurs upon the binding of oxaloacetate. It is also found that the open, unliganded X-ray conformation is situated at the edge of the steep rise in free energy, although conformations that are about 5 degrees more open were sampled. A rigid-body essential dynamics analysis of the combined open trajectories has shown that domain motions in the direction of the closed X-ray conformation are compatible with the natural domain motion of the unliganded protein, which has just two main degrees of freedom. The simulations starting from the closed conformation suggest a free-energy profile with a small barrier in going from the closed to open conformation. A combined essential dynamics and hinge-bending analysis of a trajectory that spontaneously converts from the closed to open state shows an almost exact correspondence to the experimental transition that occurs upon ligand binding. The simulations support the conclusion from an earlier analysis of the experimental transition that the beta-hairpin acts as a mechanical hinge by attaching the small domain to the large domain through a conserved main-chain hydrogen bond and salt-bridges, and allowing rotation to occur via its two flexible termini. The results point to a mechanism of domain closure in citrate synthase that has analogy to the process of closing a door.     

Crystal structure of Bordetella pertussis BugD solute receptor unveils the basis of ligand binding in a new family of periplasmic binding proteins

Periplasmic binding proteins of a new family particularly well represented in Bordetella pertussis have been called Bug receptors. One B.pertussis Bug protein is part of a tripartite tricarboxylate transporter while the functions of the other 77 are unknown. We report the first structure of a Bug receptor, BugD. It adopts the characteristic Venus flytrap motif observed in other periplasmic binding proteins, with two globular domains bisected by a deep cleft. BugD displays a closed conformation resulting from the fortuitous capture of a ligand, identified from the electron density as an aspartate. The structure reveals a distinctive alpha carboxylate-binding motif, involving two water molecules that bridge the carboxylate oxygen atoms to the protein. Both water molecules are hydrogen bonded to a common carbonyl group from Ala14, and each forms a hydrogen bond with one carboxylate oxygen atom of the ligand. Additional hydrogen bonds are found between the ligand alpha carboxylate oxygen atoms and protein backbone amide groups and with a threonine hydroxyl group. This specific ligand-binding motif is highly conserved in Bug proteins, indicating that they may all be receptors of amino acids or other carboxylated solutes, with a similar binding mode. The present structure thus unveils the bases of ligand binding in this large family of periplasmic binding proteins, several hundred members of which have been identified in various bacterial species.     

Identification of specific interactions that drive ligand-induced closure in five enzymes with classic domain movements

In order to better understand ligand-induced closure in domain enzymes, open unliganded X-ray structures and closed liganded X-ray structures have been studied in five enzymes: adenylate kinase, aspartate aminotransferase, citrate synthase, liver alcohol dehydrogenase, and the catalytic subunit of cAMP-dependent protein kinase. A sequential model of ligand binding and domain closure was used to test the hypothesis that the ligand actively drives closure from an open conformation. The analysis supports the assumption that each enzyme has a dedicated binding domain to which the ligand binds first and a closing domain. In every case, a small number of residues are identified to interact with the ligand to initiate and drive domain closure. In all cases except adenylate kinase, the backbone of residues located in an interdomain-bending region (hinge site) is identified to interact with the ligand to aid in driving closure. In adenylate kinase, the side-chain of a residue located directly adjacent to a bending region drives closure. It is thought that by binding near a hinge site the ligand is able to get within interaction range of residues when the enzyme is in the open conformation. Interdomain bending regions not involved in inducing closure are involved in control, helping to determine the location of the hinge axis. Similarities have been discovered between aspartate aminotransferase and citrate synthase that only come to light in the context of their dynamical behaviour in response to binding their substrate. Similarity also exists between liver alcohol dehydrogenase and cAMP-dependent protein kinase whereby groups on NAD and ATP, respectively, mimic the backbone of a single amino acid residue in a process where a three residue segment located at the terminus of a beta-sheet, moves to form hydrogen bonds with the mimic that resemble those found in a parallel beta-sheet. This interaction helps to drive domain closure in a process that has analogy to protein folding.     

The mutation beta 99 Asp-Tyr stabilizes Y--a new, composite quaternary state of human hemoglobin

Carbonmonoxy hemoglobin Ypsilanti (beta 99 Asp-Tyr) exhibits a quaternary form distinctly different from any structures previously observed for human hemoglobins. The relative orientation of alpha beta dimers in the new quaternary form lies well outside the range of values observed for normal unliganded and liganded tetramers (Baldwin, J., Chothia, C., J. Mol. Biol. 129:175-220, 1979). Despite this large quaternary structural difference between carbonmonoxy hemoglobin Ypsilanti and the two canonical structures, the new quaternary structure's hydrogen bonding interactions in the "switch" region, and packing interactions in the "flexible joint" region, show noncovalent interactions characteristic of the alpha 1 beta 2 contacts of both unliganded and liganded normal hemoglobins. In contrast to both canonical structures, the beta 97 histidine residue in carbonmonoxy hemoglobin Ypsilanti is disengaged from quaternary packing interactions that are generally believed to enforce two-state behavior in ligand binding. These features of the new quaternary structure, denoted Y, may therefore be representative of quaternary states that occur transiently along pathways between the normal unliganded, T, and liganded, R, hemoglobin structures.     

