Negative Cooperativity In Binding Research Articles

Plasmodium falciparum SSB Tetramer Binds Single-Stranded DNA Only in a Fully Wrapped Mode

The tetrameric Escherichia coli single-stranded DNA (ssDNA) binding protein (Ec-SSB) functions in DNA metabolism by binding to ssDNA and interacting directly with numerous DNA repair and replication proteins. Ec-SSB tetramers can bind ssDNA in multiple DNA binding modes that differ in the extent of ssDNA wrapping. Here, we show that the structurally similar SSB protein from the malarial parasite Plasmodium falciparum (Pf-SSB) also binds tightly to ssDNA but does not display the same number of ssDNA binding modes as Ec-SSB, binding ssDNA exclusively in fully wrapped complexes with site sizes of 52–65 nt/tetramer. Pf-SSB does not transition to the more cooperative (SSB)35 DNA binding mode observed for Ec-SSB. Consistent with this, Pf-SSB tetramers also do not display the dramatic intra-tetramer negative cooperativity for binding of a second (dT)35 molecule that is evident in Ec-SSB. These findings highlight variations in the DNA binding properties of these two highly conserved homotetrameric SSB proteins, and these differences might be tailored to suit their specific functions in the cell.

Structural basis for negative cooperativity within agonist-bound TR:RXR heterodimers

Thyroid hormones such as 3,3',5 triiodo-L-thyronine (T3) control numerous aspects of mammalian development and metabolism. The actions of such hormones are mediated by specific thyroid hormone receptors (TRs). TR belongs to the nuclear receptor family of modular transcription factors that binds to specific DNA-response elements within target promoters. These receptors can function as homo- or heterodimers such as TR:9-cis retinoic acid receptor (RXR). Here, we present the atomic resolution structure of the TRα•T3:RXRα•9-cis retinoic acid (9c) ligand binding domain heterodimer complex at 2.95 Å along with T3 hormone binding and dissociation and coactivator binding studies. Our data provide a structural basis for allosteric communication between T3 and 9c and negative cooperativity between their binding pockets. In this structure, both TR and RXR are in the active state conformation for optimal binding to coactivator proteins. However, the structure of TR•T3 within TR•T3:RXR•9c is in a relative state of disorder, and the observed kinetics of binding show that T3 dissociates more rapidly from TR•T3:RXR•9c than from TR•T3:RXR. Also, coactivator binding studies with a steroid receptor coactivator-1 (receptor interaction domains 1-3) fragment show lower affinities (K(a)) for TR•T3:RXR•9c than TR•T3:RXR. Our study corroborates previously reported observations from cell-based and binding studies and offers a structural mechanism for the repression of TR•T3:RXR transactivation by RXR agonists. Furthermore, the recent discoveries of multiple endogenous RXR agonists that mediate physiological tasks such as lipid biosynthesis underscore the pharmacological importance of negative cooperativity in ligand binding within TR:RXR heterodimers.

Functionally Important Structurally-Specific Homodimerization of the Glucagon Like Peptide 1 Receptor

The glucagon-like peptide-1 (GLP-1) receptor is an important target for agonist drugs that may be useful in the treatment of type 2 diabetes mellitus. This receptor is a member of class B GPCRs, a group believed to associate with themselves and with each other to form oligomeric complexes. However, the way such complexes might affect the action of these drugs is not known. In the current work, we have studied the ability of GLP-1 receptors to oligomerize and have explored the influence of receptor oligomerization on the effects of both peptide and small molecule agonists that activate this receptor. Bioluminescence resonance energy transfer and bimolecular complementation were used to demonstrate that GLP-1 receptors constitutively form homodimers that were unaffected by occupation with any of these agonists. The lipid-exposed face of transmembrane segment 4 (TM4) was the critical determinant for complex formation, based on observations that competition with TM4 peptide could disrupt such receptor complexes and that TM4 mutants could interfere with the formation of these complexes. The affinities for binding and the potencies for agonist stimulation were lower for the monomeric state than for the dimeric state of this receptor. Treatment with GppNHp shifted the affinity of the dimeric receptor state of the receptor, but not its monomeric state. Negative cooperativity of natural ligand binding was observed only for the dimeric receptor state as well. We also characterized the influence of the dimeric state on signaling activities of various orthosteric and allosteric GLP-1 receptor agonists. The work provides novel insight into the importance of receptor oligomerization on the function of Family B GPCRs.

