HIV-1 protease inhibitors: enthalpic versus entropic optimization of the binding affinity

Existing experimental as well as computational screening methods select potential ligands or drug candidates on the basis of binding affinity. Since the binding affinity is a function of the enthalpy (DeltaH) and entropy (DeltaS) changes, it is apparent that improved binding can be achieved in different ways: by optimizing DeltaH, DeltaS, or a combination of both. However, the behavior of enthalpically or entropically optimized inhibitors is fundamentally different, including their response to mutations that may elicit drug resistance. In the design of HIV-1 protease inhibitors, high binding affinity has usually been achieved by preshaping lead compounds to the geometry of the binding site and by incorporating a high degree of hydrophobicity. The thermodynamic consequence of that approach is that the binding affinity of the resulting inhibitors becomes entropically favorable but enthalpically unfavorable. Specifically, the resulting high binding affinity is due to an increased solvation entropy (hydrophobic effect) combined with a reduced loss of conformational entropy of the inhibitor upon binding (structural rigidity). Here we report that tripeptide inhibitors derived from the transframe region of Gag-Pol (Glu-Asp-Leu and Glu-Asp-Phe) bind to the HIV-1 protease with a favorable enthalpy change. This behavior is qualitatively different from that of known inhibitors and points to new strategies for inhibitor design. Since the binding affinities of enthalpically favorable and enthalpically unfavorable inhibitors have opposite temperature dependence, it is possible to design fast screening protocols that simultaneously select inhibitors on the basis of affinity and enthalpy.     

Thermodynamic characterization of interleukin-8 monomer binding to CXCR1 receptor N-terminal domain

Chemokines elicit their function by binding receptors of the G-protein-coupled receptor class, and the N-terminal domain (N-domain) of the receptor is one of the two critical ligand-binding sites. In this study, the thermodynamic basis for binding of the chemokine interleukin-8 (IL-8) to the N-domain of its receptor CXCR1 was characterized using isothermal titration calorimetry. We have shown previously that only the monomer of IL-8, and not the dimer, functions as a high-affinity ligand, so in this study we used the IL-8(1-66) deletion mutant which exists as a monomer. Calorimetry data indicate that the binding is enthalpically favored and entropically disfavored, and a negative heat capacity change indicates burial of hydrophobic residues in the complex. A characteristic feature of chemokine receptor N-domains is the large number of acidic residues, and experiments using different buffers show no net proton transfer, indicating that the CXCR1 N-domain acidic residues are not protonated in the binding process. CXCR1 N-domain peptide is unstructured in the free form but adopts a more defined structure in the bound form, and so binding is coupled to induction of the structure of the N-domain. Measurements in the presence of the osmolyte, trimethylamine N-oxide, which induces the structure of unfolded proteins, show that formation of the coupled N-domain structure involves only small DeltaH and DeltaS changes. These results together indicate that the binding is driven by packing interactions in the complex that are enthalpically favored, and are consistent with the observation that the N-domain binds in an extended form and interacts with multiple IL-8 N-loop residues over a large surface area.     

Binding thermodynamics of substituted diaminopyrimidine renin inhibitors

Renin is an aspartyl protease involved in the production of angiotensin II, a potent vasoconstrictor. Renin inhibitors can prevent blood vessel constriction and therefore could be useful for the treatment of hypertension. High-throughput screening efforts identified a small molecule renin inhibitor with a core substituted diaminopyrimidine ring. Parallel medicinal chemistry efforts based on this lead resulted in compound 1. A complex of 1 bound to renin was crystallized, and structural data were obtained by X-ray diffraction. The structure indicated that there were adjacent unoccupied binding pockets. Synthetic efforts were initiated to extend functionality into these pockets so as to improve affinity and adjust pharmacokinetic parameters. Thermodynamics data for inhibitor binding to renin were also collected using isothermal titration calorimetry. These data were used to help guide inhibitor optimization by suggesting molecular alterations to improve binding affinity from both thermodynamic and structural perspectives. The addition of a methoxypropyl group extending into the S3 subpocket improved inhibitor affinity and resulted in greater binding enthalpy. Initial additions to the pyrimidine ring template that extended into the large hydrophobic S2 pocket did not improve affinity and dramatically altered the thermodynamic driving force for the binding interaction. Binding of the core template was enthalpically driven, whereas binding of initial inhibitors with S2 extensions was both enthalpically and entropically driven but lost significant binding enthalpy. Additional electrostatic interactions were then incorporated into the S2 extension to improve binding enthalpy while taking advantage of the favorable entropy.     

