Ligand-linked structural changes in the Escherichia coli biotin repressor: the significance of surface loops for binding and allostery.

The Escherichia coli repressor of biotin biosynthesis (BirA) is an allosteric site-specific DNA-binding protein. BirA catalyzes synthesis of biotinyl-5'-AMP from substrates biotin and ATP and the adenylate serves as the positive allosteric effector in binding of the repressor to the biotin operator sequence. Although a three-dimensional structure of the apo-repressor has been determined by X-ray crystallographic techniques, no structures of any ligand-bound forms of the repressor are yet available. Results of previously published solution studies are consistent with the occurrence of conformational changes in the protein concomitant with ligand binding. In this work the hydroxyl radical footprinting technique has been used to probe changes in reactivity of the peptide backbone of BirA that accompany ligand binding. Results of these studies indicate that binding of biotin to the protein results in protection of regions of the central domain in the vicinity of the active site and the C-terminal domain from chemical cleavage. Biotin-linked changes in reactivity constitute a subset of those linked to adenylate binding. Binding of both bio-5'-AMP and biotin operator DNA suppresses cleavage at additional sites in the amino and carboxy-terminal domains of the protein. Varying degrees of protection of the five surface loops on BirA from hydroxyl radical-mediated cleavage are observed in all complexes. These results implicate the C-terminal domain of BirA, for which no function has previously been known, in small ligand and site-specific DNA binding and highlight the significance of surface loops, some of which are disordered in the apoBirA structure, for ligand binding and transmission of allosteric information in the protein.     

Crystal structures of biotin protein ligase from Pyrococcus horikoshii OT3 and its complexes: structural basis of biotin activation

Biotin protein ligase (EC 6.3.4.15) catalyses the synthesis of an activated form of biotin, biotinyl-5'-AMP, from substrates biotin and ATP followed by biotinylation of the biotin carboxyl carrier protein subunit of acetyl-CoA carboxylase. The three-dimensional structure of biotin protein ligase from Pyrococcus horikoshii OT3 has been determined by X-ray diffraction at 1.6A resolution. The structure reveals a homodimer as the functional unit. Each subunit contains two domains, a larger N-terminal catalytic domain and a smaller C-terminal domain. The structural feature of the active site has been studied by determination of the crystal structures of complexes of the enzyme with biotin, ADP and the reaction intermediate biotinyl-5'-AMP at atomic resolution. This is the first report of the liganded structures of biotin protein ligase with nucleotide and biotinyl-5'-AMP. The structures of the unliganded and the liganded forms are isomorphous except for an ordering of the active site loop upon ligand binding. Catalytic binding sites are suitably arranged to minimize the conformational changes required during the reaction, as the pockets for biotin and nucleotide are located spatially adjacent to each other in a cleft of the catalytic domain and the pocket for biotinyl-5'-AMP binding mimics the combination of those of the substrates. The exact locations of the ligands and the active site residues allow us to propose a general scheme for the first step of the reaction carried out by biotin protein ligase in which the positively charged epsilon-amino group of Lys111 facilitates the nucleophilic attack on the ATP alpha-phosphate group by the biotin carboxyl oxygen atom and stabilizes the negatively charged intermediates.     

Function of a conserved sequence motif in biotin holoenzyme synthetases

The biotin holoenzyme synthetases (BHS) are essential enzymes in all organisms that catalyze post-translational linkage of biotin to biotin-dependent carboxylases. The primary sequences of a large number of these enzymes are now available and homologies are found among all. The glycine-rich sequence, GRGRXG, constitutes one of the homologous regions in these enzymes and, based on its similarity to sequences found in a number of mononucleotide binding enzymes, has been proposed to function in ATP binding in the BHSs. In the Escherichia coli enzyme, the only member of the family for which a three-dimensional structure has been determined, the conserved sequence is found in a partially disordered surface loop. Mutations in the sequence have previously been isolated and characterized in vivo. In this work these single-site mutants, G115S, R118G, and R119W, of the E. coli BHS have been purified and biochemically characterized with respect to binding of small molecule substrates and the intermediate in the biotinylation reaction. Results of this characterization indicate that, rather than functioning in ATP binding, this glycine-rich sequence is required for binding the substrate biotin and the intermediate in the biotinylation reaction, biotinyl-5'-AMP. These results are of general significance for understanding structure-function relationships in biotin holoenzyme synthetases.     