A Negative Cooperativity Mechanism of Human CYP2E1 Inferred from Molecular Dynamics Simulations and Free Energy Calculations

Human cytochrome P450 2E1 (CYP2E1) participates in the metabolism of over 2% of all the oral drugs. A hallmark peculiar feature of this enzyme is that it exhibits a pronounced negative cooperativity in substrate binding. However the mechanism by which the negative cooperativity occurs is unclear. Here, we performed molecular dynamics simulations and free energy calculations on human CYP2E1 to examine the structural differences between the substrate-free and the enzymes with one and two aniline molecules bound. Our results indicate that although the effector substrate does not bind in the active site cavity, it still can directly interact with the active site residues of human CYP2E1. The interaction of the effector substrate with the active site leads to a reorientation of active site residues, which thereby weakens the interactions of the active substrate with this site. We also identify a conserved residue T303 that plays a crucial role in the negative cooperative binding on the short-range effects. This residue is a key factor in the positioning of substrates and in proton delivery to the active site. Additionally, a long-range effect of the effector substrate is identified in which F478 is proposed to play a key role. As located in the interface between the active and effector sites, this residue structurally links the active and effector sites and is found to play a significant role in affecting substrate access and ligand positioning within the active site. In the negative cooperative binding, this residue can decrease the interactions of the active substrate with the active site by π-π stacking which then lowers the hydroxylation activity for the active substrate. These findings are in agreement with previous experimental observations and thus provide detailed atomistic insight into the poorly understood mechanism of the negative cooperativity in human CYP2E1.

Formation of repressor-inducer-operator ternary complex: negative cooperativity of d-camphor binding to CamR

A repressor composed of homodimeric subunits, as is often found in bacteria, possesses two effector-binding sites per molecule, enabling sophisticated regulation by the cooperative binding of two effector molecules. Positive cooperativity generates a narrower region of effector concentration for switching, but little is known about the role of negative cooperativity. d-camphor, an inducer for Pseudomonas putida cytochrome P450cam hydroxylase operon (camDCAB), binds to the homodimeric cam repressor (CamR). Here, we report solid evidence that the complex of CamR and an operator DNA is not dissociated by the first binding of d-camphor but, at a higher concentration, is dissociated by the second binding. d-camphor thus binds to the CamR in two steps with negative cooperativity, yielding two distinct dissociation constants of K(d1 ) =( ) 0.064 ± 0.030 and K(d2 ) =( ) 14 ± 0.3 μm, as well as the Hill coefficient of 0.56 ± 0.05 (<1). The first binding guarantees the high specificity of the inducer by the high affinity, although the second binding turns on the gene expression at a 200-fold higher concentration, a more suitable switching point for the catabolism of d-camphor.

Positive and negative cooperativity of agonist and allosteric modulator binding in alpha7 nAChR: Looking for the therapeutic window

Positive and negative cooperativity of agonist and allosteric modulator binding in alpha7 nAChR: Looking for the therapeutic window

Glycine Dimerization Motif in the N-terminal Transmembrane Domain of the High Density Lipoprotein Receptor SR-BI Required for Normal Receptor Oligomerization and Lipid Transport

