Identification of residues involved in the interaction of Staphylococcus aureus fibronectin-binding protein with the (4)F1(5)F1 module pair of human fibronectin using heteronuclear NMR spectroscopy

Many pathogenic Gram-positive bacteria express cell surface proteins that bind to components of the extracellular matrix. This paper describes studies of the interaction between ligand binding repeats (D3 and D1-D4) of a fibronectin-binding protein from Staphylococcus aureus with a module pair ((4)F1(5)F1) from the N-terminal region of fibronectin. When D3 was added to isotope-labeled (4)F1(5)F1, (1)H, (15)N, and (13)C NMR chemical shift changes indicate that binding is primarily via residues in (4)F1, although a few residues in (5)F1 are also affected. Both hydrophobic and electrostatic interactions appear to be involved. The NMR data indicate that part of the D3 repeat converts from a disordered to a more ordered, extended conformation on binding to (4)F1(5)F1. In further NMR experiments, selective reduction of the intensity of D1-D4 resonances was observed on binding to (4)F1(5)F1, consistent with previous suggestions that in each of D1, D2, and D3 repeats, the main fibronectin binding site is in the C-terminal region of the repeat. In D1-D4, these regions also appear to go from a disordered to a more ordered conformation of fibronectin binding. Although the regions of the two proteins which interact had been previously identified, the findings presented here identify, for the first time, the specific residues in both proteins that are likely to be involved in the interaction.     

NMR characterization of the electrostatic interaction of the basic residues in HDGF and FGF2 during heparin binding

Electrostatic interaction is a major driving force in the binding of proteins to highly acidic glycosaminoglycan, such as heparin. Although NMR backbone chemical shifts have generally been used to identify the heparin-binding site on a protein, however, there is no correlation between the binding free energies and the perturbed backbone chemical shifts for individual residues. The binding event occurs at the end of a side chain of basic residue, and does not require causing significant alterations in the backbone environment at a distance of multiple bonds. We used the H₂CN NMR pulse sequence to detect heparin binding through the side-chain resonances Hε–Cε–Nζ of Lys and Hδ–Cδ–Nε of Arg in the two proteins of hepatoma-derived growth factor (HDGF) and basic fibroblast growth factor (FGF2). H₂CN titration experiments revealed chemical shift perturbations in the side chains, which were correlated with the free energy changes in various mutants. The residues K19 in HDGF and K125 in FGF2 demonstrated the most significant perturbations, consistent with our previous observation that the two residues are crucial for binding. The result suggests that H₂CN NMR provides a precise evaluation for the electrostatic interactions. The discrepancy observed between backbone and side chain chemical shifts is correlated to the solvent accessibility of residues that the K19 and K125 backbones are highly buried with the restricted backbone conformation and are not strongly affected by the events at the end of the side chains.     

The interaction between calcium- and integrin-binding protein 1 and the alphaIIb integrin cytoplasmic domain involves a novel C-terminal displacement mechanism

Calcium- and integrin-binding protein 1 (CIB1) regulates platelet aggregation in hemostasis through a specific interaction with the alphaIIb cytoplasmic domain of platelet integrin alphaIIbbeta3. In this work we report the structural characteristics of CIB1 in solution and the mechanistic details of its interaction with a synthetic peptide derived from the alphaIIb cytoplasmic domain. NMR spectroscopy experiments using perdeuterated CIB1 together with heteronuclear nuclear Overhauser effect experiments have revealed a well folded alpha-helical structure for both the ligand-free and alphaIIb-bound forms of the protein. Residual dipolar coupling experiments have shown that the N and C domains of CIB1 are positioned side by side, and chemical shift perturbation mapping has identified the alphaIIb-binding site as a hydrophobic channel spanning the entire C domain and part of the N domain. Data obtained with a truncated version of CIB1 suggest that the extreme C-terminal end of the protein weakly interacts with this channel in the absence of a biological target, but it is displaced by the alphaIIb cytoplasmic domain, suggesting a novel mechanism to increase binding specificity.     

