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Dynamics of Disordered Proteins Under Confinement: Memory Effects and Internal Friction Atanu Das, and Dmitrii E. Makarov J. Phys. Chem. B, Just Accepted Manuscript • DOI: 10.1021/acs.jpcb.8b06112 • Publication Date (Web): 09 Aug 2018 Downloaded from http://pubs.acs.org on August 13, 2018
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The Journal of Physical Chemistry
Dynamics of Disordered Proteins Under Confinement: Memory Effects and Internal Friction Atanu Das† and Dmitrii E. Makarov*†‡ Department of Chemistry, University of Texas at Austin, Austin, Texas 78712, USA
†
‡
Institute for Computational Engineering and Sciences, University of Texas at Austin, Austin, Texas 78712, USA
ABSTRACT: Many proteins are disordered under physiological conditions. How efficiently they can search for their cellular targets and how fast they can fold upon target binding is determined by their intrinsic dynamics, which have thus attracted much recent attention. Experiments and molecular simulations show that the inherent reconfiguration timescale for unfolded proteins has a solvent friction component and an internal friction component, and the microscopic origin of the latter, along with its proper mathematical description, has been a topic of considerable debate. Internal friction varies across different proteins of comparable length and increases with decreasing denaturant concentration, showing that it depends on how compact the protein is. Here we report on a systematic atomistic simulation study of how confinement, which induces a more
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compact unfolded state, affects dynamics and friction in disordered peptides. We find that the average reconfiguration timescales increase exponentially as the peptide’s spatial dimensions are reduced; at the same time, confinement broadens the spectrum of relaxation timescales exhibited by the peptide. There are two important implications of this broadening: First, it limits applicability of the common Rouse and Zimm models with internal friction, as those models attempt to capture internal friction effects by introducing a single internal friction timescale. Second, the long-tailed distribution of relaxation times leads to anomalous diffusion effects in the dynamics of intramolecular distances. Analysis and interpretation of experimental signals from various measurements that probe intramolecular protein dynamics (such as single-molecule fluorescence correlation spectroscopy and single-molecule force spectroscopy) rely on the assumption of diffusive dynamics along the distances being probed; hence, our results suggest the need for more general models allowing for anomalous diffusion effects.
1. INTRODUCTION It has been recognized for decades that that elementary steps in protein folding are largely determined by the reconfiguration dynamics in the unfolded state . Thus motivated, many 1-3
experiments focused on the dynamics of unfolded proteins . But the significance of the dynamics 4-16
in the unfolded state goes far beyond the subject of protein folding. Many proteins are either disordered or contain long disordered segments under physiological conditions. To understand how quickly they can search for their biological targets, it is essential to study their dynamics . 17-18
Recent discovery that protein interactions may occur via highly dynamic, unstructured complexes
19
will likely further increase interest in the thermodynamics and dynamics of the unfolded state.
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One of the somewhat unexpected findings emerging from experimental studies , as well as 20-25
from theoretical studies and simulations , is that the observable dynamics and folding of proteins, 26-34
large macromolecules with heterogeneous chemical sequences, can be rationalized using the rather simple model of moving along a one-dimensional “reaction coordinate” R, which is usually synonymous with or related to the experimental signal . In application to folding or other large 35
conformational rearrangements, the existence of such a coordinate, which is descriptive of the conformational change of interest, is, of course, the fundamental premise of transition state theory, but transition state theory is not expected to apply to molecules as large, as complex, and as floppy as proteins. The limitations of transition-state theory in application to polyatomic molecules were recognized long ago by Kramers , who was the first to propose that the perturbation exerted by 36
many molecular degrees of freedom on the reaction coordinate can be modeled as friction similar to the hydrodynamic friction appearing in the theory of Brownian motion. Kramers himself, however, was well aware of the potential inadequacy of this model: while the origin of the hydrodynamic friction acting on micrometer-sized Brownian particles is well understood, similar justification for a friction force acting along a molecular reaction coordinate and being proportional to velocity does not exist. At best, certain, special coordinates, to which a one-dimensional diffusion picture is applicable, are anticipated theoretically . Those coordinates are, however, 37-40
complex functions of all the molecular coordinates. As such, they are a challenge to predict even computationally, and they are unlikely to coincide with, or be close to common experimental reaction coordinates. Despite these caveats, the Kramers model of folding kinetics was embraced by the protein folding community and led to many important insights. In terms of this model, the dynamics along an experimental observable R is completely described by a potential of mean force U(R) and by a
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friction coefficient γ (where −γ dR /dt is the friction force), or, equivalently, by a diffusion coefficient, which is related to the friction coefficient via the Einstein-Smoluchowski relationship D = kBT / γ . The dynamics of the protein in the unfolded state is then completely characterized
by introducing a characteristic timescale (known as the reconfiguration timescale τ r ) and a characteristic lengthscale l (which, for example, can be taken to be the polypeptide’s radius of gyration or the root mean square of its end-to-end distance); in terms of these two scales, the diffusion coefficient can be expressed as l2 D~ . τr
The rate of protein folding k f can be further rationalized by employing the Kramers formula, which gives an Arrhenius-type law ΔU
1 −k T kf ~ e B , τr
where is ΔU the free energy barrier encountered along the potential of mean force. Further refinements of this result are possible to account, for example, for the spatial variation of the diffusion coefficient D = D(R)
28, 41-45
. Given its central role in this diffusive model of folding
dynamics, understanding the physical nature of the diffusion coefficient (or quantities related to it) became the subject of many experimental studies and remains a topic of active research at present
25, 46-49
.
