Studies of inhibitor binding to Escherichia coli purine nucleoside phosphorylase using the transferred nuclear Overhauser effect and rotating-frame nuclear Overhauser enhancement

XRCC1 interaction with the REV1 C-terminal domain suggests a role in post replication repair

The function of X-ray cross complementing group 1 protein (XRCC1), a scaffold that binds to DNA repair enzymes involved in single-strand break and base excision repair, requires that it be recruited to sites of damaged DNA. However, structural insights into this recruitment are currently limited. Sequence analysis of the first unstructured linker domain of XRCC1 identifies a segment consistent with a possible REV1 interacting region (X1RIR) motif. The X1RIR motif is present in translesion polymerases that can be recruited to the pol /REV1 DNA repair complex via a specific interaction with the REV1 C-terminal domain. NMR and fluorescence titration studies were performed on XRCC1-derived peptides containing this putative RIR motif in order to evaluate the binding affinity for the REV1 C-terminal domain. These studies demonstrate an interaction of the XRCC1-derived peptide with the human REV1 C-terminal domain characterized by dissociation constants in the low micromolar range. Ligand competition studies comparing the XRCC1 RIR peptide with previously studied RIR peptides were found to be inconsistent with the NMR based Kd values. These discrepancies were resolved using a fluorescence assay for which the RIR–REV1 system is particularly well suited. The structure of a REV1-XRCC1 peptide complex was determined by using NOE restraints to dock the unlabeled XRCC1 peptide with a labeled REV1 C-terminal domain. The structure is generally homologous with previously determined complexes with the pol κ and pol η RIR peptides, although the helical segment in XRCC1 is shorter than was observed in these cases. These studies suggest the possible involvement of XRCC1 and its associated repair factors in post replication repair.

Insights into phosphate cooperativity and influence of substrate modifications on binding and catalysis of hexameric purine nucleoside phosphorylases

The hexameric purine nucleoside phosphorylase from Bacillus subtilis (BsPNP233) displays great potential to produce nucleoside analogues in industry and can be exploited in the development of new anti-tumor gene therapies. In order to provide structural basis for enzyme and substrates rational optimization, aiming at those applications, the present work shows a thorough and detailed structural description of the binding mode of substrates and nucleoside analogues to the active site of the hexameric BsPNP233. Here we report the crystal structure of BsPNP233 in the apo form and in complex with 11 ligands, including clinically relevant compounds. The crystal structure of six ligands (adenine, 2'deoxyguanosine, aciclovir, ganciclovir, 8-bromoguanosine, 6-chloroguanosine) in complex with a hexameric PNP are presented for the first time. Our data showed that free bases adopt alternative conformations in the BsPNP233 active site and indicated that binding of the co-substrate (2'deoxy)ribose 1-phosphate might contribute for stabilizing the bases in a favorable orientation for catalysis. The BsPNP233-adenosine complex revealed that a hydrogen bond between the 5' hydroxyl group of adenosine and Arg(43*) side chain contributes for the ribosyl radical to adopt an unusual C3'-endo conformation. The structures with 6-chloroguanosine and 8-bromoguanosine pointed out that the Cl(6) and Br(8) substrate modifications seem to be detrimental for catalysis and can be explored in the design of inhibitors for hexameric PNPs from pathogens. Our data also corroborated the competitive inhibition mechanism of hexameric PNPs by tubercidin and suggested that the acyclic nucleoside ganciclovir is a better inhibitor for hexameric PNPs than aciclovir. Furthermore, comparative structural analyses indicated that the replacement of Ser(90) by a threonine in the B. cereus hexameric adenosine phosphorylase (Thr(91)) is responsible for the lack of negative cooperativity of phosphate binding in this enzyme.

