Phosphorylation causes subtle changes in solvent accessibility at the interdomain interface of methylesterase CheB.

The crystal structure of the unphosphorylated state of methylesterase CheB shows that the regulatory domain blocks access of substrate to the active site of the catalytic domain. Phosphorylation of CheB at Asp56 results in a catalytically active transiently phosphorylated enzyme with a lifetime of approximately two seconds. Solvent accessibility changes in this transiently phosphorylated state were probed by MALDI-TOF-detected amide hydrogen/deuterium exchange. No changes in solvent accessibility were seen in the regulatory domain upon phosphorylation of Asp56, but two regions in the catalytic domain (199-203 and 310-317) became more solvent accessible. These two regions flank the active site and contain domain-domain contact residues. Comparison with results from the isolated catalytic domain-containing C-terminal fragment of CheB (residues 147-349) showed that the increased solvent accessibility was less than would have occurred upon detachment of the regulatory domain. Thus, phosphorylation causes subtle changes in solvent accessibility at the interdomain interface of CheB.

Protein docking using continuum electrostatics and geometric fit.

The computer program DOT quickly finds low-energy docked structures for two proteins by performing a systematic search over six degrees of freedom. A novel feature of DOT is its energy function, which is the sum of both a Poisson-Boltzmann electrostatic energy and a van der Waals energy, each represented as a grid-based correlation function. DOT evaluates the energy of interaction for many orientations of the moving molecule and maintains separate lists scored by either the electrostatic energy, the van der Waals energy or the composite sum of both. The free energy is obtained by summing the Boltzmann factor over all rotations at each grid point. Three important findings are presented. First, for a wide variety of protein-protein interactions, the composite-energy function is shown to produce larger clusters of correct answers than found by scoring with either van der Waals energy (geometric fit) or electrostatic energy alone. Second, free-energy clusters are demonstrated to be indicators of binding sites. Third, the contributions of electrostatic and attractive van der Waals energies to the total energy term appropriately reflect the nature of the various types of protein-protein interactions studied.

Solvent accessibility of the thrombin-thrombomodulin interface.

The kinetics of solvent accessibility at the protein-protein interface between thrombin and a fragment of thrombomodulin, TMEGF45, have been monitored by amide hydrogen/deuterium (H/2H) exchange detected by MALDI-TOF mass spectrometry. The interaction is rapid and reversible, requiring development of theory and experimental methods to distinguish H/2H exchange due to solvent accessibility at the interface from H/2H exchange due to complex dissociation. Association and dissociation rate constants were measured by surface plasmon resonance and amide H/2H exchange rates were measured at different pH values and concentrations of TMEGF45. When essentially 100% of the thrombin was bound to TMEGF45, two segments of thrombin became completely solvent-inaccessible, as evidenced by the pH insensitivity of the amide H/2H exchange rates. These segments form part of anion-binding exosite I and contain the residues for which alanine substitution abolishes TM binding. Several other regions of thrombin showed slowing of amide exchange upon TMEGF45 binding, but the exchange remained pH-dependent, suggesting that these regions of thrombin were rendered only partially solvent-inaccessible by TMEGF45 binding. These partially inaccessible regions of thrombin form both surface and buried contacts into the active site of thrombin and contain residues implicated in allosteric changes in thrombin upon TM binding.

Identification of protein-protein interfaces by decreased amide proton solvent accessibility.

Matrix-assisted laser desorption ionization-time-of-flight mass spectrometry was used to identify peptic fragments from protein complexes that retained deuterium under hydrogen exchange conditions due to decreased solvent accessibility at the interface of the complex. Short deuteration times allowed preferential labeling of rapidly exchanging surface amides so that primarily solvent accessibility changes and not conformational changes were detected. A single mass spectrum of the peptic digest mixture was analyzed to determine the deuterium content of all proteolytic fragments of the protein. The protein-protein interface was reliably indicated by those peptides that retained more deuterons in the complex compared with control experiments in which only one protein was present. The method was used to identify the kinase inhibitor [PKI(5-24)] and ATP-binding sites in the cyclic-AMP-dependent protein kinase. Three overlapping peptides identified the ATP-binding site, three overlapping peptides identified the glycine-rich loop, and two peptides identified the PKI(5-24)-binding site. A complex of unknown structure also was analyzed, human alpha-thrombin bound to an 83-aa fragment of human thrombomodulin [TMEGF(4-5)]. Five peptides from thrombin showed significantly decreased solvent accessibility in the complex. Three peptides identified the anion-binding exosite I, confirming ligand competition experiments. Two peptides identified a new region of thrombin near the active site providing a potential mechanism of how thrombomodulin alters thrombin substrate specificity.

Measurement of amide hydrogen exchange by MALDI-TOF mass spectrometry.

Matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry (MS) was used to determine amide proton/deuteron (H/D) exchange rates. The method has broad application to the study of protein conformation and folding and to the study of protein-ligand interactions and requires no modifications of the instrument. Amide protons were allowed to exchange with deuterons in buffered D2O at room temperature, pD 7.25. Exchanged deuterons were "frozen" in the exchanged state by quenching at pH 2.5, 0 degree C and analyzed by MALDI-TOF MS. The matrix mixture consisted of 5 mg/mL alpha-cyano-4-hydroxycinnamic acid, acetonitrile, ethanol, and 0.1% TFA. The matrix was adjusted to pH 2.5, and the chilled MALDI target was rapidly dried. Deuteration of amide protons on cyclic AMP-dependent protein kinase was measured after short times of incubation in deuterium by pepsin protein digestion and MALDI-TOF MS analysis. The unseparated peptic digest was analyzed in a single spectrum of the mixture. From five spectra, H/D exchange rates were determined for some 40 peptides covering 65% of the protein sequence.