In particular, does the effective friction along the reaction coordinate originate from intrachain interactions within the polypeptide (internal friction) or from interactions with the surrounding water (solvent friction) ? To answer this question, one can measure the viscosity dependence of 50-53
the friction coefficient and identify the viscosity independent component as internal friction and
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viscosity dependent component as solvent friction . The relative contribution of internal friction 52
has indeed been found to be significant; it is also strongly dependent on the system and on the timescale of interest . 54-60
The physical origin of internal friction has been a subject of some debate, and many different (but not mutually exclusive) mechanisms have been proposed, including roughness of the energy landscape , hydrogen bonding , salt bridges , solvent memory effects , and crankshaft-like 61-62
63-64
65
66-67
dihedral rotations . 68-69
In polymer physics, the subject of internal friction (or internal viscosity) dates back to the work of Kuhn (see ref.
70-74
for a survey of this topic); many recent efforts to understand internal friction
have thus turned to polymer physics ideas
58-59, 63, 68-69, 75-76
. The relevance of simple polymer theories,
usually based on homopolymer models, as a description of polypeptide chains with highly heterogeneous sequences is far from obvious . Yet large body of evidence indicates that such 77
models provide a good first order approximation for the chain statistics
78-82
and dynamics
58, 76, 83-85
in the
unfolded state. In particular, the experimentally observed dynamics of proteins that are either disordered intrinsically or unfolded using denaturants can often be described using remarkably simple models from polymer physics based that are extensions of the classic Rouse and Zimm models
58, 73, 76, 84
. In the
Rouse or Zimm model with internal friction (RIF and ZIF), the effect of internal friction is captured by a single, and experimentally measurable , internal friction timescale τ i , which is equal to the 76
polypeptide’s relaxation timescale extrapolated to zero solvent viscosity. RIF and ZIF have been the focus of many recent theoretical studies
84, 86-90
experimental observations
58, 76, 85, 91
and have been used to rationalize a number of
.
