Functional and structural characterisation of RimL from Bacillus cereus, a new Nα-acetyltransferase of ribosomal proteins that was wrongly assigned as an aminoglycosyltransferase.

Enzymes of the GNAT (GCN5-relate N-acetyltransferases) superfamily are important regulators of cell growth and development. They are functionally diverse and share low amino acid sequence identity, making functional annotation difficult. In this study, we report the function and structure of a new ribosomal enzyme, Nα-acetyl transferase from Bacillus cereus (RimLBC), a protein that was previously wrongly annotated as an aminoglycosyltransferase. Firstly, extensive comparative amino acid sequence analyses suggested RimLBC belongs to a cluster of proteins mediating acetylation of the ribosomal protein L7/L12. To assess if this was the case, several well established substrates of aminoglycosyltransferases were screened. The results of these studies did not support an aminoglycoside acetylating function for RimLBC. To gain further insight into RimLBC biological role, a series of studies that included MALDI-TOF, isothermal titration calorimetry, NMR, X-ray protein crystallography, and site-directed mutagenesis confirmed RimLBC affinity for Acetyl-CoA and that the ribosomal protein L7/L12 is a substrate of RimLBC. Last, we advance a mechanistic model of RimLBC mode of recognition of its protein substrates. Taken together, our studies confirmed RimLBC as a new ribosomal Nα-acetyltransferase and provide structural and functional insights into substrate recognition by Nα-acetyltransferases and protein acetylation in bacteria.

Free and protein-bound carbohydrate structures.

Several areas of research in the study of the structure and dynamics of free and protein-bound carbohydrates have experienced considerable advances during the past year. These include the application of state-of-the-art NMR techniques using (13)C-labeled sugars to obtain conformational information, the full structural characterization of several saccharides that either form part of glycoproteins or form noncovalent complexes, both in solution and in the solid state, the description of several enzyme-carbohydrate complexes at the atomic level and last, but not least, the development and analysis of calculation protocols to predict the dynamical and conformational behavior of oligosaccharides.

DNA-triplex stabilizing properties of 8-aminoguanine.

A DNA-triplex stabilizing purine (8-aminoguanine) is designed based on molecular modeling and synthesized. The substitution of guanine by 8-aminoguanine largely stabilizes the triplex both at neutral and acidic pH, as suggested by molecular dynamics and thermodynamic integration calculations, and demonstrated by melting experiments. NMR experiments confirm the triplex-stabilizing properties of 8-aminoguanine and demonstrate that few changes are found in the structure of the triplex due to the presence of this modified base.

Solution conformation of a parallel DNA triple helix with 5' and 3' triplex-duplex junctions.

BACKGROUND: Polypurine x polypyrimidine sequences of DNA can form parallel triple helices via Hoogsteen hydrogen bonds with a third DNA strand that is complementary to the purine strand. The triplex prevents transcription and could therefore potentially be used to regulate specific genes. The determination of the structures of triplex-duplex junctions can help us to understand the structural basis of specificity, and aid in the design of optimal antigene oligonucleotides. RESULTS: The solution structures of the junction triplexes d(GAGAGACGTA)-X-(TACGTCTCTC)-X-(CTCTCT) and d(CTCTCT)-X-(TCTCTCAGTC)-X-(GACTGAGAGA) (where X is bis(octylphosphate) and nucleotides in the triplex regions are underlined) have been solved using nuclear magnetic resonance (NMR) spectroscopy. The structure is characterised by significant changes in the conformation of the purine residues, asymmetry of the 5' and 3' junctions, and variations in groove widths associated with the positive charge of the protonated cytosine residues in the third strand. The thermodynamic stability of triplexes with either a 5' or a 3'CH+ is higher than those with a terminal thymidine. CONCLUSIONS: The observed sequence dependence of the triplex structure, and the distortions of the DNA at the 5' and 3' termini has implications for the design of optimal triplex-forming sequences, both in terms of the terminal bases and the importance of including positive charges in the third strand. Thus, triplex-stabilising ligands might be designed that can discriminate between TA x T-rich and CG x C+-rich sequences that depend not only on charge, but also on local groove widths. This could improve the stabilisation and specificity of antigene triplex formation.

