Two-dimensional NMR and photo-CIDNP studies of the insulin monomer: assignment of aromatic resonances with application to protein folding, structure, and dynamics

The aromatic 1H NMR resonances of the insulin monomer are assigned at 500 MHz by comparative studies of chemically modified and genetically altered variants, including a mutant insulin (PheB25----Leu) associated with diabetes mellitus. The two histidines, three phenylalanines, and four tyrosines are observed to be in distinct local environments; their assignment provides sensitive markers for studies of tertiary structure, protein dynamics, and protein folding. The environments of the tyrosine residues have also been investigated by photochemically induced dynamic nuclear polarization (photo-CIDNP) and analyzed in relation to packing constraints in the crystal structures of insulin. Dimerization involving specific B-chain interactions is observed with increasing protein concentration and is shown to depend on temperature, pH, and solvent composition. In the monomer large variations are observed in the line widths of amide resonances, suggesting intermediate exchange among conformational substates; such substates may relate to conformational changes observed in different crystal states and proposed to occur in the hormone-receptor complex. Additional evidence for multiple conformations in solution is provided by comparative studies of an insulin analogue containing a peptide bond between residues B29 and A1 (mini-proinsulin). This analogue forms dimers and higher-order oligomers under conditions in which native insulin is monomeric, suggesting that the B29-A1 peptide bond stabilizes a conformational substate favorable for dimerization. Such stabilization is not observed in corresponding studies of native proinsulin, in which a 35-residue connecting peptide joins residues B30 and A1; this extended tether is presumably too flexible to constrain the conformation of the B-chain. The differences between proinsulin and mini-proinsulin suggest a structural mechanism for the observation that the fully reduced B29-A1 analogue folds more efficiently than proinsulin to form the correct pattern of disulfide bonds. These results are discussed in relation to molecular mechanics calculations of insulin based on the available crystal structures.     

Two-dimensional NMR studies on des-pentapeptide-insulin. Proton resonance assignments and secondary structure analysis

The shortened analogue of insulin, des-(B26-B30)-pentapeptide insulin, has been characterized by two-dimensional 1H NMR. The 1H resonance assignments and the secondary structure in water solution are discussed The results indicate that the secondary structure in solution is very similar to that reported for the crystalline state. A high flexibility of both A and B chains is observed. Of the two conformations seen in the 2-Zn insulin crystals and indicated as molecules 1 and 2 (Chinese nomenclature), the structure of the analogue is more similar to that of molecule 1.     

Glycolipid membrane surface structure: orientation, conformation, and motion of a disaccharide headgroup

The orientation of the disaccharide headgroup of a lactose-containing lipid, 3-O-(4-O-beta-D-galactopyranosyl-beta-D-glucopyranosyl)-1,2-di-O-tetrade cyl-sn- glycerol (DTLL), relative to the surface of bilayer membranes has been determined via 2H NMR. The lactosyl headgroup is extended away from the membrane surface into the aqueous phase. The headgroup motion has axial symmetry as evidenced by the spectral line shape and order parameter tensor. 2H NMR of oriented multibilayers of DTLL confirms that the director of motional averaging is the bilayer normal. The two sugar residues have segmental order parameters S (glucose, 0.53; galactose, 0.51) which indicate that the headgroup fluctuates about the bilayer normal as a rigid unit. 2H spin-lattice relaxation times T1z for deuterons on each of the two sugar rings are similar, indicating further that there is no substantial motion about the disaccharide linkage within the headgroup. The magnitude of the relaxation times (4 ms) suggests that the rigid body motions of the headgroup are approaching the Larmor frequency; however, they increase with increasing temperature, indicating that the motions are rapid enough to be in the fast motional regime (omega o2 tau c2 less than 1). The conformation about the galactose-glucose intersaccharide linkage, calculated from the 2H NMR data, is shown to differ substantially from those found in X-ray diffraction studies of crystalline lactose and high-resolution NMR studies of methyl lactoside in nonviscous solution. The orientations of the hydroxymethyl groups in the headgroup have been calculated from the 2H NMR data. For the galactosyl residue the data are consistent with the presence of more than one rotamer about the C5"-C6" bond which are in fast exchange on the 2H NMR time scale. The hydroxymethyl group of the glucose residue exists in two rotameric forms about the C5'-C6' bond which have relative populations of ca. 2:1 and which are in slow exchange on the 2H NMR time scale (10(-5) s). The two rotamers differ from those deduced from X-ray crystallography of crystalline lactose and 13C NMR studies of methyl lactoside in solution.     