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Further modification of the classic Rouse and Zimm models is required to account for the denaturant-induced changes in the polymer statistics and dimensions. For example, a protein that is unfolded under native conditions is expected to have a smaller radius of gyration than the same protein at a high concentration of denaturant. Moreover, while highly denatured proteins are expected to behave like excluded-volume like random coils , they are often close to the theta point 79
under native conditions . Even under the native conditions, there is large variation in the 92-98
compactness of the unfolded state, with highly charged intrinsically disordered proteins often being more expanded than unfolded proteins that have a well defined folded state. A simple way to account for these effects is to introduce an attractive potential; for example, in our earlier work
76,
84
we envisioned placing the protein in a trap that exerts an attractive central parabolic potential on
each monomer, whose strength is adjusted to match the experimentally observed dimensions of the chain at different denaturant concentrations. Although, of course, such an ad hoc model does not capture the physical mechanisms of a denaturant’s action , it is consistent with more realistic 99-100
models of the coil-globule transition and it captures the experimentally observed effect of 76
denaturants on polypeptide dynamics while preserving linearity, and thus simplicity, of the Rouse 84
and Zimm models. The model that mimics the effects of a denaturant via a confining potential captures the speedup of intrachain dynamics with decreased denaturant concentration
12-13, 84
as long as internal friction
effects are negligible; when they are not, they result in the opposite trend, where increased compaction of the chain leads to an increase in the internal friction timescale τ i thus slowing intrachain dynamics . 76
Similar correlation between the internal friction timescale and the
compactness of the unfolded chain is also observed across different proteins , with highly charged 76
and thus expanded intrinsically disordered proteins showing little internal friction even under
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native conditions . This correlation suggests that nonlocal sequence-distant interactions (which 58
increase upon chain compaction) are responsible for internal friction. Thus assertion, however, appears to be at odds with the finding that local properties of the polypeptide’s energy landscape such as the barrier to dihedral rotations control the magnitude of internal friction . Specifically, 68-69
decreasing (increasing) the magnitude of the dihedral barrier Udih in simulations of an unfolded protein has led to a smaller (greater) value of τ i ; moreover, the dependence of τ i on Udih is close U dih
to exponential, τ i ∝e
kBT
, consistent with the picture that dihedral rotations control the protein’s
reconfiguration dynamics in the limit where internal friction effects dominate. But since changing U does not significantly change the dimensions of the unfolded chain, the role of the chain dih
compactness is not explained within this picture. Thus complete understanding of the molecular mechanisms leading to internal friction in unfolded proteins is still lacking. Another open question about the dynamics of unfolded proteins is concerned with validity of the model of one-dimensional diffusion along an experimental reaction coordinate. Several theoretical and experimental 101
21-22
studies attacked this question directly, concluding that this model
is adequate, at least for a subset of experimental systems studies by single-molecule force spectroscopy. At the same time, there is overwhelming evidence from molecular simulations that the dynamics of inter-monomer distances and other commonly used reaction coordinates cannot always be modeled as a memoryless diffusion process
32, 40, 68, 102-109
report anomalous diffusion
110-111
.
, and several experimental studies also
In particular, subdiffusive dynamics, where mean square
displacements grow more slowly than linear in time, is often observed in simulation studies. Such subdiffusive behavior is not a short-time effect that becomes negligible when longer-time phenomena are studied: subdiffusive character of the dynamics, for example, drastically affects
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the folding dynamics of a fast folding protein at timescales of several hundreds of nanoseconds , 112
106
which are longer than its average transition path time. Subdiffusive monomer dynamics is to be expected for the Rouse and Zimm models at intermediate timescales
87, 113-114
; however, analysis of
RIF/ZIF dynamics shows that diffusive behavior should be recovered in the limit of high internal friction . But direct simulations of protein dynamics in this limit show that this is not so, calling 84
68
validity of RIF and ZIF models into question. Motivated by the above questions, we seek here to understand how reconfiguration dynamics of disordered polypeptides depend on both their dihedral energy landscape and on their compactness, how the dynamics in a polypeptide’s conformational space is manifested when further projected onto a one-dimensional reaction coordinate, and why (and if) this one-dimensional dynamics is subdiffusive. We chose the Gly-Ser repeat peptide as a model system, because its properties are close to those of a random coil
13, 84
and because it is implicated in cellular processes . We induce a 115
more compact state of the chain by simply placing within a cubic trap made from Argon atoms, as shown in Figure 1. We note that, in addition to elucidating how protein compactness affects internal friction, our simulations also offer insight as to how cellular crowding or protein encapsulation within, e.g., nanoparticles might affect protein dynamics. A key finding of our study is that, although compaction leads to higher internal friction (as found in earlier studies), this effect cannot be simply described in terms of a single internal friction timescale τ i assumed by simple polymer models. Rather, a distribution of timescales, which is shifted toward longer times while, at the same time, becomes more heavy-tailed, must be considered in order to account for anomalous diffusion effects observed in the dynamics of intermonomer distances.