Transferred NOESY NMR studies of biotin mimetic peptide (FSHPQNT) bound to streptavidin: a structural model for studies of peptide-protein interactions

Protein-protein interactions control signaling, specific adhesion, and many other biological functions. The three-dimensional structures of the interfaces and bound ligand can be approached with transferred nuclear Overhauser effect spectroscopy NMR, which can be applied to much larger proteins than conventional NMR and requires less concentrated protein. However, it is not clear how accurately the structures of protein-bound peptides can be determined by transferred nuclear Overhauser effect spectroscopy. We studied the structure of a biotin mimetic peptide (FSHPQNT) bound to streptavidin, because the X-ray structure of the complex is available to 1.74 Å resolution, and we found that conditions could be adjusted so that the off-rates were fast enough for transferred nuclear Overhauser effect spectroscopy NMR. The off-rate was determined with (19)F NMR, using a para-fluoro-phenylalanine analog of the peptide. A new criterion for a lower limit on kinetic off-rate was found, which allowed accurate structure determination at a slower off-rate. Non-specific binding of the peptide to streptavidin was not significant, because biotin blocked the peptide transferred nuclear Overhauser effect spectroscopy. Protein mediation for the long-range peptide transferred nuclear Overhauser effect spectroscopy cross-peaks was corrected by a transferred nuclear Overhauser effect spectroscopy/ROESY averaging procedure. The protein-bound structure of the peptide was determined by transferred nuclear Overhauser effect spectroscopy constrained and simulated annealing. The structure deduced from the NMR was close to the X-ray structure.

Ternary borate-nucleoside complex stabilization by ribonuclease A demonstrates phosphate mimicry

Phosphate esters play a central role in cellular energetics, biochemical activation, signal transduction and conformational switching. The structural homology of the borate anion with phosphate, combined with its ability to spontaneously esterify hydroxyl groups, suggested that phosphate ester recognition sites on proteins might exhibit significant affinity for nonenzymatically formed borate esters. (11)B NMR studies and activity measurements on ribonuclease A (RNase A) in the presence of borate and several cytidine analogs demonstrate the formation of a stable ternary RNase A.3'-deoxycytidine-2'-borate ternary complex that mimics the complex formed between RNase A and a 2'-cytidine monophosphate (2'-CMP) inhibitor. Alternatively, no slowly exchanging borate resonance is observed for a ternary RNase A, borate, 2'-deoxycytidine mixture, demonstrating the critical importance of the 2'-hydroxyl group for complex formation. Titration of the ternary complex with 2'-CMP shows that it can displace the bound borate ester with a binding constant that is close to the reported inhibition constant of RNase A by 2'-CMP. RNase A binding of a cyclic cytidine-2',3'-borate ester, which is a structural homolog of the cytidine-2',3'-cyclic phosphate substrate, could also be demonstrated. The apparent dissociation constant for the cytidine-2',3'-borate.RNase A complex is 0.8 mM, which compares with a Michaelis constant of 11 mM for cytidine-2',3'-cyclic phosphate at pH 7, indicating considerably stronger binding. However, the value is 1,000-fold larger than the reported dissociation constant of the RNase A complex with uridine-vanadate. These results are consistent with recent reports suggesting that in situ formation of borate esters that mimic the corresponding phosphate esters supports enzyme catalysis.

Conformation of 3'CMP bound to RNase A using TrNOESY

The conditions for accurately determining distance constraints from TrNOESY data on a small ligand (3'CMP) bound to a small protein (RNase A, <14 kDa) are described. For small proteins, normal TrNOESY conditions of 10:1 ligand:protein or greater can lead to inaccurate structures for the ligand-bound conformation due to the contribution of the free ligand to the TrNOESY signals. By using two ligand:protein ratios (2:1 and 5:1), which give the same distance constraints, a conformation of 3'CMP bound to RNase A was determined (glycosidic torsion angle, chi=-166 degrees ; pseudorotational phase angle, 0 degrees < or = P < or =36 degrees ). Ligand-protein NOESY cross peaks were also observed and used to dock 3'CMP into the binding pocket of the apo-protein (7rsa). After energy minimization, the conformation of the 3'CMP:RNase A complex was similar to the X-ray structure (1 rpf) except that a C3'-endo conformation for the ribose ring (rather than C2'-exo conformation) was found in the TrNOESY structure.

