Price for Opening the Transient Specificity Pocket in Human Aldose Reductase upon Ligand Binding: Structural, Thermodynamic, Kinetic, and Computational Analysis

Insights into the thermodynamic and kinetic signature of the transient opening of a protein-binding pocket resulting from accommodation of suitable substituents attached to a given parent ligand scaffold are presented. As a target, we selected human aldose reductase, an enzyme involved in the development of late-stage diabetic complications. To recognize a large scope of substrate molecules, this reductase opens a transient specificity pocket. The pocket-opening step was studied by X-ray crystallography, microcalorimetry, and surface plasmon resonance using a narrow series of 2-carbamoyl-phenoxy-acetic acid derivatives. Molecular dynamics simulations suggest that pocket opening occurs only once an appropriate substituent is attached to the parent scaffold. Transient pocket opening of the uncomplexed protein is hardly recorded. Hydration-site analysis suggests that up to five water molecules entering the opened pocket cannot stabilize this state. Sole substitution with a benzyl group stabilizes the opened state, and the energetic barrier for opening is estimated to be ∼5 kJ/mol. Additional decoration of the pocket-opening benzyl substituent with a nitro group results in a huge enthalpy-driven potency increase; on the other hand, an isosteric carboxylic acid group reduces the potency 1000-fold, and binding occurs without pocket opening. We suggest a ligand induced-fit mechanism for the pocket-opening step, which, however, does not represent the rate-determining step in binding kinetics.

Mapping the Interactions of Selective Biochemical Probes of Antibody Conformation by Hydrogen-Deuterium Exchange Mass Spectrometry

Protein-based pharmaceuticals represent the fastest growing group of drugs in development in the pharmaceutical industry. One of the major challenges in the discovery, development, and distribution of biopharmaceuticals is the assessment of changes in their higher-order structure due to chemical modification. Here, we investigated the interactions of three different biochemical probes (F_ab s) generated to detect conformational changes in a therapeutic IgG1 antibody (mAbX) by local hydrogen-deuterium exchange mass spectrometry (HDX-MS). We show that two of the probes target the F_c part of the antibody, whereas the third probe binds to the hinge region. Through HDX-ETD, we could distinguish specific binding patterns of the F_c -binding probes on mAbX at the amino-acid level. Preliminary surface plasmon resonance (SPR) experiments showed that these domain-selective F_ab probes are sensitive to conformational changes in distinct regions of a full-length therapeutic antibody upon oxidation.

Family-wide chemical profiling and structural analysis of PARP and tankyrase inhibitors

Inhibitors of poly-ADP-ribose polymerase (PARP) family proteins are currently in clinical trials as cancer therapeutics, yet the specificity of many of these compounds is unknown. Here we evaluated a series of 185 small-molecule inhibitors, including research reagents and compounds being tested clinically, for the ability to bind to the catalytic domains of 13 of the 17 human PARP family members including the tankyrases, TNKS1 and TNKS2. Many of the best-known inhibitors, including TIQ-A, 6(5H)-phenanthridinone, olaparib, ABT-888 and rucaparib, bound to several PARP family members, suggesting that these molecules lack specificity and have promiscuous inhibitory activity. We also determined X-ray crystal structures for five TNKS2 ligand complexes and four PARP14 ligand complexes. In addition to showing that the majority of PARP inhibitors bind multiple targets, these results provide insight into the design of new inhibitors.

The importance of correct protein concentration for kinetics and affinity determination in structure-function analysis

In this study, we explore the interaction between the bovine cysteine protease inhibitor cystatin B and a catalytically inactive form of papain (Fig. 1), a plant cysteine protease, by real-time label-free analysis using Biacore X100. Several cystatin B variants with point mutations in areas of interaction with papain, are produced. For each cystatin B variant we determine its specific binding concentration using calibration-free concentration analysis (CFCA) and compare the values obtained with total protein concentration as determined by A(280). After that, the kinetics of each cystatin B variant binding to papain is measured using single-cycle kinetics (SCK). We show that one of the four cystatin B variants we examine is only partially active for binding. This partial activity, revealed by CFCA, translates to a significant difference in the association rate constant (k(a)) and affinity (K(D)), compared to the values calculated using total protein concentration. Using CFCA in combination with kinetic analysis in a structure-function study contributes to obtaining reliable results, and helps to make the right interpretation of the interaction mechanism.