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2. METHODS 2.1. Simulations of Unconfined Peptides. We performed simulations of an 11-residue peptide fragment with the Gly-Ser repeat, which is often viewed as a model polypeptide with properties close to those of a random coil . The random-coil behavior of this peptide is confirmed by the 13, 84
distribution of its end-to-end distance, which is close to that expected for a random coil (Fig. S1). Molecular dynamics simulations were performed using the GROMACS software package, version 4.5.5 . Parameters were taken from the Amber03 parameter set . TIP4P-D explicit water model 116
117
was used to represent the solvent, because this water model is known to accurately reproduce experimentally observed conformational ensembles for disordered proteins . The peptide was 118
solvated in a cubic 5.2 ´ 5.2 ´ 5.2 nm box. Counterions were added using the genion module of 3
GROMACS, which randomly replaces water molecules with counterions in favorable locations determined by computing the electrostatic potential at the insertion site. Each system was energy minimized by, first, the steepest descent algorithm and then by a conjugate gradient algorithm, to arrive at a conformation with no steric clashes. Each of these minimized conformations was equilibrated in two steps, with position restraints applied to all the heavy atoms throughout. The first step involved simulating each system for 500 ps under a constant volume (NVT) ensemble. All the atoms were coupled to a bath, with the temperature kept at 300 K using the Berendsen weak coupling method. Following NVT equilibration, 500 ps of constant pressure (NPT) equilibration was accomplished to maintain pressure isotropically at 0.138 atm. All the simulations were performed in a cubic cell employing periodic boundary conditions with the standard minimum image convention in all three directions. Long-range electrostatics was treated with the particle mesh Ewald method . The cutoff used for Lennard-Jones interactions was 9 Å. Particle 119
mesh Ewald method with a real space cut-off at 9 Å was used to account for the electrostatic
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interactions. All bond lengths and all angles involving hydrogen atoms were constrained using the LINCS algorithm . An integration time step of 2 fs was used for all the simulations. Production 120
MD runs were performed at T=300 K and P=0.138 atm in the absence of any restraints; these conditions are close to those employed in previous experimental and theoretical 76
68-69
studies. The
modified Berendsen thermostat was used to maintain temperature, and the Parrinello-Rahman 121
barostat was used to isotropically regulate pressure during the production runs. The total length 122
of a production run varies from ~2 µs (for the unconfined peptides) to ~10 µs (for the confined peptides). A set of three independent trajectories was run for all the systems to estimate the error bars on the relaxation times and the exponent α .
2.2. Simulations of Confined Peptides. To study how compaction affects peptide dynamics, we placed peptides inside a cubic argon box with a layer of argon atoms on all the three sides of the box. We chose argon to minimize any specific interactions between the peptide and the box. Argon parameters were taken from OPLS-AA parameter set.
123-124
Four different cubic argon boxes
were used, with edge lengths of 4.2 nm, 3.6 nm, 3.0 nm, and 2.4 nm. Each of these systems was then placed inside a cubic cell whose edge length was 5.2 nm, as in the case of unconfined peptides. The molecules were solvated with TIP4P-D water molecules, and counterions were added following the same procedure as in the case of unconfined peptides. Minimization, equilibration, and production runs were performed as described above for the case of unconfined peptides, the only difference being that position restraints were applied to all the argon atoms throughout the production run in order to maintain the size and the shape of the argon box.
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2.3. Simulations with Modified Dihedral Barrier Heights. The potential energy function describing the backbone dihedral angles has the form:
U U(θ ) = n [1+ cos(nθ − γ )] 2
(1)
where θ is the dihedral angle (either φ or ψ ) and Un is the corresponding force constant. The phase angle γ takes values of either 0° or 180°, and n is an integer that determines the periodicity of the potential . 117
To explore the connection between internal friction and the dihedral energy landscape, we repeated our simulations for the 11-residue Gly-Ser repeat peptide using two stronger and two softer dihedral potentials by rescaling all dihedral force constants by factors of 1/2, 3/4, 3/2, and 2. Since the dihedral barrier heights are somewhat different (but comparable) for φ and ψ (see Fig. S2), the value for the dihedral barrier Udih reported above is that for the angle φ .
2.4. Calculation of the Relaxation Times. The relaxation time of the quantity of interest was computed from its autocorrelation function (ACF) C(τ ) , according to ∞
τ r = ∫ CN (t)dt , (2) 0
where C(τ )− C(∞) C N (τ ) = C(0)− C(∞)
(3)
is the normalized autocorrelation function. For a dihedral angle θ(t), the corresponding autocorrelation function was defined as : 125
C (τ ) = cos ⎡⎣θ ( t ) − θ ( t + τ ) ⎤⎦
(4)
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Normalized dihedral ACF was further averaged over all the dihedrals in the peptide before computing a single dihedral relaxation time from Eq. 2. For the end-to-end vector R, the ACF was defined as C (τ ) = R (t ) R (t + τ ) , and for the endto-end distance R we have C (τ ) = R ( t ) R ( t + τ ) . Because of the noise in the raw ACFs, the integral of Eq. 2 was evaluated using analytic fits of C N (t) . Single exponential, bi-exponential and stretched exponential fits were, respectively, used
for the end-to-end vector, dihedral angle and end-to-end distance ACFs. Those fits along with the raw autocorrelation functions are shown in Fig. S3-S51.