Probing the Kinetic Landscape of Transient Peptide−Protein Interactions by Use of Peptide 15N NMR Relaxation Dispersion Spectroscopy: Binding of an Antithrombin Peptide to Human Prothrombin

Protein-ligand interactions may lead to the formation of multiple molecular complexes in dynamic exchange, affecting the kinetic and thermodynamic characteristics of the binding equilibrium. We followed the dissociation kinetics of the transient and specific complex of an antithrombotic peptide N-acetyl-Asp(55)-Phe-Glu-Glu-Ile-Pro(60)-Glu-Glu-Tyr-Leu-Gln(65) with human prothrombin by use of (15)N NMR relaxation dispersion spectroscopy of the peptide. Every one of the five (15)N-labeled adjacent residues of the peptide exhibited apparently different kinetic exchange and relaxation behaviors, which were especially evident at different concentrations of prothrombin. Binding-induced (15)N relaxation dispersion of residues Phe(56), Glu(57), Glu(58), and Ile(59) can be fitted phenomenologically to a two-site on-and-off exchange mechanism with physically feasible relaxation and kinetic parameters obtained for residues Phe(56), Glu(58), and Ile(59), independent of the prothrombin concentration. The apparent kinetic parameters of Glu(57) show some dependence on the concentration of prothrombin and the extracted transverse relaxation rate for Glu(57) in the bound state was severalfold higher than that expected for a protein-peptide complex with a size of approximately 72 kDa. In addition, the equilibrium population of the bound peptide obtained for Glu(57) was inconsistent with those for Phe(56), Glu(58), and Ile(59) and with the prothrombin/peptide ratios used in the experiments. These discrepancies can be explained by the presence of two conformations for the peptide-protein complex exchanging at a rate of approximately 100 s(-)(1). In all, our study shows that fast dissociation of protein-peptide complexes can be studied quantitatively using peptide (15)N NMR relaxation dispersion measurements without a precise knowledge of the peptide and protein concentrations. In addition, protein titration was found to improve the accuracy of quantitative analysis and may make it possible to determine the rate of conformational changes within the protein-peptide complex.

Selection of a high-energy bioactive conformation of a sulfonium-ion glycosidase inhibitor by the enzyme glucoamylase G2

Transferred nuclear Overhauser effect and rotating-frame Overhauser enhancement NMR spectroscopies are used to probe the conformation of a bicyclic sulfonium ion, which is an analogue of the naturally occurring glycosidase inhibitor castanospermine, bound to the enzyme glucoamylase G2. Enzyme inhibition assays indicate that the bicyclic sulfonium ion is a slightly better inhibitor (K(i) = 1.32 mM) of glucoamylase G2 than the naturally occurring sulfonium-ion glycosidase inhibitor, salacinol, with a K(i) value of 1.7 mM. The NMR results are interpreted in terms of the selection by the enzyme of a high-energy conformation of the ligand that is already represented in the ensemble of free-ligand conformations.

Expression, purification, and characterization of recombinant purine nucleoside phosphorylase from Escherichia coli

Recombinant purine nucleoside phosphorylase (PNPase) from Escherichia coli was prepared in high yield in order to facilitate its use in coupled assays to measure the kinetics of phosphate-liberating enzymes. The E. coli enzyme was overexpressed in E. coli by inserting the genomic fragment containing the deoD gene downstream of the isopropyl beta-d-thiogalactoside-inducible promotor of pSE380 expression vector. The recombinant protein was purified to approximately 90% homogeneity and with a yield of approximately 9000 units of activity/L of culture, using an efficient one-column procedure. A continuous spectrophotometric assay coupling P(i) release to the phosphorolysis of the nucleoside analogue 7-methylinosine (m(7)Ino) was recently described. Here, we report the steady-state kinetic parameters of the recombinant E. coli PNPase catalyzed reaction with m(7)Ino and P(i) as substrates and compare these parameters with those of a bacterial PNPase commercially available for use in coupled assays. Under the assay conditions described, the recombinant E. coli protein is active at higher pH values and is stable up to a temperature of approximately 55 degrees C and following multiple freeze-thaw cycles. It is activated by high ionic strength but loses some activity following dialysis or concentration under pressure. Finally, a new procedure for the synthesis of m(7)Ino from inosine is described which is safe and cost effective, making the use of this methylated nucleoside in PNPase-coupled P(i) assays more attractive.