A global benchmark study using affinity-based biosensors

To explore the variability in biosensor studies, 150 participants from 20 countries were given the same protein samples and asked to determine kinetic rate constants for the interaction. We chose a protein system that was amenable to analysis using different biosensor platforms as well as by users of different expertise levels. The two proteins (a 50-kDa Fab and a 60-kDa glutathione S-transferase [GST] antigen) form a relatively high-affinity complex, so participants needed to optimize several experimental parameters, including ligand immobilization and regeneration conditions as well as analyte concentrations and injection/dissociation times. Although most participants collected binding responses that could be fit to yield kinetic parameters, the quality of a few data sets could have been improved by optimizing the assay design. Once these outliers were removed, the average reported affinity across the remaining panel of participants was 620 pM with a standard deviation of 980 pM. These results demonstrate that when this biosensor assay was designed and executed appropriately, the reported rate constants were consistent, and independent of which protein was immobilized and which biosensor was used.

Biosensor-based characterization of serum antibodies during development of an anti-IgE immunotherapeutic against allergy and asthma

Antibody responses, induced in Cynomolgus monkey by recombinant IgE-derived immunotherapeutic protein against atopic allergies and asthma, were characterized using label-free, real-time protein interaction analysis. The effects of two different immunotherapeutic proteins were compared. Active concentrations of specific anti-IgE antibodies formed were determined in sera sampled at multiple time points, using conditions of total mass transport limitation that were proved to exist on the sensor surface. These concentrations varied from about 0.4 to 35 microg/ml among the monkeys and throughout the immunization period. Based on these concentrations, the rate and affinity constants for the binding of antibody populations to the antigen could be determined. The apparent equilibrium dissociation constant decreased during the immunization period, for all the monkeys, by a factor between 6 and 50, ending at values from approximately 2 x 10(-9) to approximately 2 x 10(-11) M among the animals. This affinity maturation was attributable to the changes in both rate constants, although the magnitude of the contribution of each constant depended partly on specimen, but primarily on the immunotherapeutic used. The immunotherapeutic proteins examined showed excellent immunogenic properties, providing the basis for a new and effective treatment for allergy and asthma.

Kinetic mechanism of deoxyadenosine kinase from Mycoplasma determined by surface plasmon resonance technology

Surface plasmon resonance (SPR) detection technology was employed to investigate the kinetic mechanism of deoxyadenosine kinase from Mycoplasma mycoides ssp. mycoides SC. In our experimental approach, the enzyme was attached to the sensor surface, the reactants were injected in the mobile phase, and the product-enzyme complex formation was measured using the fact that the rate of product formation exceeds that of its dissociation. The pre-steady-state analysis of deoxyguanosine phosphorylation showed the presence of a burst phase, which is consistent with product dissociation being a rate-limiting step. High activity of the immobilized enzyme was demonstrated by analyzing the reaction mixture eluted from the chip and by determining the Michaelis-Menten constants for several phosphate acceptors (e.g., deoxyadenosine) and phosphate donors (e.g., ATP) using SPR detection. These values were in good agreement with those reported previously [Wang, L. et al. (2001) Mol. Microbiol. 42, 1065-1073]. The bisubstrate initial rate pattern obtained was characteristic of a sequential kinetic mechanism. Because in the method applied here it is the mass change on the surface that is monitored, a new mathematical approach to interpreting product inhibition experiments was proposed. According to that approach, product inhibition studies, supported by product binding experiments, indicated that the reaction mechanism was of Bi Bi sequential ordered type, involving the formation of a ternary complex, in which ATP and deoxyadenosine bound sequentially, followed by a transfer of the phosphate group, and an ordered release of products with ADP dissociating before dAMP.

Analyzing a kinetic titration series using affinity biosensors

The classical method of measuring binding constants with affinity-based biosensors involves testing several analyte concentrations over the same ligand surface and regenerating the surface between binding cycles. Here we describe an alternative approach to collecting kinetic binding data, which we call "kinetic titration." This method involves sequentially injecting an analyte concentration series without any regeneration steps. Through a combination of simulation and experimentation, we show that this method can be as robust as the classical method of analysis. In addition, kinetic titrations can be more efficient than the conventional data collection method and allow us to fully characterize analyte binding to ligand surfaces that are difficult to regenerate.

