Effects of Weak Nonspecific Interactions with ATP on Proteins.

Adenosine triphosphate (ATP) is an immensely well-studied metabolite serving multiple key biochemical roles as the major chemical energy currency in living systems, a building block of ribonucleic acids, and a phosphoryl group donor in kinase-mediated signaling. Intriguingly, ATP has been recently proposed to act as a hydrotrope that inhibits aggregation of amyloidogenic proteins; however, the underlying mechanism and the general physicochemical effect that coexistence with ATP exerts on proteins remain unclear. By combining NMR spectroscopy and MD simulations, here we observed weak but unambiguously measurable and concentration-dependent noncovalent interactions between ATP and various proteins. The interactions were most pronounced for an intrinsically disordered protein (α-synuclein) and for residues in flexible regions (e.g., loops or termini) of two representative folded proteins (ubiquitin and the dimeric ubiquitin-binding domain of p62). As shown by solution NMR, a consequence of the ATP-protein interaction was altered hydration of solvent-exposed residues in the protein. The observation that ATP interacted with all three proteins suggests that ATP is a general nonspecific binder of proteins. Several complementary biophysical methods further confirmed that, at physiological concentrations of ∼5-10 mM, ATP starts to form oligomeric states via magnesium-chelating and chelation-independent mechanisms, in agreement with previous studies. Although the observed ATP-protein interaction was relatively weak overall, the high ratio of ATP (monomeric free ATP, mono- and divalent ion-bound ATP, oligomeric and chelated ATP) to proteins in cells suggests that most proteins are likely to encounter transient interactions with ATP (and chemically similar metabolites) that confer metabolite-mediated protein surface protection.

Structural Dynamic Heterogeneity of Polyubiquitin Subunits Affects Phosphorylation Susceptibility.

Polyubiquitin is a multifunctional protein tag formed by the covalent conjugation of ubiquitin molecules. Due to the high rigidity of the ubiquitin fold, the ubiquitin moieties in a polyubiquitin chain appear to be structurally equivalent to each other. It is therefore unclear how a specific ubiquitin moiety in a chain may be preferentially recognized by some proteins, such as the kinase PINK1. Here we show that there is structural dynamic heterogeneity in the two ubiquitin moieties of K48-linked diubiquitin by NMR spectroscopic analyses. Our analyses capture subunit-asymmetric structural fluctuations that are not directly related to the closed-to-open transition of the two ubiquitin moieties in diubiquitin. Strikingly, these newly identified heterogeneous structural fluctuations may be linked to an increase in susceptibility to phosphorylation by PINK1. Coupled with the fact that there are almost no differences in static tertiary structure among ubiquitin moieties in a chain, the observed subunit-specific structural fluctuations may be an important factor that distinguishes individual ubiquitin moieties in a chain, thereby aiding both efficiency and specificity in post-translational modifications.

Pinpoint analysis of a protein in slow exchange using F1F2-selective ZZ-exchange spectroscopy: assignment and kinetic analysis.

ZZ-exchange spectroscopy is widely used to study slow exchange processes in biomolecules, especially determination of exchange rates and assignment of minor peaks. However, if the exchange cross peaks overlap or the populations are skewed, kinetic analysis is hindered. In order to analyze slow exchange protein dynamics under such conditions, here we have developed a new method by combining ZZ-exchange and F1F2-selective NMR spectroscopy. We demonstrate the utility of this method by examining the monomer-dimer transition of the ubiquitin-associated domain of p62, successfully assigning the minor (monomeric) peaks and obtaining the exchange rates, which cannot be achieved by ZZ-exchange alone.

High-Sensitivity Rheo-NMR Spectroscopy for Protein Studies.

Shear stress can induce structural deformation of proteins, which might result in aggregate formation. Rheo-NMR spectroscopy has the potential to monitor structural changes in proteins under shear stress at the atomic level; however, existing Rheo-NMR methodologies have insufficient sensitivity to probe protein structure and dynamics. Here we present a simple and versatile approach to Rheo-NMR, which maximizes sensitivity by using a spectrometer equipped with a cryogenic probe. As a result, the sensitivity of the instrument ranks highest among the Rheo-NMR spectrometers reported so far. We demonstrate that the newly developed Rheo-NMR instrument can acquire high-quality relaxation data for a protein under shear stress and can trace structural changes in a protein during fibril formation in real time. The described approach will facilitate rheological studies on protein structural deformation, thereby aiding a physical understanding of shear-induced amyloid fibril formation.

Efficient identification and analysis of chemical exchange in biomolecules by R1ρ relaxation dispersion with Amaterasu.

UNLABELLED: We introduce here a novel acquisition and processing methodology for cross-polarization based 1D rotating-frame relaxation dispersion NMR experiments. This easy-to-use protocol greatly facilitates the screening, acquisition, processing and model fitting of large on- and off-resonance R1ρ relaxation dispersion NMR datasets in an automated manner for the analysis of chemical exchange phenomena in biomolecules. AVAILABILITY AND IMPLEMENTATION: The Amaterasu package including the spreadsheet, Bruker pulse programs and analysis software is available at www.moleng.kyoto-u.ac.jp/∼moleng_01/amaterasu CONTACT: : sugase@moleng.kyoto-u.ac.jp.