Inhibitors of human immunodeficiency virus-1 protease.

We have shown that the interaction of pepstatin A with human immunodeficiency virus-1 protease (HIV-1 protease) can be characterized by a high-affinity mode (Ki = 478 +/- 27 nM), resulting in pure competitive inhibition of the hydrolytic activity of HIV-1 protease toward the fluorogenic substrate. Binding of pepstatin in this mode induces a blue shift in the endogenous fluorescence arising from the tryptophan residues in HIV-1 protease. This shift is maximal in the presence of 10 microM pepstatin. Haloperidol, in contrast, interacts with HIV-1 protease with weaker affinity (Ki = 19 +/- 1 microM) in a mode which results in pure noncompetitive inhibition of the hydrolytic activity of HIV-1 protease. Binding of haloperidol in this mode induces a red shift in the endogenous fluorescence arising from the tryptophan residues in HIV-1 protease. This shift is maximal in the presence of 200 microM haloperidol. Addition of both pepstatin and haloperidol at concentrations in the range of their Ki values results in additive inhibition of the hydrolytic activity of HIV-1 protease, as well as an additive effect on the tryptophan fluorescence of protease. However, at saturating concentrations of pepstatin and haloperidol, the effect of haloperidol was predominant, as measured by the changes in the intrinsic fluorescence of HIV-1 protease.     

Interactions of different inhibitors with active-site aspartyl residues of HIV-1 protease and possible relevance to pepsin

The importance of the active site region aspartyl residues 25 and 29 of the mature HIV-1 protease (PR) for the binding of five clinical and three experimental protease inhibitors [symmetric cyclic urea inhibitor DMP323, nonhydrolyzable substrate analog (RPB) and the generic aspartic protease inhibitor acetyl-pepstatin (Ac-PEP)] was assessed by differential scanning calorimetry. DeltaT(m) values, defined as the difference in T(m) for a given protein in the presence and absence of inhibitor, for PR with DRV, ATV, SQV, RTV, APV, DMP323, RPB, and Ac-PEP are 22.4, 20.8, 19.3, 15.6, 14.3, 14.7, 8.7, and 6.5 degrees C, respectively. Binding of APV and Ac-PEP is most sensitive to the D25N mutation, as shown by DeltaT(m) ratios [DeltaT(m)(PR)/DeltaT(m)(PR(D25N))] of 35.8 and 16.3, respectively, whereas binding of DMP323 and RPB (DeltaT(m) ratios of 1-2) is least affected. Binding of the substrate-like inhibitors RPB and Ac-PEP is nearly abolished (DeltaT(m)(PR)/DeltaT(m)(PR(D29N)) > or = 44) by the D29N mutation, whereas this mutation only moderately affects binding of the smaller inhibitors (DeltaT(m) ratios of 1.4-2.2). Of the nine FDA-approved clinical HIV-1 protease inhibitors screened, APV, RTV, and DRV competitively inhibit porcine pepsin with K(i) values of 0.3, 0.6, and 2.14 microM, respectively. DSC results were consistent with this relatively weak binding of APV (DeltaT(m) 2.7 degrees C) compared with the tight binding of Ac-PEP (DeltaT(m) > or = 17 degrees C). Comparison of superimposed structures of the PR/APV complex with those of PR/Ac-PEP and pepsin/pepstatin A complexes suggests a role for Asp215, Asp32, and Ser219 in pepsin, equivalent to Asp25, Asp25', and Asp29 in PR in the binding and stabilization of the pepsin/APV complex.     