Contributions of individual residues in the N-terminal region of cystatin B (stefin B) to inhibition of cysteine proteinases

The importance of individual residues in the N-terminal region of cystatin B for proteinase inhibition was elucidated by measurements of the affinity and kinetics of binding of N-terminally truncated, recombinant variants of the bovine inhibitor to cysteine proteinases. Removal of Met-1 caused an 8- to 10-fold lower affinity for papain and cathepsin B, decreased the affinity also for cathepsin L but only minimally affected cathepsin H affinity. Additional truncation of Met-2 further weakened the binding to papain and cathepsin B by 40-70-fold, whereas the affinity for cathepsins L and H was essentially unaffected. Removal of Cys-3 had the most drastic effects on the interactions, resulting in a further affinity decrease of approximately 1500-fold for papain, approximately 700-fold for cathepsin L and approximately 15-fold for cathepsin H; the binding to cathepsin B could not be assessed. The binding kinetics could only be evaluated for papain and cathepsin H and showed that the reduced affinities for these enzymes were predominantly due to increased dissociation rate constants. These results demonstrate that the N-terminal region of cystatin B contributes appreciably to proteinase inhibition, in contrast to previous proposals. It is responsible for 12-40% of the total binding energy of the inhibitor to the proteinases investigated, being of least importance for cathepsin H binding. Cys-3 is the most important residue of the N-terminal region for inhibition of papain, cathepsin L and cathepsin H, the role of the other residues of this region varying with the target proteinase.

Role of the single cysteine residue, Cys 3, of human and bovine cystatin B (stefin B) in the inhibition of cysteine proteinases

Cystatin B is unique among cysteine proteinase inhibitors of the cystatin superfamily in having a free Cys in the N-terminal segment of the proteinase binding region. The importance of this residue for inhibition of target proteinases was assessed by studies of the affinity and kinetics of interaction of human and bovine wild-type cystatin B and the Cys 3-to-Ser mutants of the inhibitors with papain and cathepsins L, H, and B. The wild-type forms from the two species had about the same affinity for each proteinase, binding tightly to papain and cathepsin L and more weakly to cathepsins H and B. In general, these affinities were appreciably higher than those reported earlier, perhaps because of irreversible oxidation of Cys 3 in previous work. The Cys-to-Ser mutation resulted in weaker binding of cystatin B to all four proteinases examined, the effect varying with both the proteinase and the species variant of the inhibitor. The affinities of the human inhibitor for papain and cathepsin H were decreased by threefold to fourfold and that for cathepsin B by approximately 20-fold, whereas the reductions in the affinities of the bovine inhibitor for papain and cathepsins H and B were approximately 14-fold, approximately 10-fold and approximately 300-fold, respectively. The decreases in affinity for cathepsin L could not be properly quantified but were greater than threefold. Increased dissociation rate constants were responsible for the weaker binding of both mutants to papain. By contrast, the reduced affinities for cathepsins H and B were due to decreased association rate constants. Cys 3 of both human and bovine cystatin B is thus of appreciable importance for inhibition of cysteine proteinases, in particular cathepsin B.

Importance of the second binding loop and the C-terminal end of cystatin B (stefin B) for inhibition of cysteine proteinases

The importance of residues in the second hairpin loop and the C-terminal end of mammalian cystatin B for binding of proteinases was elucidated by mutagenesis of the bovine inhibitor. Bovine cystatin B was modeled onto the crystal structure of the human inhibitor in complex with papain with minimal structural changes. Substitution of the two deduced contact residues in the second hairpin loop, Leu-73 and His-75, with Gly resulted in appreciably reduced affinities for papain and cathepsins H and B. These losses indicated that the two residues together contribute 20-30% of the free energy of binding of cystatin B to these enzymes and that Leu-73 is responsible for most of this contribution. In contrast, the small decrease in the affinity for cathepsin L suggested that the second hairpin loop is less important for inhibition of this proteinase. Replacement of the contact residue in the C-terminal end, Tyr-97, with Ala resulted in losses in affinity for papain and cathepsins L and H that were consistent with Tyr-97 contributing 6-12% of the energy of binding of cystatin B to these enzymes. However, this substitution minimally affected the affinity for cathepsin B, indicating that the C-terminal end is of limited importance for binding of this proteinase. All affinity decreases were due predominantly to increased dissociation rate constants. These results show that both the second hairpin loop and the C-terminal end of cystatin B contribute to anchoring the inhibitor to target proteinases, each of the two regions interacting with a different domain of the enzyme. However, the relative contributions of these two interactions vary with the proteinase.

