Project description:Deubiquitination has emerged as an essential regulatory mechanism of a number of cellular processes. An in-depth understanding of deubiquitinating enzyme (DUB) catalysis, particularly the mode of ubiquitin binding and the individual steps in the DUB catalytic turnover, is imperative for exploiting DUBs for therapeutic intervention. In this work, we present a transient kinetic study of USP2 in hydrolyzing a model substrate Ub-AMC and a physiological substrate K48-linked diubiquitin. We conducted stopped-flow fluorescence analyses of the binding of mono- and diubiquitin to an inactive USP2 mutant and unveiled interesting differences in the binding kinetics between the two substrates. While a simple one-step binding of monoubiquitin to USP2 was observed, a biphasic binding was evident for diubiquitin. We further followed the deubiquitination reaction of Ub-AMC and K48-linked IQF-diubiquitin by USP2 using stopped-flow florescence under a single-turnover condition. Global fitting of the reaction traces revealed differences in the microscopic rate constants between Ub-AMC and the physiological diubiquitin substrate. Our binding and single-turnover data support a conformational rearrangement of the diubiquitin substrate in USP2-catalyzed deubiquitination. This finding is significant given the recent finding that the K48-linked diubiquitin is dynamic in its conformation. Our results provide useful insights into the mechanism of how USP recognizes ubiquitin moieties in a chain structure, which is important for understanding USP catalysis and developing inhibitors against USPs.

Project description:The data described herein are related to the article entitled "Lys63-linked ubiquitin chain adopts multiple conformational states for specific target recognition" [1], and to the coordinates for the ensemble structure of Lys63-linked diubiquitin (PDB code 2N2K). A Lys63-linked diubiquitin exists in three conformational states with different orientations for the two subunits, each responsible for binding to a target protein and encoding a specific cell signal. An atomic entry in the ensemble structure file consists multiple lines, representing alternative locations of the atom and recapitulating the dynamics of the protein. Experimental details about obtaining strictly intramolecular paramagnetic restraints and determining the relative occupancies of the conformational states are presented. The experimental design and procedures in this Data article can be useful for characterizing the structure and dynamics of other multi-domain proteins.

Project description:Telomerase is a ribonucleoprotein complex that replicates the 3' ends of linear chromosomes by successive additions of telomere repeat DNA. The telomerase holoenzyme contains two essential components for catalysis, a telomerase reverse transcriptase (TERT) and telomerase RNA (TER). The TER includes a template for telomere repeat synthesis as well as other domains required for function. We report the solution structure of the wild-type minimal conserved human TER pseudoknot refined with an extensive set of RDCs, and a detailed analysis of the effect of the bulge U177 on pseudoknot structure, dynamics analyzed by RDC and 13C relaxation measurements, and base pair stability. The overall structure of PKWT is highly similar to the previously reported DeltaU177 pseudoknot (PKDU) that has a deletion of a conserved bulge U important for catalytic activity. For direct comparison to PKWT, the structure of PKDU was re-refined with a comparable set of RDCs. Both pseudoknots contain a catalytically essential triple helix at the junction of the two stems, including two stem 1-loop 2 minor groove triples, a junction loop 1-loop 2 Hoogsteen base pair, and stem 2-loop 1 major groove U.A-U Watson-Crick-Hoogsteen triples located directly above the bulge U177. However, there are significant differences in the stabilities of base pairs near the bulge and the dynamics of some nucleotides. The stability of the base pairs in stem 2 surrounding the bulge U177 is greatly decreased, with the result that the Watson-Crick pairs in the triple helix begin to unfold before the Hoogsteen pairs, which may affect telomerase assembly and activity. The bulge U is positioned in the minor groove on the face opposite the triple helical interactions, and sterically blocks the A176 2'OH, which has recently been proposed to have a role in catalysis. The bulge U may serve as a hinge providing backbone flexibility in this region.

Project description:Lys48-linked polyubiquitin chains are recognized by the proteasome as a tag for the degradation of the attached substrates. Here, a new crystal form of Lys48-linked diubiquitin (Ub2) was obtained and the crystal structure was refined to 1.6 A resolution. The structure reveals an ordered isopeptide bond in a trans configuration. All three molecules in the asymmetric unit were in the same closed conformation, in which the hydrophobic patches of both the distal and the proximal moieties interact with each other. Despite the different crystallization conditions and different crystal packing, the new crystal structure of Ub2 is similar to the previously published structure of diubiquitin, but differences are observed in the conformation of the flexible isopeptide linkage.

Project description:Apoptosis-inducing factor (AIF) is a bifunctional mitochondrial flavoprotein critical for energy metabolism and induction of caspase-independent apoptosis, whose exact role in normal mitochondria remains unknown. Upon reduction with NADH, AIF undergoes dimerization and forms tight, long-lived FADH(2)-NAD charge-transfer complexes (CTC) that are proposed to be functionally important. To obtain a deeper insight into structure/function relations and redox mechanism of this vitally important protein, we determined the X-ray structures of oxidized and NADH-reduced forms of naturally folded recombinant murine AIF. Our structures reveal that CTC with the pyridine nucleotide is stabilized by (i) pi-stacking interactions between coplanar nicotinamide, isoalloxazine, and Phe309 rings; (ii) rearrangement of multiple aromatic residues in the C-terminal domain, likely serving as an electron delocalization site; and (iii) an extensive hydrogen-bonding network involving His453, a key residue that undergoes a conformational switch to directly interact with and optimally orient the nicotinamide for charge transfer. Via the His453-containing peptide, redox changes in the active site are transmitted to the surface, promoting AIF dimerization and restricting access to a primary nuclear localization signal through which the apoptogenic form is transported to the nucleus. Structural findings agree with biochemical data and support the hypothesis that both normal and apoptogenic functions of AIF are controlled by NADH.