NMR investigations of protein-carbohydrate interactions: insights into the topology of the bound conformation of a lactose isomer and beta-galactosyl xyloses to mistletoe lectin and galectin-1.

A hallmark of oligosaccharides is their often limited spatial flexibility, allowing them to access a distinct set of conformers in solution. Viewing each individual or even the complete ensemble of conformations as potential binding partner(s) for lectins in protein-carbohydrate interactions, it is pertinent to address the question on the characteristics of bound state conformation(s) in solution. Also, it is possible that entering the lectin's binding site distorts the low-energy topology of a glycosidic linkage. As a step to delineate the strategy of ligand selection for galactosides, a common physiological docking point, we have performed a NMR study on two non-homologous lectins showing identical monosaccharide specificity. Thus, the conformation of lactose analogues bound to bovine heart galectin-1 and to mistletoe lectin in solution has been determined by transferred nuclear Overhauser effect measurements. It is demonstrated that the lectins select the syn conformation of lactose and various structural analogues (Galbeta(1-->4)Xyl, Galbeta(1-->3)Xyl, Galbeta(1-->2)Xyl, and Galbeta(1-->3)Glc) from the ensemble of presented conformations. No evidence for conformational distortion was obtained. Docking of the analogues to the modeled binding sites furnishes explanations, in structural terms, for exclusive recognition of the syn conformer despite the non-homologous design of the binding sites.

The contribution of cytosine protonation to the stability of parallel DNA triple helices.

The influence of the position of the CG.C+ triplet and the contribution of protonation at the N3 of the Hoogsteen cytosine residue on the stability of various sequences of parallel triple helices having the general composition d[(A5G)-x-(T5C)-x-(T5C)] and d[(A4G2)-x-(T4C2)-x-(T4C2)], where x is the hexaethylene glycol linker, has been determined by NMR, ultraviolet melting and absorbance spectrophotometry. The apparent pK value, i.e. the pH at which the observable has changed by 50% of its range, was typically in the range 6 to 7. However, the NMR spectra unequivocally showed that the pK of the protonated cytosine residue must be at least 9.5 for internal positions. This is five units above the pK of the free nucleotide, and represents a free energy of stabilisation from protonation of >11.5 RT. The pK of terminal cytosine residues is much lower, in the range 6.2 to 7.2, accounting for a free energy of stabilisation from protonation of 3.6 to 6 RT. The van't Hoff enthalpies were determined for the dissociation of the protonated triplex into the duplex+strand, and for the duplex to strand transition. The mean value for the duplexes were 23 to 27 kJ mol-1 base-pair, and 25 to 30 kJ mol-1 for the triplexes containing internal CG.C+ triplets. Good agreement was obtained for the thermodynamic parameters by the different methods. Free energy differences for the transition between the protonated triplex and the duplex+protonated strand were calculated at 298 K. The DeltaG of stabilisation of an internal CG.C triplet compared with a terminal CG.C triplet was about 6 kJ mol-1 ; a similar stabilisation was observed for the triplexes containing two CG.C triplets compared with those containing a single CG.C triplet. The very large stabilisation from protonation is too large to be accounted for by a single hydrogen bond, and is likely to include contributions from electrostatic interactions of the positive charge with the phosphate backbone, and more favourable interactions between neighbouring bases owing to the very different electronic properties of the protonated C.

Structural basis for chitin recognition by defense proteins: GlcNAc residues are bound in a multivalent fashion by extended binding sites in hevein domains.

