Protein motions control enzyme catalysis through mechanisms that are incompletely understood. Here NMR 13 C relaxation dispersion experiments were used to monitor changes in side-chain motions that occur in response to activation by phosphorylation of the MAP kinase ERK2. NMR data for the methyl side chains on Ile, Leu, and Val residues showed changes in conformational exchange dynamics in the microsecond-to-millisecond time regime between the different activity states of ERK2. In inactive, unphosphorylated ERK2, localized conformational exchange was observed among methyl side chains, with little evidence for coupling between residues. Upon dual phosphorylation by MAP kinase kinase 1, the dynamics of assigned methyls in ERK2 were altered throughout the conserved kinase core, including many residues in the catalytic pocket. The majority of residues in active ERK2 fit to a single conformational exchange process, with k ex ≈ 300 s −1 (k AB ≈ 240 s −1 /k BA ≈ 60 s −1 ) and p A /p B ≈ 20%/80%, suggesting global domain motions involving interconversion between two states. A mutant of ERK2, engineered to enhance conformational mobility at the hinge region linking the N-and C-terminal domains, also induced two-state conformational exchange throughout the kinase core, with exchange properties of k ex ≈ 500 s −1 (k AB ≈ 15 s −1 /k BA ≈ 485 s −1 ) and p A /p B ≈ 97%/3%. Thus, phosphorylation and activation of ERK2 lead to a dramatic shift in conformational exchange dynamics, likely through release of constraints at the hinge.T he MAP kinase, extracellular signal-regulated kinase 2 (ERK2), is a key regulator of cell signaling and a model for protein kinase activation mechanisms (1). ERK2 can be activated by MAP kinase kinases 1 and 2 (MKK1 and 2) through dual phosphorylation of Thr and Tyr residues located at the activation loop (Thr183 and Tyr185, numbered in rat ERK2) (1, 2). Phosphorylation at both sites is required for kinase activation, resulting in increased phosphoryl transfer rate and enhanced affinity for ATP and substrate (3).Conformational changes accompanying the activation of ERK2 have been documented by X-ray structures of the inactive, unphosphorylated (0P-ERK2) and the active, dual-phosphorylated (2P-ERK2) forms (4, 5). Phosphorylation rearranges the activation loop, leading to new ion-pair interactions between phosphoThr and phospho-Tyr residues and basic residues in the N-and C-terminal domains of the kinase core structure. This leads to a repositioning of active site residues surrounding the catalytic base, enabling recognition of the Ser/Thr-Pro sequence motif at phosphorylation sites and exposing a recognition site for interactions with docking sequences in substrates and scaffolds (6).Less is known about how changes in internal motions contribute to kinase activation. Previous studies using hydrogenexchange mass spectrometry (HX-MS) and electron paramagnetic resonance spectroscopy (7-9) led to a model where conformational mobility at the hinge linking the N-and C-terminal domains is increased by phosph...
ClpB N-terminal domain plays a regulatory role in protein disaggregation
ClpB/Hsp100 is an ATP-dependent disaggregase that solubilizes and reactivates protein aggregates in cooperation with the DnaK/ Hsp70 chaperone system. The ClpB-substrate interaction is mediated by conserved tyrosine residues located in flexible loops in nucleotide-binding domain-1 that extend into the ClpB central pore. In addition to the tyrosines, the ClpB N-terminal domain (NTD) was suggested to provide a second substrate-binding site; however, the manner in which the NTD recognizes and binds substrate proteins has remained elusive. Herein, we present an NMR spectroscopy study to structurally characterize the NTD-substrate interaction. We show that the NTD includes a substrate-binding groove that specifically recognizes exposed hydrophobic stretches in unfolded or aggregated client proteins. Using an optimized segmental labeling technique in combination with methyl-transverse relaxation optimized spectroscopy (TROSY) NMR, the interaction of client proteins with both the NTD and the pore-loop tyrosines in the 580-kDa ClpB hexamer has been characterized. Unlike contacts with the tyrosines, the NTD-substrate interaction is independent of the ClpB nucleotide state and protein conformational changes that result from ATP hydrolysis. The NTD interaction destabilizes client proteins, priming them for subsequent unfolding and translocation. Mutations in the NTD substrate-binding groove are shown to have a dramatic effect on protein translocation through the ClpB central pore, suggesting that, before their interaction with substrates, the NTDs block the translocation channel. Together, our findings provide both a detailed characterization of the NTD-substrate complex and insight into the functional regulatory role of the ClpB NTD in protein disaggregation.T he heat shock protein ClpB (Escherichia coli) or Hsp100 (eukaryotes) is the main protein disaggregase in bacteria, yeast, plants, and mitochondria of all eukaryotic cells, and it is essential for cell survival during severe stress (1-4). Recovery of functional proteins from aggregates by ClpB requires the synergistic interaction with a second molecular chaperone, DnaK (1). Through its cochaperone, DnaJ, DnaK initially binds to the aggregates, leading to the exposure of peptide segments that can be recognized by ClpB (5, 6). DnaK then recruits ClpB to the site of aggregation through direct physical interaction (7, 8), transferring the aggregate to ClpB. Using the energy derived from ATP hydrolysis, ClpB unravels the aggregate by threading single polypeptide chains, one at a time, through the central pore of its hexameric ring (9). Once released from the aggregate, the unfolded polypeptides can either refold spontaneously or fold with the help of additional cellular chaperones.Like other Hsp100 proteins, ClpB forms a hexameric ring, with each protomer comprising an N-terminal domain (NTD) and two nucleotide binding domains (NBD1 and NBD2) separated by a unique regulatory coil-coil domain (10) essential for DnaK binding (7, 11) ( Fig. 1 A and B). Both NBDs contain Walk...
