A one- and two-dimensional NMR study of the B to Z transition of (m5dC-dG)3 in methanolic solution

The deoxyribose hexanucleoside pentaphosphate (m5dC-dG)3 has been studied by 500 MHz 1H NMR in D2O (0.1 M NaCl) and in D2O/deuterated methanol mixtures. Two conformations, in slow equilibrium on the NMR time scale, were detected in methanolic solution. Two-dimensional nuclear Overhauser effect (NOE) experiments were used to assign the base and many of the sugar resonances as well as to determine structural features for both conformations. The results were consistent with the an equilibrium in solution between B-DNA and Z-DNA. The majority of the molecules have a B-DNA structure in low-salt D2O and a Z-DNA structure at high methanol concentrations. A cross-strand NOE between methyl groups on adjacent cytosines is observed for Z-DNA but not B-DNA. The B-DNA conformation predominates at low methanol concentrations and is stabilized by increasing temperature, while the Z-DNA conformation predominates at high methanol concentrations and low temperatures. 31P NMR spectra gave results consistent with those obtained by 1H NMR. Comparison of the 31P spectra with those obtained on poly(dG-m5dC) allow assignment of the lower field resonances to GpC in the Z conformation.     

NMR studies of [U-13C]cyclosporin A bound to cyclophilin: bound conformation and portions of cyclosporin involved in binding

Cyclosporin A (CsA), a potent immunosuppressant, is known to bind with high specificity to cyclophilin (CyP), a 17.7 kDa protein with peptidyl-prolyl isomerase activity. In order to investigate the three-dimensional structure of the CsA/CyP complex, we have applied a variety of multidimensional NMR methods in the study of uniformly 13C-labeled CsA bound to cyclophilin. The 1H and 13C NMR signals of cyclosporin A in the bound state have been assigned, and from a quantitative interpretation of the 3D NOE data, the bound conformation of CsA has been determined. Three-dimensional structures of CsA calculated from the NOE data by using a distance geometry/simulated appealing protocol were found to be very different from previously determined crystalline and solution conformations of uncomplexed CsA. In addition, from CsA/CyP NOEs, the portions of CsA that interact with cyclophilin were identified. For the most part, those CsA residues with NOEs to cyclophilin were the same residues important for cyclophilin binding and immunosuppressive activity as determined from structure/activity relationships. The structural information derived in this study together with the known structure/activity relationships for CsA analogues may prove useful in the design of improved immunosuppressants. Moreover, the approach that is described for obtaining the structural information is widely applicable to the study of small molecule/large molecule interactions.     

Troponin I inhibitory peptide (96-115) has an extended conformation when bound to skeletal muscle troponin C.

We have utilized CD and NMR spectroscopy to study the conformation of the troponin I (TnI) inhibitory peptide [TnI(96-115)] free in solution and when bound to troponin C (TnC). Analysis of the CD spectrum of the free peptide in aqueous solution indicates it is only approximately 3% helix. Upon complex formation with TnC, there is no change in total helix content compared to the sum of the free components. The NMR data support a predominantly extended conformation for the free peptide. TnI(96-115) bound to TnC was selectively observed by NMR using deuterated TnC (dTnC). For the 1:1 ratio of TnI(96-115) to dTnC used, 95% of the peptide was bound to dTnC. The chemical shifts of the TnC-bound peptide resonances are similar to those of the free peptide, indicating that the change in peptide conformation as a consequence of binding to TnC is small. For the TnC-bound TnI(96-115) peptide, the ratios of sequential Halpha-HN to intraresidue HN-Halpha NOE cross-peak volumes support a predominantly extended conformation, possibly kinked at Gly104. The results presented here are in agreement with sequence analysis predictions for TnI(96-115) as a free peptide or within the intact TnI sequence. The predominantly extended structure for the 96-115 inhibitory sequence segment of TnI with a kink at Gly104 may facilitate its binding alternately to actin or TnC in response to the Ca2+ signals that control thick and thin filament interactions during the contractile cycle.     