Scavenger receptor class B, type I (SR-BI), a CD36 superfamily member, is an oligomeric high density lipoprotein (HDL) receptor that mediates negatively cooperative HDL binding and selective lipid uptake. We identified in the N-terminal transmembrane (N-TM) domain of SR-BI a conserved glycine dimerization motif, G(15)X(2)G(18)X(3)AX(2)G(25), of which the submotif G(18)X(3)AX(2)G(25) significantly contributes to homodimerization and lipid uptake activity. SR-BI variants were generated by mutations (single or multiple Gly → Leu substitutions) or by replacing the N-TM domain with those from other CD36 superfamily members containing (croquemort) or lacking (lysosomal integral membrane protein (LIMP) II) this glycine motif (chimeras). None of the SR-BI variants exhibited altered surface expression (based on antibody binding) or HDL binding. However, the G15L/G18L/G25L triple mutant exhibited reductions in cell surface homo-oligomerization (>10-fold) and the rate of selective lipid uptake (∼ 2-fold). Gly(18) and Gly(25) were necessary for normal lipid uptake activity of SR-BI and the SR-BI/croquemort chimera. The lipid uptake activity of the glycine motif-deficient SR-BI/LIMP II chimera was low but could be increased by introducing glycines at positions 18 and 25. The rate of lipid uptake mediated by SR-BI/LIMP II chimeras was proportional to the extent of receptor oligomerization. Thus, the glycine dimerization motif G(18)X(3)AX(2)G(25) in the N-TM domain of SR-BI contributes substantially to the homo-oligomerization and lipid transport activity of SR-BI but does not influence the negative cooperativity of HDL binding. Oligomerization-independent binding cooperativity suggests that classic allostery is not involved and that the negative cooperativity is probably the consequence of a "lattice effect" (interligand steric interference accompanying binding to adjacent receptors).

A marriage full of surprises; forty-five years living with glutamate dehydrogenase

Detailed kinetic studies of bovine glutamate dehydrogenase [GDH] from the 1960s revealed complexities that remain to be fully explained. In the absence of heterotropic nucleotide regulators the enzyme follows a random pathway of substrate addition but saturation with ADP enforces a compulsory-order mechanism in which glutamate is the leading substrate. The rate dependence on NAD(P) + concentration is complex and is probably only partly explained by negative binding cooperativity. Bovine GDH eluded successful analysis by crystallographers for 30 years but the final structural solution presented in this symposium at last provides a comprehensible framework for much of the heterotropic regulation, focussing attention on an antenna region in the C-terminal tail, a structure that is missing in the slightly smaller hexameric GDHs of lower organisms. Nonetheless, our studies with one such smaller (clostridial) GDH reveal that even without the antenna the underlying core structure still mediates homotropic cooperativity, and the ability to generate a variety of mutants has made it possible to start to dissect this machinery. In addition, this short personal review discusses a number of unresolved issues such as the significance of phospholipid inhibition and of specific interaction with mRNA, and above all the question of why it is necessary to regulate an enzyme reputedly maintaining its reactants at equilibrium and whether this might be in some way related to its coexistence with an energy-linked transhydrogenase.

Negative cooperativity in binding of muscarinic receptor agonists and GDP as a measure of agonist efficacy.

BACKGROUND AND PURPOSEConventional determination of agonist efficacy at G-protein coupled receptors is measured by stimulation of guanosine-5′-γ−thiotriphosphate (GTPγS) binding. We analysed the role of guanosine diphosphate (GDP) in the process of activation of the M2 muscarinic acetylcholine receptor and provide evidence that negative cooperativity between agonist and GDP binding is an alternative measure of agonist efficacy.EXPERIMENTAL APPROACHFiltration and scintillation proximity assays measured equilibrium binding as well as binding kinetics of [35S]GTPγS and [3H]GDP to a mixture of G-proteins as well as individual classes of G-proteins upon binding of structurally different agonists to the M2 muscarinic acetylcholine receptor.KEY RESULTSAgonists displayed biphasic competition curves with the antagonist [3H]-N-methylscopolamine. GTPγS (1 µM) changed the competition curves to monophasic with low affinity and 50 µM GDP produced a similar effect. Depletion of membrane-bound GDP increased the proportion of agonist high-affinity sites. Carbachol accelerated the dissociation of [3H]GDP from membranes. The inverse agonist N-methylscopolamine slowed GDP dissociation and GTPγS binding without changing affinity for GDP. Carbachol affected both GDP association with and dissociation from Gi/o G-proteins but only its dissociation from Gs/olf G-proteins.CONCLUSIONS AND IMPLICATIONSThese findings suggest the existence of a low-affinity agonist-receptor conformation complexed with GDP-liganded G-protein. Also the negative cooperativity between GDP and agonist binding at the receptor/G-protein complex determines agonist efficacy. GDP binding reveals differences in action of agonists versus inverse agonists as well as differences in activation of Gi/o versus Gs/olf G-proteins that are not identified by conventional GTPγS binding.