Investigating the binding behaviour of two avidin‐based testosterone binders using molecular recognition force spectroscopy

Molecular recognition force spectroscopy, a biosensing atomic force microscopy technique allows to characterise the dissociation of ligand–receptor complexes at the molecular level. Here, we used molecular recognition force spectroscopy to study the binding capability of recently developed testosterone binders. The two avidin‐based proteins called sbAvd‐1 and sbAvd‐2 are expected to bind both testosterone and biotin but differ in their binding behaviour towards these ligands. To explore the ligand binding and dissociation energy landscape of these proteins, we tethered biotin or testosterone to the atomic force microscopy probe while the testosterone‐binding protein was immobilized on the surface. Repeated formation and rupture of the ligand–receptor complex at different pulling velocities allowed determination of the loading rate dependence of the complex‐rupturing force. In this way, we obtained the molecular dissociation rate (k_off) and energy landscape distances (x_β) of the four possible complexes: sbAvd‐1‐biotin, sbAvd‐1‐testosterone, sbAvd‐2‐biotin and sbAvd‐2‐testosterone. It was found that the kinetic off‐rates for both proteins and both ligands are similar. In contrast, the x_β values, as well as the probability of complex formations, varied considerably. In addition, competitive binding experiments with biotin and testosterone in solution differ significantly for the two testosterone‐binding proteins, implying a decreased cross‐reactivity of sbAvd‐2. Unravelling the binding behaviour of the investigated testosterone‐binding proteins is expected to improve their usability for possible sensing applications. Copyright © 2014 John Wiley & Sons, Ltd.     

Co-repressor induced order and biotin repressor dimerization: a case for divergent followed by convergent evolution

BirA catalyzes the adenylation and subsequent covalent attachment of biotin to the biotin carboxyl carrier protein (BCCP). In the absence of apo-BCCP, biotin-5'-AMP acts as a co-repressor that induces BirA dimerization and binding to the bio operator to repress biotin biosynthesis. The crystal structures of apo-BirA, and BirA in complex with biotin have been reported. We here describe the 2.8A resolution crystal structure of BirA in complex with the co-repressor analog biotinol-5'-AMP. It was previously shown that the structure of apo-BirA is monomeric and that binding of biotin weakly induces a dimeric structure in which three disordered surface loops become organized to form the dimer interface. The structure of the co-repressor complex is also a dimer, clearly related to the BirA.biotin structure, but with several significant conformational changes. A hitherto disordered "adenylate binding loop" forms a well-defined structure covering the co-repressor. The co-repressor buttresses the dimer interface, resulting in improved packing and a 12 degrees change in the hinge-bending angle along the dimer interface relative to the BirA.biotin structure. This helps explain why the binding of the co-repressor is necessary to optimize the binding of BirA to the bioO operator. The structure reveals an unexpected use of the nucleotide-binding motif GXGXXG in binding adenylate and controlling the repressor function. Finally, based on structural analysis we propose that the class of adenylating enzymes represented by BirA, lipoate protein ligase and class II tRNA synthetases diverged early and were selected based on their ability to sequester co-factors or amino acid residues, and adenylation activity arose independently through functional convergence.     

Multiple disordered loops function in corepressor-induced dimerization of the biotin repressor

Cooperative association of the Escherichia coli biotin repressor with the biotin operator is allosterically activated by binding of the corepressor, bio-5'-AMP. The corepressor function of the adenylate is due, in part, to its ability to induce repressor dimerization. Since a high-resolution structure of only the apo or unliganded repressor is currently available, the location of the dimerization interface on the protein structure is not known. Here, five mutants in the corepressor-binding domain of the repressor have been analyzed with respect to their DNA-binding and self-assembly properties. Results of these studies reveal that four of the mutant proteins exhibit defects in DNA binding. These same proteins are compromised in self-assembly. Furthermore, in the three-dimensional structure of the apo protein the mutations all lie in partially disordered surface loops, one of which is known to participate directly in corepressor binding. These results suggest that multiple disordered surface loops function in the corepressor-induced dimerization required for sequence-specific DNA binding by the biotin repressor.     