Solution structure of a common substrate mimetic of cyclooxygenase-downstream synthases bound to an engineered thromboxane A2 synthase using a high-resolution NMR technique

Understanding the docking mechanism of the common substrate, prostaglandin H(2) (PGH(2)), into the active sites of different cyclooxygenase(COX)-downstream synthases is a key step toward uncovering the molecular basis of the isomerization of PGH(2) to different prostanoids. A high-resolution NMR spectroscopy was used to determine the conformational changes and solution 3D structure of U44069, a PGH(2) analogue, bound to one of the COX-downstream synthases-an engineered thromboxane A(2) synthase (TXAS). The dynamic binding was clearly observed by (1)D NMR titration. The detailed conformational change and 3D structure of U44069 bound to the TXAS were demonstrated by 2D (1)H NMR experiments using transferred NOEs. Through the assignments for the 2D (1)H NMR spectra, TOCSY, DQF-COSY, NOESY, and the structural calculations based on the NOE constraints, they demonstrated that the widely open conformation with a triangle shape of the free U44069 changed to a compact structure with an oval shape when bound to the TXAS. The putative substrate-binding pocket of the TXAS model fits the conformation of the TXAS-bound U44069 appropriately, but could not fit the free form of U44069. It was the first to provide structural information for the dynamic docking of the PGH(2) mimic of the TXAS in solution, and to imply that PGH(2) undergoes conformational changes when bound to different COX-downstream synthases, which may play important roles in the isomerization of PGH(2) to different prostanoids. The NMR technique can be used as a powerful tool to determine the conformations of PGH(2) bound to other COX-downstream synthases.     

High-resolution NMR structure of an RNA model system: the 14-mer cUUCGg tetraloop hairpin RNA

We present a high-resolution nuclear magnetic resonance (NMR) solution structure of a 14-mer RNA hairpin capped by cUUCGg tetraloop. This short and very stable RNA presents an important model system for the study of RNA structure and dynamics using NMR spectroscopy, molecular dynamics (MD) simulations and RNA force-field development. The extraordinary high precision of the structure (root mean square deviation of 0.3 Å) could be achieved by measuring and incorporating all currently accessible NMR parameters, including distances derived from nuclear Overhauser effect (NOE) intensities, torsion-angle dependent homonuclear and heteronuclear scalar coupling constants, projection-angle-dependent cross-correlated relaxation rates and residual dipolar couplings. The structure calculations were performed with the program CNS using the ARIA setup and protocols. The structure quality was further improved by a final refinement in explicit water using OPLS force field parameters for non-bonded interactions and charges. In addition, the 2′-hydroxyl groups have been assigned and their conformation has been analyzed based on NOE contacts. The structure currently defines a benchmark for the precision and accuracy amenable to RNA structure determination by NMR spectroscopy. Here, we discuss the impact of various NMR restraints on structure quality and discuss in detail the dynamics of this system as previously determined.     

A polynomial-time algorithm for de novo protein backbone structure determination from nuclear magnetic resonance data.

We describe an efficient algorithm for protein backbone structure determination from solution Nuclear Magnetic Resonance (NMR) data. A key feature of our algorithm is that it finds the conformation and orientation of secondary structure elements as well as the global fold in polynomial time. This is the first polynomial-time algorithm for de novo high-resolution biomacromolecular structure determination using experimentally recorded data from either NMR spectroscopy or X-ray crystallography. Previous algorithmic formulations of this problem focused on using local distance restraints from NMR (e.g., nuclear Overhauser effect [NOE] restraints) to determine protein structure. This approach has been shown to be NP-hard, essentially due to the local nature of the constraints. In practice, approaches such as molecular dynamics and simulated annealing, which lack both combinatorial precision and guarantees on running time and solution quality, are used routinely for structure determination. We show that residual dipolar coupling (RDC) data, which gives global restraints on the orientation of internuclear bond vectors, can be used in conjunction with very sparse NOE data to obtain a polynomial-time algorithm for structure determination. Furthermore, an implementation of our algorithm has been applied to six different real biological NMR data sets recorded for three proteins. Our algorithm is combinatorially precise, polynomialtime, and uses much less NMR data to produce results that are as good or better than previous approaches in terms of accuracy of the computed structure as well as running time.     