Proper functioning of RNAs requires the formation of complex three-dimensional structures combined with the ability to rapidly interconvert between multiple functional states. This review covers recent advances in isotope-labeling strategies and NMR experimental approaches that have promise for facilitating solution structure determinations and dynamics studies of biologically active RNAs. Improved methods for the production of isotopically labeled RNAs combined with new multidimensional heteronuclear NMR experiments make it possible to dramatically reduce spectral crowding and simplify resonance assignments for RNAs. Several novel applications of experiments that directly detect hydrogen-bonding interactions are discussed. These studies demonstrate how NMR spectroscopy can be used to distinguish between possible secondary structures and identify mechanisms of ligand binding in RNAs. A variety of recently developed methods for measuring base and sugar residual dipolar couplings are described. NMR residual dipolar coupling techniques provide valuable data for determining the long-range structure and orientation of helical regions in RNAs. A number of studies are also presented where residual dipolar coupling constraints are used to determine the global structure and dynamics of RNAs. NMR relaxation data can be used to probe the dynamics of macromolecules in solution. The power dependence of transverse rotating-frame relaxation rates was used here to study dynamics in the minimal hammerhead ribozyme. Improved methods for isotopically labeling RNAs combined with new types of structural data obtained from a growing repertoire of NMR experiments are facilitating structural and dynamic studies of larger RNAs.
The apparent on-and off-rate constants for theophylline binding to its RNA aptamer in the absence of Mg 2+ were determined here by 2D 1 H-1 H NMR ZZ-exchange spectroscopy. Analysis of the buildup rate of the exchange cross peaks for several base-paired imino protons in the RNA yielded an apparent k on of 600 M -1 s -1 . This small apparent k on results from the free RNA existing as a dynamic equilibrium of inactive states rapidly interconverting with a low population of active species. The data here indicate that the RNA aptamer employs a conformational selection mechanism for binding theophylline in the absence of Mg 2+ . The kinetic data here also explain a very unusual property of this RNA-theophylline system, slow exchange on the NMR chemical shift timescale for a weakbinding complex. To our knowledge, it is unprecedented to have such a weak binding complex (K d ≈ 3.0 mM at 15 °C) show slow exchange on the NMR chemical shift timescale, but the results clearly demonstrate that slow exchange and weak binding are readily rationalized by a small k on . Comparisons with other ligand-receptor interactions are presented.RNAs often require divalent metal ions to fold into active conformations and efficiently carry out their biological functions. 1,2 For example, divalent metal ions are required for the high affinity binding of the bronchodilator drug theophylline to its in vitro selected RNA aptamer ( Figure 1A and B), which has a K d of ∼300 nM in 10 mM Mg 2+.3,4 This aptamer still binds theophylline in the absence of divalent metals ions, but with a 10 4 lower binding affinity. 3,5 Analysis of NMR lineshapes can yield information on the kinetics of ligand binding. 6 High affinity complexes (K d < 0.5 μM) are usually in "slow exchange" and low affinity complexes (K d > 100 μM) are usually in "fast exchange" on the NMR chemical shift timescale. Here, we observe slow exchange on the NMR chemical shift timescale for a very low affinity complex: the RNA aptamer-theophylline complex in the absence of divalent metal ions, which has a K d of ∼ 7 mM at 25 °C. ZZ-exchange NMR experiments 7,8 were used to determine the onand off-rate constants for this complex. The results here demonstrate that a very weak binding complex can exist in slow exchange on the NMR timescale. This phenomenon arises from a slow apparent on-rate, consistent with a small population of binding-competent species and a conformational selection mechanism. This type of weak binding combined with slow exchange may be seen in other partially unstructured molecules, such as other RNA aptamers or riboswitches binding their small molecule ligands.RNA-theophylline complex formation can be described by the bimolecular association reaction:arthur.pardi@colorado.edu. † Present address: CombinatoRx, 245 First St., Boston, MA 02142 § Present address: Department of Molecular Genetics, University of Toronto, Toronto, Ontario, Canada, M5S 1AB Supporting Information paragraph NMR spectra and description of the methods used for analysis of these spectra. This in...
Cleavage and polyadenylation (C/P) of mRNA is an important cellular process that promotes increased diversity of mRNA isoforms and could change their stability in different cell types. The cleavage stimulation factor (CstF) complex, part of the C/P machinery, binds to U- and GU-rich sequences located downstream from the cleavage site through its RNA-binding subunit, CstF-64. Less is known about the function of the other two subunits of CstF, CstF-77 and CstF-50. Here, we show that the carboxy-terminus of CstF-77 plays a previously unrecognized role in enhancing C/P by altering how the RNA recognition motif (RRM) of CstF-64 binds RNA. In support of this finding, we also show that CstF-64 relies on CstF-77 to be transported to the nucleus; excess CstF-64 localizes to the cytoplasm, possibly via interaction with cytoplasmic RNAs. Reverse genetics and nuclear magnetic resonance studies of recombinant CstF-64 (RRM-Hinge) and CstF-77 (monkeytail-carboxy-terminal domain) indicate that the last 30 amino acids of CstF-77 increases the stability of the RRM, thus altering the affinity of the complex for RNA. These results provide new insights into the mechanism by which CstF regulates the location of the RNA cleavage site during C/P.
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