Project description:G protein-coupled receptors (GPCRs) comprise a large family of seven-helix transmembrane proteins which regulate cellular signaling by sensing light, ligands, and binding proteins. The GPCR activation process, however, is not a simple on-off switch; current models suggest a complex conformational landscape in which the active, signaling state includes multiple conformations with similar downstream activity. The present study probes the conformational dynamics of single ?(2)-adrenergic receptors (?(2)ARs) in the solution phase by Anti-Brownian ELectrokinetic (ABEL) trapping. The ABEL trap uses fast electrokinetic feedback in a microfluidic configuration to allow direct observation of a single fluorescently labeled ?(2)AR for hundreds of milliseconds to seconds. By choosing a reporter dye and labeling site sensitive to ligand binding, we observe a diversity of discrete fluorescence intensity and lifetime levels in single ?(2)ARs, indicating a varying radiative lifetime and a range of discrete conformational states with dwell times of hundreds of milliseconds. We find that the binding of agonist increases the dwell times of these states, and furthermore, we observe millisecond fluctuations within states. The intensity autocorrelations of these faster fluctuations are well-described by stretched exponential functions with a stretching exponent ? ~ 0.5, suggesting protein dynamics over a range of time scales.

Project description:Observing the dynamics of single biomolecules over prolonged time periods is difficult to achieve without significantly altering the molecule through immobilization. It can, however, be accomplished using the Anti-Brownian ELectrokinetic (ABEL) Trap, which allows extended investigation of solution-phase biomolecules - without immobilization -through real-time electrokinetic feedback. Here we apply the ABEL trap to study an important photosynthetic antenna protein, Allophycocyanin (APC). The technique allows the observation of single molecules of solution-phase APC for more than one second. We observe a complex relationship between fluorescence intensity and lifetime that cannot be explained by simple static kinetic models. Light-induced conformational changes are shown to occur and evidence is obtained for fluctuations in the spontaneous emission lifetime, which is typically assumed to be constant. Our methods provide a new window into the dynamics of fluorescent proteins and the observations are relevant for the interpretation of in vivo single-molecule imaging experiments, bacterial photosynthetic regulation, and biomaterials for solar energy harvesting.

Project description:A growing body of evidences has established that in many cases proteins may preserve most of their function and flexibility in a crystalline environment, and several techniques are today capable to characterize molecular properties of proteins in tightly packed lattices. Intriguingly, in the case of amyloidogenic precursors, the presence of transiently populated states (hidden to conventional crystallographic studies) can be correlated to the pathological fate of the native fold; the low fold stability of the native state is a hallmark of aggregation propensity. It remains unclear, however, to which extent biophysical properties of proteins such as the presence of transient conformations or protein stability characterized in crystallo reflect the protein behavior that is more commonly studied in solution. Here, we address this question by investigating some biophysical properties of a prototypical amyloidogenic system, β2-microglobulin in solution and in microcrystalline state. By combining NMR chemical shifts with molecular dynamics simulations, we confirmed that conformational dynamics of β2-microglobulin native state in the crystal lattice is in keeping with what observed in solution. A comparative study of protein stability in solution and in crystallo is then carried out, monitoring the change in protein secondary structure at increasing temperature by Fourier transform infrared spectroscopy. The increased structural order of the crystalline state contributes to provide better resolved spectral components compared to those collected in solution and crucially, the crystalline samples display thermal stabilities in good agreement with the trend observed in solution. Overall, this work shows that protein stability and occurrence of pathological hidden states in crystals parallel their solution counterpart, confirming the interest of crystals as a platform for the biophysical characterization of processes such as unfolding and aggregation.

Project description:The quaternary transition between the relaxed (R) and tense (T) states of heme-binding proteins is a textbook example for the allosteric structural transition. Homodimeric hemoglobin (HbI) from Scapharca inaequivalvis is a useful model system for investigating the allosteric behavior because of the relatively simple quaternary structure. To understand the cooperative transition of HbI, wild-type and mutants of HbI have been studied by using time-resolved X-ray solution scattering (TRXSS), which is sensitive to the conformational changes. Herein, we review the structural dynamics of HbI investigated by TRXSS and compare the results of TRXSS with those of other techniques.

Project description:We present here the results of a series of small-angle X-ray scattering studies aimed at understanding the role of conformational changes and structural flexibility in DNA binding and allosteric signaling in a bacterial transcription regulator, lactose repressor protein (LacI). Experiments were designed to detect possible conformational changes that occur when LacI binds either DNA or the inducer IPTG, or both. Our studies included the native LacI dimer of homodimers and a dimeric variant (R3), enabling us to probe conformational changes within the homodimers and distinguish them from those involving changes in the homodimer-homodimer relationships. The scattering data indicate that removal of operator DNA (oDNA) from R3 results in an unfolding and extension of the hinge helix that connects the LacI regulatory and DNA-binding domains. In contrast, only very subtle conformational changes occur in the R3 dimer-oDNA complex upon IPTG binding, indicative of small adjustments in the orientations of domains and/or subdomains within the structure. The binding of IPTG to native (tetrameric) LacI-oDNA complexes also appears to facilitate a modest change in the average homodimer-homodimer disposition. Notably, the crystal structure of the native LacI-oDNA complex differs significantly from the average solution conformation. The solution scattering data are best fit by an ensemble of structures that includes (1) approximately 60% of the V-shaped dimer of homodimers observed in the crystal structure and (2) approximately 40% of molecules with more "open" forms, such as those generated when the homodimers move with respect to each other about the tetramerization domain. In gene regulation, such a flexible LacI would be beneficial for the interaction of its two DNA-binding domains, positioned at the tips of the V, with the required two of three LacI operators needed for full repression.