Solution structure of human Brg1 bromodomain and its specific binding to acetylated histone tails

Human brahma-related gene 1 (Brg1) is a core protein in human SWI/SNF chromatin-remodeling complex which regulates gene expression. Brg1 contains a bromodomain that has been shown to anchor the entire complex to promoter nucleosomes by interacting with histones that are acetylated at specific lysine residues. The Brg1 bromodomain belongs to an important subclass of the bromodomain family for which no structural information is known. Here we report the solution structure of the Brg1 bromodomain determined by NMR. The Brg1 bromodomain conserves the left-handed, four-helix bundle topology found in other bromodomain structures. However, the alphaZ helix of Brg1 bromodomain is about 4 residues shorter relative to previously published bromodomain structures. Using NMR perturbation studies, we demonstrate the Brg1 bromodomain binds acetyllysine in the context of histone tails, with no comparable affinity for unacetylated peptides. The estimated dissociation constants (KD) for acetylated histone peptides H4-AcK8 and H4-AcK12 are 4.0 and 3.6 mM, respectively. In this study the dominant substrate was H3-AcK14 (KD approximately 1.2 mM). Mutagenesis analysis reveals several residues important for the binding specificity. Using molecular dynamics simulations, we present a model of the Brg1 bromodomain in complex with H3-AcK14 and discuss the potential interactions which provide the selectivity of the Brg1 bromodomain for histone H3-AcK14.     

Solution structure of human proinsulin C-peptide

The C-peptide of proinsulin is important for the biosynthesis of insulin, but has been considered for a long time to be biologically inert. Recent studies in diabetic patients have stimulated a new debate about its possible regulatory role, suggesting that it is a hormonally active peptide. We describe structural studies of the C-peptide using 2D NMR spectroscopy. In aqueous solution, the NOE patterns and chemical shifts indicate that the ensemble is a nonrandom structure and contains substructures with defined local conformations. These are more clearly visible in 50% H2O/50% 2,2,2-trifluoroethanol. The N-terminal region (residues 2-5) forms a type I beta-turn, whereas the C-terminal region (residues 27-31) presents the most well-defined structure of the whole molecule including a type III'beta-turn. The C-terminal pentapeptide (EGSLQ) has been suggested to be responsible for chiral interactions with an as yet uncharacterized, probably a G-protein-coupled, receptor. The three central regions of the molecule (residues 9-12, 15-18 and 22-25) show tendencies to form beta-bends. We propose that the structure described here for the C-terminal pentapeptide is consistent with the previously postulated CA knuckle, believed to represent the active site of the C-peptide of human proinsulin.     

High-resolution 1H NMR study of the solution structure of delta-hemolysin

The 26-residue toxin from Staphylococcus aureus, delta-hemolysin, is thought to act by traversing the plasma membrane. The structure of this peptide, in methanol solution, has been investigated by using high-resolution NMR in combination with molecular dynamics calculations. The 1H NMR spectrum has been completely assigned, and it is shown that residues 2-20 form a relatively stable helix while the residues at the C-terminal end appear to be more flexible. The structures were calculated only from nuclear Overhauser effect data and standard bond lengths. It is shown that the results are consistent with 3JNH-alpha CH coupling constants and amide hydrogen exchange rates.     