The Tethering Arm of the EGF Receptor Is Required for Negative Cooperativity and Signal Transduction

The EGF receptor is a classical receptor-tyrosine kinase. In the absence of ligand, the receptor adopts a closed conformation in which the dimerization arm of subdomain II interacts with the tethering arm in subdomain IV. Following the binding of EGF, the receptor opens to form a symmetric, back-to-back dimer. Although it is clear that the dimerization arm of subdomain II is central to the formation of receptor dimers, the role of the tethering arm of subdomain IV (residues 561-585) in this configuration is not known. Here we use (125)I-EGF binding studies to assess the functional role of the tethering arm in the EGF receptor dimer. Mutation of the three major residues that contribute to tethering (D563A,H566A,K585A-EGF receptor) did not significantly alter either the ligand binding properties or the signaling properties of the EGF receptor. By contrast, breaking the Cys(558)-Cys(567) disulfide bond through double alanine replacements or deleting the loop entirely led to a decrease in the negative cooperativity in EGF binding and was associated with small changes in downstream signaling. Deletion of the Cys(571)-Cys(593) disulfide bond abrogated cooperativity, resulting in a high affinity receptor and increased sensitivity of downstream signaling pathways to EGF. Releasing the Cys(571)-Cys(593) disulfide bond resulted in extreme negative cooperativity, ligand-independent kinase activity, and impaired downstream signaling. These data demonstrate that the tethering arm plays an important role in supporting cooperativity in ligand binding. Because cooperativity implies subunit-subunit interactions, these results also suggest that the tethering arm contributes to intersubunit interactions within the EGF receptor dimer.

Experimental Characterization and Mathematical Modeling of P2X7 Receptor Channel Gating

The P2X7 receptor is a trimeric channel with three binding sites for ATP, but how the occupancy of these sites affects gating is still not understood. Here we show that naive receptors activated and deactivated monophasically at low and biphasically at higher agonist concentrations. Both phases of response were abolished by application of Az10606120, a P2X7R-specific antagonist. The slow secondary growth of current in the biphasic response coincided temporally with pore dilation. Repetitive stimulation with the same agonist concentration caused sensitization of receptors, which manifested as a progressive increase in the current amplitude, accompanied by a slower deactivation rate. Once a steady level of the secondary current was reached, responses at high agonist concentrations were no longer biphasic but monophasic. Sensitization of receptors was independent of Na(+) and Ca(2+) influx and ∼30 min washout was needed to reestablish the initial gating properties. T15E- and T15K-P2X7 mutants showed increased sensitivity for agonists, responded with monophasic currents at all agonist concentrations, activated immediately with dilated pores, and deactivated slowly. The complex pattern of gating exhibited by wild-type channels can be accounted for by a Markov state model that includes negative cooperativity of agonist binding to unsensitized receptors caused by the occupancy of one or two binding sites, opening of the channel pore to a low conductance state when two sites are bound, and sensitization with pore dilation to a high conductance state when three sites are occupied.

Structural Basis for Negative Cooperativity in Growth Factor Binding to an EGF Receptor

Transmembrane signaling by the epidermal growth factor receptor (EGFR) involves ligand-induced dimerization and allosteric regulation of the intracellular tyrosine kinase domain. Crystallographic studies have shown how ligand binding induces dimerization of the EGFR extracellular region but cannot explain the "high-affinity" and "low-affinity" classes of cell-surface EGF-binding sites inferred from curved Scatchard plots. From a series of crystal structures of the Drosophila EGFR extracellular region, we show here how Scatchard plot curvature arises from negatively cooperative ligand binding. The first ligand-binding event induces formation of an asymmetric dimer with only one bound ligand. The unoccupied site in this dimer is structurally restrained, leading to reduced affinity for binding of the second ligand, and thus negative cooperativity. Our results explain the cell-surface binding characteristics of EGF receptors and suggest how individual EGFR ligands might stabilize distinct dimeric species with different signaling properties.

