Your search keyword '"Patrick Farber"' showing total 4 results

1. Relaxation dispersion NMR spectroscopy for the study of protein allostery

Author

Patrick Farber and Anthony Mittermaier

Subjects

Chemistry, Allosteric regulation, Relaxation (NMR), fungi, Biophysics, Nuclear magnetic resonance spectroscopy, Review, Folding (chemistry), Microsecond, Nuclear magnetic resonance, Structural Biology, Chemical physics, Dispersion (optics), Helix, Spectroscopy, Molecular Biology

Abstract

Allosteric transmission of information between distant sites in biological macromolecules often involves collective transitions between active and inactive conformations. Nuclear magnetic resonance (NMR) spectroscopy can yield detailed information on these dynamics. In particular, relaxation dispersion techniques provide structural, dynamic, and mechanistic information on conformational transitions occurring on the millisecond to microsecond timescales. In this review, we provide an overview of the theory and analysis of Carr-Purcell-Meiboom-Gill (CPMG) relaxation dispersion NMR experiments and briefly describe their application to the study of allosteric dynamics in the homeodomain from the PBX transcription factor (PBX-HD). CPMG NMR data show that local folding (helix/coil) transitions in one part of PBX-HD help to communicate information between two distant binding sites. Furthermore, the combination of CPMG and other spin relaxation data show that this region can also undergo local misfolding, reminiscent of conformational ensemble models of allostery.

Published

2014

2. How Electrostatics Influences the Conformational Disorder and Dynamics of the Sic1 Protein: A Single-Molecule Study

Author

Baoxu Liu, Veronika Csizmok, Patrick Farber, Julie D. Forman-Kay, and Claudiu C. Gradinaru

Subjects

Crystallography, Direct evidence, Chemical physics, Chemistry, Phase (matter), Biophysics, Molecule, Ionic bonding, Electrostatics, Acceptor, Fluorescence, Polyelectrolyte

Abstract

In yeast, the cyclin-dependent kinase inhibitor Sic1 is a disordered protein which interacts with a single site on its acceptor Cdc4 only upon multi-phosphorylation of its dispersed sites. To gain insight into the multi-phosphorylation dependence in Sic1-Cdc4 interaction, the conformational properties of the disordered Sic1 N-terminal targeting region were studied using single-molecule fluorescence spectroscopy.At least two Sic1 conformational populations with different sensitivities to charge screening by non-denaturing salts and ionic denaturants were identified. As described by the polyelectrolyte theory, the chain dimensions decrease monotonically with salt concentration and roll over at high denaturant, although a scaling factor of 1.2 indicates that Sic1 is not accurately described as a random chain. Fluorescence correlation analysis shows that Sic1 structure fluctuations occur on fast (10-100 ns) and slow (10-100 ms) ranges, with the fast phase being absent at low salt. Our data provides direct evidence that intrachain charge repulsions are significant for the conformational landscape of Sic1, and support the role of electrostatics in determining the size and shape of intrinsically-disordered proteins.View Large Image | View Hi-Res Image | Download PowerPoint Slide

Published

2014

3. Electrostatics-Dependent Shape of the Intrinsically-Disordered Protein Sic1

Author

Julie D. Forman-Kay, Veronika Csizmok, Claudiu C. Gradinaru, Patrick Farber, Gregory W. Gomes, and Baoxu Liu

Subjects

Small-angle X-ray scattering, Chemistry, Gaussian, Biophysics, Electrostatics, Intrinsically disordered proteins, Gyration, symbols.namesake, Crystallography, Chemical physics, symbols, Polymer physics, Spectroscopy, Fluorescence anisotropy

Abstract

For intrinsically disordered proteins (IDPs) containing a high density of charged residues, a Gaussian chain is an inadequate description of the protein's shape. One such IDP is Sic1, a highly positively charged IDP in the budding yeast Saccharomyces Cerevisiae which prevents the cell cycle from entering the S-phase from the G1-phase. Sic1's binding affinity for Cdc4 is highly phosphorylation state dependent, although the corresponding physical basis is not fully understood. NMR data supports the presence of a dynamic complex of Sic1:Cdc4 and a poly-electrostatic model has been proposed by Forman-Kay and coworkers.We studied the Sic1 N-terminal targeting region (1-90) to better understand the role of intrachain electrostatics, and to compare with the structural ensembles calculated from NMR and SAXS data. Sic1 is characterized using time-resolved fluorescence anisotropy (TRFA), which is sensitive to rotational and conformational dynamics. Sic1 exists in a dynamic ensemble of conformations and ensemble-averaged experiments have limitations in identifying and characterizing static and/or dynamic inhomogeneity in the motional dynamics. Therefore, we also performed burst spectroscopy and single-molecule TRFA on freely diffusing Sic1. Shape and flexibility were probed by varying the degree of intrachain repulsion screening through adjusting salt concentrations and described within a polymer physics framework, the polyelectrolyte model. To investigate the relative contributions of “global rotation” and “conformational flexibility”, Sic1 was labelled at three different sites. Sic1 is found to be well modelled as a prolate ellipsoid with internal flexibility.The single-molecule derived TRFA distribution data may be valuable as a constraint incorporated in future conformational ensemble calculations, complementary to SAXS and NMR data. Additionally, these measurements raise questions about the accuracy of highly charged IDP's radii of gyration when calculated from sm-FRET derived end-to-end distances, which often assume a Gaussian chain model for the end-to-end distance probability distribution.

Published

2014

4. Analyzing protein folding cooperativity by differential scanning calorimetry and NMR spectroscopy

Author

Hariyanto Darmawan, Patrick Farber, Anthony Mittermaier, and Tara Sprules

Subjects

Homeodomain Proteins, education.field_of_study, Protein Folding, Calorimetry, Differential Scanning, Chemistry, Population, Energy landscape, Cooperativity, General Chemistry, Nuclear magnetic resonance spectroscopy, Biochemistry, Catalysis, Crystallography, Colloid and Surface Chemistry, Differential scanning calorimetry, Chemical physics, Native state, Humans, Protein folding, Downhill folding, education, Nuclear Magnetic Resonance, Biomolecular

Abstract

Some marginally stable proteins undergo microsecond time scale folding reactions that involve significant populations of partly ordered forms, making it difficult to discern individual steps in their folding pathways. It has been suggested that many of these proteins fold non-cooperatively, with no significant barriers to separate the energy landscape into distinct thermodynamic states. Here we present an approach for studying the cooperativity of rapid protein folding with a combination of differential scanning calorimetry (DSC), nuclear magnetic resonance (NMR) relaxation dispersion experiments, and an analysis of the temperature dependence of amide (1)H and (15)N chemical shifts. We applied this method to the PBX homeodomain (PBX-HD), which folds on the microsecond time scale and produces a broad DSC thermogram with an elevated and steeply sloping native-state heat capacity baseline, making it a candidate for barrierless folding. However, by globally fitting the NMR thermal melt and DSC data, and by comparing these results to those obtained from the NMR relaxation dispersion experiments, we show that the native form of the protein undergoes two-state exchange with a small population of the thermally denatured form, well below the melting temperature. This result directly demonstrates the coexistence of distinct folded and unfolded forms and firmly establishes that folding of PBX-HD is cooperative. Further, we see evidence of large-scale structural and dynamical changes within the native state by NMR, which helps to explain the broad and shallow DSC profile. This study illustrates the potential of combining calorimetry with NMR dynamics experiments to dissect mechanisms of protein folding.

Published

2010