Strong Salt Bridge Research Articles

Small nonphosphorylated Grb2–SH2 domain antagonists evaluated by surface plasmon resonance technology

The growth factor receptor-binding protein-Src homology 2 (Grb2-SH2) domain plays an important role in the oncogenic Ras signal transduction pathway, which involves cell proliferation and differentiation. Therefore, the Grb2-SH2 domain has been chosen as our target for development of potential antiproliferative agents. Herein, we report the study of the inhibitory effects of small nonphosphorylated peptide analogs interacting with the Grb2-SH2 domain protein by surface plasmon resonance (SPR) technology. A set of 8 related peptide analogs were synthesized, purified, and characterized. Their inhibitory effects on Grb2-SH2 were evaluated by the SPR technology developed with the BIACORE X instrument. The lead peptide, Fmoc-Glu-Tyr-Aib-Asn-NH2 (Fmoc-E-Y-Aib-N; Fmoc: 9-fluorenylmethyoxycarbonyl; Aib=alpha-amino isobutyric acid) inhibited Grb2-SH2 domain function with an IC50 value of 8.7 microM. A molecular modeling study of the lead peptide indicated that the glutamate in the Fmoc peptide is ideally positioned to form a strong salt bridge to Arg 67 in the Grb2-SH2 domain, using both its backbone carbonyl and its acidic group. Residue Glu 89 in Grb2-SH2 flips inward to fill the binding site and partially replace the phosphate group as a hydrogen-bond acceptor. Results of these studies provide important information for further development of potent nonphosphorylated peptide inhibitors of the Grb2-SH2 domain.

Binding and Hydrolysis of Ampicillin in the Active Site of a Zinc Lactamase

Binding and hydrolysis of ampicillin are described in a model active site derived from dinuclear B. fragilis zinc lactamase. The protein binding site consists of the two zinc cations bound with a bridging hydroxide and ligands from the first-shell residues, conserved residues near the zinc site, and the moveable loop of residues from numbers 43−53. The model active site consists of the first-shell residues, the conserved residues, and glu45 and glu47 from the moveable loop. Ampicillin is primarily located in the active site by the binding of the thiazolidine ring's extra-cyclic carboxylate to the ammonium of conserved lysine 184 when water bound to Zn2 in the active site is retained. A comparable strong salt bridge is formed between the ammonium of the ampicillin zwitterion and glu45 on the flexible loop that moves mostly as a unit at least 10 A to complete the binding site. The zwitterion character of this antibiotic influences the final docking arrangement and ultimate reaction path. Classical molecular...

Differences in Electrostatic Properties at Antibody–Antigen Binding Sites: Implications for Specificity and Cross-Reactivity

Antibodies HyHEL8, HyHEL10, and HyHEL26 (HH8, HH10, and HH26, respectively) recognize highly overlapping epitopes on hen egg-white lysozyme (HEL) with similar affinities, but with different specificities. HH8 binding to HEL is least sensitive toward mutations in the epitope and thus is most cross-reactive, HH26 is most sensitive, whereas the sensitivity of HH10 lies in between HH8 and HH26. Here we have investigated intra- and intermolecular interactions in three antibody–protein complexes: theoretical models of HH8-HEL and HH26-HEL complexes, and the x-ray crystal structure of HH10-HEL complex. Our results show that HH8-HEL has the lowest number and HH26-HEL has the highest number of intra- and intermolecular hydrogen bonds. The number of salt bridges is lowest in HH8-HEL and highest in HH26-HEL. The binding site salt bridges in HH8-HEL are not networked, and are weak, whereas, in HH26-HEL, an intramolecular salt-bridge triad at the binding site is networked to an intermolecular triad to form a pentad. The pentad and each salt bridge of this pentad are exceptionally stabilizing. The number of binding-site salt bridges and their strengths are intermediate in HH10-HEL, with an intramolecular triad. Our further calculations show that the electrostatic component contributes the most to binding energy of HH26-HEL, whereas the hydrophobic component contributes the most in the case of HH8-HEL. A “hot-spot” epitope residue Lys-97 forms an intermolecular salt bridge in HH8-HEL, and participates in the intermolecular pentad in the HH26-HEL complex. Mutant modeling and surface plasmon resonance (SPR) studies show that this hot-spot epitope residue contributes significantly more to the binding than an adjacent epitope residue, Lys-96, which does not form a salt bridge in any of the three HH-HEL complexes. Furthermore, the effect of mutating Lys-97 is most severe in HH26-HEL. Lys-96, being a charged residue, also contributes the most in HH26-HEL among the three complexes. The SPR results on these mutants also highlight that the apparent “electrostatic steering” on net on rates actually act at post-collision level stabilization of the complex. The significance of this work is the observed variations in electrostatic interactions among the three complexes. Our work demonstrates that higher electrostatics, both as a number of short-range electrostatic interactions and their contributions, leads to higher binding specificity. Strong salt bridges, their networking, and electrostatically driven binding, limit flexibilities through geometric constrains. In contrast, hydrophobic driven binding and low levels of electrostatic interactions are associated with conformational flexibility and cross-reactivity.