Measurement of the binding parameters of annexin derivative–erythrocyte membrane interactions

Erythrocyte ghosts prepared from fresh blood expressed phosphatidylserine (PS) on the membrane surfaces in a rather stable fashion. The binding of fluorescein-5-isothiocyanate (FITC)-labeled annexin V (ANV) derivatives to these membranes was studied by titration with proteins and with calcium. Whereas the preaddition of ethylenediaminetetraacetic acid (EDTA) to reaction mixtures totally prevented membrane binding, Ca 2+-dependent binding was only partially reversed by EDTA treatment, consistent with an initial Ca 2+-dependent binding that became partially Ca 2+ independent. Data derived from saturation titration with ANV derivatives poorly fit the simple protein–membrane equilibrium binding equation and showed negative cooperativity of binding with increasing membrane occupancy. In contrast, calcium titration at low binding site occupancy resulted in excellent fit into the protein–Ca 2+–membrane equilibrium binding equation. Calcium titrations of FITC-labeled ANV and ANV-6L15 (a novel ANV–Kunitz protease inhibitor fusion protein) yielded a Hill coefficient of approximately 4 in both cases. The apparent dissociation constant for ANV-6L15 was approximately 4-fold lower than that of ANV at 1.2–2.5 mM Ca 2+. We propose that ANV-6L15 may provide improved detection of PS exposed on the membrane surfaces of pathological cells in vitro and in vivo.

Symmetric allosteric mechanism of hexameric Escherichia coli arginine repressor exploits competition between L-arginine ligands and resident arginine residues.

An elegantly simple and probably ancient molecular mechanism of allostery is described for the Escherichia coli arginine repressor ArgR, the master feedback regulator of transcription in L-arginine metabolism. Molecular dynamics simulations with ArgRC, the hexameric domain that binds L-arginine with negative cooperativity, reveal that conserved arginine and aspartate residues in each ligand-binding pocket promote rotational oscillation of apoArgRC trimers by engagement and release of hydrogen-bonded salt bridges. Binding of exogenous L-arginine displaces resident arginine residues and arrests oscillation, shifting the equilibrium quaternary ensemble and promoting motions that maintain the configurational entropy of the system. A single L-arg ligand is necessary and sufficient to arrest oscillation, and enables formation of a cooperative hydrogen-bond network at the subunit interface. The results are used to construct a free-energy reaction coordinate that accounts for the negative cooperativity and distinctive thermodynamic signature of L-arginine binding detected by calorimetry. The symmetry of the hexamer is maintained as each ligand binds, despite the conceptual asymmetry of partially-liganded states. The results thus offer the first opportunity to describe in structural and thermodynamic terms the symmetric relaxed state predicted by the concerted allostery model of Monod, Wyman, and Changeux, revealing that this state is achieved by exploiting the dynamics of the assembly and the distributed nature of its cohesive free energy. The ArgR example reveals that symmetry can be maintained even when binding sites fill sequentially due to negative cooperativity, which was not anticipated by the Monod, Wyman, and Changeux model. The molecular mechanism identified here neither specifies nor requires a pathway for transmission of the allosteric signal through the protein, and it suggests the possibility that binding of free amino acids was an early innovation in the evolution of allostery.