Conformation and dynamics of an Fab'-bound peptide by isotope-edited NMR spectroscopy.

The dynamics and conformation of the peptide antigen MHKDFLEKIGGL bound to the Fab' fragment of the monoclonal antipeptide antibody B13A2, raised against a peptide from myohemerythrin, have been investigated by isotope-edited NMR techniques. The peptides were labeled with 15N (98%) or 13C (99%) at the backbone of individual amino acid residues. Well-resolved amide proton and nitrogen backbone resonances were obtained and assigned for eight of the 12 residues of this bound peptide. Significant resonance line width and chemical shift differences were observed. The 15N and 1H line width variations are attributed to differential backbone mobilities among the bound peptide residues which are consistent with the previously mapped epitope of this peptide antigen. Local structural information was obtained from isotope-directed NOE studies. The approximate distances associated with the experimental NOEs were estimated on the basis of a theoretical NOE analysis involving the relative integrated intensities of the NOE and source peaks. In this way, the sequential NH-NH NOEs obtained for seven of the Fab'-bound peptide residues were shown to correspond to interproton separations of approximately 3 A or less. Such short distances indicate that the backbone dihedral angles of these residues are in the alpha rather than the beta region of phi,psi conformational space; the peptide most likely adopts a helical conformation from F5 to G11 within the antibody combining site. The significance of these results with respect to the type and extent of conformational information obtainable from studies of high molecular weight systems is discussed.     

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.     

Solution conformation of endothelin and point mutants by nuclear magnetic resonance spectroscopy.

Two-dimensional NMR techniques were utilized to determine the secondary structural elements of endothelin-1 (ET-1), a potent vasoconstrictor peptide, and two of its point mutants, Met-7 to Ala-7 (ETM7A), and Asp-8 to Ala-8 (ETD8A) in acetic acid-d3/water solution. Sequence specific NMR assignments were determined for all three peptides, as well as chemical shifts and NOE connectivity patterns. The chemical shifts of ET-1 and ETM7A are identical (+/- 0.05 ppm) except for the site of substitution, whereas marked shift changes were detected between ET-1 and ETD8A. These chemical shift differences imply that the Asp-8 to Ala-8 mutation has induced a conformational change relative to the parent conformation. All three molecules show the same basic nuclear Overhauser effect (NOE) pattern, which suggests that the gross conformation of all three molecules is the same. Small changes in sequential NOE intensities and changes in medium-range NOE patterns indicate that there are subtle conformational differences between ET-1 and ETD8A.     

Solution structure of a D,L-alternating oligonorleucine as a model of double-stranded antiparallel beta-helix

Conformational characteristics of alternating D,L linear peptides are of particular interest because of their capacity to form transmembrane channels with different transport properties, as some natural antibiotics do. Single- and double-stranded beta-helical structures are common for alternating D,L peptides. The stability of the beta-helix depends on several structural factors, such as the backbone peptide length, type and position of side chains, and nature of terminal groups. The NMR and molecular dynamics solution conformation of a synthetic alternating D,L-oligopeptide with 15 norleucines (XVMe) has been used as a model to get insight in to the conformational features of double-stranded beta-helix structures. The NH chemical shift values (delta(NH)) and long-range nuclear Overhauser effects (NOE) cross peaks, in particular interstrand connectivities, clearly point to an antiparallel double-stranded beta-helix for the XVMe major conformation in solution. An extensive set of distances (from NOE cross peaks) and H-bonds (from delta(NH)) has been included in the molecular dynamics calculations. The experimental NMR data and theoretical calculations clearly indicate that the most probable conformation of XVMe in solution is a double-strand antiparallel beta(5.6) increasing decreasing-helix structure.     

