Structural characterization of two alternate conformations in a calbindin D9k-based molecular switch.

We have demonstrated that calbindin D(9k) can be converted into a calcium-sensing switch (calbindin-AFF) by duplicating the C-terminal half of the protein (residues 44-75) and appending it to the N-terminus (creating residues 44'-75'). This re-engineering results in a ligand-driven interconversion between two native folds: the wild-type structure (N) and a circularly permuted form (N'). The switch between N and N' is predicted to involve exchange of the 44-75 and 44'-75' segments, possibly linked to their respective folding and unfolding. Here we present direct structural evidence supporting the existence of N and N'. To isolate the N' and N conformations, we introduced the knockdown Ca(2+) binding mutation Glu → Gln at position 65 (E65Q mutant) or at the analogous position 65' (E65'Q mutant). E65Q and E65'Q are therefore expected to adopt conformations N' and N, respectively, in the presence of calcium. Though the amino acid sequences of E65Q and E65'Q differ at only these two positions, nuclear magnetic resonance resonance assignments, chemical shifts, and paramagnetic relaxation enhancement data reveal that they take on separate structures when bound to calcium. Both proteins are comprised of a well-folded domain and a disordered region. However, the segment that is disordered in E65Q (residues 44-75) is folded in E65'Q, and the region that is disordered in E65'Q (residues 44'-75') is structured in E65Q. The results demonstrate that the N' N' conformational change is mediated by a mutually exclusive folding reaction in which folding of one segment of the protein is coupled to unfolding of another segment, and vice versa.

The cold denatured state of the C-terminal domain of protein L9 is compact and contains both native and non-native structure.

Cold denaturation is a general property of globular proteins, and the process provides insight into the origins of the cooperativity of protein folding and the nature of partially folded states. Unfortunately, studies of protein cold denaturation have been hindered by the fact that the cold denatured state is normally difficult to access experimentally. Special conditions such as addition of high concentrations of denaturant, encapsulation into reverse micelles, the formation of emulsified solutions, high pressure, or extremes of pH have been applied, but these can perturb the unfolded state of proteins. The cold denatured state of the C-terminal domain of the ribosomal protein L9 can be populated under native-like conditions by taking advantage of a destabilizing point mutation which leads to cold denaturation at temperatures above 0 degrees C. This state is in slow exchange with the native state on the NMR time scale. Virtually complete backbone (15)N, (13)C, and (1)H as well as side-chain (13)C(beta) and (1)H(beta) chemical shift assignments were obtained for the cold denatured state at pH 5.7, 12 degrees C. Chemical shift analysis, backbone N-H residual dipolar couplings, amide proton NOEs, and R(2) relaxation rates all indicate that the cold denatured state of CTL9 (the C-terminal domain of the ribosomal protein L9) not only contains significant native-like secondary structure but also non-native structure. The regions corresponding to the two native alpha-helices show a strong tendency to populate helical Phi and Psi angles. The segment which connects alpha-helix 2 and beta-strand 2 (residues 107-124) in the native state exhibits a significant preference to form non-native helical structure in the cold denatured state. The structure observed in the cold denatured state of the I98A mutant is similar to that observed in the pH 3.8 unfolded state of wild type CTL9 at 25 degrees C, suggesting that it is a robust feature of the denatured state ensemble of this protein. The implications for protein folding and for studies of cold denatured states are discussed.

Charge neutralization and collapse of the C-terminal tail of alpha-synuclein at low pH.

