A recombinant glutamine-binding protein from Escherichia coli: effect of ligand-binding on protein conformational dynamics

We have investigated the effect of the binding of glutamine on the conformational dynamics of the recombinant glutamine binding protein (GlnBP) from Escherichia coli by steady-state and time-resolved fluorescence techniques. The structural stability of the protein was also studied by far-UV circular dichroism spectroscopy in the range of temperature between 25 and 80 degrees C. The results showed that the interaction of the protein with the ligand resulted in a marked change of the structural and conformational dynamics features of the protein. In particular, the fluorescence and circular dichroism data showed that the presence of glutamine resulted in a dramatic increase of the protein thermal stability of about 10 degrees C. In addition, the fluorescence time-resolved data pointed out that both in the absence and in the presence of glutamine the protein structure was highly rigid with small amplitude of segmental motion up to 65 degrees C and a low accessibility of the protein tryptophan residues to acrylamide. The obtained results on the structural properties of the recombinant glutamine-binding protein in the absence and in the presence of glutamine can contribute to a better understanding of the transport-related functions of the protein and structurally similar periplasmic transport proteins, as well as to the design and development of new biotechnological applications of this class of proteins.     

Analysis of domain movements in glutamine-binding protein with simple models

In this work, the mechanism of domain movements of glutamine-binding protein (GlnBP), especially the influence of the ligand on GlnBP dynamic behavior is investigated with the aid of a Gaussian network model (GNM) and an anisotropy elastic network model. The results show that the "open-closed" transition mainly appears as the large movement of the small domain, especially the top region including two alpha-helices and two beta-strands. The slowest mode of each three forms of GlnBP--ligand-free open, ligand-bound closed, and ligand-free closed GlnBP--shows that the open-closed motion of the two domains has a common hinge axis centered on Lys-87 and Gln-183. Accompanying the conformational transition, the residues within both large and small domains move in a highly coupled way. The peaks of the fast modes correspond to residues that were thought, in the GNM, to be important for the stability of the protein, and these residues may be involved in the interactions with the membrane-bound components. With the contacts between the large domain and the small domain increasing, the ability of the "open-closed" motion is decreased. All the results agree well with those of molecular dynamics simulations, and it is thought that the open-closed conformation transition is the nature of the topology structure of GlnBP. Also, the influence of the ligand on GlnBP is studied with a modified GNM method. The results obtained show that the ligand does not influence the closed-to-open transition tendency.     

The structure and stability of the glutamine-binding protein from Escherichia coli and its complex with glutamine

A study was made of the conformational changes in the Escherichia coli glutamine-binding potein (GlnBP) induced by GdnHCl, and of the effect of glutamine (Gln) binding on these processes. Intrinsic fluorescence, ANS emission fluorescence, and far- and near-UV circular dichroism spectroscopy were used. The obtained experimental data were interpreted, taking into the account results of the analysis of tryptophan and tyrosine residues microenvironments. This enabled us to explain the negligible contribution of Tyr residues to the bulk fluorescence of the native protein, the similarity of fluorescence characteristics of GlnBP and GlnBP/Gln, and an uncommon effect of the excess of fluorescence intensity at 365 nm (Trp emission) upon excitation at 297 nm compared to the excitation at 280 nm. The latter effect is explained by the spectral dependence of Trp 32 and Trp 220 contributions to protein absorption. The dependence of Trp fluorescence of protein on the excitation wavelength must be taken into account for the evaluation of Tyr residues contribution to the bulk fluorescence of protein, and in principle, it may also be used for the development of an approach to decomposition of multi-component protein fluorescence spectrum. The parametric presentation of fluorescence data showed that both GlnBP unfolding and GlnBP/Gln unfolding are three-step processes (N-->I1-->I2-->U), though in the case of the GlnBP/Gln complex these stages essentially overlap. Despite its complex character, GlnBP unfolding is completely reversible. In comparison with GlnBP, in the case of GlnBP/Gln the dramatic shift of N-->I1 process to higher GdHCl concentrations is shown.     