Improved affinity of engineered streptavidin for the Strep-tag II peptide is due to a fixed open conformation of the lid-like loop at the binding site

The Strep-tag II is a nine-amino acid peptide that was developed as an affinity tool for the purification of corresponding fusion proteins on streptavidin columns. The peptide recognizes the same pocket of streptavidin where the natural ligand is normally bound so that biotin or its chemical derivatives can be used for competitive elution. We report here the crystal structures of the streptavidin mutants '1' and '2,' which had been engineered for 10-fold higher affinity towards the Strep-tag II. Both streptavidin mutants carry mutations at positions 44, 45, and 47, that is, in a flexible loop region close to the binding site. The crystal structures of the two apo-proteins and their complexes with the Strep-tag II peptide were refined at resolutions below 2 A. Both in the presence and absence of the peptide, the lid-like loop next to the ligand pocket--comprising residues 45 through 52--adopts an 'open' conformation in all four subunits within the asymmetric unit. The same loop was previously described to be disordered in the wild-type apo-streptavidin and to close over the pocket upon complexation of the natural ligand biotin. Our findings suggest that stabilization of the 'open' loop conformation in the absence of a ligand abolishes the need for conformational rearrangement prior to the docking of the voluminous peptide. Because no direct contacts between the flexible part of the loop and the peptide ligand were detected, it seems likely that the higher affinity of the two streptavidin mutants for the Strep-tag II is caused by a predominantly entropic mechanism.     

Allosteric signaling in the biotin repressor occurs via local folding coupled to global dampening of protein dynamics

The biotin repressor is an allosterically regulated, site-specific DNA-binding protein. Binding of the small ligand bio-5′-AMP activates repressor dimerization, which is a prerequisite to DNA binding. Multiple disorder-to-order transitions, some of which are known to be important for the functional allosteric response, occur in the vicinity of the ligand-binding site concomitant with effector binding to the repressor monomer. In this work, the extent to which these local changes are coupled to additional changes in the structure/dynamics of the repressor was investigated using hydrogen/deuterium exchange coupled to mass spectrometry. Measurements were performed on the apo-protein and on complexes of the protein bound to four different effectors that elicit a range of thermodynamic responses in the repressor. Global exchange measurements indicate that binding of any effector to the intact protein is accompanied by protection from exchange. Mass spectrometric analysis of pepsin-cleavage products generated from the exchanged complexes reveals that the protection is distributed throughout the protein. Furthermore, the magnitude of the level of protection in each peptide from hydrogen/deuterium exchange correlates with the magnitude of the functional allosteric response elicited by a ligand. These results indicate that local structural changes in the binding site that occur concomitant with effector binding nucleate global dampening of dynamics. Moreover, the magnitude of dampening of repressor dynamics tracks with the magnitude of the functional response to effector binding.     

Love–Hate ligands for high resolution analysis of strain in ultra-stable protein/small molecule interaction

The pathway of ligand dissociation and how binding sites respond to force are not well understood for any macromolecule. Force effects on biological receptors have been studied through simulation or force spectroscopy, but not by high resolution structural experiments. To investigate this challenge, we took advantage of the extreme stability of the streptavidin–biotin interaction, a paradigm for understanding non-covalent binding as well as a ubiquitous research tool. We synthesized a series of biotin-conjugates having an unchanged strong-binding biotin moiety, along with pincer-like arms designed to clash with the protein surface: ‘Love–Hate ligands’. The Love–Hate ligands contained various 2,6-di-ortho aryl groups, installed using Suzuki coupling as the last synthetic step, making the steric repulsion highly modular. We determined binding affinity, as well as solving 1.1–1.6 Å resolution crystal structures of streptavidin bound to Love–Hate ligands. Striking distortion of streptavidin’s binding contacts was found for these complexes. Hydrogen bonds to biotin’s ureido and thiophene rings were preserved for all the ligands, but biotin’s valeryl tail was distorted from the classic conformation. Streptavidin’s L3/4 loop, normally forming multiple energetically-important hydrogen bonds to biotin, was forced away by clashes with Love–Hate ligands, but Ser45 from L3/4 could adapt to hydrogen-bond to a different part of the ligand. This approach of preparing conflicted ligands represents a direct way to visualize strained biological interactions and test protein plasticity.     

Avidin binding of biotinylated analogues of substance P

We report the bioactivities of three biotinylated analogues of Substance P, [alpha-biotinyl-Lys3]Substance P-(3-11), [alpha-biotinyl-Arg1]Substance P, [epsilon-biotinyl-Lys3]Substance P, as well as the bioactivities of their complexes with avidin on guinea pig ileum. The rate of dissociation of an [alpha-biotinyl-Arg1]Substance P-avidin complex has been determined in the presence of 2-(4'-hydroxyazobenzene) benzoic acid and [3H]biotin. The biphasic dissociation of a 4:4 complex between [alpha-biotinyl-Arg1]Substance P and avidin led us to postulate the existence of two sets of binding sites, with the following rates of dissociation, at 4 degrees C, kappa-1 = 6 x 10(-4) x s-1 and kappa-1 = 1.2 x 10(-5) x s-1. We have confirmed this non-equivalence of the four binding sites of avidin by nuclear magnetic resonance using a spin-echo technique. The [alpha-biotinyl-Arg1]Substance P-avidin may be used for the affinity chromatography of Substance P receptors and the decreased affinity of this complex may be taken as an advantage since it can be displaced under mild conditions, i.e. by biotin-containing buffer.     