Purification of HIV-1 wild-type protease and characterization of proteolytically inactive HIV-1 protease mutants by pepstatin A affinity chromatography

Recombinant wild-type protease of human immunodeficiency virus, type [(HIV-1) expressed in E. coli was purified by pepstatin A affinity chromatography. An 88-fold purification was achieved giving a protease preparation with a specific enzymatic activity of approximately 3700 pmol/min/μg. Two proteolytically inactive HIV-1 mutant proteases (Arg-87 → Lys; Asn-88 → Glu) were found to bind to pepstatin A agarose, and they were purified as the wild-type protease. A third mutant protease (Arg-87 → Glu) was apparently unable to bind to pepstatin A under similar conditions. Binding to pepstatin A indicates the binding ability of the substrate binding site and the ability to form dimers. These features may be used to purify and to characterize other mutated HIV-1 proteases.     

Thermodynamics of phosphopeptide binding to the human peptidyl prolyl cis/trans isomerase Pin1

Proteins containing phosphorylated Ser/Thr-Pro motifs play key roles in numerous regulatory processes in the cell. The peptidyl prolyl cis/trans isomerase Pin1 specifically catalyzes the conformational transition of phosphorylated Ser/Thr-Pro motifs. Here we report the direct analysis of the thermodynamic properties of the interaction of the PPIase Pin1 with its substrate-analogue inhibitor Ac-Phe-D-Thr(PO3H2)-Pip-Nal-Gln-NH2 specifically targeted to the PPIase active site based on the combination of isothermal titration calorimetry and studies on inhibition of enzymatic activity of wt Pin1 and active site variants. Determination of the thermodynamic parameters revealed an enthalpically and entropically favored interaction characterized by binding enthalpy deltaH(ITC) of -6.3 +/- 0.1 kcal mol(-1) and a TdeltaS(ITC) of 4.1 +/- 0.1 kcal mol(-1). The resulting dissociation constant KD for binding of the peptidic inhibitor with 1.8 x 10(-8) M resembles the dissociation constant of a Pin1 substrate in the transition state, suggesting a transition state analogue conformation of the bound inhibitor. The strongly decreased affinity of Pin1 for ligand at increasing ionic strength implicates that the potential of bidentate binding of a substrate protein by the PPIase and the WW domain of Pin1 may be required to deploy improved efficiency and specificity of Pin1 under conditions of physiological ionic strength.     

Suppression of HIV-1 protease inhibitor resistance by phosphonate-mediated solvent anchoring

The introduction of human immunodeficiency virus type 1 (HIV-1) protease inhibitors (PIs) markedly improved the clinical outcome and control of HIV-1 infection. However, cross-resistance among PIs due to a wide spectrum of mutations in viral protease is a major factor limiting their broader clinical use. Here we report on the suppression of PI resistance using a covalent attachment of a phosphonic acid motif to a peptidomimetic inhibitor scaffold. The resulting phosphonate analogs maintain high binding affinity to HIV-1 protease, potent antiretroviral activity, and unlike the parent molecules, display no loss of potency against a panel of clinically important PI-resistant HIV-1 strains. As shown by crystallographic analysis, the phosphonate moiety is highly exposed to solvent with no discernable interactions with any of the enzyme active site or surface residues. We term this effect "solvent anchoring" and demonstrate that it is driven by a favorable change in the inhibitor binding entropy upon the interaction with mutant enzymes. This type of thermodynamic behavior, which was not found with the parent scaffold fully buried in the enzyme active site, is a result of the increased degeneracy of inhibitor binding states, allowing effective molecular adaptation to the expanded cavity volume of mutant proteases. This strategy, which is applicable to various PI scaffolds, should facilitate the design of novel PIs and potentially other antiviral therapeutics.     