Figure 1. A snapshot of an 11-residue Gly-Ser repeat confined within an Argon box.
3. RESULTS 3.1. Both the End-to-End Relaxation Time τ ee and the Dihedral Relaxation Time τ dih of a Confined Polypeptide Depend Strongly on Its Radius of Gyration (Fig. 2). As seen in Figure
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2, both the end-to-end distance relaxation time and the dihedral relaxation time of a confined peptide increase by two orders of magnitude when its radius of gyration R is decreased by ~25%. g
The sharp increase in the end-to-end relaxation time upon compaction found in Figure 2 is similar to the R dependence of the internal friction time τ i found for several proteins and for varied g
denaturant concentrations, see Figure 5 in ref. . The R dependence of the dihedral relaxation time 76
g
can be fitted by the exponential function τ dih = ae
− R g /Reff
(see Fig. 2), with a characteristic length
Reff that is approximately equal to ~5.0 Å.
Figure 2. End-to-end relaxation time τ ee and dihedral relaxation time τ dih plotted as a function of the polypeptide’s radius of gyration (normalized by the radius of gyration of the same peptide in the absence of confinement). The dashed line represents exponential fit to τ dih . The inset shows the same relaxation times on a logarithmic scale.
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3.2. Both the End-to-End Relaxation Time τ ee and the Dihedral Relaxation Time τ dih of a Confined Polypeptide Increase with the Increasing Barrier to Dihedral Rotations (Fig. 3). As observed in earlier studies , the dihedral relaxation time increases exponentially with the height 68-69
of the dihedral barrier, indicating Arrhenius-type barrier crossing dynamics (Fig. 3). Indeed, the slope of the vs ln τ dih vs Udih dependence observed in Figure 3a is close to (kBT )−1 . For the largest box used in the simulations the effects of confinement are essentially negligible. In this case, the end-to-end distance relaxation time shows an upturn in its dihedral barrier dependence, where it is nearly independent of the dihedral barrier Udih when this barrier is low enough ( U dih ≤ 9 kJ/mol), but increases exponentially (and proportionally to τ dih ) for higher values of U dih (Fig. 3b). This behavior is indicative of a transition between the Rouse/Zimm type of dynamics for low dihedral barriers, where the relaxation time is controlled by the solvent friction, to Kuhn internal friction regime, where dihedral dynamics controls global relaxation of the polymer coil . Consistent with this assertion, the end-to-end distance relaxation time (indicative of 68
internal dynamics) is comparable to the end-to-end vector relaxation time (indicative of rotational dynamics) in the low-barrier case, as expected for the Rouse and Zimm models (see Table S1). In 68
contrast, for higher dihedral barriers the end-to-end distance relaxation time is much longer than the end-to-end vector relaxation time, indicating that the internal dynamics is much slower than the rotational dynamics – this is a signature of the internal-friction dominated regime . 68
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Figure 3. Relaxation times, τ dih and τ ee , vs. dihedral barrier height for different sizes L of the confining box. The vertical black dashed line shows the normal dihedral barrier height set by the force field used. The inset shows the same relaxation times on a logarithmic scale.
3.3. Dihedral and End-to-End Distance Relaxation Times Are Linearly Correlated. When the dihedral relaxation time is plotted against the end-to-end distance relaxation time (Fig. 4 – same data as in Fig. 3, with two additional data points for L = 3.0 nm and L = 2.4 nm, with normal dihedral barrier height) for different values of the dihedral barrier and different values of the box size, we see that the two times are approximately linearly correlated. When the dihedral barrier is increased, this slows down the dihedral hopping dynamics. Consistent with the picture where internal friction results from dihedral rearrangements , this also increases the global relaxation 68-69
time as quantified by the end-to-end distance relaxation time τ ee . Likewise, when the chain becomes more compact, the dihedral dynamics becomes slower and, accordingly, τ ee decreases. In fact, the effect of compaction on the dihedral relaxation time can be understood as a result of increased free energy barrier to dihedral rotations in a compacted chain (Fig. 5).
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Figure 4. Dihedral angle relaxation time vs. end-to-end distance relaxation time. Different colors correspond to different box sizes, as shown in the legend. The black dashed line shows a linear fit to the entire data set.