The Crystal Structure of Indoleglycerol-phosphate Synthase from Thermotoga maritima: KINETIC STABILIZATION BY SALT BRIDGES

The crystal structure of the thermostable indoleglycerol-phosphate synthase from Thermotoga maritima (tIGPS) was determined at 2.5 A resolution. It was compared with the structures of the thermostable sIGPS from Sulfolobus solfataricus and of the thermolabile eIGPS from Escherichia coli. The main chains of the three (beta alpha)(8)-barrel proteins superimpose closely, and the packing of side chains in the beta-barrel cores, as well as the architecture of surface loops, is very similar. Both thermostable proteins have, however, 17 strong salt bridges, compared with only 10 in eIGPS. The number of additional salt bridges in tIGPS and sIGPS correlates well with their reduced rate of irreversible thermal inactivation at 90 degrees C. Only 3 of 17 salt bridges in tIGPS and sIGPS are topologically conserved. The major difference between the two proteins is the preference for interhelical salt bridges in sIGPS and intrahelical ones in tIGPS. The different implementation of salt bridges in the closely related proteins suggests that the stabilizing effect of salt bridges depends rather on the sum of their individual contributions than on their location. This observation is consistent with a protein unfolding mechanism where the simultaneous breakdown of all salt bridges is the rate-determining step.

Crystal structures of the class D β-lactamase OXA-13 in the native form and in complex with meropenem

The therapeutic problems posed by class D β-lactamases, a family of serine enzymes that hydrolyse β-lactam antibiotics following an acylation-deacylation mechanism, are increased by the very low level of sensitivity of these enzymes to β-lactamase inhibitors. To gain structural and mechanistic insights to aid the design of new inhibitors, we have determined the crystal structure of OXA-13 from Pseudomonas aeruginosa in the apo form and in complex with the carbapenem meropenem. The native form consisted of a dimer displaying an overall organisation similar to that found in the closely related enzyme OXA-10. In the acyl-enzyme complex, the positioning of the antibiotic appeared to be ensured mainly by (i) the covalent acyl bond and (ii) a strong salt-bridge involving the carboxylate moiety of the drug. Comparison of the structures of OXA-13 in the apo form and in complex with meropenem revealed an unsuspected flexibility in the region of the essential serine 115 residue, with possible consequences for the catalytic properties of the enzyme. In the apo form, the Ser115 side-chain is oriented outside the active site, whereas the general base Lys70 adopts a conformation that seems to be incompatible with the activation of the catalytic water molecule required for the deacylation step. In the OXA-13:meropenem complex, a 3.5 Å movement of the backbone of the 114–116 loop towards the side-chain of Lys70 was observed, which seems to be driven by a displacement of the neighbouring 91–104 loop and which results in the repositioning of the side-chain hydroxyl group of Ser115 toward the catalytic centre. Concomitantly, the side-chain of Lys70 is forced to curve in the direction of the deacylating water molecule, which is then strongly bound and activated by this residue. However, a distance of ca 5 Å separates the catalytic water molecule from the acyl carbonyl group of meropenem, a structural feature that accounts for the inhibition of OXA-13 by this drug. Finally, the low level of penicillinase activity revealed by the kinetic analysis of OXA-13 could be related to the specific presence in position 73 of a serine residue located close to the general base Lys70, which results in a decrease of the number of hydrogen-bonding interactions stabilising the catalytic water molecule.