Virtual and solution conformations of oligosaccharides

The possibility that observed nuclear Overhauser enhancements and bulk longitudinal relaxation times, parameters measured by 1H NMR and often employed in determining the preferred solution conformation of biologically important molecules, are the result of averaging over many conformational states is quantitatively evaluated. Of particular interest was to ascertain whether certain 1H NMR determined conformations are "virtual" in nature; i.e., the fraction of the population of molecules actually found at any time within the subset of conformational space defined as the "solution conformation" is vanishingly small. A statistical mechanics approach was utilized to calculate an ensemble average relaxation matrix from which (NOE)'s and (T1)'s are calculated. Model glycosidic linkages in four oligosaccharides were studied. The solution conformation at any glycosidic linkage is properly represented by a normalized, Boltzmann distribution of conformers generated from an appropriate potential energy surface. The nature of the resultant population distributions is such that 50% of the molecular population is found within 1% of available microstates, while 99% of the molecular population occupies about 10% of the ensemble microstates, a number roughly equal to that sterically allowed. From this analysis we conclude that in many cases quantitative interpretation of NMR relaxation data, which attempts to define a single set of allowable torsion angle values consistent with the observed data, will lead to solution conformations that are either virtual or reflect torsion angle values possessed by a minority of the molecular population. On the other hand, calculation of ensemble average NMR relaxation data yields values in agreement with experimental results. Observed values of NMR relaxation data are the result of the complex interdependence of the population distribution and NOE (or T1) surfaces in conformational space. In conformational analyses, NMR data can therefore be used to test different population distributions calculated from empirical potential energy functions.     

The determination of the conformational properties of nucleic acids in solution from NMR data

A program, NUCFIT, has been written for simulating the effects of conformational averaging on nuclear Overhauser enhancement (NOE) intensities for the spin systems found in nucleic acids. Arbitrary structures can be generated, and the NOE time courses can be calculated for truncated one-dimensional NOEs, two-dimensional NOE and rotating frame NOE spectroscopy (NOESY and ROESY) experiments. Both isotropic and anisotropic molecular rotation can be treated, using Woessner's formalism (J. Chem. Phys. (1962) 37, 647-654). The effects of slow conformational averaging are simulated by taking population-weighted means of the conformations present. Rapid motions are allowed for by using order parameters which can be supplied by the user, or calculated for specific motional models using the formalism of Tropp (J. Chem. Phys. (1980) 72, 6035-6043). NOE time courses have been simulated for a wide variety of conformations and used to determine the quality of structure determinations using NMR data for nucleic acids. The program also allows grid-searching with least-squares fitting of structures to experimental data, including the effects of spin-diffusion, conformational averaging and rapid internal motions. The effects of variation of intra and internucleotide conformational parameters on NOE intensities has been systematically explored. It is found that (i) the conformation of nucleotides is well determined by realistic NOE data sets, (ii) some of the helical parameters, particularly the base pair roll, are poorly determined even for extensive, noise-free data sets, (iii) conformational averaging of the sugars by pseudorotation has at most second-order influence on the determination of other parameters and (iv) averaging about the glycosidic torsion bond also has, in most cases, an insignificant effect on the determination of the conformation of nucleotides.     

Structure of a glycoconjugate in solution and in complex with an antibody Fv fragment

By use of heteronuclear (¹³c, ¹H) NMR methods, the threedimensionalstructure and dynamia of the glycoconjugate estrone-3-glucuronide(E3G) uniformly ¹³c enriched in the glucuronic acid moiety hasbeen probed both in free solution and in association with ananti-E3G antibody singlechain Fv fragment. The glycan is foundto exist in multiple conformations in free solution, with particularlylarge torsional fluctuations about the glycosidic linkage .Resonance assignments and distance restraints for the glycococonjugatein the bound state were obtained from heteronuclear protonarbon-carbon-proton-COSYand isotopeedited NOESY techniques, respectively. Quantitationof the NOE data with a full-relaxation matrix approach showedthat the antibody selects a conformation from the solution repertoirewhich does not correspond with either of the two lowest energyconformations of the free glycan, and the internal energy ofthe glycan in the bound state is estimated to be at most 15kcal/mol higher than the global minimum energy conformation.The glucuronide moiety undergoes a stacking interaction withan aromatic ring in the binding site, and both ring-currentshifts and nuclear Overhauser effects computed from the predictedboundstate conformation are in good agreement with experiment.The bound-state conformation is also in goad agreement withpreliminary x-ray data on a related complex. NMR estrone antibody ring current shifts     

A transferred NOE study of a tricyclic analog of acyclovir bound to thymidine kinase