Figure 5. The effect of confinement on the potential of mean force measured as a function of the
f dihedral angle of GLY-5: The free energy barrier to dihedral rotation increases as a result of chain compaction. A detailed analysis of all the backbone f and y dihedral angles is given in the Supporting Information (Fig. S52).
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3.4. Confinement Increases Non-Markov, Subdiffusive Character of End-to-End Distance Dynamics. In the case of Rouse or Zimm dynamics, all the dynamical timescales of the polymer scale proportionally to the solvent friction. Given the nearly linear correlation between the dihedral relaxation time and the global end-to-end distance relaxation time, and given that the dihedral relaxation time is proportional to the internal friction timescale τ i , it is tempting to propose that 68
internal friction has a similar effect to that of solvent friction, leading to proportional scaling of all relevant timescales. This is, however, not the case; instead, the nature of dynamics changes upon compaction of the polypeptide. Indeed, consider the behavior of the mean square displacement measured along a polypeptide’s trajectory 2
2
ΔR (Δt)
dt $%R(t + Δt)− R(t)&' ∫ = ∫ dt
,
(5)
where R(t ) is its end-to-end distance as a function of time. If the dynamics of the end-to-end distance is diffusive, then, at short enough times (where the effects of the chain connectivity or, equivalently, of the associated potential of mean force are negligible), one has
ΔR2(Δt) = 2DΔt , (6) where D is a diffusion coefficient. For free diffusion, the above equation holds for any time Δt , but, of course, chain connectivity precludes free diffusion of one chain end relative to the other. For short enough times, however, chain connectivity effects become negligible and the diffusion coefficient D can be estimated.
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The assumption of diffusive dynamics is, however, incorrect for the end-to-end dynamics of the peptides studied here (Fig. 6). Instead, their dynamics is subdiffusive, with the mean square displacement growing with time as a power law,
ΔR2(Δt ) ∝ Δt α
(7)
Such subdiffusive behavior has been reported in earlier studies
40, 68, 102, 105-106, 126-127
. A remarkable feature
observed in Figure 6 is that the dynamics becomes more subdiffusive as confinement is increased, with the exponent α decreasing from ~0.6 for the unconfined peptide to ~0.1 for the most compact peptide. This finding shows that compaction does not merely lengthen the internal friction timescale, but fundamentally alters the nature of protein dynamics. To further emphasize this point, let us reiterate that the effect of compaction on both the dihedral ( τ dih ) and end-to-end distance ( τ ee ) relaxation times can be interpreted as a result of increased free energy barrier to dihedral rotations. In other words, both times can be changed, in a similar way, by either changing the enthalpy barrier associated with dihedral rotation or by changing the volume within which the chain is confined. In contrast, the exponent α is essentially unaffected by the dihedral enthalpy barrier (Fig. 7), while it is significantly affected by confinement. Thus a single internal friction timescale τ i (which is proportional to τ dih ) cannot provide a complete description of dynamics in the internal-friction dominated regime. As will be further argued in the next Section, the distribution of relaxation times, rather than merely their mean, must be considered to understand how peptide dynamics is altered by confinement. Anomalous diffusion observed in the time evolution of inter-monomer distances is a fingerprint of non-Markovian dynamics. The increasingly non-Markovian character of the trajectories R(t )
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observed with the increased confinement can also directly be seen by applying the “nonMarkovianity” test proposed in ref. . In this test, one defines an interval (a,b) within which the 128
motion is investigated and measures the probability P(a → b|R) that a specified point R, a < R < b , belongs to a path that enters this interval from the left through the boundary a and exits the interval to the right through the boundary b. For a Markov process, the maximum value of P(a → b|R) is achieved at some intermediate point within the interval and is equal exactly to 1/4.
For a non-Markov process, however, the maximum value is below 1/4, with a decreasing maximum value indicating increasingly pronounced memory effects. We applied this test to each of the peptide trajectories (Fig. 8). Because the range of values of the end-to-end distance R spanned by each peptide depends on confinement, we chose, in each case, a value of a that corresponds to the maximum of the probability distribution of R. The value of b was then chosen equal to a plus the variance of the distribution of R.