Crystal structure of the HNF4 alpha ligand binding domain in complex with endogenous fatty acid ligand

HNF4 alpha is an orphan member of the nuclear receptor family with prominent functions in liver, gut, kidney and pancreatic beta cells. We have solved the x-ray crystal structure of the HNF4 alpha ligand binding domain, which adopts a canonical fold. Two conformational states are present within each homodimer: an open form with alpha helix 12 (alpha 12) extended and collinear with alpha 10 and a closed form with alpha 12 folded against the body of the domain. Although the protein was crystallized without added ligands, the ligand binding pockets of both closed and open forms contain fatty acids. The carboxylic acid headgroup of the fatty acid ion pairs with the guanidinium group of Arg(226) at one end of the ligand binding pocket, while the aliphatic chain fills a long, narrow channel that is lined with hydrophobic residues. These findings suggest that fatty acids are endogenous ligands for HNF4 alpha and establish a framework for understanding how HNF4 alpha activity is enhanced by ligand binding and diminished by MODY1 mutations.     

Evaluation of the relative stability of liganded versus ligand-free protein conformations using Simplicial Neighborhood Analysis of Protein Packing (SNAPP) method

Many proteins change their conformation upon ligand binding. For instance, bacterial periplasmic binding proteins (bPBPs), which transport nutrients into the cytoplasm, generally consist of two globular domains connected by strands, forming a hinge. During ligand binding, hinge motion changes the conformation from the open to the closed form. Both forms can be crystallized without a ligand, suggesting that the energy difference between them is small. We applied Simplicial Neighborhood Analysis of Protein Packing (SNAPP) as a method to evaluate the relative stability of open and closed forms in bPBPs. Using united residue representation of amino acids, SNAPP performs Delaunay tessellation of the protein, producing an aggregate of space-filling, irregular tetrahedra with nearest neighbor residues at the vertices. The SNAPP statistical scoring function is derived from log-likelihood scores for all possible quadruplet compositions of amino acids found in a representative subset of the Protein Data Bank, and the sum of the scores for a given protein provides the total SNAPP score. Results of scoring for bPBPs suggest that in most cases, the unliganded form is more stable than the liganded form, and this conclusion is corroborated by similar observations of other proteins undergoing conformation changes upon binding their ligands. The results of these studies suggest that the SNAPP method can be used to predict the relative stability of accessible protein conformations. Furthermore, the SNAPP method allows delineation of the role of individual residues in protein stabilization, thereby providing new testable hypotheses for rational site-directed mutagenesis in the context of protein engineering.     

Structural basis of beta-adrenergic receptor function

Receptors that mediate their actions by stimulating guanine nucleotide binding regulatory proteins (G proteins) share structural as well as functional similarities. The structural motif characteristic of receptors of this class includes seven hydrophobic putative transmembrane domains linked by hydrophilic loops. Genetic analysis of the beta-adrenergic receptor (beta AR) revealed that the ligand binding domain of this receptor, like that of rhodopsin, involves residues within the hydrophobic core of the protein. On the basis of these studies, a model for ligand binding to the receptor has been developed in which the amino group of an agonist or antagonist is anchored to the receptor through the carboxylate side chain of Asp113 in the third transmembrane helix. Other interactions between specific residues of the receptor and functional groups on the ligand have also been proposed. The interaction between the beta AR and the G protein Gs has been shown to involve an intracellular region that is postulated to form an amphiphilic alpha helix. This region of the beta AR is also critical for sequestration, which accompanies agonist-mediated desensitization, to occur. Structural similarities among G protein-linked receptors suggest that the information gained from the genetic analysis of the beta AR should help define functionally important regions of other receptors of this class.     