NMR characterization of interleukin-2 in complexes with the IL-2Ralpha receptor component,and with low molecular weight compounds that inhibit the IL-2/IL-Ralpha interaction

Nuclear magnetic resonance (NMR) methods were employed to study the interaction of the cytokine Interleukin-2 (IL-2) with the alpha-subunit of its receptor (IL-2Ralpha), and to help understand the behavior of small molecule inhibitors of this interaction. Heteronuclear (1)H-(15)N HSQC experiments were used to identify the interaction surface of (15)N-enriched Interleukin-2 ((15)N-IL-2) in complex with human IL-2Ralpha. In these experiments, chemical shift and line width changes in the heteronuclear single-quantum coherence (HSQC) spectra upon binding of (15)N-IL-2 enabled classification of NH atoms as either near to, or far from, the IL-2Ralpha interaction surface. These data were complemented by hydrogen/deuterium (H/D) exchange measurements, which illustrated enhanced protection of slowly-exchanging IL-2 NH protons near the site of interaction with IL-2Ralpha. The interaction surface defined by NMR compared well with the IL-2Ralpha binding site identified previously using mutagenesis of human and murine IL-2. Two low molecular weight inhibitors of the IL-2/IL-2Ralpha interaction were studied: one (a cyclic peptide derivative) was found to mimic a part of the cytokine and bind to IL-2Ralpha; the other (an acylphenylalanine derivative) was found to bind to IL-2. For the interaction between IL-2 and the acylphenylalanine, chemical shift perturbations of (15)N and (15)NH backbone resonances were tracked as a function of ligand concentration. The perturbation pattern observed for this complex revealed that the acylphenylalanine is a competitive inhibitor-it binds to the same site on IL-2 that interacts with IL-2Ralpha.     

Characterisation of the interaction of the C-terminus of the dopamine D2 receptor with neuronal calcium sensor-1

NCS-1 is a member of the neuronal calcium sensor (NCS) family of EF-hand Ca(2+) binding proteins which has been implicated in several physiological functions including regulation of neurotransmitter release, membrane traffic, voltage gated Ca(2+) channels, neuronal development, synaptic plasticity, and learning. NCS-1 binds to the dopamine D2 receptor, potentially affecting its internalisation and controlling dopamine D2 receptor surface expression. The D2 receptor binds NCS-1 via a short 16-residue cytoplasmic C-terminal tail. We have used NMR and fluorescence spectroscopy to characterise the interactions between the NCS-1/Ca(2+) and D2 peptide. The data show that NCS-1 binds D2 peptide with a K(d) of ～14.3 μM and stoichiometry of peptide binding to NCS-1 of 2:1. NMR chemical shift mapping confirms that D2 peptide binds to the large, solvent-exposed hydrophobic groove, on one face of the NCS-1 molecule, with residues affected by the presence of the peptide spanning both the N and C-terminal portions of the protein. The NMR and mutagenesis data further show that movement of the C-terminal helix 11 of NCS-1 to fully expose the hydrophobic groove is important for D2 peptide binding. Molecular docking using restraints derived from the NMR chemical shift data, together with the experimentally-derived stoichiometry, produced a model of the complex between NCS-1 and the dopamine receptor, in which two molecules of the receptor are able to simultaneously bind to the NCS-1 monomer.     

Interaction of an ionic complementary peptide with a hydrophobic graphite surface

Protein adsorption on a surface plays an important role in biomaterial science and medicine. It is strongly related to the interaction between the protein residues and the surface. Here we report all‐atom molecular dynamics simulations of the adsorption of an ionic complementary peptide, EAK16‐II, to the hydrophobic highly ordered pyrolytic graphite surface. We find that, the hydrophobic interaction is the main force to govern the adsorption, and the peptide interchain electrostatic interaction affects the adsorption rate. Under neutral pH condition, the interchain electrostatic attraction facilitates the adsorption, whereas under acidic and basic conditions, because of the protonation and deprotonation of glutamic acid and lysine residues, respectively, the resulting electrostatic repulsion slows down the adsorption. We also found that under basic condition, during the adsorption peptide Chain II will be up against a choice to adsorb to the surface through the hydrophobic interaction or to form a temporary hydrophobic core with the deposited peptide Chain I. These results provide a basis for understanding some of the fundamental interactions governing peptide adsorption on the surface, which can shed new light on novel applications, such as the design of implant devices and drug delivery materials.     