BACKGROUND: Many plants respond to pathogenic attack by producing defense proteins that are capable of reversible binding to chitin, a polysaccharide present in the cell wall of fungi and the exoskeleton of insects. Most of these chitin-binding proteins include a common structural motif of 30 to 43 residues organized around a conserved four-disulfide core, known as the 'hevein domain' or 'chitin-binding' motif. Although a number of structural and thermodynamic studies on hevein-type domains have been reported, these studies do not clarify how chitin recognition is achieved. RESULTS: The specific interaction of hevein with several (GlcNAc)(n) oligomers has been studied using nuclear magnetic resonance (NMR), analytical ultracentrifugation and isothermal titration microcalorimetry (ITC). The data demonstrate that hevein binds (GlcNAc)(2-4) in 1:1 stoichiometry with millimolar affinity. In contrast, for (GlcNAc)(5), a significant increase in binding affinity is observed. Analytical ultracentrifugation studies on the hevein-(GlcNAc)(5,8) interaction allowed detection of protein-carbohydrate complexes with a ratio of 2:1 in solution. NMR structural studies on the hevein-(GlcNAc)(5) complex showed the existence of an extended binding site with at least five GlcNAc units directly involved in protein-sugar contacts. CONCLUSIONS: The first detailed structural model for the hevein-chitin complex is presented on the basis of the analysis of NMR data. The resulting model, in combination with ITC and analytical ultracentrifugation data, conclusively shows that recognition of chitin by hevein domains is a dynamic process, which is not exclusively restricted to the binding of the nonreducing end of the polymer as previously thought. This allows chitin to bind with high affinity to a variable number of protein molecules, depending on the polysaccharide chain length. The biological process is multivalent.

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.

Solution conformation and dynamics of a tetrasaccharide related to the Lewix(X) antigen deduced by 1H NMR NOESY, ROESY, and T-ROESY measurements.

The conformational and dynamical features of a Le(X) tetrasaccharide analogue GalNAc (alpha 1-3)Gal(beta 1-4)[Fuc(alpha 1-3)]Glc(beta OMe) 1 have been studied through 1H NMR relaxation measurements. The results indicate that the different glycosidic linkages of 1 present distinct conformational flexibility in solution. In addition, the use of T-ROESY experiments in conformational analysis of oligosaccharides is explored emphasizing its scope and limitations.

Solution conformation and dynamics of the trisaccharide fragments of the O-antigen of Vibrio cholerae O1, serotypes Inaba and Ogawa.

The conformational behavior of the trisaccharide fragments of the Ogawa and Inaba Vibrio cholera serotypes has been studied using NMR and molecular dynamics (MD). The obtained results indicate that there are no significant differences in the major conformation and in the extent of motion of the glycosidic torsions of these molecules. The differences in biological activity are probably not due to conformational effects but to van der Waals and/or hydrogen bonding interactions between the antigens and the biological receptor.

The use of CVFF and CFF91 force fields in conformational analysis of carbohydrate molecules. Comparison with AMBER molecular mechanics and dynamics calculations for methyl alpha-lactoside.

The solution conformation of methyl alpha-lactoside has been studied through molecular mechanics calculations using the AMBER/Homans, CVFF and CFF91 force fields, and compared to NMR nuclear Overhauser data. Steady-state and transient nuclear Overhauser effects (NOEs) have been interpreted in terms of the ensemble average distribution of conformers. The NOEs have been analysed using the complete relaxation matrix approach for a rigid and isotropic motion model. The molecular mechanics calculations have been performed at two dielectric constants (i.e. epsilon = 1 and 80 debyes, or epsilon = r and 80 debyes) in an exhaustive way, and, in some cases, have been complemented by specific calculations at intermediate epsilon values. Relaxed energy maps and adiabatic surfaces have been generated for the different dielectric constants. The probability distribution of conformers has been estimated from these steric energy maps. Molecular dynamics simulations in vacuo have also been performed. Our results indicate that the beta-(1-->4) glycosidic linkage shows some fluctuations between three low-energy regions, although it spends about 90% of its time in the region close to the global minimum. The observed conformation of methyl alpha-lactoside seems to be closer to that predicted by CVFF, although the AMBER/Homans results are also in qualitative agreement with the experimental data.