Thermodynamic dissection of the binding energetics of KNI-272, a potent HIV-1 protease inhibitor

KNI-272 is a powerful HIV-1 protease inhibitor with a reported inhibition constant in the picomolar range. In this paper, a complete experimental dissection of the thermodynamic forces that define the binding affinity of this inhibitor to the wild-type and drug-resistant mutant V82F/184V is presented. Unlike other protease inhibitors, KNI-272 binds to the protease with a favorable binding enthalpy. The origin of the favorable binding enthalpy has been traced to the coupling of the binding reaction to the burial of six water molecules. These bound water molecules, previously identified by NMR studies, optimize the atomic packing at the inhibitor/protein interface enhancing van der Waals and other favorable interactions. These interactions offset the unfavorable enthalpy usually associated with the binding of hydrophobic molecules. The association constant to the drug resistant mutant is 100-500 times weaker. The decrease in binding affinity corresponds to an increase in the Gibbs energy of binding of 3-3.5 kcal/mol, which originates from less favorable enthalpy (1.7 kcal/mol more positive) and entropy changes. Calorimetric binding experiments performed as a function of pH and utilizing buffers with different ionization enthalpies have permitted the dissection of proton linkage effects. According to these experiments, the binding of the inhibitor is linked to the protonation/deprotonation of two groups. In the uncomplexed form these groups have pKs of 6.0 and 4.8, and become 6.6 and 2.9 in the complex. These groups have been identified as one of the aspartates in the catalytic aspartyl dyad in the protease and the isoquinoline nitrogen in the inhibitor molecule. The binding affinity is maximal between pH 5 and pH 6. At those pH values the affinity is close to 6 x 10(10) M(-1) (Kd = 16 pM). Global analysis of the data yield a buffer- and pH-independent binding enthalpy of -6.3 kcal/mol. Under conditions in which the exchange of protons is zero, the Gibbs energy of binding is -14.7 kcal/mol from which a binding entropy of 28 cal/K mol is obtained. Thus, the binding of KNI-272 is both enthalpically and entropically favorable. The structure-based thermodynamic analysis indicates that the allophenylnorstatine nucleus of KNI-272 provides an important scaffold for the design of inhibitors that are less susceptible to resistant mutations.     

Computational design and experimental study of tighter binding peptides to an inactivated mutant of HIV-1 protease

Drug resistance in HIV-1 protease, a barrier to effective treatment, is generally caused by mutations in the enzyme that disrupt inhibitor binding but still allow for substrate processing. Structural studies with mutant, inactive enzyme, have provided detailed information regarding how the substrates bind to the protease yet avoid resistance mutations; insights obtained inform the development of next generation therapeutics. Although structures have been obtained of complexes between substrate peptide and inactivated (D25N) protease, thermodynamic studies of peptide binding have been challenging due to low affinity. Peptides that bind tighter to the inactivated protease than the natural substrates would be valuable for thermodynamic studies as well as to explore whether the structural envelope observed for substrate peptides is a function of weak binding. Here, two computational methods-namely, charge optimization and protein design-were applied to identify peptide sequences predicted to have higher binding affinity to the inactivated protease, starting from an RT-RH derived substrate peptide. Of the candidate designed peptides, three were tested for binding with isothermal titration calorimetry, with one, containing a single threonine to valine substitution, measured to have more than a 10-fold improvement over the tightest binding natural substrate. Crystal structures were also obtained for the same three designed peptide complexes; they show good agreement with computational prediction. Thermodynamic studies show that binding is entropically driven, more so for designed affinity enhanced variants than for the starting substrate. Structural studies show strong similarities between natural and tighter-binding designed peptide complexes, which may have implications in understanding the molecular mechanisms of drug resistance in HIV-1 protease.     

Insights into the structural function of the complex of HIV-1 protease with TMC-126: molecular dynamics simulations and free-energy calculations

The binding properties of the protein–inhibitor complex of human immunodeficiency virus type 1 (HIV-1) protease with the inhibitor TMC-126 are investigated by combining computational alanine scanning (CAS) mutagenesis with binding free-energy decomposition (BFED). The calculated results demonstrate that the flap region (residues 38–58) and the active site region (residues 23–32) in HIV-1 protease contribute 63.72% of the protease to the binding of the inhibitor. In particular, the mechanisms for the interactions of key residues of these species are fully explored and analyzed. Interestingly, the regression analyses show that both CAS and BFED based on the generalized Born model yield similar results, with a correlation coefficient of 0.94. However, compared to CAS, BFED is faster and can decompose the per-residue binding free-energy contributions into backbone and side-chain contributions. The results obtained in this study are useful for studying the binding mechanism between receptor and ligand and for designing potent inhibitors that can combat diseases.     