The interaction of cytostatic drugs with adsorbents in aqueous media. The potential implications for liposome preparation

A new method that involves the use of the cation exchange resin Dowex 50W-X4 to remove non-encapsulated drugs from liposome dispersions was investigated. Cytostatic drugs widely varying in their molecular structure can be removed from aqueous solutions by Dowex 50W-X4. The applicability of the resin to separate free from liposome-bound drugs was illustrated for a number of cytostatic drugs (cisplatin, doxorubicin, vincristine). The technique presented allows for a rapid, efficient and convenient procedure for the free drug removal from liposome dispersions without dilution of the liposomal preparation. Studies with liposome-encapsulated drugs will be facilitated by the use of this method, since it avoids many of the problems introduced by conventional methods as dialysis, gel filtration and centrifugation/washing. To elucidate the interaction mechanism of doxorubicin with Dowex 50W-X4, alternative adsorbents were studied for their doxorubicin binding properties. In the adsorption process of doxorubicin onto Dowex 50W-X4 both electrostatic (ion exchange) and hydrophobic effects play a role. The results indicate that hydrophobic contributions to the interaction are responsible for the high resistance offered by the binding forces against desorption of adsorbed doxorubicin. For other adsorbents the interactions are either mainly of an electrostatic or a hydrophobic nature.     

Peptide binding proclivities of calcium loaded calbindin-D28k

Calbindin-D28k is known to function as a calcium-buffering protein in the cell. Moreover, recent evidence shows that it also plays a role as a sensor. Using circular dichroism and NMR, we show that calbindin-D28k undergoes significant conformational changes upon binding calcium, whereas only minor changes occur when binding target peptides in its Ca(2+)-loaded state. NMR experiments also identify residues that undergo chemical shift changes as a result of peptide binding. The subsequent use of computational protein-protein docking protocols produce a model describing the interaction interface between calbindin-D28k and its target peptides.     

Auto-FACE: An NMR Based Binding Site Mapping Program for Fast Chemical Exchange Protein-Ligand Systems

Background

Nuclear Magnetic Resonance (NMR) spectroscopy offers a variety of experiments to study protein-ligand interactions at atomic resolution. Among these experiments, N Heteronuclear Single Quantum Correlation (HSQC) experiment is simple, less time consuming and highly informative in mapping the binding site of the ligand. The interpretation of N HSQC becomes ambiguous when the chemical shift perturbations are caused by non-specific interactions like allosteric changes and local structural rearrangement. Under such cases, detailed chemical exchange analysis based on chemical shift perturbation will assist in locating the binding site accurately.

Methodology/Principal Findings

We have automated the mapping of binding sites for fast chemical exchange systems using information obtained from N HSQC spectra of protein serially titrated with ligand of increasing concentrations. The automated program Auto-FACE (Auto-FAst Chemical Exchange analyzer) determines the parameters, e.g. rate of change of perturbation, binding equilibrium constant and magnitude of chemical shift perturbation to map the binding site residues. Interestingly, the rate of change of perturbation at lower ligand concentration is highly sensitive in differentiating the binding site residues from the non-binding site residues. To validate this program, the interaction between the protein and the ligand BH3I-1 was studied. Residues in the hydrophobic BH3 binding groove of were easily identified to be crucial for interaction with BH3I-1 from other residues that also exhibited perturbation. The geometrically averaged equilibrium constant () calculated for the residues present at the identified binding site is consistent with the values obtained by other techniques like isothermal calorimetry and fluorescence polarization assays (). Adjacent to the primary site, an additional binding site was identified which had an affinity of 3.8 times weaker than the former one. Further NMR based model fitting for individual residues suggest single site model for residues present at these binding sites and two site model for residues present between these sites. This implies that chemical shift perturbation can represent the local binding event much more accurately than the global binding event.

Conclusion/Significance

Detail NMR chemical shift perturbation analysis enabled binding site residues to be distinguished from non-binding site residues for accurate mapping of interaction site in complex fast exchange system between small molecule and protein. The methodology is automated and implemented in a program called “Auto-FACE”, which also allowed quantitative information of each interaction site and elucidation of binding mechanism.     

The interaction between severe acute respiratory syndrome coronavirus 3C-like proteinase and a dimeric inhibitor by capillary electrophoresis

3C-like proteinase of severe acute respiratory syndrome (SARS) coronavirus has been demonstrated to be a key target for drug design against SARS. The interaction between SARS coronavirus 3C-like (3CL) proteinase and an octapeptide interface inhibitor was studied by affinity capillary electrophoresis (ACE). The binding constants were estimated by the change of migration time of the analytes in the buffer solution containing different concentrations of SARS 3CL proteinase. The results showed that SARS 3CL proteinase was able to complex with the octapeptide competitively, with binding constants of 2.44 x 10(4) M(-1) at 20 degrees C and 2.11 x 10(4)M(-1) at 37 degrees C. In addition, the thermodynamic parameters deduced reveal that hydrophobic interaction might play major roles, along with electrostatic force, in the binding process. The ACE method used here could be developed to be an effective and simple way of applying large-scale drug screening and evaluation.     