The use of the AMBER force field in conformational analysis of carbohydrate molecules: determination of the solution conformation of methyl alpha-lactoside by NMR spectroscopy, assisted by molecular mechanics and dynamics calculations.

The solution conformation of methyl alpha-lactoside has been studied through nmr spectroscopy and molecular mechanics calculations using the assisted model building with energy refinement (AMBER) force field. The nmr data have included nuclear Overhauser effect (NOE) measurements both in the laboratory and rotating frames, longitudinal relaxation times, and homonuclear and heteronuclear coupling constants. The steady-state and transient NOEs have been interpreted in terms of an ensemble average distribution of conformers, making use of the complete relaxation matrix approach. The molecular mechanics calculations have been performed at two dielectric constants [epsilon = 1*r and 80 Debyes (D)] in an exhaustive way, and have been complemented with specific calculations at intermediate epsilon values. Relaxed energy maps and adiabatic surfaces have been generated for the different dielectric constants. The probability distribution of conformers has been estimated from these steric energy maps. Molecular dynamics simulations in vacuo have also been performed. The experimental results indicate that the beta (1-->4)-glycosidic linkage shows some fluctuations among three low energy regions, although spends ca. 85% of its time in the region close to the global minimum. It is shown that the overestimation of the electrostatic contributions in AMBER is responsible for the failure of this force field to explain the experimental results when used at low dielectric constant (epsilon < 20 D). The matching between the expected and observed facts increases for epsilon > 40 D. Different conditions have been tested to perform temperature constant molecular dynamics simulations in vacuo, which have indicated that, when used without explicit solvent, this force field should only be employed in a qualitatively way when analyzing dynamical properties of oligosaccharides.

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)

Comparison of the solution structures of intramolecular DNA triple helices containing adjacent and non-adjacent CG.C+ triplets.

The solution conformations of the intramolecular triple helices d(AGAAGA-X-TCTTCT-X-TC+TTC+T) and d(AAGGAA-X-TTCCTT-X-TTC+C+TT) (X = non-nucleotide linker) have been determined by NMR.1H NMR spectra in H2O showed that the third strand cytosine residues are fully paired with the guanine residues, each using two Hoogsteen hydrogen bonds. Determination of the13C chemical shifts of the cytosine C6 and C5 and their one-bond coupling constants (1 J CH) conclusively showed that the Hoogsteen cytosine residues are protonated at N3. The global conformations of the two molecules determined with >19 restraints per residue are very similar (RMSD = 0.96 A). However, some differences in local conformation and dynamics were observed for the central two base triplets of the two molecules. The C N3H were less labile in adjacent CG.C+triplets than in non-adjacent ones, indicating that the adjacent charge does not kinetically destabilize these triplets. The sugar conformations of the two adjacent cytosine residues were different and the 5'-residue was atypical of protonated cytosine. Hence, there are subtle effects of the interaction between two adjacent cytosine residues. The central two purines in each sequence showed non-standard backbone conformations, averaging between gamma approximately 60 degrees and gamma approximately 180 degrees. This may be related to the difference in the dependence of the thermodynamic stability on pH observed for these two sequences.

The interaction of hevein with N-acetylglucosamine-containing oligosaccharides. Solution structure of hevein complexed to chitobiose.