The ligand-mediated affinity of brain-type fatty acid-binding protein for membranes determines the directionality of lipophilic cargo transport

The intracellular transport of lipophilic cargoes is a highly dynamic process. In eukaryotic cells, the uptake and release of long-chain fatty acids (LCFAs) are executed by fatty-acid binding proteins. However, how these carriers control the directionality of cargo trafficking remains unclear. Here, we revealed that the unliganded archetypal Drosophila brain-type fatty acid-binding protein (dFABP) possesses a stronger binding affinity than its liganded counterpart for empty nanodiscs (ND). Titrating unliganded dFABP and nanodiscs with LCFAs rescued the broadening of FABP cross-peak intensities in HSQC spectra from a weakened protein–membrane interaction. Two out of the 3 strongest LCFA contacting residues in dFABP identified by NMR HSQC chemical shift perturbation (CSP) are also part of the 30 ND-contacting residues (out of the total 130 residues in dFABP), revealed by attenuated TROSY signal in the presence of lipid ND to apo-like dFABP. Our crystallographic temperature factor data suggest enhanced αII helix dynamics upon LCFA binding, compensating for the entropic loss in the βC-D/βE-F loops. The aliphatic tail of bound LCFA impedes the charge-charge interaction between dFABP and the head groups of the membrane, and dFABP is prone to dissociate from the membrane upon ligand binding. We therefore conclude that lipophilic ligands participate directly in the control of the functionally required membrane association and dissociation of FABPs.     

Conformational Changes and Ligand Recognition of Escherichia colid-Xylose Binding Protein Revealed

ATP binding cassette transport systems account for most import of necessary nutrients in bacteria. The periplasmic binding component (or an equivalent membrane-anchored protein) is critical to recognizing cognate ligand and directing it to the appropriate membrane permease. Here we report the X-ray structures of d-xylose binding protein from Escherichia coli in ligand-free open form, ligand-bound open form, and ligand-bound closed form at 2.15 Å, 2.2 Å, and 2.2 Å resolutions, respectively. The ligand-bound open form is the first such structure to be reported at high resolution; the combination of the three different forms from the same protein furthermore gives unprecedented details concerning the conformational changes involved in binding protein function. As is typical of the structural family, the protein has two similar globular domains, which are connected by a three-stranded hinge region. The open liganded structure shows that xylose binds first to the C-terminal domain, with only very small conformational changes resulting. After a 34° closing motion, additional interactions are formed with the N-terminal domain; changes in this domain are larger and serve to make the structure more ordered near the ligand. An analysis of the interactions suggests why xylose is the preferred ligand. Furthermore, a comparison with the most closely related proteins in the structural family shows that the conformational changes are distinct in each type of binding protein, which may have implications for how the individual proteins act in concert with their respective membrane permeases.     

Characterization of ligand-binding properties of the human BMP type II receptor extracellular domain

ActR-IIA, ActR-IIB, and BMPR-II are low-affinity type II receptors that bind bone morphogenetic proteins (BMPs) in the same overall manner. The binding of BMPs by ActR-IIs has been analyzed structurally and functionally, but no detailed analysis of BMPR-II has been reported. The objective of this study was to determine ligand-binding epitopes and specificity determinants in two regions, the hydrophobic patch and the A-loop of the BMPR-II extracellular domain (ECD). A series of alanine-substituted variants was generated using a recently published X-ray structure of the unliganded form of the ovine BMPR-II ECD as a guide. These variants were characterized using one-dimensional NMR and functional activity assays with BMP-2, BMP-7 and GDF-5 as ligands. The results showed that alanine substitutions of conserved residues W85 and Y113 within the hydrophobic patch of the ECD differentially perturbed BMP ligand binding without disrupting receptor folding, suggesting that they are critical determinants for ligand binding and ligand specificity. Our results further revealed that the nonconserved residue L69 in the hydrophobic patch contributes to ligand-binding activity and specificity. Mutations of several residues within the A-loop resulted in minimal effects on the binding of the different BMP ligands. Overall, these observations identify several amino acid residues that play different roles in BMPR-II and ActR-II and thereby enable BMPR-II and ActR-IIs to bind different subclasses of BMP ligands.     

ATP-induced structural change of dephosphocoenzyme A kinase from Thermus thermophilus HB8

Dephosphocoenzyme A kinase (DCK) catalyzes phosphorylation in the final step of coenzyme A (CoA) biosynthesis. In this phosphorylation process, domain movements play a very important role. To reveal the structural changes induced by ligand binding, we determined the crystal structure of DCK from Thermus thermophilus HB8 by the multiwavelength anomalous dispersion method at 2.8 A. The crystal structure includes three independent protein molecules in the asymmetric unit: One is a liganded form and the others are unliganded. The topology shows a canonical nucleotide-binding protein possessing the P-loop motif. A structure homology search by DALI revealed the similarity of the DCKs from T. thermophilus HB8, Haemophilus influenzae, and Escherichia coli. Structural comparisons between the liganded and unliganded forms of DCK from T. thermophilus HB8 indicated domain movements induced by adenosine triphosphate (ATP) binding. For the domain movements, proline residues confer flexibility at the domain linkages. In particular, Pro91 plays an important role in moving the CoA domain.     

