Extracellular-regulated kinase 2 is activated by the enhancement of hinge flexibility.

Protein motions underlie conformational and entropic contributions to enzyme catalysis; however, relatively little is known about the ways in which this occurs. Studies of the mitogen-activated protein kinase ERK2 (extracellular-regulated protein kinase 2) by hydrogen-exchange mass spectrometry suggest that activation enhances backbone flexibility at the linker between N- and C-terminal domains while altering nucleotide binding mode. Here, we address the hypothesis that enhanced backbone flexibility within the hinge region facilitates kinase activation. We show that hinge mutations enhancing flexibility promote changes in the nucleotide binding mode consistent with domain movement, without requiring phosphorylation. They also lead to the activation of monophosphorylated ERK2, a form that is normally inactive. The hinge mutations bypass the need for pTyr but not pThr, suggesting that Tyr phosphorylation controls hinge motions. In agreement, monophosphorylation of pTyr enhances both hinge flexibility and nucleotide binding mode, measured by hydrogen-exchange mass spectrometry. Our findings demonstrate that regulated protein motions underlie kinase activation. Our working model is that constraints to domain movement in ERK2 are overcome by phosphorylation at pTyr, which increases hinge dynamics to promote the active conformation of the catalytic site.

Comparative hydrogen-deuterium exchange for a mesophilic vs thermophilic dihydrofolate reductase at 25 °C: identification of a single active site region with enhanced flexibility in the mesophilic protein.

The technique of hydrogen-deuterium exchange coupled to mass spectrometry (HDX-MS) has been applied to a mesophilic (E. coli) dihydrofolate reductase under conditions that allow direct comparison to a thermophilic (B. stearothermophilus) ortholog, Ec-DHFR and Bs-DHFR, respectively. The analysis of hydrogen-deuterium exchange patterns within proteolytically derived peptides allows spatial resolution, while requiring a series of controls to compare orthologous proteins with only ca. 40% sequence identity. These controls include the determination of primary structure effects on intrinsic rate constants for HDX as well as the use of existing 3-dimensional structures to evaluate the distance of each backbone amide hydrogen to the protein surface. Only a single peptide from the Ec-DHFR is found to be substantially more flexible than the Bs-DHFR at 25 °C in a region located within the protein interior at the intersection of the cofactor and substrate-binding sites. The surrounding regions of the enzyme are either unchanged or more flexible in the thermophilic DHFR from B. stearothermophilus. The region with increased flexibility in Ec-DHFR corresponds to one of two regions previously proposed to control the enthalpic barrier for hydride transfer in Bs-DHFR [Oyeyemi et al. (2010) Proc. Natl. Acad. Sci. U.S.A. 107, 10074].

Distinct patterns of activation-dependent changes in conformational mobility between ERK1 and ERK2.

Hydrogen/deuterium exchange measurements by mass spectrometry (HX-MS) can be used to report localized conformational mobility within folded proteins, where exchange predominantly occurs through low energy fluctuations in structure, allowing transient solvent exposure. Changes in conformational mobility may impact protein function, even in cases where structural changes are unobservable. Previous studies of the MAP kinase, ERK2, revealed increases in HX upon activation occured at the hinge between conserved N- and C-terminal domains, which could be ascribed to enhanced backbone flexibility. This implied that kinase activation modulates interdomain closure, and was supported by evidence for two modes of nucleotide binding that were consistent with closed vs open conformations in active vs inactive forms of ERK2, respectively. Thus, phosphorylation of ERK2 releases constraints to interdomain closure, by modulating hinge flexibility. In this study, we examined ERK1, which shares 90% sequence identity with ERK2. HX-MS measurements of ERK1 showed similarities with ERK2 in overall deuteration, consistent with their similar tertiary structures. However, the patterns of HX that were altered upon activation of ERK1 differed from those in ERK2. In particular, alterations in HX at the hinge region upon activation of ERK2 did not occur in ERK1, suggesting that the two enzymes differ with respect to their regulation of hinge mobility and interdomain closure. In agreement, HX-MS measurements of nucleotide binding suggested revealed domain closure in both inactive and active forms of ERK1. We conclude that although ERK1 and ERK2 are closely related with respect to primary sequence and tertiary structure, they utilize distinct mechanisms for controlling enzyme function through interdomain interactions.