The conformation of the T-antigen disaccharide bound to Maclura pomifera agglutinin in aqueous solution

The complex of Maclura pomifera agglutinin with the T-antigen disaccharide (beta-d-Gal-(1-->3)-alpha-d-GalNAc-(1-->O)-Me) was investigated by NMR spectroscopy in aqueous solution. Intramolecular transferred nuclear Overhauser enhancement (NOE) effects between the monosaccharide moieties were used to derive the ligand conformation in the lectin-bound state. Ligand protons in contact with the protein were identified by saturation transfer difference experiments and intermolecular transferred NOE effects. It is demonstrated that structural differences exist for the ligand-lectin complex in aqueous solution as compared with the previously published crystal structure (Lee, X., Thompson, A., Zhiming, Z., Ton-that, H., Biesterfeldt, J., Ogata, C., Xu, L., Johnston, R. A. Z. , and Young, N. M. (1998) J. Biol. Chem. 273, 6312-6318). In order to accommodate the O-methyl group of the disaccharide, the amino acid side chain of Tyr-122 has to rotate from its position in the crystal. The NMR data are in accord with two conformational families at the beta-(1-->3)glycosidic linkage in the solution complex with interglycosidic angles phi/psi = 45/-65 degrees and -65/-18 degrees. These differ from the bound conformation of the ligand in the crystal (phi/psi = 39/-8 degrees ) and are not highly populated by the ligand in the free state. The reason for the structural differences at the beta-(1-->3)glycosidic linkage are hydrogen bonds that stabilize the relative orientation of the monosaccharide units in the crystal. Our results demonstrate that the crystallization of a protein-carbohydrate complex can interfere with the delicate process of carbohydrate recognition in solution.

Determination of the solution conformation of d-gluco-dihydroacarbose, a high-affinity inhibitor bound to glucoamylase by transferred NOE NMR spectroscopy

The determination of the bound solution conformation of D-gluco-dihydroacarbose (GAC), a tight-binding inhibitor of several glycosidase and amylase enzymes, by glucoamylase is described. Transferred NOE NMR experiments and line-broadening effects indicate that GAC is bound in a conformation resembling that observed in the crystal structure. This contrasts with the predominant conformation of GAC when free in solution. The NMR results also suggest regions on the carbohydrate that are in close contact with the protein. The determination of the bound solution conformation of GAC by glucoamylase using transferred NOE (trNOE) measurements is a significant achievement given the high affinity constant (Ka = 3 x 10(7) M(-1)) for this receptor-ligand pair. It is striking that the off-rate for complexation is still sufficiently high to permit observation of trNOEs.

Theoretical analysis of the inter-ligand overhauser effect: a new approach for mapping structural relationships of macromolecular ligands