4. DISCUSSION AND CONCLUSIONS Let us restate two key findings that emerge from our results: (i) Both increased confinement and increased enthalpic dihedral barrier slow down the global dynamics of peptides, an effect that can be interpreted as increased internal friction. (ii) Yet increased confinement fundamentally changes the character of the dynamics of intramolecular distances, making them more subdiffusive. In contrast, simply changing the dihedral barrier does not. These observations lead us to conclude that peptide dynamics cannot be fully characterized in terms of the internal friction timescale τ i alone. To further emphasize this point, we recall that the Rouse and Zimm models with internal friction predict that an increased internal friction timescale results in less subdiffusive dynamics of intermolecular distances , a prediction opposite what we observe here. 84
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To understand what causes this discrepancy, we need to examine the microscopic origins of subdiffusive dynamics. Many distinct physical mechanisms may account for the behavior expressed by Eq. 7 ; a common feature of the systems displaying such anomalous diffusion is that 129
they lack a single characteristic timescale. In particular, conformational trapping has been proposed to explain anomalous diffusion effects in proteins
102-103, 126
. This explanation is appealing in
the present context because confinement is expected to increase the likelihood that the peptide becomes trapped in a local energy minimum, as escaping the minimum may require a large conformational rearrangement of the chain impeded by the confining volume
130-131
.
A quantitative view of how trapping leads to anomalous diffusion is provided by continuous time random walk (CTRW) type models , where the system undergoes discrete jumps in 129
conformational space. An essential feature that leads to non-diffusive behavior in these models is a broad distribution of the waiting times between successive jumps . In particular, slowly decaying 126
waiting time distributions with power-law tails are known to lead to subdiffusive dynamics
129, 132
.
Is the peptide dynamics studied here consistent with the CTRW picture? To answer this question, we have examined the waiting time distributions between distinct structural jumps exhibited by the peptides. The structural jumps were identified in two ways. First, we have defined them as distinct events where one of the dihedrals of the chain transitions into a different region of the Ramachandran plot (see Fig. S53). Second, we employed principal component analysis and considered the time evolution of the first principal component (PC1) . Distinct jumps in PC1 were 133
then identified using the change point algorithm of Watkins et al. . In each case, the distribution 134
of the waiting times between jumps was computed (Fig. 9a,b). As seen from Fig. 9, the distribution of the waiting times between subsequent jumps is generally nonexponential. Although insufficient statistics prevents us from establishing its precise functional
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form, we can quantify its nonexponentiality by evaluating the coefficient of variation (CV) defined as the ratio of the standard deviation of a distribution to its mean,
CV =
⎛ t2 − t 2⎞ ⎝ ⎠ t
1/2
(8)
For an exponential distribution, we have CV=1, values of CV significantly exceeding 1 indicate a long-tailed distribution . Starting from unconfined peptide and decreasing the box size to 4.2, 135
3.6, 3.0, and 2.4 nm, the values of CV calculated for the distributions shown in Fig. 9 are 2.5, 3.7, 4.2, 6.9, and 29.9 for the waiting time analysis based on PCl; they are equal to 3.79, 4.63, 6.78, 12.7, and 16.9 for the waiting time distributions of the dihedral jumps. Therefore, the distributions increasingly deviate from the exponential form as the peptide conformations become more compact, consistent with the observation that the dynamics becomes less Markovian. This finding lends support to the CTRW-type mechanism of subdiffusive dynamics, where confinement broadens the distribution of barriers to transition among different conformations thereby also broadening the waiting time distribution. Despite evidence in support of the conformational trapping mechanism (see also ref. ), our 102
understanding of the physical origins of subdiffusive dynamics is incomplete. In particular, the standard CTRW model with a power-law distribution of waiting time leads to a subdiffusive behavior for the mean square displacement averaged over an ensemble of trajectories R(t )
⎡⎣ R(Δt )− R(0)⎤⎦
2
129
∝ Δt α (9) ensemble
Because CTRW dynamics is not ergodic , this average differs from the time average performed 129
along a single trajectory, as prescribed by Eq. 5. In fact, the average of Eq. 5 for a CTRW in free space still shows linear growth with Δt , which contradicts our observations. Noisy CTRWs or 129
129
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CTRW models with non-power-law waiting time distributions may be better candidates for models describing our data and should be explored in the future. Chemically denaturated proteins are often well described as Flory random coils
, even when
79-80, 95
residual structure is non-negligible . Somewhat surprisingly, simple models treating proteins as 81-82
random homopolymers often provide a good description of intrinsically disordered proteins and of proteins unfolded under native conditions
93, 136-137
, an observation also supported by computer