Physico-chemical boundaries in the continuous and one-step discontinuous affinity-chromatographic isolation of proteins.

From a physico-chemical point of view, affinity chromatography has no unambiguous definition. It is generally understood as the one-step chromatographic isolation of a protein from a biological sample. For such processes the protein recovery and the adsorption capacity for a given adsorption time is limited by static and dynamic physico-chemical properties of the system. The protein recovery is limited by the ratio of the static capacity, n(s), and the dissociation constant, K, for the interaction with the immobilized binding site. The limits of these quantities for 90% and 99% protein recovery were estimated. The residence time required to reach 90% of the adsorptive capacity of an adsorbent is a function of the above static properties, the pore-diffusion coefficient, D(p), and the diffusion distance in the adsorbent. It was estimated and was found to correlate well with experimental data. The one-step discontinuous or continuous chromatographic isolation of one protein from a biological sample by means of adsorbents that separate with respect to different properties is reviewed. This is only possible with selective specific adsorbents and, in special cases, also with bifunctional adsorbents that use hydrophobic interactions for the adsorption, and electrostatic repulsion for the desorption.     

Human opioid peptide Met-enkephalin binds to anionic phosphatidylserine in high preference to zwitterionic phosphatidylcholine: natural-abundance 13C NMR study on the binding state in large unilamellar vesicles

A human opioid neuropeptide, Met-enkephalin (M-Enk: Tyr1-Gly2-Gly3-Phe4-Met5), having no net charge binds to anionic phosphatidylserine (PS) in high preference to zwitterionic phosphatidylcholine (PC). The binding mechanism in the PS and PC bilayers was studied on the basis of the inter- and intramolecular interaction data obtained by natural-abundance 13C nuclear magnetic resonance (NMR) of the peptide. Prominent upfield changes of the 13C resonance were observed in the C-terminal residue upon binding to PS, whereas no such marked change was observed upon binding to PC. The upfield chemical shift changes with their characteristic carbon site dependence are ascribed to the electrostatic binding between the peptide C-terminal CO2- and the PS headgroup NH3+. Despite the net negative charge of the PS bilayer surface, M-Enk thus anchors the negatively charged C-terminus. In the N-terminal residue, on the other hand, marked downfield chemical shift changes are observed upon binding to both the PS and PC bilayers, the magnitude of the changes being much larger in the PS system. The downfield changes with their characteristic carbon site dependence are ascribed to the electrostatic binding between the peptide N-terminal NH3+ and the lipid headgroup negative charge(s) (CO2- or PO4- in PS, PO4- in PC). Perturbation on the signal half-widths due to membrane binding also indicates the preferential and deeper binding of M-Enk on the PS membrane surface than on the PC membrane surface. Local charge cancellation takes place efficiently between M-Enk termini and the PS headgroups and compensates for the strong electrostatic hydration of the ionic groups. Distribution of the charged (positive and negative) and uncharged sites in the headgroups along the bilayer normal is responsible for the marked difference between PS and PC headgroups in controlling the binding state of the zwitterionic M-Enk.     

Ligand-induced changes in dynamics in the RT loop of the C-terminal SH3 domain of Sem-5 indicate cooperative conformational coupling

We report the effects of peptide binding on the (15)N relaxation rates and chemical shifts of the C-SH3 of Sem-5. (15)N spin-lattice relaxation time (T(1)), spin-spin relaxation time (T(2)), and ((1)H)-(15)N NOE were obtained from heteronuclear 2D NMR experiments. These parameters were then analyzed using the Lipari-Szabo model free formalism to obtain parameters that describe the internal motions of the protein. High-order parameters (S(2) > 0.8) are found in elements of regular secondary structure, whereas some residues in the loop regions show relatively low-order parameters, notably the RT loop. Peptide binding is characterized by a significant decrease in the (15)N relaxation in the RT loop. Concomitant with the change in dynamics is a cooperative change in chemical shifts. The agreement between the binding constants calculated from chemical shift differences and that obtained from ITC indicates that the binding of Sem-5 C-SH3 to its putative peptide ligand is coupled to a cooperative conformational change in which a portion of the binding site undergoes a significant reduction in conformational heterogeneity.     