Origins of PDZ domain ligand specificity. Structure determination and mutagenesis of the Erbin PDZ domain

The LAP (leucine-rich repeat and PDZ-containing) family of proteins play a role in maintaining epithelial and neuronal cell size, and mutation of these proteins can have oncogenic consequences. The LAP protein Erbin has been implicated previously in a number of cellular activities by virtue of its PDZ domain-dependent association with the C termini of both ERB-B2 and the p120-catenins. The present work describes the NMR structure of Erbin PDZ in complex with a high affinity peptide ligand and includes a comprehensive energetic analysis of both the ligand and PDZ domain side chains responsible for binding. C-terminal phage display has been used to identify preferred ligands, whereas binding affinity measurements provide precise details of the energetic importance of each ligand side chain to binding. Alanine and homolog scanning mutagenesis (in a combinatorial phage display format) identifies Erbin side chains that make energetically important contacts with the ligand. The structure of a phage-optimized peptide (Ac-TGW(-4)ETW(-1)V; IC(50) = approximately 0.15 microm) in complex with Erbin PDZ provides a structural context to understand the binding energetics. In particular, the very favorable interactions with Trp(-1) are not Erbin side chain-mediated (and therefore may be generally applicable to many PDZ domains), whereas the beta2-beta3 loop provides a binding site for the Trp(-4) side chain (specific to Erbin because it has an unusually long loop). These results contribute to a growing appreciation for the importance of at least five ligand C-terminal side chains in determining PDZ domain binding energy and highlight the mechanisms of ligand discrimination among the several hundred PDZ domains present in the human genome.     

Ligands for insulin receptor isolation

Biotinylated insulins are bivalent molecules having the ability to bind to insulin receptors on the one hand and to "avidins" on the other. In order to be useful as ligands for insulin receptor isolation, biotinylated insulins must be developed that have the capacity to bind simultaneously to both and insulin receptor. The present investigation addresses this problem. A series of biotinylated and dethiobiotinylated insulins has been prepared in which the distance between the biotin carboxyl group and the insulin varies from 7 to 20 atoms. These compounds form complexes with succinoylavidin. The dissociation rates (K-1) of these complexes have been determined from the [14C]biotin exchange assay. The dissociation kinetics of most of these complexes are biphasic, and the kinetic constants reported are those corresponding to the slow rate. Ligands containing dethiobiotin dissociate more rapidly than the corresponding biotin derivatives. The interposition of a spacer arm substantially decreases the rate of dissociation. The [14C]biotin exchange assay could not be used with streptavidin complexes of the above ligand since biotin dissociates more rapidly from streptavidin than from succinoylavidin. However, the relative dissociation rates of a series of ligands could be determined and were as follows: 6-(dethiobiotinylamido)-hexanoic acid greater than dethiobiotinyl-A1-insulin greater than biotinylinsulin greater than biotinyl-A1-insulin greater than biotinyl-A2-insulin. Dethiobiotin and its amide failed to form complexes with streptavidin. The affinity of the ligands for insulin receptors was determined by measuring their ability to stimulate 14CO2 formation from [1-14C]glucose in rat epididymal adipocytes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Solid-phase assay for determination of binding parameters of ligand-protein complexes with high dissociation rates

The binding parameters, the affinity constant (Ka) and binding capacity (Q), of a protein possessing ligand-protein complexes with a high dissociation rate (Sex Steroid Binding protein from Bufo arenarum) were determined using a solid-phase method. The technique is based upon the adsorption of the steroid-protein complex to DEAE-cellulose. This method was compared with a nonequilibrium method (charcoal adsorption of free ligand), and the latter resulted in underestimation of both binding parameters, Ka and Q. The solid-phase method reported here is appropriate to determine the binding parameters of proteins with high dissociation rates because the results are independent of the complex half-time. The method also possesses advantages compared to other equilibrium assays such as dialysis or steady-state electrophoresis. With minor modifications, it may be useful to characterize different proteins, particularly those possessing ligand-protein complexes with very high dissociation rates.     