A theoretical framework has been developed for the evaluation of inter-ligand Overhauser effects (ILOE), predicted when pairs of ligands are observed in the presence of a macromolecular receptor which can form a ternary complex such that some of the protons on the two ligands are in close proximity with each other (generally less than approximately 5 A). Simulations for a pair of ligands with three spins each have been performed for a variety of geometric and rate parameters. Analogous to previously described calculations of TRNOE behavior, theoretical behavior of each of the nine cross peaks, A(ij), in a NOESY experiment involving ligands which can exist in the free, binary, or ternary complex states can be calculated. However, for exchange which is sufficiently rapid on the relaxation and chemical shift time scales, use of a collapsed matrix, C, corresponding to sums of sets of nine elements, will often be appropriate and generally simplifies the analysis. In order to generate inter-ligand Overhauser effects, it is optimal for the fraction of receptor involved in the ternary complex to be reasonably large; i.e., concentrations of both ligands should be near saturation. Based on a model assuming random binding order of the ligands, the dependence of ILOE resonance intensities on kinetic rate constants roughly parallels the dependence of transferred NOE (TRNOE) intensities. For diffusion controlled binding, i.e., k(on) approximately 10(8) M(-1) s(-1), the method is best suited for equilibrium dissociation constants in the micromolar-millimolar range (k(off) approximately 10(2)-10(5) s(-1)). Toward the slower dissociation rate constant end of this range, TRNOE and ILOE effects are still predicted, but the initial build-up curves become markedly nonlinear. For a kinetic binding scheme which assumes ordered binding of the ligands, the inherent asymmetry of the ligand binding process leads to more complex kinetics and alters the dependence of the ILOE on the kinetic parameters. In this case, the binding of the second ligand effectively reduces the exchange rate of the first ligand, reducing the transfer of NOE and ILOE information. The reduction in TRNOE and ILOE information which is prediced for the ordered ligand binding model is overcome at larger dissociation rate constants for either ligand 1 or ligand 2. In addition to the structural information available from ILOE data, the strong dependence of TRNOE and ILOE curves on ordered ligand binding suggests that such measurements could be useful for the characterization of ligand binding kinetics.

Structure of heparin-derived tetrasaccharide complexed to the plasma protein antithrombin derived from NOEs, J-couplings and chemical shifts

A complex of the synthetic tetrasaccharide AGA*IM [GlcN, 6-SO3-alpha(1-4)-GlcA-beta(1-4)-GlcN,3, 6-SO3-alpha(1-4)-IdoA-alphaOMe] and the plasma protein antithrombin has been studied by NMR spectroscopy. 1H and 13C chemical shifts, three-bond proton-proton (3JH-H) and one-bond proton-carbon coupling constants (1JC-H) as well as transferred NOEs and rotating frame Overhauser effects (ROEs) were monitored as a function of the protein : ligand molar ratio and temperature. Considerable changes were observed at both 20 : 1 and 10 : 1 ratios (AGA*IM : antithrombin) in 1H as well as 13C chemical shifts. The largest changes in 1H chemical shifts, and the linewidths, were found for proton resonances (A1, A2, A6, A6', A1*, A2*, A3*, A4*) in GlcN, 6-SO3 and GlcN,3,6-SO3 units, indicating that both glucosamine residues are strongly involved in the binding process. The changes in the linewidths in the IdoA residue were considerably smaller than those in other residues, suggesting that the IdoA unit experienced different internal dynamics during the binding process. This observation was supported by measurements of 3JH-H and 1JC-H. The magnitude of the three-bond proton-proton couplings (3JH1-H2 = 2.51 Hz and 3JH4-H5 = 2.23 Hz) indicate that in the free state an equilibrium exists between 1C4 and 2S0 conformers in the ratio of approximately 75 : 25. The chair form appears the more favourable in the presence of antithrombin, as inferred from the magnitude of the coupling constants. In addition, two-dimensional NOESY and ROESY experiments in the free ligand, as well as transferred NOESY and ROESY spectra of the complex, were measured and interpreted using full relaxation and conformational exchange matrix analysis. The theoretical NOEs were computed using the geometry of the tetrasaccharide found in a Monte Carlo conformational search, and the three-dimensional structures of AGA*IM in both free and bound forms were derived. All monitored NMR variables, 1H and 13C chemical shifts, 1JC-H couplings and transferred NOEs, indicated that the changes in conformation at the glycosidic linkage GlcN, 6-SO3-alpha(1-4)-GlcA were induced by the presence of antithrombin and suggested that the receptor selected a conformer different from that in the free state. Such changes are compatible with the two-step model [Desai, U.R., Petitou, M., Bjork, I. & Olson, S. (1998) J. Biol. Chem. 273, 7478-7487] for the interaction of heparin-derived oligosaccharides with antithrombin, but with a minor extension: in the first step a low-affinity recognition complex between ligand and receptor is formed, accompanied by a conformational change in the tetrasaccharide, possibly creating a complementary three-dimensional structure to fit the protein-binding site. During the second step, as observed in a structurally similar pentasaccharide [Skinner, R., Abrahams, J.-P., Whisstock, J.C., Lesk, A.M., Carrell, R.W. & Wardell, M.R. (1997) J. Mol. Biol. 266, 601-609; Jin, L., Abrahams, J.-P., Skinner, R., Petitou, M., Pike, R. N. & Carrell, R.W. (1997) Proc. Natl Acad. Sci. USA 94, 14683-14688], conformational changes in the binding site of the protein result in a latent conformation.