Single-Stranded DNA Binding by F TraI Relaxase and Helicase Domains Is Coordinately Regulated

Transfer of conjugative plasmids requires relaxases, proteins that cleave one plasmid strand sequence specifically. The F plasmid relaxase TraI (1,756 amino acids) is also a highly processive DNA helicase. The TraI relaxase activity is located within the N-terminal approximately 300 amino acids, while helicase motifs are located in the region comprising positions 990 to 1450. For efficient F transfer, the two activities must be physically linked. The two TraI activities are likely used in different stages of transfer; how the protein regulates the transition between activities is unknown. We examined TraI helicase single-stranded DNA (ssDNA) recognition to complement previous explorations of relaxase ssDNA binding. Here, we show that TraI helicase-associated ssDNA binding is independent of and located N-terminal to all helicase motifs. The helicase-associated site binds ssDNA oligonucleotides with nM-range equilibrium dissociation constants and some sequence specificity. Significantly, we observe an apparent strong negative cooperativity in ssDNA binding between relaxase and helicase-associated sites. We examined three TraI variants having 31-amino-acid insertions in or near the helicase-associated ssDNA binding site. B. A. Traxler and colleagues (J. Bacteriol. 188:6346-6353) showed that under certain conditions, these variants are released from a form of negative regulation, allowing them to facilitate transfer more efficiently than wild-type TraI. We find that these variants display both moderately reduced affinity for ssDNA by their helicase-associated binding sites and a significant reduction in the apparent negative cooperativity of binding, relative to wild-type TraI. These results suggest that the apparent negative cooperativity of binding to the two ssDNA binding sites of TraI serves a major regulatory function in F transfer.

Cocaine self‐administration markedly increases dopamine D2 receptor negative cooperativity for dopamine binding: A receptor dimer‐based analysis

The proportion of dopamine D(2)(High) receptors has been reported to increase after cocaine self-administration without a significant change in the total number of D(2) receptors. In the present article, the data of competition by dopamine of [(3)H]domperidone binding to striatal samples from naïve and cocaine-addicted animals (Briand et al., [2008] Eur Neuropsychopharmacol 18:551-556) are analyzed assuming that D(2) receptors are constitutive dimers. The results show another way of interpreting those previous results and lead to the finding that cocaine affects agonist affinity and may strongly affect the receptor-receptor cooperation between dimers, a result that can contribute to dopamine supersensitivity.

Docking of insulin to a structurally equilibrated insulin receptor ectodomain

The insulin receptor (IR) is a homo-dimeric, disulfide-linked, membrane-spanning tyrosine kinase. IR displays negative cooperativity in insulin binding to its two pockets, suggesting "see-sawing" between symmetry-inverted conformations. The crystal structure of the dimeric IR ectodomain, IRDeltabeta [PDB code 2DTG (McKern et al., Nature 2006 443:218-221)], provides structural bases for this speculation. Unfortunately, neither binding pocket of the crystallographic IRDeltabeta structure allows steric accommodation of insulin. During almost 70-ns of all-atom, explicit-water MD simulation ( approximately 0.5 million atoms), IRDeltabeta undergoes significant asymmetric interdomain and intersubunit conformational fluctuations that do not alter its quaternary structure. Subtle variations in intersubunit buried surface area coincide with these conformational fluctuations, resulting in one easily-accessible insulin binding pocket with the other blocked. We use a combination of Metropolis Monte-Carlo and MD simulations to dock both T- and R-state insulin into the open binding pocket. Both complexes remain stable during 30-ns of MD simulation. In these complexes, "hexamer interface" residues on insulin directly contact the "site-2" epitope on the first type-III fibronectin domain (F1) of IR. Our results support the hypothesis that intersubunit flexibility of IR, governed by alternating modulation of buried intersubunit surface area, is the physical mechanism underlying a "see-saw" model of negative cooperativity.