Summary A purine derivative with an acyclic sugar analog, 3,9-dihydro-3-[(2-hydroxyethoxy)methyl]-6-ethyl-9-oxo-5H-imidazo[1,2-a]purine, was studied in the free state and in complex with herpes simplex virus thymidine kinase (HSV1 TK). Transferred NOE experiments, combined with a full relaxation matrix analysis of the substrate's spin system, resulted in a set of distance constraints for all proton pairs. These constraints were used in structure determination procedures based on simulated annealing and molecular dynamics simulations to obtain a family of structures compatible with the experimental NMR data. The results indicate that, although in both states the chains have the syn orientation with respect to the aromatic rings, in the free state the substrate's acyclic moiety is relatively disordered, while in the bound state only one specific conformation is preferred. Fluctuations can only be seen in the case of the terminal hydroxyl group, for which no NOE was recorded and hence no constraints were available.     

NMR experiments reveal distinct antibody-bound conformations of a synthetic disaccharide representing a general structural element of bacterial lipopolysaccharide epitopes.

The recognition reactions between a synthetic disaccharide alpha-Kdo-(2-->4)-alpha-Kdo-(2-->O)-allyl and two monoclonal antibodies (mAbs) were studied by NMR, yielding two distinct bound conformations of the carbohydrate ligand. One mAb, S23-24, recognizes the disaccharides alpha-Kdo-(2-->4)-alpha-Kdo-(2-->O)-allyl and alpha-Kdo-(2-->8)-alpha-Kdo-(2-->O)-allyl with similar affinities, whereas mAb S25-2 binds to the disaccharide alpha-Kdo-(2-->8)-alpha-Kdo-(2-->O)-allyl with an approximately 10-fold higher affinity than to the disaccharide alpha-Kdo-(2-->4)-alpha-Kdo-(2-->O)-allyl. Compared to S25-2, S23-24 binds to alpha-Kdo-(2-->4)-alpha-Kdo-(2-->O)-allyl with an approximately 50-fold increased affinity. We used NMR experiments that are based on the transferred NOE effect, specifically, trNOESY, trROESY, QUIET-trNOESY, and MINSY experiments, to show that the (2-->8)-specific mAb, S25-2, stabilizes a conformation of the alpha-(2-->4)-linked disaccharide that is not highly populated in solution. S23-24 recognizes two conformations of alpha-Kdo-(2-->4)-alpha-Kdo-(2-->O)-allyl, one that is highly populated in aqueous solution and another conformation that is similar to the one bound by S25-2. This is the first example where it is experimentally shown that a carbohydrate ligand may adopt different bioactive conformations upon interaction with mAbs with different fine specificities. Our NMR studies indicate that a careful examination of spin diffusion is critical for the analysis of bioactive conformations of carbohydrate ligands.     

Conformational Analysis of the β-amyloid Peptide Fragment, β(12-28)

Abstract NMR and CD spectroscopy have been used to examine the conformation of the peptide, β(12-28), (VHHQKLVFFAEDVGSNK) in aqueous and 60% TFE/40% H(2)0 solution at pH 2.4. In 60% TFE solution, the peptide is helical as confirmed by the CD spectrum and by the pattern of the NOE cross peaks detected in the NOESY spectrum of the peptide. In aqueous solution, the peptide adopts a more extended and flexible conformation. Broadening of resonances at low temperature, temperature-dependent changes in the chemical shifts of several of the CH(α) resonances and the observation of a number of NOE contacts between the hydrophobic side-chain protons of the peptide are indicative of aggregation in aqueous solution. The behavior of β(12-28) in 60% TFE and in aqueous solution are consistent with the overall conformation and aggregation behavior reported for the larger peptide fragment, β(1-28) and the parent β-amyloid peptide.     

Structural studies of 5-ethyl-2'-deoxyuridine by selective pulse 1H DPFGSE NOE spectroscopy and PM3 calculations.

The solution conformation of 5-ethyl-2'-deoxyuridine (EDU) has been calculated from the vicinyl proton-proton NMR coupling constants and nuclear Overhauser (NOE) distances using excitation sculpting of selective pulses (Double Pulsed Field Gradient Spin Echo NOE) at 500 MHz and molecular modelling (PM3) studies.     