Porcine pancreatic phospholipase A2: sequence-specific 1H and 15N NMR assignments and secondary structure

The solution structure of porcine pancreatic phospholipase A2 (124 residues, 14 kDa) has been studied by two-dimensional homonuclear 1H and two- and three-dimensional heteronuclear 15N-1H nuclear magnetic resonance spectroscopy. Backbone assignments were made for 117 of the 124 amino acids. Short-range nuclear Overhauser effect (NOE) data show three alpha-helices from residues 1-13, 40-58, and 90-109, an antiparallel beta-sheet for residues 74-85, and a small antiparallel beta-sheet between residues 25-26 and 115-116. A 15N-1H heteronuclear multiple-quantum correlation experiment was used to monitor amide proton exchange over a period of 22 h. In total, 61 amide protons showed slow or intermediate exchange, 46 of which are located in the three large helices. Helix 90-109 was found to be considerably more stable than the other helices. For the beta-sheets, four hydrogen bonds could be identified. The secondary structure of porcine PLA in solution, as deduced from NMR, is basically the same as the structure of porcine PLA in the crystalline state. Differences were found in the following regions, however. Residues 1-6 in the first alpha-helix are less structured in solution than in the crystal structure. Whereas in the crystal structure residues 24-29 are involved both in a beta-sheet with residues 115-117 and in a hairpin turn, the expected hydrogen bonds between residues 24-117 and 25-29 do not show slow exchange behavior. This and the absence of several expected NOEs imply that this region has a less well defined structure in solution. Finally, the hydrogen bond between residues 78-81, which is part of a beta-sheet, does not show slow exchange behavior.     

Solution structure of micelle-bound H5 peptide (427-452): a primary structure corresponding to the pore forming region of the voltage dependent potassium channel

A 26-mer peptide with the sequence of the pore forming region (residues 427-452) of the Shaker K(+) channel (H5 region) was chemically synthesized. Analyses by CD and two-dimensional 1H NMR spectroscopy were used to investigate the structure of the peptide bound to SDS micelles in solution, which are commonly used in biophysical studies. The tertiary structure of the peptide as a monomer was composed of an alpha-helix (431-438), a turn (439-442), and random coils (427-430, 443-452), and was very similar to that of the pore forming region of the native K(+) channel from Streptomyces lividans determined by X-ray analysis. This result suggests that even an isolated peptide forms a native-like conformation for residues from 431 to 442, depending on its intrinsic amino acid sequence and the surrounding environment.     

Determination of the membrane contact residues and solution structure of the helix F/G loop of prostaglandin I2 synthase

From our topological arrangement model of prostaglandin I(2) synthase (PGIS) created by homology modeling and topology studies, we hypothesized that the helix F/G loop of PGIS contains a membrane contact region distinct from the N-terminal membrane anchor domain. To provide direct experimental data we have explored the relationship between the endoplasmic reticulum (ER) membrane and the PGIS F/G loop using a constrained synthetic peptide to mimic PGIS residues 208-230 cyclized on both ends through a disulfide bond with added Cys residues. The solution structure and the residues important for membrane contact of the constrained PGIS F/G loop peptide were investigated by high-resolution 1H two-dimensional nuclear magnetic resonance (2D NMR) experiments and a spin label incorporation technique. Through the combination of 2D NMR experiments in the presence of dodecylphosphocholine (DPC) micelles used to mimic the membrane environment, complete 1H NMR assignments of the F/G loop segment have been obtained and the solution structure of the peptide has been determined. The PGIS F/G loop segment shows a defined helix turn helix conformation, which is similar to the three-dimensional crystallography structure of P450BM3 in the corresponding region. The orientation and the residues contacted with the membrane of the PGIS F/G loop were evaluated from the effect of incorporation of a spin-labeled 12-doxylstearate into the DPC micelles with the peptide. Three residues in the peptide corresponding to the PGIS residues L217 (L11), L222 (L16), and V224 (V18) have been demonstrated to contact the DPC micelles, which implies that the residues are involved in contact with the ER membrane in the native membrane-bound PGIS. These results provided the first experimental evidence to localize the membrane contact residues in the F/G loop region of microsomal P450 and are valuable to further define and understand the membrane topology of PGIS and those of other microsomal P450s in the native membrane environment.     