Comprehensive mutagenesis of HIV-1 protease: a computational geometry approach

A computational geometry technique based on Delaunay tessellation of protein structure, represented by C(alpha) atoms, is used to study effects of single residue mutations on sequence-structure compatibility in HIV-1 protease. Profiles of residue scores derived from the four-body statistical potential are constructed for all 1881 mutants of the HIV-1 protease monomer and compared with the profile of the wild-type protein. The profiles for an isolated monomer of HIV-1 protease and the identical monomer in a dimeric state with an inhibitor are analyzed to elucidate changes to structural stability. Protease residues shown to undergo the greatest impact are those forming the dimer interface and flap region, as well as those known to be involved in inhibitor binding.     

The binding energetics of first- and second-generation HIV-1 protease inhibitors: implications for drug design

KNI-764 is a powerful HIV-1 protease inhibitor with a reported low susceptibility to the effects of protease mutations commonly associated with drug resistance. In this paper the binding thermodynamics of KNI-764 to the wild-type and drug-resistant mutant V82F/I84V are presented and the results compared to those obtained with existing clinical inhibitors. KNI-764 binds to the wild-type HIV-1 protease with very high affinity (3.1 x 10(10) M(-1) or 32 pM) in a process strongly favored by both enthalpic and entropic contributions to the Gibbs energy of binding (Delta G = -RTlnK(a)). When compared to existing clinical inhibitors, the binding affinity of KNI-764 is about 100 fold higher than that of indinavir, saquinavir, and nelfinavir, but comparable to that of ritonavir. Unlike the existing clinical inhibitors, which bind to the protease with unfavorable or only slightly favorable enthalpy changes, the binding of KNI-764 is strongly exothermic (-7.6 kcal/mol). The resistant mutation V82F/I84V lowers the binding affinity of KNI-764 26-fold, which can be accounted almost entirely by a less favorable binding enthalpy to the mutant. Since KNI-764 binds to the wild type with extremely high affinity, even after a 26-fold decrease, it still binds to the resistant mutant with an affinity comparable to that of other inhibitors against the wild type. These results indicate that the effectiveness of this inhibitor against the resistant mutant is related to two factors: extremely high affinity against the wild type achieved by combining favorable enthalpic and entropic interactions, and a mild effect of the protease mutation due to the presence of flexible structural elements at critical locations in the inhibitor molecule. The conclusions derived from the HIV-1 protease provide important thermodynamic guidelines that can be implemented in general drug design strategies.     

Reduced-bond tight-binding inhibitors of HIV-1 protease. Fine tuning of the enzyme subsite specificity.

Truncation of a peptide substrate in the N-terminus and replacement of its scissile amide bond with a non-cleavable reduced bond results in a potent inhibitor of HIV-1 protease. A series of such inhibitors has been synthesized, and S2-S3' subsites of the protease binding cleft mapped. The S2 pocket requires bulky Boc or PIV groups, large aromatic Phe residues are preferred in P1 and P1' and Glu in P2'. The S3' pocket prefers Phe over small Ala or Val. Introduction of a Glu residue into the P2' position yields a tight-binding inhibitor of HIV-1 protease, Boc-Phe-[CH2-NH]-Phe-Glu-Phe-OMe, with a subnanomolar inhibition constant. The relevant peptide derived from the same amino acid sequence binds to the protease with a Ki of 110 nM, thus still demonstrating a good fit of the amino acid residues into the protease binding pockets and also the importance of the flexibility of P1-P1' linkage for proper binding. A new type of peptide bond mimetic, N-hydroxylamine -CH2-N(OH)-, has been synthesized. Binding of hydroxylamino inhibitor of HIV-1 protease is further improved with respect to reduced-bond inhibitor.     