Strength of Solvent-Exposed Salt-Bridges

This paper uses a recently developed computer model to study the energetics of solvent-exposed salt-bridges. The model uses the “mining minima” method to compute conformational free energies with the CHARMm empirical force and the generalized Born solvation model. Satisfactory agreement is obtained in comparison with the measured binding affinities of ion pairs in solution and with the salt-bridge energetics deduced from studies of salt-bridges in helical peptides. The calculations suggest that stabilizing charge−charge interactions in helical peptides do not require well-defined salt-bridge conformations. This is in agreement with crystallographic studies of charge pairs added to T4 lysozyme by site-directed mutagenesis. The computer model is also used to make a testable prediction that arginine and phosphotyrosine residues in an (i, i + 4) relationship will form a particularly strong salt-bridge in helical peptides. The biological implications of these results are discussed.

Crystal structure of human ornithine aminotransferase complexed with the highly specific and potent inhibitor 5-fluoromethylornithine 1

Ornithine aminotransferase (l-ornithine:2-oxoacid δ-aminotransferase; EC 2.6.1.13), a pyridoxal-5′-phosphate-dependent mitochondrial enzyme controls the l-ornithine level in tissues by catalyzing the transfer of the δ-amino group of l-ornithine to 2-oxoglutarate, producing l-glutamate- γ-semialdehyde and l-glutamate. (2S,5S)-5-Fluoromethylornithine is the only inhibitor exclusively specific for ornithine aminotransferase known to date. Both in vitro and in vivo, it blocks the enzyme by a suicide reaction leading to a covalent adduct with the cofactor. The crystal structure of the enzyme-inhibitor complex was solved at a resolution of 1.95 Å. No significant conformational changes compared with the native enzyme structure were observed. The structure reveals the atomic details of the cofactor-inhibitor adduct and its interactions with the active site of the enzyme. The main residues responsible for specific binding of the inhibitor are Arg180, which forms a strong salt bridge with the α-carboxylate and Tyr55, which is involved in a short hydrogen bond with the α-amino group. The experimental observation that in the racemic mixture, (2S,5S)-5-fluoromethylornithine is exclusively responsible for the enzyme inhibition can be explained on the basis of the active site topology. Model building studies strongly suggest that the natural substrate l-ornithine, in its external aldimine adduct with the enzyme, makes use of the same recognition site as the inhibitor. It is proposed that the neutralization of the active site Arg413 by a salt bridge with Glu235 also plays an important role in productive binding of both 5-fluoromethylornithine and l-ornithine. Arg180 and Arg413 are believed to be instrumental in recognition of l -glutamate, by binding its γ and α-carboxylate groups, respectively. This requires a different side-chain conformation of Glu235. Lys292 is the only obvious candidate for catalyzing the rate-limiting proton transfer steps in the transamination reaction.

Complete measurement of the pKa values of the carboxyl and imidazole groups in Bacillus circulans xylanase.

Electrostatic interactions in proteins can be dissected experimentally by determining the pKa values of their constituent ionizable amino acids. To complement previous studies of the glutamic acid and histidine residues in Bacillus circulans xylanase (BCX), we have used NMR methods to measure the pKa s of the seven aspartic acids and the C-terminus of this protein. The pKa s of these carboxyls are all less than the corresponding values observed with random coil polypeptides, indicating that their ionization contributes favorably to the stability of the folded enzyme. In general, the aspartic acids with the most reduced pKa s are those with limited exposure to the solvent and a high degree of conservation among homologous xylanases. Most dramatically, Asp 83 and Asp 101 have pKa s < 2 and thus remain deprotonated in native BCX under all conditions examined. Asp 83 is completely buried, forming a strong salt bridge with Arg 136. In contrast, Asp 101 is located on the surface of the protein, stabilized in the deprotonated form by an extensive network of hydrogen bonds involving an internal water molecule and the neutral side-chain and main-chain atoms of Ser 100 and Thr 145. These data provide a complete experimental database for theoretical studies of the ionization behavior of BCX under acidic conditions.

Exceptionally stable salt bridges in cytochrome P450cam have functional roles.