Alpha-synuclein (alphaS) is the primary component of Lewy bodies, the pathological hallmark of Parkinson's Disease. Aggregation of alphaS is thought to proceed from a primarily disordered state with nascent secondary structure through intermediate conformations to oligomeric forms and finally to mature amyloid fibrils. Low pH conditions lead to conformational changes associated with increased alphaS fibril formation. Here we characterize these structural and dynamic changes using solution state NMR measurements of secondary chemical shifts, relaxation parameters, residual dipolar couplings, and paramagnetic relaxation enhancement. We find that the neutralization of negatively charged side-chains eliminates electrostatic repulsion in the C-terminal tail of alphaS and leads to a collapse of this region at low pH. Hydrophobic contacts between the compact C-terminal tail and the NAC (non-amyloid-beta component) region are maintained and may lead to the formation of a globular domain. Transient long-range contacts between the C-terminus of the protein and regions N-terminal to the NAC region are also preserved. Thus, the release of long-range contacts does not play a role in the increased aggregation of alphaS at low pH, which we instead attribute to the increased hydrophobicity of the protein.

E46K Parkinson's-linked mutation enhances C-terminal-to-N-terminal contacts in alpha-synuclein.

Parkinson's disease (PD) is associated with the deposition of fibrillar aggregates of the protein alpha-synuclein (alphaS) in neurons. Intramolecular contacts between the acidic C-terminal tail of alphaS and its N-terminal region have been proposed to regulate alphaS aggregation, and two originally described PD mutations, A30P and A53T, reportedly reduce such contacts. We find that the most recently discovered PD-linked alphaS mutation E46K, which also accelerates the aggregation of the protein, does not interfere with C-terminal-to-N-terminal contacts and instead enhances such contacts. Furthermore, we do not observe a substantial reduction in such contacts in the two previously characterized mutants. Our results suggest that C-terminal-to-N-terminal contacts in alphaS are not strongly protective against aggregation, and that the dominant mechanism by which PD-linked mutations facilitate alphaS aggregation may be altering the physicochemical properties of the protein such as net charge (E46K) and secondary structure propensity (A30P and A53T).

The approach to the Michaelis complex in lactate dehydrogenase: the substrate binding pathway.

We examine here the dynamics of forming the Michaelis complex of the enzyme lactate dehydrogenase by characterizing the binding kinetics and thermodynamics of oxamate (a substrate mimic) to the binary lactate dehydrogenase/NADH complex over multiple timescales, from nanoseconds to tens of milliseconds. To access such a wide time range, we employ standard stopped-flow kinetic approaches (slower than 1 ms) and laser-induced temperature-jump relaxation spectroscopy (10 ns-10 ms). The emission from the nicotinamide ring of NADH is used as a marker of structural transformations. The results are well explained by a kinetic model that has binding taking place via a sequence of steps: the formation of an encounter complex in a bimolecular step followed by two unimolecular transformations on the microsecond/millisecond timescales. All steps are well described by single exponential kinetics. It appears that the various key components of the catalytically competent architecture are brought together as separate events, with the formation of strong hydrogen bonding between active site His(195) and substrate early in binding and the closure of the catalytically necessary protein surface loop over the bound substrate as the final event of the binding process. This loop remains closed during the entire period that chemistry takes place for native substrates; however, motions of other key molecular groups bringing the complex in and out of catalytic competence appear to occur on faster timescales. The on-enzyme K(d) values (the ratios of the microscopic rate constants for each unimolecular step) are not far from one. Either substantial, approximately 10-15%, transient melting of the protein or rearrangements of hydrogen bonding and solvent interactions of a number of water molecules or both appear to take place to permit substrate access to the protein binding site. The nature of activating the various steps in the binding process seems to be one overall involving substantial entropic changes.

Structural transformations in the dynamics of Michaelis complex formation in lactate dehydrogenase.

The dynamical nature of the binding of a substrate surrogate to lactate dehydrogenase is examined on the nanoseconds to milliseconds timescale by laser-induced temperature-jump relaxation spectroscopy. Fluorescence emission of the nicotinamide group of bound NADH is used to define the pathway and kinetics of substrate binding. Assignment of specific kinetic states and elucidation of their structures are accomplished using isotope edited infrared absorption spectroscopy. Such studies are poised to yield a detailed picture of the coupling of protein dynamics to function.