Fluorescence properties of glutamine-binding protein from Escherichia coli and its complex with glutamine

In this work, the fluorescence of glutamine-binding protein (GlnBP) and its complex with glutamine (GlnBP/Gln) in native and unfolded forms was studied. The experimental data were interpreted on the basis of the results of the analysis of Trp and Tyr microenvironments taking into the account the data for GlnBP mutated forms Trp32Phe(Tyr) and Trp220Phe(Tyr), which have been obtained by Axelsen et al. (Biophys. J. 1991, 60, 650-659). This allowed us to explain the negligible contribution of Tyr residues to the bulk fluorescence of the native protein, the similarity of the fluorescence characteristics of GlnBP and GlnBP/Gln, and the uncommon effect of the excess of the fluorescence intensity at 365 nm (Trp emission) upon excitation at 297 nm respect to the excitation at 280 nm. The last effect is explained by the spectral dependence of the Trp 32 and Trp 220 contributions to the protein absorption. The protein Trp fluorescence dependence on the excitation wavelength must be taken into account for the evaluation of the Tyr residues contribution to the bulk fluorescence of protein, and in principle, it also may be used for the development of an approach for the decomposition of a multicomponent protein fluorescence spectrum.     

Interdomain dynamics and ligand binding: molecular dynamics simulations of glutamine binding protein

Periplasmic binding proteins from Gram-negative bacteria possess a common architecture, comprised of two domains linked by a hinge region, a fold which they share with the neurotransmitter-binding domains of ionotropic glutamate receptors (GluRs). Glutamine-binding protein (GlnBP) is one such protein, whose crystal structure has been solved in both open and closed forms. Multi-nanosecond molecular dynamics simulations have been used to explore motions about the hinge region and how they are altered by ligand binding. Glutamine binding is seen to significantly reduce inter-domain motions about the hinge region. Essential dynamics analysis of inter-domain motion revealed the presence of both hinge-bending and twisting motions, as has been reported for a related sugar-binding protein. Significantly, the influence of the ligand on GlnBP dynamics is similar to that previously observed in simulations of rat glutamate receptor (GluR2) ligand-binding domain. The essential dynamics analysis of GlnBP also revealed a third class of motion which suggests a mechanism for signal transmission in GluRs.     

Heat capacities and a snapshot of the energy landscape in protein GB1 from the pre-denaturation temperature dependence of backbone NH nanosecond fluctuations

Protein stability is usually characterized calorimetrically by a melting temperature and related thermodynamic parameters. Despite its importance, the microscopic origin of the melting transition and the relationship between thermodynamic stability and dynamics remains a mystery. Here, NMR relaxation parameters were acquired for backbone 15NH groups of the 56 residue immunoglobulin-binding domain of streptococcal protein G over a pre-denaturation temperature range of 5-50 degrees C. Relaxation data were analyzed using three methods: the standard three-Lorentzian model free approach; the F(omega)=2omegaJ(omega) spectral density approach that yields motional correlation time distributions, and a new approach that determines frequency-dependent order parameters. Regardless of the method of analysis, the temperature dependence of internal motional correlation times and order parameters is essentially the same. Nanosecond time-scale internal motions are found for all NHs in the protein, and their temperature dependence yields activation energies ranging up to about 33kJ/mol residue. NH motional barrier heights are structurally correlated, with the largest energy barriers being found for residues in the most "rigid" segments of the fold: beta-strands 1 and 4 and the alpha-helix. Trends in this landscape also parallel the free energy of folding-unfolding derived from hydrogen-deuterium (H-D) exchange measurements, indicating that the energetics for internal motions occurring on the nanosecond time-scale mirror those occurring on the much slower time-scale of H-D exchange. Residual heat capacities, derived from the temperature dependence of order parameters, range from near zero to near 100J/mol K residue and correlate with this energy landscape. These results provide a unique picture of this protein's energy landscape and a relationship between thermodynamic stability and dynamics that suggests thermosensitive regions in the fold that could initiate the melting process.     

Mechanisms for ligand binding to GluR0 ion channels: crystal structures of the glutamate and serine complexes and a closed apo state

High-resolution structures of the ligand binding core of GluR0, a glutamate receptor ion channel from Synechocystis PCC 6803, have been solved by X-ray diffraction. The GluR0 structures reveal homology with bacterial periplasmic binding proteins and the rat GluR2 AMPA subtype neurotransmitter receptor. The ligand binding site is formed by a cleft between two globular alpha/beta domains. L-Glutamate binds in an extended conformation, similar to that observed for glutamine binding protein (GlnBP). However, the L-glutamate gamma-carboxyl group interacts exclusively with Asn51 in domain 1, different from the interactions of ligand with domain 2 residues observed for GluR2 and GlnBP. To address how neutral amino acids activate GluR0 gating we solved the structure of the binding site complex with L-serine. This revealed solvent molecules acting as surrogate ligand atoms, such that the serine OH group makes solvent-mediated hydrogen bonds with Asn51. The structure of a ligand-free, closed-cleft conformation revealed an extensive hydrogen bond network mediated by solvent molecules. Equilibrium centrifugation analysis revealed dimerization of the GluR0 ligand binding core with a dissociation constant of 0.8 microM. In the crystal, a symmetrical dimer involving residues in domain 1 occurs along a crystallographic 2-fold axis and suggests that tetrameric glutamate receptor ion channels are assembled from dimers of dimers. We propose that ligand-induced conformational changes cause the ion channel to open as a result of an increase in domain 2 separation relative to the dimer interface.     