The structure and dynamics of rat apo-cellular retinol-binding protein II in solution: comparison with the X-ray structure

The structure and dynamics of rat apo-cellular retinol binding protein II (apo-CRBP II) in solution has been determined by multidimensional NMR analysis of uniformly enriched recombinant rat 13C, 15N-apo-CRBP II and 15N-apo-CRBP II. The final ensemble of 24 NMR structures has been calculated from 3274 conformational restraints or 24.4 restraints/residue. The average root-mean-square deviation of the backbone atoms for the final 24 structures relative to their mean structure is 1.06 A. Although the average solution structure is very similar to the crystal structure, it differs at the putative entrance to the binding cavity, which is formed by the helix-turn-helix motif, the betaC-betaD turn and the betaE-betaF turn. The mean coordinates of the main-chain atoms of amino acid residues 28-38 are displaced in the solution structure relative to the crystal structure. The side-chain of F58, located on the betaC-betaD turn, is reoriented such that it interacts with L37 and no longer blocks entry into the ligand-binding pocket. Residues 28-35, which form the second helix of the helix-turn-helix motif in the crystal structure, do not exhibit a helical conformation in the solution structure. The solution structure of apo-CRBP II exhibits discrete regions of backbone disorder which are most pronounced at residues 28-32, 37-38 and 73-76 in the betaE-betaF turn as evaluated by the consensus chemical shift index, the root-mean-square deviation, amide 1H exchange rates and 15N relaxation studies. These studies indicate that fluctuations in protein conformation occur on the microseconds to ms time-scale in these regions of the protein. Some of these exchange processes can be directly observed in the three-dimensional 15N-resolved NOESY spectrum. These results suggest that in solution, apo-CRBP II undergoes conformational changes on the microseconds to ms time-scale which result in increased access to the binding cavity.     

Sequence-specific 1H NMR assignments and solution structure of bovine pancreatic polypeptide.

Sequence-specific 1H NMR assignments for the 36 residue bovine pancreatic polypeptide (bPP) have been completed. The secondary and tertiary structure of bPP in solution has been determined from experimental NMR data. It is shown that bPP has a very well-defined C-terminal alpha-helix involving residues 15-32. Although regular secondary structure cannot be clearly defined in the N-terminal region, residues 4-8 maintain a rather ordered conformation in solution. This is attributed primarily to the hydrophobic interactions between this region and the C-terminal helix. The two segments of the structure are joined by a turn which is poorly defined. The four end residues both at the N-terminus and the C-terminus are highly disordered in solution. The overall fold of the bPP molecule is very closely similar to that found in the crystal structure of avian pancreatic polypeptide (aPP). The RMS deviation for backbone atoms of residues 4-8 and 15-32 between the bPP mean structure and the aPP crystal structure is 0.65 A, although there is only 39% identity of the residues. Furthermore, the average conformations of some (mostly from the alpha-helix) side chains of bPP in solution are closely similar to those of aPP in the crystal structure. A large number of side chains of bPP, however, show significant conformational averaging in solution.     

Comparative 2D NMR studies of human insulin and des-pentapeptide insulin: sequential resonance assignment and implications for protein dynamics and receptor recognition