The three-dimensional structure of hevein, a small protein isolated from the latex of Hevea brasiliensis (rubber tree), in water solution has been obtained by using 1H-NMR spectroscopy and dynamic simulated annealing calculations. The average root-mean-square deviation (rmsd) of the best 20 refined structures generated using DIANA prior to simulated annealing was 0.092 nm for the backbone atoms and 0.163 nm for all heavy atoms (residues 3-41). The specific interaction of hevein with N-acetylglucosamine-containing oligosaccharides has also been analyzed by 1H-NMR. The association constants, Ka, for the binding of hevein to GlcNAc, chitobiose [GlcNAc-beta(1-->4)-GlcNAc], chitotriose [GlcNAc-beta(1-->4)-GlcNAc-beta(1-->4)-GlcNAc], and GlcNAc-alpha(1-->6)-Man have been estimated from 1H-NMR titration experiments. Since the measured Ka values for chitobiose binding are almost identical with and without calcium ions, it is shown that these cations are not required for sugar binding. The association increases in the order GlcNAc-alpha(1-->6)-Man < or = GlcNAc < chitobiose < chitotriose. The equilibrium thermodynamic parameters entropy and enthalpy of binding, delta S0 and delta H0, for the hevein-chitobiose and hevein-chitotriose associations have been obtained from van't Hoff analysis of the temperature dependence of the Ka values between 25-40 degrees C. The driving force for the binding process is provided for a negative delta H0 which is partially compensated by a negative delta S0. These negative signs seem to indicate that hydrogen bonding and van der Waals forces are the major interactions stabilizing the complex. Protein-carbohydrate nuclear Overhauser enhancements have allowed a three-dimensional model of the hevein-chitobiose complex to be built. From inspection of this model, a hydrogen bond between Ser19 and the non-reducing N-acetyl carbonyl group is suggested, as well as between Tyr30 and HO-3 of the same sugar residue. The N-acetyl methyl group of the non-reducing GlcNAc displays non-polar contacts to the aromatic Tyr30 and Trp21 residues. In addition, the higher affinities deduced for the beta-linked oligosaccharides with respect to GlcNAc and GlcNAc-alpha(1-->6)-Man can be explained by favourable stacking of the second beta-linked GlcNAc moiety and Trp21.

Solution conformation and dynamics of a tetrasaccharide related to the Lewis(x) antigen deduced by NMR relaxation measurements.

1H-NMR cross-relaxation rates and nonselective longitudinal relaxation times have been obtained at two magnetic fields (7.0 and 11.8 T) and at a variety of temperatures for the branched tetrasaccharide methyl 3-O-alpha-N-acetyl-galactosaminyl-beta-galactopyranosyl-(1-->4)[3-O-alph a -fucosyl]-glucopyranoside (1), an inhibitor of astrocyte growth. In addition, 13C-NMR relaxation data have also been recorded at both fields. The 1H-NMR relaxation data have been interpreted using different motional models to obtain proton-proton correlation times. The results indicate that the GalNAc and Fuc rings display more extensive local motion than the two inner Glc and Gal moieties, since those present significantly shorter local correlation times. The 13C-NMR relaxation parameters have been interpreted in terms of the Lipari-Szabo model-free approach. Thus, order parameters and internal motion correlation times have been deduced. As obtained for the 1H-NMR relaxation data, the two outer residues possess smaller order parameters than the two inner rings. Internal correlation times are in the order of 100 ps. The hydroxymethyl groups have also different behaviour, with the exocyclic carbon on the glucopyranoside unit showing the highest S2. Molecular dynamics simulations using a solvated system have also been performed and internal motion correlation functions have been deduced from these calculations. Order parameters and interproton distances have been compared to those inferred from the NMR measurements. The obtained results are in fair agreement with the experimental data.

Thermodynamic, kinetic, and conformational properties of a parallel intermolecular DNA triplex containing 5' and 3' junctions.