Analysis of MAP kinases by hydrogen exchange mass spectrometry.

Hydrogen exchange mass spectrometry (HX-MS) is an experimental technique that can be used to -examine solvent accessibility and conformational mobility in biological macromolecules. This chapter summarizes studies using HX-MS to examine the regulation of conformation, protein mobility, and ligand binding to MAP kinases. We describe the planning and design of HX-MS experiments, strategies for data analysis and interpretation, and available software.

Temperature dependence of protein motions in a thermophilic dihydrofolate reductase and its relationship to catalytic efficiency.

We report hydrogen deuterium exchange by mass spectrometry (HDX-MS) as a function of temperature in a thermophilic dihydrofolate reductase from Bacillus stearothermophilus (Bs-DHFR). Protein stability, probed with circular dichroism, established an accessible temperature range of 10 degrees C to 55 degrees C for the interrogation of HDX-MS. Although both the rate and extent of HDX are sensitive to temperature, the majority of peptides showed rapid kinetics of exchange, allowing us to focus on plateau values for the maximal extent of exchange at each temperature. Arrhenius plots of the ratio of hydrogens exchanged at 5 h normalized to the number of exchangeable hydrogens vs. 1/T provides an estimate for the apparent enthalpic change of local unfolding, DeltaH degrees (unf(avg)). Most regions in the enzyme show DeltaH degrees (unf(avg)) < or = 2.0 kcal/mol, close to the value of kT; by contrast, significantly elevated values for DeltaH degrees (unf(avg)) are observed in regions within the core of protein that contain the cofactor and substrate-binding sites. Our technique introduces a new strategy for probing the temperature dependence of local protein unfolding within native proteins. These findings are discussed in the context of the demonstrated role for nuclear tunneling in hydride transfer from NADPH to dihydrofolate, and relate the observed enthalpic changes to two classes of motion, preorganization and reorganization, that have been proposed to control the efficiency of hydrogenic wave function overlap. Our findings suggest that the enthalpic contribution to the heavy atom environmental reorganizations controlling the hydrogenic wave function overlap will be dominated by regions of the protein proximal to the bound cofactor and substrate.

Hydrogen-exchange mass spectrometry reveals activation-induced changes in the conformational mobility of p38alpha MAP kinase.

Hydrogen-deuterium exchange measurements represent a powerful approach to investigating changes in conformation and conformational mobility in proteins. Here, we examine p38alpha MAP kinase (MAPK) by hydrogen-exchange (HX) mass spectrometry to determine whether changes in conformational mobility may be induced by kinase phosphorylation and activation. Factors influencing sequence coverage in the HX mass spectrometry experiment, which show that varying sampling depths, instruments, and peptide search strategies yield the highest coverage of exchangeable amides, are examined. Patterns of regional deuteration in p38alpha are consistent with tertiary structure and similar to deuteration patterns previously determined for extracellular-signal-regulated kinase (ERK) 2, indicating that MAPKs are conserved with respect to the extent of local amide HX. Activation of p38alpha alters HX in five regions, which are interpreted by comparing X-ray structures of unphosphorylated p38alpha and X-ray structures of phosphorylated p38gamma. Conformational differences account for altered HX within the activation lip, the P+1 site, and the active site. In contrast, HX alterations are ascribed to activation-induced effects on conformational mobility, within substrate-docking sites (alphaF-alphaG, beta7-beta8), the C-terminal core (alphaE), and the N-terminal core region (beta4-beta5, alphaL16, alphaC). Activation also decreases HX in a 3-10 helix at the C-terminal extension of p38alpha. Although this helix in ERK2 forms a dimerization interface that becomes protected from HX upon activation, analytical ultracentrifugation shows that this does not occur in p38alpha because both unphosphorylated and diphosphorylated forms are monomeric. Finally, HX patterns in monophosphorylated p38alpha are similar to those in unphosphorylated kinase, indicating that the major activation lip remodeling events occur only after diphosphorylation. Importantly, patterns of activation-induced HX show differences between p38alpha and ERK2 despite their similarities in overall deuteration, suggesting that although MAPKs are closely related with respect to primary sequence and tertiary structure, they have distinct mechanisms for dynamic control of enzyme function.