The solution structure and dynamics of human insulin are investigated by 2D 1H NMR spectroscopy in reference to a previously analyzed analogue, des-pentapeptide(B26-B30) insulin (DPI; Hua, Q.X., & Weiss, M.A. (1990) Biochemistry 29, 10545-10555). This spectroscopic comparison is of interest since (i) the structure of the C-terminal region of the B-chain has not been determined in the monomeric state and (ii) the role of this region in binding to the insulin receptor has been the subject of long-standing speculation. The present NMR studies are conducted in the presence of an organic cosolvent (20% acetic acid), under which conditions both proteins are monomeric and stably folded. Complete sequential assignment of human insulin is obtained and leads to the following conclusions. (1) The secondary structure of the insulin monomer (three alpha-helices and B-chain beta-turn) is similar to that observed in the 2-Zn crystal state. (2) The folding of DPI is essentially the same as the corresponding portion of intact insulin, in accord with the similarities between their respective crystal structures. However, differences between insulin and DPI are observed in the extent of conformational broadening of amide resonances, indicating that the presence or absence of residues B26-B30 influences the overall dynamics of the protein on the millisecond time scale. (3) Residues B24-B28 adopt an extended configuration in the monomer and pack against the hydrophobic core as in crystallographic dimers; residues B29 and B30 are largely disordered. This configuration differs from that described in a more organic milieu (35% acetonitrile; Kline, A.D., & Justice, R.M., Jr. (1990) Biochemistry 29, 2906-2913), suggesting that the conformation of insulin in the latter study may have been influenced by solvent composition. (4) The insulin fold is shown to provide a model for collective motions in a protein with implications for the mechanism of protein-protein recognition. To our knowledge, this paper describes the first detailed analysis of a protein NMR spectrum under conditions of extensive conformational broadening. Such an analysis is made possible in the present case by comparative study of an analogue (DPI) with more tractable spectroscopic properties.     

Solution structure and dynamics of a designed monomeric variant of the lambda Cro repressor.

The solution structure of a monomeric variant of the lambda Cro repressor has been determined by multidimensional NMR. Cro K56[DGEVK] differs from wild-type Cro by the insertion of five amino acids at the center of the dimer interface. 1H and 15N resonances for 70 of the 71 residues have been assigned. Thirty-two structures were calculated by hybrid distance geometry/simulated annealing methods using 463 NOE-distance restraints, 26 hydrogen-bond, and 39 dihedral-angle restraints. The root-mean-square deviation (RMSD) from the average structure for atoms in residues 3-60 is 1.03 +/- 0.44 A for the peptide backbone and 1.6 +/- 0.73 A for all nonhydrogen atoms. The overall structure conforms very well to the original design. Although the five inserted residues form a beta hairpin as expected, this engineered turn as well as other turns in the structure are not well defined by the NMR data. Dynamics studies of backbone amides reveal T1/T2 ratios of residues in the alpha2-alpha3, beta2-beta3, and engineered turn that are reflective of chemical exchange or internal motion. The solution structure and dynamics are discussed in light of the conformational variation that has been observed in other Cro structures, and the importance of flexibility in DNA recognition.     

Backbone assignment and secondary structure of Rnd1, an unusual Rho family small GTPase

Rho GTPases have attracted considerable interest as signaling molecules due to their variety of functional roles in cells. Rnd1 is a relatively recently discovered Rho GTPase with no enzymatic activity against its bound GTP nucleotide, setting it apart from other family members. Research has revealed a critical role for Rnd1 not only in neurite outgrowth, dendrite development, axon guidance, but also in gastric cancer and in endothelial cells during inflammation. Structural information is crucial for understanding the mechanism that forms the basis for protein–protein interactions and functions, but until recently there were no reports of NMR studies directly on the Rnd1 protein. In this paper we report assignments for the majority of Rnd1 NMR resonances based on 2D and 3D NMR spectra. Rnd1 assignment was a challenging task, however, despite optimization strategies that have facilitated NMR studies of the protein (Cao and Buck in Small GTPase 2:295–304, 2012). Besides common triple-resonance experiments, 3D HNCA, 3D HN(CO)CA, 3D HNCO which are usually employed for sequence assignment, 3D NOESY experiments and specific labeling of 13 kinds of amino acids were also utilized to gain as many ¹H(N), ¹³C, and ¹⁵N resonances assignments as possible. For 170 cross peaks observed out of 183 possible mainchain N–H correlations in the ¹H–¹⁵N TROSY spectrum, backbone assignment was finally completed for 127 resonances. The secondary structure was then defined by chemical shifts and TALOS+ based on the assignments. The overall structure in solution compares well with that of Rnd1 in a crystal, except for two short segments, residues 77–83 and residues 127–131. Given that some features are shared among Rho GTPases, Rnd1 assignments are also compared with two other family members, Cdc42 and Rac1. The overall level of Rnd1 assignment is lower than for Cdc42 and Rac1, consistent with its lower stability and possibly increased internal dynamics. However, while the Rnd1 switch II region remained un-assigned, the switch I region could be more fully assigned compared to Cdc42 and Rac1. The NMR assignment and structure analysis reported here provides a robust basis for future study of the binding between Rnd1 and other proteins, as well as for further studies of the molecular function of this unusual GTPase.     