NMR studies of 4-19F-phenylalanine-labeled intestinal fatty acid binding protein: evidence for conformational heterogeneity in the native state

(19)F-Nuclear magnetic resonance (NMR) studies have been carried out after incorporation of 4-(19)F-phenylalanine into the intestinal fatty acid binding protein (IFABP), a protein composed of two beta-sheets containing a large hydrophobic cavity into which ligands bind. NMR spectra have been obtained with both the ligand-free and ligand-bound (oleate) forms. There are 29 residues involved in van der Waals or hydrophobic interactions or both to form a U-shaped ligand binding pocket (Sacchettni J. C., Scapin G., Gopaul D., and Gordon J. I. (1992) J. Biol. Chem. 267, 23534-23545). The protein contains eight phenylalanines, and all are included in those residues that line the pocket. Peak assignments were made using site-specific incorporation of 4-(19)F-phenylalanine. Fluorine is a highly sensitive probe to monitor the conformation and dynamics of the side chains in native state. We find that chemical exchange in the binding pocket exists in the native apo- and holo-state. Of the eight phenylalanine residues, Phe2, Phe47, Phe62, Phe68, and Phe93 are arranged on one side of the binding pocket, and all exist in two conformations with Phe2, Phe47, and Phe62 showing exchange cross-peaks with minor conformation in (19)F-(19)F nuclear Overhauser effect (NOESY) spectra. The line widths of Phe68 and Phe93 are broader than those of other phenylalanine residues and can be deconvoluted into two peaks. Phe47, Phe62, Phe68, Phe93, and Trp82 have been proposed to be involved in the early stage of collapse (Ropson, I. J., and Frieden, C. (1992) Proc. Natl. Acad. Sci U.S.A. 89, 7222-7226), but a temperature study suggests that Phe47 behaves differently than other residues and may be more involved in a later stage of folding, for example, side chain stabilization. In the holo-form, Phe17 shows an extra exchange cross-peak in addition to those exchange cross-peaks observed in apo-form. Holo-IFABP exhibits broader line width than the apo-form, suggesting more flexibility of the binding cavity upon ligand binding.     

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.     

Orientation of heparin-binding sites in native vitronectin. Analyses of ligand binding to the primary glycosaminoglycan-binding site indicate that putative secondary sites are not functional

A primary heparin-binding site in vitronectin has been localized to a cluster of cationic residues near the C terminus of the protein. More recently, secondary binding sites have been proposed. In order to investigate whether the binding site originally identified on vitronectin functions as an exclusive and independent heparin-binding domain, solution binding methods have been used in combination with NMR and recombinant approaches to evaluate ligand binding to the primary site. Evaluation of the ionic strength dependence of heparin binding to vitronectin according to classical linkage theory indicates that a single ionic bond is prominent. It had been previously shown that chemical modification of vitronectin using an arginine-reactive probe results in a significant reduction in heparin binding (Gibson, A., Baburaj, K., Day, D. E., Verhamme, I. , Shore, J. D., and Peterson, C. B. (1997) J. Biol. Chem. 272, 5112-5121). The label has now been localized to arginine residues within the cyanogen bromide fragment-(341-380) that contains the primary heparin-binding site on vitronectin. One- and two-dimensional NMR on model peptides based on this primary heparin-binding site indicate that an arginine residue participates in the ionic interaction and that other nonionic interactions may be involved in forming a complex with heparin. A recombinant polypeptide corresponding to the C-terminal 129 amino acids of vitronectin exhibits heparin-binding affinity that is comparable to that of full-length vitronectin and is equally effective at neutralizing heparin anticoagulant activity. Results from this broad experimental approach argue that the behavior of the primary site is sufficient to account for the heparin binding activity of vitronectin and support an exposed orientation for the site in the structure of the native protein.     