On the use of one-step perturbation to investigate the dependence of NOE-derived atom–atom distance bound violations of peptides upon a variation of force-field parameters

The method of one-step perturbation can be used to predict from a single molecular dynamics simulation the values of observable quantities as functions of variations in the parameters of the Hamiltonian or biomolecular force field used in the simulation. The method is used to predict violations of nuclear overhauser effect (NOE) distance bounds measured in nuclear magnetic resonance (NMR) experiments by atom–atom distances of the NOE atom pairs when varying force-field parameters. Predictions of NOE distance bound violations between different versions of the GROMOS force field for a hexa-β-peptide in solution show that the technique works for rather large force-field parameter changes as well as for very different NOE bound violation patterns. The effect of changing individual force-field parameters on the NOE distance bound violations of the β-peptide and an α-peptide was investigated too. One-step perturbation, which in this case is equivalent to reweighting configurations, constitutes an efficient technique to predict many values of different quantities from a single conformational ensemble for a particular system, which makes it a powerful force-field development technique that easily reduces the number of required separate simulations by an order of magnitude.     

Characterization of the substrate mimic bound to engineered prostacyclin synthase in solution using high-resolution NMR spectroscopy and mutagenesis: implication of the molecular mechanism in biosynthesis of prostacyclin

High-resolution NMR spectroscopy was used to determine the docking of a substrate (prostaglandin H2) mimic (U46619) to the engineered prostacyclin (PGI2) synthase (PGIS) in solution. The binding of U46619 to the PGIS protein was demonstrated by 1D NMR titration, and the significant perturbation of the chemical shifts of protons at C-11, H2C, and H20 of U46619 were observed upon U46619 binding to the engineered PGIS in a concentration-dependent manner. The detailed conformational change and 3D structure of the PGIS-bound U46619 were further demonstrated by 2D 1H NMR experiments using the transferred NOE technique. The distances between the protons H20 and H2, H18 and H2, and H18 and H4 are shorter following their binding to the PGIS in solution-down to within 5 A. These shorter distances resulted in a widely open conformation, where the triangle shape of the unbound U46619 changed to a more compact conformation with an oval shape. The bound conformation of U46619 fits the crystal structure of the PGIS substrate binding pocket considerably better than that of the unbound U46619. The residues important to the substrate binding in the active site pocket of PGIS were also predicted. For example, Trp282 could be one of the most important residues and is suspected to play a role in the determination of specific catalytic function, which has been established by the docking studies using the NMR structure of the PGIS-bound form of U46619 and the PGIS crystal structure. These studies have provided the structural information for the interaction of the PGIS with its substrate mimic. The noted conformational changes where the C-6 position is closer to the C-9 position of U46619 provided the first experimental data for understanding the molecular mechanism of the catalytic function of PGIS in the isomerization of PGH2 to prostacyclin.     

Complexes of glucoamylase with maltoside heteroanalogues: bound ligand conformations by use of transferred NOE experiments and molecular modeling

Transferred nuclear Overhauser effect (trNOE) experiments have been performed to investigate the conformations of the competitive inhibitors, methyl 5'-thio-4-N-alpha-maltoside 3a and methyl 5'-thio-4-S-alpha-maltoside 4 when bound to the catalytic subunit of the enzyme glucoamylase. These NMR data suggest that, although each of the free ligands populates two conformational families, both heteroanalogues are bound by the enzyme in conformations in the area of the global energy minimum. These conformations have been used as initial points for docking into the active site of the enzyme taken from a X-ray crystal structure of the related glucoamylase-D-gluco-dihydroacarbose 2 complex. Minimization of the resulting complexes has yielded structures for the bound complexes. Corroboration of the structures is provided by fast T(1)(rho)-relaxation effects for certain ligand protons as a result of close contacts with protons in the enzyme active site. The results auger well for the combined use of transferred NOE spectroscopy and molecular modeling based on X-ray crystal structures of complexes of suitable congeners for the rapid analysis of ligand-receptor interactions.