Solution structure of the calcium channel antagonist omega-conotoxin GVIA.

The three-dimensional solution structure is reported for omega-conotoxin GVIA, which is a potent inhibitor of presynaptic calcium channels in vertebrate neuromuscular junctions. Structures were generated by a hybrid distance geometry and restrained molecular dynamics approach using interproton distance, torsion angle, and hydrogen-bonding constraints derived from 1H NMR data. Conformations of GVIA with low constraint violations converged to a common peptide fold. The secondary structure in the peptide is an antiparallel triple-stranded beta-sheet containing a beta-hairpin and three tight turns. The NMR data are consistent with the region of the peptide from residues S9 to C16 being more dynamic than the rest of the peptide. The peptide has an amphiphilic structure with a positively charged hydrophilic side and an opposite side that contains a small hydrophobic region. Residues that are thought to be important in binding and function are located on the hydrophilic face of the peptide.     

NMR relaxation and the structure of a synthetic DNA poly(dA-dT).poly(dA-dT)

1H-1H and 31P-1H nuclear Overhauser effects and 31P NMR spin-lattice relaxation times were measured for a synthetic DNA poly(dA-dT).poly(dA-dT) in a low-salt aqueous solution. The results have shown that all bases in the double helix are anti-orientated with respect to deoxyribose residues and that the sugar-phosphate backbone has an alternating architecture.     

Solution structure of the third extracellular loop of human thromboxane A2 receptor

The extracellular domains of the thromboxane A2 receptor (TP receptor) were found to be involved in the specific ligand recognition. Determination of the three-dimensional (3D) structure of the extracellular loops would help to explain the mechanism of the ligand binding to its receptor with regard to the tertiary structure. Based on our previous studies on the extracellular loop of the human TP receptor, the synthetic loop peptides, whose termini are constrained to 10 to 14-A separations, are more likely to mimic the native structure of the extracellular loops. In this study, a peptide with the sequence of the third extracellular loop (eLP3, residues 271-289) of the TP receptor was synthesized, and its termini were constrained by the formation of a disulfide bond between the additional homocysteines located at both ends. Fluorescence spectroscopic studies showed that the fluorescence intensity of this constrained loop peptide could be increased by the addition of SQ29,548, a TP receptor antagonist, which indicated the interaction between the peptide and the ligand. The structure of this peptide was then studied by two-dimensional 1H nuclear magnetic resonance (NMR) spectroscopy. 1H NMR assignments of the peptide were obtained and structure constraints were derived from nuclear Overhauser effects and J-coupling constants. The solution structure of the peptide was then calculated based on these constraints. The overall structure shows a beta turn from residues 278 to 281. It also shows a distance of 9.45A between the ends of the N and C termini of the peptide, which agrees with the distance between the two residues at the ends of the transmembrane helices connecting the eLP3 on the TP receptor working model generated using molecular modeling, based on the crystal structure of bovine rhodopsin. These results provide valuable information for the characterization of the complete 3D structure of the extracellular domains of the human TP receptor.     

Nuclear magnetic resonance solution structure of hirudin(1-51) and comparison with corresponding three-dimensional structures determined using the complete 65-residue hirudin polypeptide chain.