Comparative analysis of the sequences and structures of HIV-1 and HIV-2 proteases

The different isolates available for HIV-1 and HIV-2 were compared for the region of the protease (PR) sequence, and the variations in amino acids were analyzed with respect to the crystal structure of HIV-1 PR with inhibitor. Based on the extensive homology (39 identical out of 99 residues), models were built of the HIV-2 PR complexed with two different aspartic protease inhibitors, acetylpepstatin and a renin inhibitor, H-261. Comparison of the HIV-1 PR crystal structure and the HIV-2 PR model structure and the analysis of the changes found in different isolates showed that correlated substitutions occur in the hydrophobic interior of the molecule and at surface residues involved in ionic or hydrogen bond interactions. The substrate binding residues of HIV-1 and HIV-2 PRs show conservative substitutions of four residues. The difference in affinity of HIV-1 and HIV-2 PRs for the two inhibitors appears to be due in part to the change of Val 32 in HIV-1 PR to Ile in HIV-2 PR.     

The binding of HIV-1 protease inhibitors to human serum proteins

The non-specific binding of a drug to plasma proteins is an important determinant of its biological efficacy since it modulates the availability of the drug to its intended target. In the case of HIV-1 protease inhibitors, binding to human serum albumin (HSA) and alpha(1)-acid glycoprotein (AAG) appears to be an important modulator of drug bioavailability. From a thermodynamic point of view, the issue of drug availability to the desired target can be formulated as a multiple equilibrium problem in which a ligand is able to bind to different proteins or other macromolecules with different binding affinities. Previously, we have measured the binding thermodynamics of HIV-1 protease inhibitors to their target. In this article, the binding energetics of four inhibitors currently in clinical use (saquinavir, indinavir, ritonavir and nelfinavir) and a second-generation inhibitor (KNI-764) to human HSA and AAG has been studied by isothermal titration calorimetry. All inhibitors exhibited a significant affinity for AAG (K(a) approximately 0.5-10 x 10(5) M(-1)) and a relatively low affinity for HSA (K(a) approximately 5-15 x 10(3) M(-1)). It is shown that under conditions that simulate in vivo concentrations of serum proteins, the inhibitor concentrations required to achieve 95% protease inhibition can be up to 10 times higher than those required in the absence of serum proteins. The effect is compounded in patients infected with drug resistant HIV-1 strains that exhibit a lower affinity for protease inhibitors. In these cases the required inhibitor concentrations can be up to 2000 times higher and beyond the solubility limits of the inhibitors.     

Inhibition of XMRV and HIV-1 proteases by pepstatin A and acetyl-pepstatin

The kinetic properties of two classical inhibitors of aspartic proteases (PRs), pepstatin A and acetyl-pepstatin, were compared in their interactions with HIV-1 and xenotropic murine leukemia virus related virus (XMRV) PRs. Both compounds are substantially weaker inhibitors of XMRV PR than of HIV-1 PR. Previous kinetic and structural studies characterized HIV-1 PR-acetyl-pepstatin and XMRV PR-pepstatin A complexes and suggested dramatically different binding modes. Interaction energies were calculated for the possible binding modes and suggested a strong preference for the one-inhibitor binding mode for HIV-1 PR-acetyl-pepstatin and the two-inhibitor binding mode for XMRV PR-pepstatin A interactions. Comparison of the molecular models suggested that in the case of XMRV PR the relatively unfavorable interactions at S3' and the favorable interactions at S4 and S4' sites with the statine residues may shift the ground state binding towards the two-inhibitor binding mode, whereas the single molecule ground state binding of statines to the HIV-1 PR appear to be more favorable. The preferred single molecular binding to HIV-1 PR allows the formation of the transition state complex, represented by substantially better binding constants. Intriguingly, the crystal structure of the complex of acetyl-pepstatin with XMRV PR has shown a mixed type of binding: the unusual binding mode of two molecules of the inhibitor to the enzyme, in a mode very similar to the previously determined complex with pepstatin A, together with the classical binding mode found for HIV-1 PR. The structure is thus in good agreement with the very similar interaction energies calculated for the two types of binding. Database The final coordinates of the crystal structure of XMRV protease complexed with acetyl-pepstatin are available in the Protein Data Bank under the accession number 4EXH Structured digital abstract ? HIV-1 PR?and?HIV-1 PR?bind?by?biochemical?(View interaction) ? XMRV PR?cleaves?MLV Gag?by?enzymatic study?(View interaction) ? XMRV PR?and?XMRV PR?bind?by?biochemical?(View interaction) ? XMRV PR?and?XMRV PR?bind?by?x-ray crystallography?(View interaction).     