Thermostabilization of Escherichia coli ribonuclease HI by replacing left-handed helical Lys95 with Gly or Asn.

From the systematic replacements of amino acid residues of Escherichia coli ribonuclease HI with those of its thermophilic counterpart, the basic protrusion domain including region 6 (R6) from residues 91 to 95 was found to increase the structural stability of the mutant protein (Kimura, S., Nakamura, H., Hashimoto, T., Oobatake, M., and Kanaya, S. (1992) J. Biol. Chem. 267, 21535-21542). Further mutagenesis concentrating in the R6 region has revealed that replacements of Lys95 at the left-handed structure with Gly or Asn essentially enhances the protein stability. Gly and Asn substitutions stabilize the protein up to 1.9 kcal/mol and 0.9 kcal/mol in the free energy changes of unfolding, respectively. We propose that the amino acid substitution of left-handed non-Gly residue with Gly or Asn residue can be used as one of the general strategies to enhance protein stability, when such a non-Gly residue itself does not seriously contribute to protein stability.     

15N NMR relaxation studies of free and ligand-bound human acidic fibroblast growth factor

15N NMR relaxation data have been used to characterize the backbone dynamics of the human acidic fibroblast growth factor (hFGF-1) in its free and sucrose octasulfate (SOS)-bound states. (15)N longitudinal (R(1)), transverse (R(2)) relaxation rates and (1H)-(15)N steady-state nuclear Overhauser effects were obtained at 500 and 600 MHz (at 25 degrees C) for all resolved backbone amide groups using (1)H- detected two-dimensional NMR experiments. Relaxation data were fit to the extended model free dynamics for each NH group. The overall correlation time (tau(m)) for the free and SOS-bound forms were estimated to be 10.4 +/- 1.07 and 11.1 +/- 1.35 ns, respectively. Titration experiments with SOS reveals that the ligand binds specifically to the C-terminal domain of the protein in a 1:1 ratio. Binding of SOS to hFGF-1 is found to induce a subtle conformational change in the protein. Significant conformational exchange (R(ex)) is observed for several residues in the free form of the protein. However, in the SOS-bound form only three residues exhibit significant R(ex) values, suggesting that the dynamics on the micro- to millisecond time scale in the free form is coupled to the cis-trans-proline isomerization. hFGF-1 is a rigid molecule with an average generalized parameter (S(2)) value of 0.89 +/- 0.03. Upon binding to SOS, there is a marked decrease in the overall flexibility (S(2) = 0.94 +/- 0.02) of the hFGF-1 molecule. However, the segment comprising residues 103-111 shows increased flexibility in the presence of SOS. Significant correlation is found between residues that show high flexibility and the putative receptor binding sites on the protein.     

Dynamics of backbone conformational heterogeneity in Bacillus subtilis ribonuclease P protein

Interconversion of protein conformations is imperative to function, as evidenced by conformational changes associated with enzyme catalytic cycles, ligand binding and post-translational modifications. In this study, we used 15N NMR relaxation experiments to probe the fast (i.e., ps-ns) and slow (i.e., micros-ms) conformational dynamics of Bacillus subtilis ribonuclease P protein (P protein) in its folded state, bound to two sulfate anions. Using the Lipari-Szabo mapping method [Andrec, M., Montelione, G. T., and Levy, R. M. (2000) J. Biomol. NMR 18, 83-100] to interpret the data, we find evidence for P protein dynamics on the mus-ms time scale in the ensemble. The residues that exhibit these slow internal motions are found in regions that have been previously identified as part of the P protein-P RNA interface. These results suggest that structural flexibility within the P protein ensemble may be important for proper RNase P holoenzyme assembly and/or catalysis.     

Identification of residues important for ligand binding of thromboxane A2 receptor in the second extracellular loop using the NMR experiment-guided mutagenesis approach