The importance of the second hairpin loop of cystatin C for proteinase binding. Characterization of the interaction of Trp-106 variants of the inhibitor with cysteine proteinases

The single Trp of human cystatin C, Trp-106, is located in the second hairpin loop of the proteinase binding surface. Substitution of this residue by Gly markedly altered the spectroscopic changes accompanying papain binding and reduced the affinity for papain, actinidin, and cathepsins B and H by 300-900-fold. The decrease in affinity indicated that the side chain of Trp-106 contributes a similar free energy, -14 to -17 kJ.mol-1, to the binding to all four cysteine proteinases, corresponding to about 20-30% of the total binding energy. Replacement of Trp-106 by Phe led to a smaller (30-120-fold) decrease in affinity for the four enzymes than Gly substitution. The binding energy of the Phe residue corresponded to 20-45% of that of Trp, showing that a phenyl group can only partly substitute for the indole ring. The reduced affinities of the cystatin C Trp-106 variants for all proteinases studied were due almost exclusively to increased dissociation rate constants. The second hairpin loop thus contributes to the binding primarily by keeping cystatin C anchored to the proteinase once the complex has been formed. This role is partly in contrast to that of the N-terminal region, which increases the affinity of cystatin C for cathepsin B by increasing the association rate constant. Removal of the N-terminal region of the Trp-106-->Gly variant by proteolytic cleavage substantially weakened the binding to papain and cathepsin B. The resulting affinity indicated that the first hairpin loop (the "QVVAG-region"), which is the only region of the proteinase binding surface remaining intact in the truncated variant, contributes 40-60% of the total free energy of binding of cystatin C to both proteinases.

Characterization by spectroscopic, kinetic and equilibrium methods of the interaction between recombinant human cystatin A (stefin A) and cysteine proteinases

The near-UV spectroscopic changes induced by the binding of recombinant human cystatin A to papain were appreciably different from those induced by cystatin C, reflecting mainly interactions involving the single tryptophan of cystatin C, Trp-106. Cystatin A bound tightly and rapidly to papain and cathepsin L, with dissociation equilibrium constants of approximately 10(-11)-10(-13) M and association rate constants of 3 x 10(6)-5 x 10(6) M-1.s-1. These affinities are at least 50-100-fold higher than previously reported values. The kinetics of binding to papain were consistent with a simple reversible bimolecular reaction mechanism, indicating that cystatin A, like chicken cystatin and cystatin C, binds to papain with no appreciable conformational adaptation of either reacting protein. Cystatin A bound more weakly to actinidin and cathepsins B, C and H, with dissociation equilibrium constants of 10(-8)-10(-9) M. The weaker binding to cathepsin B was largely due to a considerably reduced association rate constant (approximately 4 x 10(4) M-1.s-1), consistent with the 'occluding loop' of cathepsin B markedly restricting the access of cystatin A to the active site. The lower affinities for actinidin and cathepsins C and H were due partly to lower association rate constants (2 x 10(5)-6 x 10(5) M-1.s-1) but primarily to higher dissociation rate constants. The mode of binding of cystatin A to inactivated papains indicated that there is appreciably less space around the active-site cysteine of papain in the complex with cystatin A than in the complexes with chicken cystatin and cystatin C. An N-terminally truncated form of cystatin A, lacking the first six residues, had considerably lower affinity for papain than the full-length inhibitor, consistent with an intact N-terminal region being of importance for proteinase binding.

Differential changes in the association and dissociation rate constants for binding of cystatins to target proteinases occurring on N-terminal truncation of the inhibitors indicate that the interaction mechanism varies with different enzymes