High resolution structure of streptavidin in complex with a novel high affinity peptide tag mimicking the biotin binding motif

A novel peptide was designed which possesses nanomolar affinity of less than 20 nM for streptavidin. Therefore it was termed Nano-tag and has been used as an affinity tag for recombinant proteins. The minimized version of the wild type Nano-tag is a seven-amino acid peptide with the sequence fMDVEAWL. The three-dimensional structure of wild type streptavidin in complex with the minimized Nano-tag was analyzed at atomic resolution of 1.15 A and the details of the binding motif were investigated. The peptide recognizes the same pocket of streptavidin where the natural ligand biotin is bound, but the peptide requires significantly more space than biotin. Therefore the binding loop adopts an "open" conformation in order to release additional space for the peptide. The conformation of the bound Nano-tag corresponds to a 3(10) helix. However, the analysis of the intermolecular interactions of the Nano-tag with residues of the binding pocket of streptavidin reveals astonishing similarities to the biotin binding motif. In principle the three-dimensional conformation of the Nano-tag mimics the binding mode of biotin. Our results explain why the use of the Nano-tag in fusion with recombinant proteins is restricted to their N-terminus and we describe the special significance of the fMet residue for the high affinity binding mode.     

Investigation of a conserved stacking interaction in target site recognition by the U1A protein

Three highly conserved aromatic residues in RNA recognition motifs (RRM) participate in stacking interactions with RNA bases upon binding RNA. We have investigated the contribution of one of these aromatic residues, Phe56, to the complex formed between the N-terminal RRM of the spliceosomal protein U1A and stem–loop 2 of U1 snRNA. Previous work showed that the aromatic group is important for high affinity binding. Here we probe how mutation of Phe56 affects the kinetics of complex dissociation, the strength of the hydrogen bonds formed between U1A and the base that stacks with Phe56 (A6) and specific target site recognition. Substitution of Phe56 with Trp or Tyr increased the rate of dissociation of the complex, consistent with previously reported results. However, substitution of Phe56 with His decreased the rate of complex association, implying a change in the initial formation of the complex. Simultaneous modification of residue 56 and A6 revealed energetic coupling between the aromatic group and the functional groups of A6 that hydrogen bond to U1A. Finally, mutation of Phe56 to Leu reduced the ability of U1A to recognize stem–loop 2 correctly. Taken together, these experiments suggest that Phe56 contributes to binding affinity by stacking with A6 and participating in networks of energetically coupled interactions that enable this conserved aromatic amino acid to play a complex role in target site recognition.     

Role of a heterogeneous free state in the formation of a specific RNA-theophylline complex

The helical regions of RNA are generally very stable, but the single-stranded and loop regions often exist as an ensemble of conformations in solution. The theophylline-binding RNA aptamer forms a very stable structure when bound to the bronchodilator theophylline, but the theophylline binding site is not stably formed in the absence of ligand. The kinetics for theophylline binding were measured here by stopped-flow fluorescence spectroscopy to probe the mechanism for theophylline binding in this RNA aptamer. The kinetic studies showed that formation of the RNA-theophylline complex is over 1000 times slower than a diffusion-controlled rate, and the high affinity of the RNA-theophylline complex arises primarily from a slow dissociation rate for the complex. A theophylline-independent rate was observed for formation of the theophylline-RNA complex at high theophylline concentration, indicating that a conformational change in the RNA is the rate-limiting step in complex formation under these conditions. The RNA-theophylline complex requires divalent metal ions, such as Mg2+, to form a high-affinity complex, and there is a greater than 10000-fold reduction in affinity for theophylline in the absence of Mg2+. This decrease in binding affinity in the absence of Mg2+ results primarily from an increased dissociation rate for the complex. The implications of an ensemble of conformations in the free state of this theophylline-binding RNA are discussed and compared with mechanisms for formation of protein-ligand complexes.     

Description of the low‐affinity interaction between nociceptin and the second extracellular loop of its receptor by fluorescence and NMR spectroscopies

The second extracellular loop (ECL2) of the Noc receptor has been proposed to be involved in ligand binding and selectivity. The interaction of Noc with a constrained cyclic synthetic peptide, mimicking the ECL2, has been studied using fluorescence and NMR spectroscopies. Selective binding was shown with a dissociation constant of ∼10 µM (observed with the constrained cyclic loop and not with the open chain), and residues involved in ligand binding and selectivity have been identified. This bimolecular complex is stabilized by (i) ionic interactions between the two Noc basic motives and the ECL2 acidic residues; (ii) hydrophobic contacts involving Noc FGGF N‐terminal sequence and an ECL2 tryptophane residue. Our data confirm that Noc receptor's ECL2 contributes actively to ligand binding and selectivity by providing the peptidic ligand with a low affinity‐binding site. Copyright © 2008 European Peptide Society and John Wiley & Sons, Ltd.