The second extracellular loop (eLP2) of the thromboxane A(2) receptor (TP) had been proposed to be involved in ligand binding. Through two-dimensional (1)H NMR experiments, the overall three-dimensional structure of a constrained synthetic peptide mimicking the eLP2 had been determined by our group (Ruan, K.-H., So, S.-P., Wu, J., Li, D., Huang, A., and Kung, J. (2001) Biochemistry 40, 275-280). To further identify the residues involved in ligand binding, a TP receptor antagonist, SQ29,548 was used to interact with the synthetic peptide. High resolution two-dimensional (1)H NMR experiments, NOESY, and TOCSY were performed for the peptide, SQ29,548, and peptide with SQ29,548, respectively. Through completed (1)H NMR assignment and by comparing the different spectra, extra peaks were observed on the NOESY spectrum of the peptide with SQ29,548, which implied the contacts between residues of eLP2 at Val(176), Leu(185), Thr(186), and Leu(187) with SQ29,548 at position H2, H7, and H8. Site-directed mutagenesis was used to confirm the possible ligand-binding sites on native human TP receptor. Each of the four residues was mutated to the residues either in the same group, with different structure or different charged. The mutated receptors were then tested for their ligand binding activity. The receptor with V176L mutant retained binding activity to SQ29,548. All other mutations resulted in decreased or lost binding activity to SQ29,548. These mutagenesis results supported the prediction from NMR experiments in which Val(176), Leu(185), Thr(186), and Leu(187) are the possible residues involved in ligand binding. This information facilitates the understanding of the molecular mechanism of thromboxane A(2) binding to the important receptor and its signal transduction.     

Unfolding and refolding of the glutamine-binding protein from Escherichia coli and its complex with glutamine induced by guanidine hydrochloride

The aim of this work was to study the conformational changes of the Escherichia coli glutamine-binding protein (GlnBP) induced by GdnHCl and the effect of the binding of glutamine (Gln) on these processes. To this end, GdnHCl-induced unfolding of GlnBP alone and its GlnBP-Gln complex was studied by protein intrinsic fluorescence, ANS emission fluorescence, and far- and near-UV circular dichroism spectroscopy. The obtained spectroscopic data were interpreted taking into the account the peculiarities of protein three-dimensional structure. In particular, the fact that formation of a complex of GlnBP and Gln, which essentially changes the global structure of protein, affects only insignificantly the microenvironments of tryptophan residues elucidates the similarity of the emission spectra of GlnBP and the GlnBP-Gln complex, and the existence of quenching groups near tyrosine residues and an effective nonradiative Tyr --> Trp and/or Tyr --> Tyr --> Trp energy transfer provide an explanation for the negligibly small contribution of tyrosine to the bulk fluorescence of the native protein and for its increase in protein unfolding. The use of the parametric presentation of fluorescence data showed that both GlnBP unfolding and GlnBP-Gln unfolding are three-step processes (N --> I(1) --> I(2) --> U), though in the case of the GlnBP-Gln complex these stages essentially overlap. Despite the complex character, GlnBP unfolding is completely reversible. The dramatic shift of the N --> I(1) process to higher GdnHCl concentrations for the GlnBP-Gln complex in comparison with GlnBP was shown.     

19F NMR study of the leucine-specific binding protein of Escherichia coli: mutagenesis and assignment of the 5-fluorotryptophan-labeled residues

The Escherichia coli L-leucine receptor is an aqueous protein and the first component in the distinct transport pathway for hydrophobic amino acids. L-leucine binding induces a conformational change, which enables the receptor to dock to the membrane components. To investigate the ligand-induced conformational change and binding properties of this protein, we used (19)F NMR to probe the four tryptophan residues located in the two lobes of the protein. The four tryptophan residues were labeled with 5-fluorotryptophan and assigned by site-directed mutagenesis. The (19)F NMR spectra of the partially ligand free proteins show broadened peaks which sharpen when L-leucine is bound, showing that the labeled wild-type protein and mutants are functional. The titration of L-phenylalanine into the 5-fluorotryptophan labeled wild-type protein shows the presence of closed and open conformers. Urea-induced denaturation studies support the NMR results that the wild-type protein binds L-phenylalanine in a different manner to L-leucine. Our studies showed that the tryptophan to phenylalanine mutations on structural units linked to the binding pocket produce subtle changes in the environment of Trp18 located directly in the binding cleft.     

Grafting of protein-protein interaction epitope

Transferring the biological function of one protein to another is a key issue in understanding the structure and function relationship of proteins. We have developed a strategy for grafting protein-protein interaction epitopes. As a first step, residues at the interface of the ligand protein which strongly interact with the receptor protein were identified. Then protein scaffolds were docked onto receptor protein based on geometric complementarity. Only high docking score matches were saved. For each saved match, the scaffold protein was accepted if it had suitable positions for grafting key interaction residues of the ligand protein. These candidate residues were mutated to corresponding residues in the ligand protein at each relevant position and the mutated scaffold protein was co-minimized with receptor protein. Finally, the minimized complexes were evaluated by a scoring function deduced from statistical analysis of rigid binding data sets. As a test case, the binding epitope of barstar, the inhibitor of barnase, was grafted onto smaller proteins. Pheromone Er-1 (PDB entry 1erc) has been found to be a good scaffold. The calculated binding free energy for mutated Pheromone Er-1 is equivalent to that of barstar.     