Transferred nuclear Overhauser enhancement (NOE) and rotating-frame NOE experiments reflect the size of the bound segment of the Forssman pentasaccharide in the binding site of Dolichos biflorus lectin

A complex between the Forssman pentasaccharide alpha-D-GalNAc-(1-->3)-beta-D-GalNAc-(1-->3)-alpha-D-Gal-(1-->4)-beta-D- Gal-(1-->4)-D-Glc and the seed lectin from Dolichos biflorus was studied using transfer-NOESY and transfer rotating frame NOE spectroscopy (ROESY) experiments. The evolution of transferred NOEs and ROEs as a function of the pentasaccharide/lectin ratio was different for the non-reducing disaccharide moiety alpha-D-GalNAc-(1-->3)-beta-D-GalNac compared to the rest of the molecule, which reflects distinct relaxation properties and effects of exchange broadening of the corresponding ligand resonances. Significantly, several intermolecular transferred NOEs were observed between protons of the nonreducing disaccharide moiety alpha-D-GalNAc-(1-->3)-beta-D-GalNAc and aliphatic as well as aromatic amino acid side chain protons in the binding pocket of the lectin. It is concluded that the non-reducing disaccharide fragment is buried in the lectin-binding pocket, whereas the reducing trisaccharide portion alpha-D-Gal-(1-->4)-beta-D-Gal-(1-->4)-D-Glc has no immediate contacts with the protein. The experimental transfer NOE data were qualitatively compared to theoretical proton-proton distances from a model that was based on a previous homology modeling study of a complex between the disaccharide fragment alpha-D-GalNAc-(1-->3)-beta-D-GalNAc and D. biflorus lectin. It was found that all intermolecular transferred NOEs matched short interatomic distances between ligand protons and aliphatic or aromatic amino acid side chain protons predicted by the theoretical model.

Applications of nuclear magnetic resonance spectroscopy and molecular modeling to the study of protein-carbohydrate interactions

This work provides an overview of the applications of NMR to the study of protein-carbohydrate interactions. The use of TR-NOE experiments in this context is given. In particular, the study of Ricin/lactose and Hevein/chitobiose complexes is detailed.

The conformation of inosine 5'-monophosphate (IMP) bound to IMP dehydrogenase determined by transferred nuclear overhauser effect spectroscopy

IMP dehydrogenase (IMPDH) catalyzes the NAD-dependent synthesis of xanthosine 5'-monophosphate which is the rate-limiting step in guanine nucleotide biosynthesis. Although IMPDH is the target of numerous chemotherapeutic agents, nothing has been known about the conformation of the enzyme-bound substrates. The conformation of IMP bound to human type II IMP dehydrogenase has been determined by two-dimensional transferred nuclear Overhauser effect NMR spectroscopy at 600 MHz. NOE buildup rates were determined by recording NOESY spectra at numerous mixing times. The cross-relaxation rates determined from the initial NOE build-up rates were used to calculate inter-proton distances of bound IMP. The conformation of the enzyme-bound IMP was obtained by molecular modeling with energy minimization using the experimentally determined inter-proton distance constraints. The glycosidic torsion angle of the bound nucleotide is anti and the sugar is in the C2-endo-conformation. This conformation places H2 of IMP, which is transferred to NAD in the reaction, in a position clear of the rest of the molecule in order to facilitate the reaction.

