The kinetics of conformational fluctuations in an unfolded protein measured by fluorescence methods

Chattopadhyay, Krishnananda; Elson, Elliot L.; Frieden, Carl

doi:10.1073/pnas.0500127102

Cited by 135 publications

(145 citation statements)

References 32 publications

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“…Recent experiments (22,23) suggest that the end-to-end distance dynamics for a denatured protein of the size of protein L are on the microsecond time scale, whereas the smFRET data are averaged over millisecond fluorescence bursts. We therefore took the mean E of the denatured-state distribution as an average over the end-to-end distance distribution, P(R ee ), of the protein…”

Section: Resultsmentioning

confidence: 99%

Coil–globule transition in the denatured state of a small protein

Sherman

Haran

2006

Proc. Natl. Acad. Sci. U.S.A.

286

383

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Upon transfer from strongly denaturing to native conditions, proteins undergo a collapse that either precedes folding or occurs simultaneously with it. This collapse is similar to the well known coil-globule transition of polymers. Here we employ singlemolecule fluorescence methods to fully characterize the equilibrium coil-globule transition in the denatured state of the IgGbinding domain of protein L. By using FRET measurements on freely diffusing individual molecules, we determine the radius of gyration of the protein, which shows a gradual expansion as the concentration of the denaturant, guanidinium hydrochloride, is increased all the way up to 7 M. This expansion is observed also in fluorescence correlation spectroscopy measurements of the hydro- fluorescence correlation spectroscopy ͉ protein folding ͉ single-molecule fluorescence T he coil-globule (CG) transition is a hallmark of the physics of polymers in solution. When a polymer molecule is transferred from a good solvent to a bad one, it undergoes a collapse from an expanded coil-like conformation to a contracted, globule-like conformation. This collapse is typically a second-order phase transition and can be accounted well by mean-field theory (1, 2). Proteins are heteropolymers and therefore should exhibit a similar transition. Because proteins also undergo a first-order folding transition to form their native structure, it is of prime interest to deduce the relation between collapse and folding (3). If the CG transition precedes folding significantly, then the final rearrangements of the protein chain to form the native structure occur within a relatively limited configurational space, which might affect the efficiency and speed of the process. The CG transition of proteins is also important for the elucidation of the properties of their denatured states. Chain collapse can have an impact on secondary-structure formation in the denatured protein (4). Determining the energetics of the collapse, which involve changes in the solvation energy of the protein as the solution conditions are varied, might allow us to understand better the role of the denatured state in the folding transition (5).The occurrence of a collapse preceding protein folding was inferred from kinetic experiments (6-11) and also reported in equilibrium experiments, using small-angle x-ray scattering (SAXS) (12) and single-molecule fluorescence (13,14). However, the thermodynamics of the CG transition have not been characterized yet. In this work, we use two methods, singlemolecule FRET (smFRET) and fluorescence correlation spectroscopy (FCS), to measure the CG transition of a 64-amino acid protein exhibiting two-state folding, the IgG-binding domain of protein L (hereafter denoted simply as protein L) (15). The CG transition is driven by the chemical denaturant guanidinium hydrochloride (GuHCl). We then employ a version of the mean-field theory of Sanchez (16) to obtain a full thermodynamic characterization of the CG transition of a protein, identifying the transition point as well ...

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Section: Resultsmentioning

confidence: 99%

Coil–globule transition in the denatured state of a small protein

Sherman

Haran

2006

Proc. Natl. Acad. Sci. U.S.A.

286

383

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“…Equation (1) can be evaluated from first principles assuming that the dynamics of l is slow compared to the characteristic time scales of the solvent molecules and the components, which constitute the barrier [15]. This condition is fulfilled since the radial relaxation time for random coiled polypeptides is in the μsec range [16] while the passive diffusion of macromolecules over length scales of the NPC is a msec phenomenon. Such an approach shows that F(l) is the free energy of the total system constrained to a particular value of l. D is the diffusion constant of the cargo-carrier complex.…”

Section: Modelmentioning

confidence: 99%

Managing Free-energy Barriers in Nuclear Pore Transport

2006

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The Nuclear Pore Complexes (NPC) facilitate highly selective gateways for transport of macromolecules across the Nuclear Envelope (NE). Based on the current accumulated knowledge of the architecture of NPC we have established a minimal physical model of the pore and the transport mechanism. The barrier properties of the NPC model are analyzed by the recently established WangLandau Monte Carlo computer simulation technique and the transport properties are extracted by employing Kramers' theory of reaction rates. We show that our physical model can account for a range of characteristics observed for nuclear pore transport.

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“…In completely unfolded proteins at high denaturant concentration, diffusive interconversion of different conformations have been shown to occur on the Ϸ1-to Ϸ200-s time scale (54,55). The Ϸ1-s motions, which scale as n Ϫ3/2 , represent the time scale for the diffusive formation of a single long-range contact between distal regions of the protein chain separated by n residues (56).…”

Section: Absence Of a Significant Free Energy Barrier During The Sub-msmentioning

confidence: 99%

Barrierless evolution of structure during the submillisecond refolding reaction of a small protein

Sinha

Udgaonkar

2008

Proc. Natl. Acad. Sci. U.S.A.

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To determine whether a protein folding reaction can occur in the absence of a dominant barrier is crucial for understanding its complexity. Here direct ultrafast kinetic measurements have been used to study the initial submillisecond (sub-ms) folding reaction of the small protein barstar. The cooperativity of the initial folding reaction has been explored by using two probes: fluorescence resonance energy transfer, through which the contraction of two intramolecular distances is measured, and the binding of 8-anilino-1-naphthalene sulfonic acid, through which the formation of hydrophobic clusters is monitored. A fast chain contraction is shown to precede the formation of hydrophobic clusters, indicating that the sub-ms folding reaction is not cooperative. The observed rate constant of the sub-ms folding reaction monitored by 8-anilino-1-naphthalene sulfonic acid fluorescence has been found to be the same in stabilizing conditions (low urea concentrations), in which specific structure is formed, and in marginally stabilizing conditions (higher urea concentrations), where virtually no structure is formed in the product of the sub-ms folding reaction. The observation that the folding rate is independent of the folding conditions suggests that the initial folding reaction occurs in the absence of a dominant free energy barrier. These results provide kinetic evidence that the formation of specific structure need not be slowed down by any significant free energy barrier during the course of a very fast protein folding reaction.noncooperative ͉ submillisecond protein folding

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The kinetics of conformational fluctuations in an unfolded protein measured by fluorescence methods

Cited by 135 publications

References 32 publications

Coil–globule transition in the denatured state of a small protein

Coil–globule transition in the denatured state of a small protein

Managing Free-energy Barriers in Nuclear Pore Transport

Barrierless evolution of structure during the submillisecond refolding reaction of a small protein

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