A long-standing puzzle in structure-function studies of cytochrome P450cam is how the substrate, camphor, reaches the buried active site. The crystal structure shows no channel from the surface to the active site large enough for substrate to pass through. Recent experiments indicate that access of the rather nonpolar substrate to the active site is controlled by electrostatic interactions and may involve rupture of the two salt links to Asp251 [Deprez, E., Gerber, N. C., Di Primo, C., Douzou, P., Sligar, S. G., & Hui Bon Hoa, G. (1994) Biochemistry 33, 14464-14468]. Consequently, we have computed the electrostatic strength of 53 ionic pairs, including 32 salt links, in cytochrome P450cam by numerical solution of the finite-difference linearized Poisson-Boltzmann equation. The calculated electrostatic free energies, delta Gtot, of the salt links range from -9 to +6 kcal/mol with approximately 60% of the salt links being energetically favorable and 40% being unfavorable with respect to mutation to their uncharged, nonpolar isosteres. Strikingly, of the four most stable salt links in the protein (delta Gtot < -6 kcal/mol), two involve the propionate groups of the heme and the other two involve Asp251. In the modeled D251N mutant, for which electrostatic effects on substrate binding are diminished, the latter two salt links lose their stability (delta Gtot > -2.4 kcal/mol). Thus it appears that cytochrome P450cam has evolved four unusually strong salt bridges, stabilized by surrounding charged and polar groups in the protein, to keep its heme cofactor in place and to regulate substrate binding.

Inorganic phosphate binding and electrostatic effects in the active center of aspartate aminotransferase apoenzyme.

The ionization state of the phosphate group bound at the aspartate aminotransferase apoenzyme's active site has been investigated utilizing Fourier-transform infrared spectroscopy following the band corresponding to the symmetric stretching of the dianionic phosphate. Unlike free phosphate, when inorganic phosphate is bound at the enzyme's active site, the integrated intensity value of the dianionic band does not change with pH within the studied range, and this value is similar to that for free dianionic phosphate at pH 8.3. From these results, we propose a dianionic state for the phosphate ion bound to cytosolic aspartate aminotransferase throughout the pH range of 5.7-8.3. The presence of other anions such as acetate and chloride or the substrate aspartate and its analogues produces a pH-dependent phosphate removal from the active site which is favored at low pH values. Elimination of the charged primary amine at the active-site Lys-258, through formation of a Schiff base with pyridoxal or chemical modification by carbamylation, also produces a pH-independent phosphate release. These results are interpreted as Lys-258 together with the active-site alpha-helix and other residues may be involved in stabilizing phosphate as a dianion in the apoenzyme phosphate pocket which anchors the phosphate ester of pyridoxal phosphate in the holoenzyme. It is proposed that the dianionic phosphate contributes to the apoenzyme's thermal stability through formation of strong hydrogen bond and salt bridges with the amino acid residues forming the phosphate binding pocket with assistance of Lys-258, and other active-site cationic components.

Contributions of engineered surface salt bridges to the stability of T4 lysozyme determined by directed mutagenesis

Six designed mutants of T4 lysozyme were created in an attempt to create putative salt bridges on the surface of the protein. The first three of the mutants, T115E (Thr 115 to Glu), Q123E, and N144E, were designed to introduce a new charged side chain close to one or more existing charged groups of the opposite sign on the surface of the protein. In each of these cases the putative electrostatic interactions introduced by the mutation include possible salt bridges between residues within consecutive turns of an alpha-helix. Effects of the mutations ranged from no change in stability to a 1.5 degrees C (0.5 kcal/mol) increase in melting temperature. In two cases, secondary (double) mutants were constructed as controls in which the charge partner was removed from the primary mutant structure. These controls proteins indicate that the contributions to stability from each of the engineered salt bridges is very small (about 0.1-0.25 kcal/mol in 0.15 M KCl). The structures of the three primary mutants were determined by X-ray crystallography and shown to be essentially the same as the wild-type structure except at the site of the mutation. Although the introduced charges in the T115E and Q123E structures are within 3-5 A of their intended partner, the introduced side chains and their intended partners were observed to be quite mobile. It has been shown that the salt bridge between His 31 and Asp 70 in T4 lysozyme stabilizes the protein by 3-5 kcal/mol [Anderson, D. E., Becktel, W. J., & Dahlquist, F. W. (1990) Biochemistry 29, 2403-2408]. To test the effectiveness of His...Asp interactions in general, three additional double mutants, K60H/L13D, K83H/A112D, and S90H/Q122D, were created in order to introduce histidine-aspartate charge pairs on the surface of the protein. Each of these mutants destabilizes the protein by 1-3 kcal/mol in 0.15 M KCl at pH values from 2 to 6.5. The X-ray crystallographic structure of the mutant K83H/A112D has been determined and shows that there are backbone conformational changes of 0.3-0.6 A extending over several residues. The introduction of the histidine and aspartate presumably introduces strain into the folded protein that destabilizes this variant. It is concluded that pairs of oppositely charged residues that are on the surface of a protein and have freedom to adopt different conformations do not tend to come together to form structurally localized salt bridges. Rather, such residues tend to remain mobile, interact weakly if at all, and do not contribute significantly to protein stability. It is argued that the entropic cost of localizing a pair of solvent-exposed charged groups on the surface of a protein largely offsets the interaction energy expected from the formation of a defined salt bridge. There are examples of strong salt bridges in proteins, but such interactions require that the folding of the protein provides the requisite driving energy to hold the interacting partners in the correct rigid alignment.