Determinants of intra versus intermolecular self-association within the regulatory domains of Rlk and Itk

A protein fragment from the Tec family member Rlk (also known as Txk) containing a single proline-rich ligand adjacent to a Src homology 3 (SH3) domain has been investigated by nuclear magnetic resonance (NMR) spectroscopy. Analysis of the concentration dependence of the chemical shifts, NMR linewidths and self-diffusion coefficients reveal that the Rlk fragment dimerizes in solution. Mutation of two critical prolines in the proline-rich ligand abolishes dimerization. Furthermore, analysis of the extrapolated chemical shifts at infinite dilution reveal that intramolecular binding of the proline-rich ligand to the SH3 domain is disfavored. This is in contrast to the corresponding fragment of Itk, for which the proline-rich ligand/SH3 interaction occurs exclusively in an intramolecular fashion and no intermolecular binding is observed. Comparison of the Itk and Rlk sequences reveals that Rlk contains five fewer residues than Itk in the linker region between the proline-rich ligand and the SH3 domain. To assess whether linker length is a molecular determinant of intra- versus intermolecular self-association, we varied the length of the linker in both Rlk and Itk and analyzed the resulting variants by NMR. Intramolecular binding in Itk is reduced by shortening the linker and conversely a longer linker between the proline-rich ligand and the SH3 domain in Rlk enhances intramolecular self-association. Association constants for the binding of peptides corresponding to the proline-rich ligand with their respective SH3 domains were also measured by NMR. The protein/peptide data combined with the association constants for binding of each proline-rich peptide to the corresponding SH3 domain provide an explanation for the opposing modes of self-association within the otherwise closely related Rlk and Itk proteins.     

Turkey egg white lysozyme. Free energy, enthalpy, and steady state kinetics of reaction with N-acetylglucosamine oligosaccharides.

Equilibrium and calorimetric studies of substrate binding to turkey egg white (TEW) lysozyme were carried out at 30degrees as a function of pH (2 to 9) and ligand size (monosaccharide to hexasaccharide of N-acetylglucosamine). Steady state kinetic measurements using the N-acetylglucosamine hexasaccharide were carried out as a function of pH (2 to 9) and temperature (20-60degrees). These experiments allow comparison of the properties of TEW lysozyme with those of the hen egg white (HEW) enzyme reported previously (Banerjee, S. K., Holler, E., Hess, G. P., and Rupley, J. A. (1975) J. Biol. Chem. 250, 4355-4367, and references therein). The free energies and enthalpies of oligosaccharide binding are the same for TEW and HEW lysozymes at pH 2 but are less negative for TEW lysozyme at pH 5. The pH dependence of the binding of (GlcNAc)3 and higher oligomers to TEW lysozyme is like that for the binding of beta-methyl-N-acetylglucosaminide to TEW lysozyme. These data indicate that oligosaccharide ligands bind identically with HEW and TEW lysozymes, except for the interactions of residue 101, which is aspartic acid in the HEW protein and glycine in the TEW protein (Larue, J. N., and Speck, J. C., Jr. (1970) J. Biol. Chem. 245, 1985-1991). The pH dependence of kcat is described by apparent pK values of 3.9 and 6.8 and a maximum value of kcat of 0.135 s-1. A value of 21.0 kcal/mol was calculated for deltaH from the temperature dependence of kcat. These values and the dependence of the transglycosylation reaction on acceptor concentration are within experimental error the same as those for HEW lysozyme. The more acid pK seen in the pH rate profile reflects the ionization of Asp-52 in the lysozyme-(GlcNAc)6 complex. The pK of Asp-52 in the free protein is 0.3 pK unit lower. The essential identity of the active sites of the HEW and TEW enzymes, except for the Asp-101 interactions, allows estimation of the thermodynamic properties associated with formation of the two hydrogen bonds between Asp-101 and substrate as deltaG0 = -1.2 kcal/mol, DeltaH0 = -3.6 kcal/mol, and deltaS0 = -7.9 e.u.