Hydrophobic sliding: a possible mechanism for drug resistance in human immunodeficiency virus type 1 protease

Hydrophobic residues outside the active site of HIV-1 protease frequently mutate in patients undergoing protease inhibitor therapy; however, the mechanism by which these mutations confer drug resistance is not understood. From analysis of molecular dynamics simulations, 19 core hydrophobic residues appear to facilitate the conformational changes that occur in HIV-1 protease. The hydrophobic core residues slide by each other, exchanging one hydrophobic van der Waal contact for another, with little energy penalty, while maintaining many structurally important hydrogen bonds. Such hydrophobic sliding may represent a general mechanism by which proteins undergo conformational changes. Mutation of these residues in HIV-1 protease would alter the packing of the hydrophobic core, affecting the conformational flexibility of the protease. Therefore these residues impact the dynamic balance between processing substrates and binding inhibitors, and thus contribute to drug resistance.     

Specific potassium binding stabilizes pI258 arsenate reductase from Staphylococcus aureus

Arsenate reductase (ArsC) from Staphylococcus aureus plasmid pI258 catalyzes the reduction of arsenate to arsenite and plays a role in bacterial heavy metal resistance. The high resolution x-ray structure of ArsC reveals the atomic details of the K+ binding site situated next to the catalytic P-loop structural motif of this redox enzyme. A full thermodynamic study of the binding characteristics of a series of monovalent cations (Li+, Na+, K+, Rb+, and Cs+) and their influence on the thermal stability of ArsC was performed with isothermal titration calorimetry, circular dichroism spectroscopy, and differential scanning calorimetry. Potassium has the largest affinity with a Ka of 3.8 x 10(3) m(-1), and the effectiveness of stabilization of ArsC by monovalent cations follows the binding affinity order: K+ > Rb+ > Cs+ > Na+ > Li+. A mutagenesis study on the K+ binding side chains showed that Asn-13 and Asp-65 are essential for potassium binding, but the impact on the stability of ArsC was the most extreme when mutating Ser-36. Additionally, the thermal stabilization by K+ is significantly reduced in the case of the ArsC E21A mutant, showing the importance of a Glu-21-coordinated water molecule in its contact with K+. Although potassium is not essential for catalysis, in its presence the kcat/KM increases with a factor of 5. Altogether, the interaction of K+ with specific residues in ArsC is an enthalpydriven process that stabilizes ArsC and increases the specific activity of this redox enzyme.     

Thermodynamic Analysis of the Binding of 2F5 (Fab and Immunoglobulin G Forms) to Its gp41 Epitope Reveals a Strong Influence of the Immunoglobulin Fc Region on Affinity

Immunotherapies and vaccines based on the induction of broadly neutralizing monoclonal antibodies (bNAbs) have become outstanding strategies against HIV-1. Diverse bNAbs recognizing different regions of the HIV-1 envelope have been identified and extensively studied. However, there is little information about the thermodynamics of binding of these bNAbs and their epitopes. We used isothermal titration calorimetry to characterize thermodynamically the interactions between bNAb 2F5 (in both the IgG and Fab forms) and its functional and core epitope peptides. We found that these interactions are enthalpically driven and opposed by a negative entropy change. The highest affinity was found for 2F5 IgG for its functional epitope, indicating that additional interactions involving residues flanking the core epitope contribute strongly to higher affinity. In addition, the strong influence of the Fc region on the binding affinity suggests long-range allosteric effects within IgG. Our results provide useful information for developing new therapeutics against HIV-1 and, in a broader scope, contribute to a better understanding of antigen-antibody recognition.