The three-dimensional structure of the N-terminal 51-residue domain of recombinant hirudin in aqueous solution was determined by 1H nuclear magnetic resonance (NMR) spectroscopy, and the resulting high-quality solution structure was compared with corresponding structures obtained from studies with the intact, 65-residue polypeptide chain of hirudin. On the basis of 580 distance constraints derived from nuclear Overhauser effects and 109 dihedral angle constraints, a group of 20 conformers representing the solution structure of hirudin(1-51) was computed with the program DIANA and energy-minimized with a modified version of the program AMBER. Residues 3 to 30 and 37 to 48 form a well-defined molecular core with two antiparallel beta-sheets composed of residues 14 to 16 and 20 to 22, and 27 to 31 and 36 to 40, and three reverse turns at residues 8 to 11 (type II), 17 to 20 (type II') and 23 to 26 (type II). The average root-mean-square deviation of the individual NMR conformers relative to their mean co-ordinates is 0.38 A for the backbone atoms and 0.77 A for all heavy atoms of these residues. Increased structural disorder was found for the N-terminal dipeptide segment, the loop at residues 31 to 36, and the C-terminal tripeptide segment. The solution structure of hirudin(1-51) has the same molecular architecture as the corresponding polypeptide segment in natural hirudin and recombinant desulfatohirudin. It is also closely similar to the crystal structure of the N-terminal 51-residue segment of hirudin in a hirudin-thrombin complex, with root-mean-square deviations of the crystal structure relative to the mean solution structure of 0.61 A for the backbone atoms and 0.91 A for all heavy atoms of residues 3 to 30 and 37 to 48. Further coincidence is found for the loop formed by residues 31 to 36, which shows increased structural disorder in all available solution structures of hirudin, and of which residues 32 to 35 are not observable in the electron density map of the thrombin complex. Significant local structural differences between hirudin(1-51) in solution and hirudin in the crystalline thrombin complex were identified mainly for the N-terminal tripeptide segment and residues 17 to 21. These are further analyzed in an accompanying paper.     

Solution structure of human survivin and its binding interface with Smac/Diablo

NMR studies of the antiapoptotic protein survivin have been used to determine the homodimer interface of the protein in solution and to identify residues of the protein that interact with Smac/Diablo. In solution, survivin(1-120) forms a bow-tie-shaped dimer whose interface is composed of its N-terminal residues as well as residues connecting its BIR domain to the C-terminal alpha helix. The solution structure resolves the controversy regarding the two possible dimer interfaces for survivin observed in X-ray crystal structures. The structural basis for the interaction between survivin and Smac/Diablo was also investigated. When Smac/Diablo or N-terminal Smac/Diablo peptide analogues are added to a solution of survivin, specific residues near alpha4 and beta3 are perturbed. NMR experiments indicate that the peptides bind across the third beta-strand of survivin in a manner similar to the way Smac/Diablo peptides bind to the BIR3 domain of X-linked IAP (XIAP).     

Monomeric solution structure of the prototypical 'C' chemokine lymphotactin

Lymphotactin, the sole identified member of the C class of chemokines, specifically attracts T lymphocytes and natural killer cells. This 93-residue protein lacks 2 of the 4 conserved cysteine residues characteristic of the other 3 classes of chemokines and possesses an extended carboxyl terminus, which is required for chemotactic activity. We have determined the three-dimensional solution structure of recombinant human lymphotactin by NMR spectroscopy. Under the conditions used for the structure determination, lymphotactin was predominantly monomeric; however, pulsed field gradient NMR self-diffusion measurements and analytical ultracentrifugation revealed evidence of dimer formation. Sequence-specific chemical shift assignments were determined through analysis of two- and three-dimensional NMR spectra of (15)N- and (13)C/(15)N-enriched protein samples. Input for the torsion angle dynamics calculations used in determining the structure included 1258 unique NOE-derived distance constraints and 60 dihedral angle constraints obtained from chemical-shift-based searching of a protein conformational database. The ensemble of 20 structures chosen to represent the structure had backbone and heavy atom rms deviations of 0.46 +/- 0.11 and 1.02 +/- 0.14 A, respectively. The results revealed that human lymphotactin adopts the conserved chemokine fold, which is characterized by a three-stranded antiparallel beta-sheet and a C-terminal alpha-helix. Two regions are dynamically disordered as evidenced by (1)H and (13)C chemical shifts and [(15)N]-(1)H NOEs: residues 1-9 of the amino terminus and residues 69-93 of the C-terminal extension. A functional role for the C-terminal extension, which is unique to lymphotactin, remains to be elucidated.