The interaction of the 11-mer oligodeoxypyrimidine d(TCTTCTUTCCT) with the 17 bp duplex d(CGCTAGAAGAAAGGACG).d(CGTCCUTTCTTCTAGCG) in forming an intermolecular DNA triplex has been examined in solution by surface plasmon resonance (SPR), UV thermal denaturation, circular dichroism (CD), and NMR methods. Thermodynamic data were also acquired for the shorter 15 bp target duplex d(CGCTAGAAGAAAGGA). d(TCCUTTCTTCTAGCG), which forms a 3' flush-ended parallel triplex. CD titrations at pH 5 gave a triplex --> (duplex + strand) dissociation constant Kd of 0.5 microM at 15 degreesC and approximately 2 microM at 25 degreesC for both the 11-15.15 and 11-17.17 systems, in agreement with analysis of the UV melting data and a direct calorimetric measurement. In contrast, the "apparent" Kd value determined by SPR was 10-20-fold smaller. The rate constant for dissociation (kd) of the third strand from the triplex was found to be approximately 0.0002 s-1 at 25 degreesC by SPR. The rate constant for exchange between the triplex and duplex states determined by NMR was approximately 2 s-1 at 40 degreesC. The dissociation kinetics measured by SPR are considerably underestimated, which largely accounts for the poor estimation of Kd using this technique. Extensive 1H NMR assignments were obtained for both the 17 bp DNA duplex and the triplex. Large changes in chemical shifts were observed in the purine strand of the host duplex, but only small shift changes were induced in the complementary pyrimidine strand. Dramatic differences in shifts were observed for the G and A residues, especially in the minor groove, consistent with only small, localized conformational changes in the underlying duplex. The magnitude of the shift changes decreased to baseline within one base of the 3' triplex-duplex junction and over two to three bases at the 5' junction. Chemical shift changes at the 5' junction suggest small conformational anomalies at this site. COSY and NOESY spectra indicate that the nucleotides are in the "S" domain in both the triplex and duplex states. These data rule out major conformation changes at the triplex-duplex boundaries. NOEs between pyrimidines in the third strand and those in the duplex showed proximity for these bases in the major groove, which could be ascribed to buckling of the Hoogsteen bases out of the plane of the Watson-Crick base pairs.

Conformational differences between O- and C-glycosides: the alpha-O-man-(1-->1)-beta-Gal/alpha-C-Man-(1-->1)-beta-Gal case--a decisive demonstration of the importance of the exo-anomeric effect on the conformation of glycosides.

The conformational behavior of alpha-O-Man-(1-->1)-beta-Gal (1) and its C-analogue (2) has been studied using J/NOE NMR data, molecular mechanics, molecular dynamics, and ab initio calculations. The population distribution around the glycosidic linkages of 1 and 2 is rather different, especially for the alpha-Man linkage. A lower limit for the exo-anomeric effect in water has been experimentally determined.

NMR investigations of protein-carbohydrate interactions: refined three-dimensional structure of the complex between hevein and methyl beta-chitobioside.

The specific interaction of hevein with GlcNAc-containing oligosaccharides has been analyzed by1H-NMR spectroscopy. The association constants for the binding of hevein to a variety of ligands have been estimated from1H-NMR titration experiments. The association constants increase in the order GlcNAc-alpha(1-->6)-Man < GlcNAc < benzyl-beta-GlcNAc < p-nitrophenyl-beta-GlcNAc < chitobiose < p-nitrophenyl-beta-chitobioside < methyl-beta-chitobioside < chitotriose. Entropy and enthalpy of binding for different complexes have been obtained from van't Hoff analysis. The driving force for the binding process is provided by a negative DeltaH0which is partially compensated by negative DeltaS0. These negative signs indicate that hydrogen bonding and van der Waals forces are the major interactions stabilizing the complex. NOESY NMR experiments in water solution provided 475 accurate protein proton-proton distance constraints after employing the MARDIGRAS program. In addition, 15 unambiguous protein/carbohydrate NOEs were detected. All the experimental constraints were used in a refinement protocol including restrained molecular dynamics in order to determine the highly refined solution conformation of this protein-carbohydrate complex. With regard to the NMR structure of the free protein, no important changes in the protein nOe's were observed, indicating that carbohydrate-induced conformational changes are small. The average backbone rmsd of the 20 refined structures was 0.055 nm, while the heavy atom rmsd was 0.116 nm. It can be deduced that both hydrogen bonds and van der Waals contacts confer stability to the complex. A comparison of the three-dimensional structure of hevein in solution to those reported for wheat germ agglutinin (WGA) and hevein itself in the solid state has also been performed. The polypeptide conformation has also been compared to the NMR-derived structure of a smaller antifungical peptide, Ac-AMP2.