Nucleotide- and Substrate-Induced Conformational Transitions in the CBS Domain-Containing Pyrophosphatase of Moorella thermoacetica

In contrast to all other known pyrophosphatases, Moorella thermoacetica pyrophosphatase (mtCBS-PPase) contains nucleotide-binding CBS domains and is thus strongly regulated by adenine nucleotides. Stopped-flow measurements using a fluorescent AMP analogue, 2'(3')-O-(N-methylanthranoyl)-AMP (Mant-AMP), reveal that nucleotide binding to mtCBS-PPase involves a three-step increase in Mant-AMP fluorescence with relaxation times from 0.01 to 100 s, implying conformational changes in the complex. This effect is reversed by AMP. Metal cofactors (Co(2+) and Mg(2+)) enhance the fluorescence signal but are not absolutely required, unlike what is seen when the catalytic reaction is examined. The relaxation times and amplitudes of the fluorescence signals depend on Mant-AMP concentration in a manner suggestive of the presence of a second binding site for Mant-AMP on the protein. Equilibrium fluorescence titration experiments additionally support the presence of two types of AMP binding sites with different affinities, whereas equilibrium dialysis and membrane filtration measurements reveal binding of one AMP molecule per enzyme monomer, implying negative cooperativity in nucleotide binding. The substrate (PP(i)) modulates Mant-AMP binding, leading to a further conformational change in the enzyme-Mant-AMP complex, and stimulates mtCBS-PPase in alkaline medium within a time scale of minutes, via conversion to a more active form. This active form initially comprises only a third of the enzyme, as estimated from kinetic titration with ADP. AMP inhibits both enzyme forms but is unable to independently induce interconversion. Our results collectively suggest that nucleotides and the substrate induce multiple conformational changes in mtCBS-PPase occurring over a wide time scale; the changes are distinct and almost independent.

Hetero-oligomerization of CCR2, CCR5, and CXCR4 and the Protean Effects of “Selective” Antagonists

Chemokine receptors constitute an attractive family of drug targets in the frame of inflammatory diseases. However, targeting specific chemokine receptors may be complicated by their ability to form dimers or higher order oligomers. Using a combination of luminescence complementation and bioluminescence resonance energy transfer assays, we demonstrate for the first time the existence of hetero-oligomeric complexes composed of at least three chemokine receptors (CCR2, CCR5, and CXCR4). We show in T cells and monocytes that negative binding cooperativity takes place between the binding pockets of these receptors, demonstrating their functional interaction in leukocytes. We also show that specific antagonists of one receptor (TAK-779 or AMD3100) lead to functional cross-inhibition of the others. Finally, using the air pouch model in mice, we show that the CCR2 and CCR5 antagonist TAK-779 inhibits cell recruitment promoted by the CXCR4 agonist SDF-1 alpha, demonstrating that cross-inhibition by antagonists also occurs in vivo. Thus, antagonists of the therapeutically important chemokine receptors regulate the functional properties of other receptors to which they do not bind directly with important implications for the use of these agents in vivo.

Solution Structure of Ectodomains of the Insulin Receptor Family: The Ectodomain of the Type 1 Insulin-Like Growth Factor Receptor Displays Asymmetry of Ligand Binding Accompanied by Limited Conformational Change

The insulin receptor (IR) and the homologous Type 1 insulin-like growth factor receptor (IGF-1R) are cell-surface tyrosine kinase receptors that effect signaling within the respective pathways of glucose metabolism and normal human growth. While ligand binding to these receptors is assumed to result in a structural transition within the receptor ectodomain that then effects signal transduction across the cell membrane, little is known about the molecular detail of these events. Presented here are small-angle X-ray scattering data obtained from the IR and IGF-1R ectodomains in solution. We show that, in solution, the ectodomains of IR and IGF-1R have a domain disposition that is very similar to that seen in the crystal structure of the ectodomain of IR, despite the constituent domains being in relatively sparse contact and potentially mobile. We also show that the IGF-1R ectodomain is capable of binding up to three molecules of IGF-1 in solution, with surprisingly little apparent change in relative domain disposition compared to the apo form. While the observed 3:1 ligand-binding stoichiometry appears to contradict earlier explanations of the absence of a bell-shaped dose–response curve for IGF-1R in ligand displacement assays, it is readily understood in the context of the harmonic oscillator model of the negative cooperativity of ligand binding to IGF-1R. Taken together, our findings suggest that the structural movements within these receptors upon ligand binding are small and are possibly limited to local rotation of domains.