Veratridine binding to a transmembrane helix of sodium channel Nav1.4 determined by solid-state NMR

The multi-step ligand action to a target protein is an important aspect when understanding mechanisms of ligand binding and discovering new drugs. However, structurally capturing such complex mechanisms is challenging. This is particularly true for interactions between large membrane proteins and small molecules. One such large membrane of interest is Na_v1.4, a eukaryotic voltage-gated sodium channel. Domain 4 segment 6 (D4S6) of Na_v1.4 is a transmembrane α-helical segment playing a key role in channel gating regulation, and is targeted by a neurotoxin, veratridine (VTD). VTD has been suggested to exhibit a two-step action to activate Na_v1.4. Here, we determine the NMR structure of a selectively ¹³C-labeled peptide corresponding to D4S6 and its VTD binding site in lipid bilayers determined by using magic-angle spinning solid-state NMR. By ¹³C NMR, we obtain NMR structural constraints as ¹³C chemical shifts and the ¹H-²H dipolar couplings between the peptide and deuterated lipids. The peptide backbone structure and its location with respect to the membrane are determined under the obtained NMR structural constraints aided by replica exchange molecular dynamics simulations with an implicit membrane/solvent system. Further, by measuring the ¹H-²H dipolar couplings to monitor the peptide-lipid interaction, we identify a VTD binding site on D4S6. When superimposed to a crystal structure of a bacterial sodium channel Na_vRh, the determined binding site is the only surface exposed to the protein exterior and localizes beside the second-step binding site reported in the past. Based on these results, we propose that VTD initially binds to these newly-determined residues on D4S6 from the membrane hydrophobic domain, which induces the first-step channel opening followed by the second-step blocking of channel inactivation of Na_v1.4. Our findings provide new detailed insights of the VTD action mechanism, which could be useful in designing new drugs targeting D4S6.     

Interactions of diastereomeric tripeptides of lysyl-5-fluorotryptophyllysine with DNA. 1. Optical and 19F NMR studies of native DNA complexes

Lysyl-5-fluoro-L-tryptophyllysine and lysyl-5-fluoro-D-tryptophyllysine were synthesized, and their interactions with double-stranded DNA were investigated as a model for protein-nucleic acid interactions. The binding to DNA was studied by monitoring various 19F NMR parameters, the fluorescence, and the optical absorbance in thermal denaturation. The 19F resonance of the L-Trp peptide shifts upfield in the presence of DNA, and that of the D-Trp peptide shifts downfield with DNA present. The influence of ionic strength on the binding of each peptide to DNA and the fluorescence quenching titration of each with DNA indicate that electrostatic bonding (approximately 2 per peptide-DNA complex) dominates the binding in each case and accounts for the similar binding constants determined from the fluorescence quenching, i.e., 7.7 X 10(4) M-1 for the L-Trp complex and 6.2 X 10(-1) for the D-Trp complex. The 19F NMR chemical shift, line width, 19F[1H] nuclear Overhauser effect, and spin-lattice relaxation time (T1) changes all indicate that the aromatic moiety of the L-Trp complex, but not that of the D-Trp complex, is stacked between the bases of DNA. The relative increases in DNA melting temperature caused by binding of the tripeptide diastereomers are also consistent with stacking in the case of the L-Trp peptide. The magnitude of the changes and the susceptibility of the 19F NMR chemical shift to altering the solvent isotope (H2O vs. D2O) suggest that the L-Trp ring is not intercalated in the classical sense but is partially inserted between the bases of one strand of the double helix.     

The conformation of a signal peptide bound by Escherichia coli preprotein translocase SecA

To understand the structural nature of signal sequence recognition by the preprotein translocase SecA, we have characterized the interactions of a signal peptide corresponding to a LamB signal sequence (modified to enhance aqueous solubility) with SecA by NMR methods. One-dimensional NMR studies showed that the signal peptide binds SecA with a moderately fast exchange rate (Kd approximately 10(-5) m). The line-broadening effects observed from one-dimensional and two-dimensional NMR spectra indicated that the binding mode does not equally immobilize all segments of this peptide. The positively charged arginine residues of the n-region and the hydrophobic residues of the h-region had less mobility than the polar residues of the c-region in the SecA-bound state, suggesting that this peptide has both electrostatic and hydrophobic interactions with the binding pocket of SecA. Transferred nuclear Overhauser experiments revealed that the h-region and part of the c-region of the signal peptide form an alpha-helical conformation upon binding to SecA. One side of the hydrophobic core of the helical h-region appeared to be more strongly bound in the binding pocket, whereas the extreme C terminus of the peptide was not intimately involved. These results argue that the positive charges at the n-region and the hydrophobic helical h-region are the selective features for recognition of signal sequences by SecA and that the signal peptide-binding site on SecA is not fully buried within its structure.     