A1H and13C NMR Study on the Role of Salt-Bridges in the Formation of a Type I β-Turn in N-Acetyl-L-Asp-L-Glu-L-Lys-L-Ser-NH2

Abstract The conformation of the tetrapeptide N-Acetyl-Asp7-Glu8-Lys9-Ser10-NH2, a fragment of the type I collagen α-1 chain N-telopeptide, has been studied by 1H and 13C NMR and circular dichroism spectroscopy. The spectroscopic evidence, based on two-dimensional, phase-sensitive NMR techniques such as COSY, ROESY, proton-carbon shift correlation and selective COLOC, indicates a strong dependence of the conformation on the experimental conditions. In CD3OH/H2O (60/40) at ca. neutral pH the tetrapeptide forms a β-turn, stabilized by a hydrogen bond between NH(S10) and CO(D7) and a strong salt-bridge between COO−(E8) and NH3 +(K9). The β-turn is type I and appears to coexist with a non-hydrogen-bonded structure. The coexistence of these two conformers is proven by proton NMR data such as NH-NH ROEs, reduced NH-Hα(E8) coupling constant NH(E8) low-field shift and the temperature coefficient of NH(S10), whereas the conclusion regarding the salt-bridge is based on 13C results. In the same solvent, at a pH below the pKa of the carboxyl groups, no evidence for a conformation other than extended can be found. In aqueous solution at approximately neutral pH, evidence for the E8-K9 charge interaction is observed, but not for a hydrogen bond anywhere in the molecule.

Peptide models of electrostatic interactions in proteins: NMR studies on two beta-turn tetrapeptides containing Asp-His and Asp-Lys salt bridges.

Two model peptides Boc-Asp-Pro-Aib-X-NHMe [X = His (1) and X = Lys (2)] were synthesized to simulate intramolecular electrostatic interactions between ionizable side chains. Conformational analysis by 270-MHz 1H NMR in (CD3)2SO reveals that the backbone secondary structures of these two peptides are stabilized by two strong intramolecular hydrogen bonds, involving the consecutive carboxy-terminal NH groups. 1H NMR chemical shifts were measured in 1, 2, and a protected derivative, Boc-Asp(OBzl)-Pro-Aib-His-NHMe (3). These shifts were also measured for the model compounds Ac-Lys-NHMe, Boc-Asp-NHMe, and Boc-His-NHMe in their different states of ionization. An analysis of the chemical shifts of the ionization-sensitive reporter resonances suggests the formation of a strong intramolecular salt bridge in the lysyl peptide 2 and a bridge of moderate strength in the histidyl peptide 1. A comparison of the temperature dependence of chemical shifts in peptides 1-3 suggests that intramolecular salt bridge formation results in diminished backbone flexibility. The results establish that proximity effects confer far greater stability to intramolecular ion pair interactions vis-a-vis their intermolecular counterparts. The salt bridge interaction in peptide 1 displays a remarkable sensitivity to the dielectric constant of the solvent medium. The results suggest that these peptides are good simulators of the role of salt bridges in the structural dynamics of proteins.

A study of liquid-junction potentials in aqueous solutions

Due to the simultaneously unknown individual ion activity coefficients and liquid-junction potentials, a reasonable convention must be introduced defining the former in order to permit the calculation of the latter. The Guggenheim convention is analysed and chosen.Examples are reported of determination of potentials arising at junctions between concentrated strong acids and salt bridges. Liquid junction potentials set up between two concentrated strong acids at identical molalities are also considered, on the basis of a modified Henderson equation.