Structural characterization of a new binding motif and a novel binding mode in group 2 WW domains

Formin homology 1 (FH1), is a long proline-rich region of formins, shown to bind to five WW containing proteins named formin binding proteins (FBPs). FH1 has several potential binding regions but only the PPLPx motif and its interaction with FBP11WW1 has been characterized structurally. To detect whether additional motifs exist in FH1, we synthesized five peptides and investigated their interaction with FBP28WW2, FBP11WW1 and FBP11WW2 domains. Peptides of sequence PTPPPLPP (positive control), PPPLIPPPP and PPLIPPPP (new motifs) interact with the domains with micromolar affinity. We observed that FBP28WW2 and FBP11WW2 behave differently from FBP11WW1 in terms of motif selection and affinity, since they prefer a doubly interrupted proline stretch of sequence PPLIPP. We determined the NMR structure of three complexes involving the FBP28WW2 domain and the three ligands. Depending on the peptide under study, the domain interacts with two proline residues accommodated in either the XP or the XP2 groove. This difference represents a one-turn displacement of the domain along the ligand sequence. To understand what drives this behavior, we performed further structural studies with the FBP11WW1 and a mutant of FBP28WW2 mimicking the XP2 groove of FBP11WW1. Our observations suggest that the nature of the XP2 groove and the balance of flexibility/rigidity around loop 1 of the domain contribute to the selection of the final ligand positioning in fully independent domains. Additionally, we analyzed the binding of a double WW domain region, FBP11WW1-2, to a long stretch of FH1 using fluorescence spectroscopy and NMR titrations. With this we show that the presence of two consecutive WW domains may also influence the selection of the binding mode, particularly if both domains can interact with consecutive motifs in the ligand. Our results represent the first observation of protein-ligand recognition where a pair of WW and two consecutive motifs in a ligand participate simultaneously.     

Structure of unliganded GRP94, the endoplasmic reticulum Hsp90. Basis for nucleotide-induced conformational change

GRP94, the endoplasmic reticulum paralog of Hsp90, is regulated by adenosine nucleotides that bind to its N-terminal regulatory domain. Because of its weak affinity for nucleotides, the functionally relevant transition in GRP94 is likely to be between the unliganded and nucleotide-bound states. We have determined the structure of the unliganded GRP94 N-domain. The helix 1-4-5 subdomain of the unliganded protein adopts the closed conformation seen in the structure of the protein in complex with inhibitors. This conformation is distinct from the open conformation of the subdomain seen when the protein is bound to ATP or ADP. ADP soaked into crystals of the unliganded protein reveals an intermediate conformation midway between the open and closed states and demonstrates that in GRP94 the conversion between the open and closed states is driven by ligand binding. The direction of the observed movement in GRP94 shows that nucleotides act to open the subdomain elements rather than close them, which is contrary to the motion proposed for Hsp90. These observations support a model where ATP binding dictates the conformation of the N-domain and regulates its ability to form quaternary structural interactions.     

TR surfaces and conformations required to bind nuclear receptor corepressor

Residues of the TR that are critical for binding the nuclear receptor corepressor (N-CoR) were identified by testing more than 100 separate mutations of the full-length human TRbeta that scan the surface of its ligand binding domain. The primary inferred interaction surface overlaps the surface described for binding of p160 coactivators, but differs by extending to a novel site underneath which helix 12 rests in the liganded TR, rather than including residues of helix 12. Nonconservative mutations of this surface diminished binding similarly to three isolated N-CoR receptor interaction domains (RIDs), but conservative mutations affected binding variably, consistent with a role for this surface in RID selectivity. The commonality of this surface in binding N-CoR was confirmed for the RXRs and ERs. Deletion of helix 12 increased N-CoR binding by the TR modestly, and by the RXR and ER to a much greater extent, indicating a competition between this helix and the corepressor that regulates the extent of corepressor binding by nuclear receptors. When helix 12 was deleted, N-CoR binding by the ER was stimulated by tamoxifen, and binding by the TR was stimulated by Triac, indicating that helix 12 is not the only feature that regulates corepressor binding. Two additional mutationsensitive surfaces were found alongside helix 1, near the previously described CoR box, and above helix 11, nearby but separate from residues that help link receptor in dimers. Based on effects of selected mutations on T(3) and coactivator binding, and on results of combined mutations of the three sites on corepressor binding, we propose that the second and third surfaces stabilize TR unliganded conformation(s) required for efficient N-CoR binding. In transfection assays mutations of all three surfaces impaired the corepressor-mediated functions of unliganded TR repression or activation. These detailed mapping results suggest approaches for selective modulation of corepressor interaction that include the shape of the molecular binding surface, the competitive occupancy by helix 12, pharmacological stimulation, and specific conformational stabilization.