The essentiality of His-47 and the N-terminal region for the binding of 8-anilinonaphthalene-1-sulfonate with Taiwan cobra phospholipase A2

The binding of the apolar fluorescent dye 8-anilinonaphthalene-1-sulfonate (ANS) toNaja naja atra phospholipase A₂ (PLA₂) as well as the enhancement of ANS fluorescence of the PLA₂-ANS complex decreased with increasing pH in a pH range from 3 to 9. These pH-dependent curves can be well interpreted as the perturbation of an ionizable group with pK value of 5.8, which was assigned as His-47 in the active site of PLA₂. The ionizable group with pK 5.8 was no longer observed after methylation of His-47, supporting the idea that thepH dependence of ANS binding arose from an electrostatic interaction between His-47 and the bound ANS. Removal of the N-terminal octapeptide of PLA₂ caused a precipitous drop in the capability of PLA₂ for binding with ANS and enhancing ANS fluorescence, reflecting that the integrity of the N-terminal region was essential for maintaining the hydrophobic character of the ANS-binding site. However, the nonpolarity of the ANS-binding site in the N-terminus-removed derivative was still partially retained at lowpH, but was completely lost at highpH. Evidently, the N-terminal region plays a more crucial role in ANS binding at highpH than at lowpH. These results indicate that hydrophobic interaction as well as electrostatic interaction are involved in the binding of ANS to PLA₂, and that the relative contributions of both interactions in ANS fluorescence enhancement may be different under differentpH.     

Probing the interaction between cHAVc3 peptide and the EC1 domain of E-cadherin using NMR and molecular dynamics simulations

The goal of this work is to probe the interaction between cyclic cHAVc3 peptide and the EC1 domain of human E-cadherin protein. Cyclic cHAVc3 peptide (cyclo(1,6)Ac-CSHAVC-NH₂) binds to the EC1 domain as shown by chemical shift perturbations in the 2D ¹H,-¹⁵N-HSQC NMR spectrum. The molecular dynamics (MD) simulations of the EC1 domain showed folding of the C-terminal tail region into the main head region of the EC1 domain. For cHAVc3 peptide, replica exchange molecular dynamics (REMD) simulations generated five structural clusters of cHAVc3 peptide. Representative structures of cHAVc3 and the EC1 structure from MD simulations were used in molecular docking experiments with NMR constraints to determine the binding site of the peptide on EC1. The results suggest that cHAVc3 binds to EC1 around residues Y36, S37, I38, I53, F77, S78, H79, and I94. The dissociation constants (K_d values) of cHAVc3 peptide to EC1 were estimated using the NMR chemical shifts data and the estimated K_ds are in the range of .5 × 10^?5–7.0 × 10^?5 M.     

Triple-resonance multidimensional NMR study of calmodulin complexed with the binding domain of skeletal muscle myosin light-chain kinase: indication of a conformational change in the central helix

Heteronuclear 3D and 4D NMR experiments have been used to obtain 1H, 13C, and 15N backbone chemical shift assignments in Ca(2+)-loaded calmodulin complexed with a 26-residue synthetic peptide (M13) corresponding to the calmodulin-binding domain (residues 577-602) of rabbit skeletal muscle myosin light-chain kinase. Comparison of the chemical shift values with those observed in peptide-free calmodulin [Ikura, M., Kay, L. E., & Bax, A. (1990) Biochemistry 29, 4659-4667] shows that binding of M13 peptide induces substantial chemical shift changes that are not localized in one particular region of the protein. The largest changes are found in the first helix of the Ca(2+)-binding site I (E11-E14), the N-terminal portion of the central helix (M72-D78), and the second helix of the Ca(2+)-binding site IV (F141-M145). Analysis of backbone NOE connectivities indicates a change from alpha-helical to an extended conformation for residues 75-77 upon complexation with M13. This conformational change is supported by upfield changes in the C alpha and carbonyl chemical shifts of these residues relative to M13-free calmodulin and by hydrogen-exchange experiments that indicate that the amide protons of residues 75-82 are in fast exchange (kexch greater than 10 s-1 at pH 7, 35 degrees C) with the solvent. No changes in secondary structure are observed for the first helix of site I or the C-terminal helix of site IV. Upon complexation with M13, a significant decrease in the amide exchange rate is observed for residues T110, L112, G113, and E114 at the end of the second helix of site III.