The importance of the N-terminal region of human cystatin C or chicken cystatin for the kinetics of interactions of the inhibitors with four cysteine proteinases was characterized. The association rate constants for the binding of recombinant human cystatin C to papain, ficin, actinidin and recombinant rat cathepsin B were 1.1 x 10(7), 7.0 x 10(6), 2.4 x 10(6) and 1.4 x 10(6) M-1.s-1, whereas the corresponding dissociation rate constants were 1.3 x 10(-7), 9.2 x 10(-6), 4.6 x 10(-2) and 3.5 x 10(-4) s-1. N-Terminal truncation of the first ten residues of the inhibitor negligibly affected the association rate constant with papain or ficin, but increased the dissociation rate constant approx. 3 x 10(4)- to 2 x 10(6)-fold. In contrast, such truncation decreased the association rate constant with cathepsin B approx. 60-fold, while minimally affecting the dissociation rate constant. With actinidin, the truncated cystatin C had both an approx. 15-fold lower association rate constant and an approx. 15-fold higher dissociation rate constant than the intact inhibitor. Similar results were obtained for intact and N-terminally truncated chicken cystatin. The decreased affinity of human cystatin C or chicken cystatin for cysteine proteinases after removal of the N-terminal region is thus due to either a decreased association rate constant or an increased dissociation rate constant, or both, depending on the enzyme. This behaviour indicates that the contribution of the N-terminal segment of the two inhibitors to the interaction mechanism varies with the target proteinase as a result of structural differences in the active-site region of the enzyme.

Characterization by rapid-kinetic and equilibrium methods of the interaction between N-terminally truncated forms of chicken cystatin and the cysteine proteinases papain and actinidin

The interaction between five N-terminally truncated forms of chicken cystatin (starting at Leu-7, Leu-8, Gly-9, Ala-10 and Asp-15) and the cysteine proteinases papain and actinidin was studied by spectroscopic, kinetic and equilibrium methods. The u.v. absorption, near-u.v. c.d. and fluorescence emission difference spectra for the interactions with papain were all similar to the corresponding spectra for intact cystatin. The second-order association rate constants at 25 degrees C, pH 7.4, I 0.15, for the binding of the truncated forms to papain varied about 2-fold, from 6 x 10(6) to 1.5 x 10(7) M-1.s-1, and were comparable to the value of 9.9 x 10(6) M-1.s-1 for intact cystatin. In contrast, the rate constants for the dissociation of the complexes with papain increased markedly with increasing extent of truncation, from 7.5 x 10(-6)s-1 for Leu7 cystatin (a truncated form of cystatin having Leu-7 as its N-terminal amino acid) to 1.6s-1 for Ala10-cystatin, whereas the dissociation rate constants for the latter form and Asp15-cystatin were similar. Consequently, the binding affinities between the truncated cystatins and papain decreased in an analogous manner, as was also shown for the interaction with actinidin by equilibrium measurements. Studies of the binding of the truncated cystatins to inactivated papains indicated that small substituents on the active-site cysteine of the enzyme can be accommodated in the complex without any loss of affinity when the N-terminal segment of the inhibitor is removed. Taken together, the results suggest that in the N-terminal region of chicken cystatin only residues preceding Ala-10 participate in the interaction with proteinases. Of these residues, Leu-7 and Leu-8 together account for about two-thirds of the unitary free energy of binding contributed by the N-terminal region, the relative importance of the two residues being dependent on the target proteinase. Both Gly-9 and residues N-terminal of Leu-7 further stabilize the interaction but contribute substantially smaller binding energies than do the two leucine residues.

Biphasic transition curve on denaturation of chicken cystatin by guanidinium chloride. Evidence for an independently unfolding structural region

Far-ultraviolet circular dichroism and tryptophan fluorescence measurements showed that the reversible unfolding of the cysteine proteinase inhibitor, chicken cystatin, by guanidinium chloride is a two-step process with transition midpoints at approximately 3.4 and approximately 5.4 M denaturant. The partially unfolded intermediate had both far- and near-ultraviolet circular dichroism and fluorescence emission spectra comparable to those of the native protein. The largely retained tertiary structure suggests that the intermediate represents a species in which a separate region of lower stability has been unfolded, rather than an intermediate of the 'molten globule' type. Such a structurally independent region is apparent in the three-dimensional structure of the inhibitor.

Perceived parental rearing styles of agoraphobic and socially phobic in-patients

The perceived parental rearing practices and attitudes of agoraphobics, social phobics and non-patient normal controls were investigated, employing the EMBU, an inventory for assessing memories of upbringing. Findings obtained previously with out-patients were replicated with in-patients as subjects. Compared with the controls, agoraphobics rated both their parents as having been less emotionally warm but only their mothers as having been rejective. Socially phobic in-patients rated both their parents as having been rejective, as having lacked emotional warmth, and as having been over-protective. Comparisons between agoraphobics and social phobics showed differences in certain aspects of parental rearing, with the socially phobic in-patients assigning ratings more negatively than the agoraphobic group.