Studies of the bound conformations of methyl alpha-lactoside and methyl beta-allolactoside to ricin B chain using transferred NOE experiments in the laboratory and rotating frames, assisted by molecular mechanics and dynamics calculations

The conformation in solution of methyl beta-galactopyranosyl-(1-->4)-alpha-glucopyranoside (methyl alpha-lactoside) and methyl beta-galactopyranosyl-(1-->6)-beta-glucopyranoside (methyl beta-allolactoside) has been studied through NMR spectroscopy and molecular mechanics calculations. NOE measurements both in the laboratory and rotating frames, have been interpreted in terms of an ensemble average distribution of conformers. Molecular mechanics calculations have been performed to estimate the probability distribution of conformers from the steric energy maps. The experimental results indicate that methyl alpha-lactoside spends about 90% of its time in a broad low-energy region close to the global minimum, while methyl beta-allolactoside presents much higher flexibility. The conformational changes that occur when both disaccharides are bound to the ricin B chain in aqueous solution have been studied using transferred NOE experiments at several protein/ligand ratios. The observed data indicate that the protein causes a conformational variation in the torsion angles of methyl alpha-lactoside changing towards smaller angle values (phi/psi approximately -20/-20), although the recognized conformer is still within the lowest energy region. In particular, the torsional changes separate Gal H1 from Glc H3 and Glc H6 protons, with a noticeable decrease in the intensities of the corresponding NOE cross-peaks, which were clearly observed for the free disaccharide. On the other hand, different conformations around the phi, psi, and omega glycosidic bonds of methyl beta-allolactoside are recognized by the lectin. In fact, for the methyl-beta-allolactoside-ricin-B complex, only the NOESY cross-peaks corresponding to the protons of the galactose residue are negative, as expected for a molecule in the slow motion regime. In contrast, the corresponding cross peaks for the glucose residue were about zero, as expected for a molecule whose motion is practically independent of the protein. However, for the methyl-alpha-lactoside-ricin-B complex, all the NOESY cross-peaks for both the galactose and glucose moieties were clearly negative. From the NMR experimental point of view, it is demonstrated that the comparison of longitudinal and transversal transferred NOEs allows one to clearly differentiate direct enhancements from spin diffusion effects, which are of major concern when analysing NOE spectra of macromolecules.(ABSTRACT TRUNCATED AT 250 WORDS)

NMR studies of novel inhibitors bound to farnesyl-protein transferase

Farnesyl-protein transferase (FPTase) catalyzes the posttranslational farnesylation of the cysteine residue located in the carboxyl-terminal tetrapeptide of the Ras oncoprotein. Prenylation of this residue is essential for the membrane association and cell-transforming activities of ras. Inhibitors of FPTase have been demonstrated to inhibit ras-dependent cell transformation and thus represent a potential therapeutic strategy for the treatment of human cancers. The FPTase-bound conformation of a tetrapeptide inhibitor, CVWM, and a novel pseudopeptide inhibitor, L-739,787, have been determined by NMR spectroscopy. Distance constraints were derived from two-dimensional transferred nuclear Overhauser effect experiments. Ligand competition experiments identified the NOEs that originate from the active-site conformation. Structures were calculated with the combination of distance geometry and restrained energy minimization. Both peptide backbones are shown to adopt nonideal reverse-turn conformations most closely approximating a type III beta-turn. These results provide a basis for understanding the spatial arrangements necessary for inhibitor binding and selectivity and may aid in the design of therapeutic agents.