simulations . A key breakthrough in understanding the dynamics of unfolded proteins, which 58, 69
typically occurs at a nanosecond timescale, came from single-molecule fluorescence correlation spectroscopy (FCS) experiments
20, 138-142
. Interpretation of such studies, however, faces a challenge:
the dynamics of even the simplest Flory random coil, as described by Rouse and Zimm models, exhibits a spectrum of timescales corresponding to various collective modes , while experimental 143
information extracted from FCS studies usually involves a single timescale corresponding to the relative motion of a pair of monomers. By placing probes at different positions along polypeptide chains
, by studying the viscosity and denaturant dependence of the dynamics , and by
76, 144
76
combining FCS measurements with other techniques such as quenching studies and with molecular simulations , it was possible to tease out certain details about spatio-temporal correlations within 58
unfolded proteins. Yet findings reported here suggest that a comprehensive picture is still lacking. Outlined below are the specific challenges that we believe still should be addressed in future work: (i) The most successful polymer physics model of protein dynamics as observed in FCS and contact quenching studies is the Rouse/Zimm model with internal friction (RIF/ZIF)
73, 76, 84
. Many
predictions of this model are consistent with experimental measurements . However findings 58, 76
presented here and in an earlier study indicate that certain predictions from ZIF/RIF disagree with 68
simulations. Specifically, RIF/ZIF predicts that inter-monomer dynamics must become purely
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diffusive in the limit where internal friction dominates . Here, in contrast, we find that the inter84
monomer dynamics becomes increasingly non-Markov and subdiffusive as the internal friction effects are increased as a result of confinement. This disagreement can be traced back to the fact that RIF/ZIF predict that the internal-friction-dominated regime can be characterized by a single characteristic timescale τ i . At odds with this assertion, we see a long-tailed distribution of timescales that becomes broader as internal friction increases. Is it possible to generalize RIF/ZIF to account for a distribution of internal friction timescales? Can alternative polymer models
59
describe this behavior better? (ii) Results reported here and in earlier studies
68, 106
suggest that the dynamics of common
experimental observables such as interatomic distances are almost universally subdiffusive. Yet analysis of experimental studies often relies on the model of diffusive dynamics
138-140
. To ensure
internal consistency between data analysis and experimental conclusions, more general models (either those describing the dynamics of one-dimensional reaction coordinates or models of polymer dynamics) are desirable. (iii) Related to the above two points, given that the assumption of one-dimensional diffusive dynamics along intramolecular distances and other common reaction coordinates breaks down 106
(at least in simulation studies), is there a more general theoretical model that can be used instead? Several generalizations, in fact, exist that account for subdiffusive dynamics. Those include the generalized Langevin equation with a memory kernel and a number of different generalizations of the Smoluchowski equation
106, 126, 132, 145-147
. Although all of them capture anomalous diffusion, their
specific predictions are different; for example some of them show nonergodic behavior while others do not. Which one (if any) is consistent with both microscopic dynamics seen in simulations and with experimental observations?
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Much of our current understanding of the unfolded state of proteins, of its thermodynamics, and of its dynamics is a result of closely coupled efforts from experimentalists and theoreticians. The authors, likewise, hope that the above questions will be answered in the near future through synergy of experimental, computational, and theoretical efforts.
Figure 6. Mean square displacement of the end-to-end distance as a function of time plotted on a log-log scale. The slope of the plot is the exponent α defined by Eq. 7. Different colors correspond to different box sizes. The peptide shows increasingly subdiffusive behavior (i.e., smaller values of α ) as the confinement increases.
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Figure 7. Exponent α plotted as a function of the dihedral barrier for free and confined peptides. Dashed lines show linear fits of the data.
Figure 8. “Markovianity test” : the probability P(a → b|R) that a point R belongs to a transition 128
path traveling from a point a to a point b>a (a chosen at the maximum of the distribution of R and b-a chosen to be equal to the variance of the distribution) peaks at a value that becomes smaller as confinement is increased. While in the absence of confinement this peak value is close to 0.25, a value expected for Markov dynamics, progressively low values observed as confinement is increased indicate increased memory effects.
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Figure 9. Waiting time distributions for jumps in (a) first principal component PC1 and (b) dihedral angles.
ASSOCIATED CONTENT Supporting Information. Random coil behavior of the Gly-Ser repeat peptide; force field defined torsional barrier height; end-to-end distance, end-to-end vector, and dihedral angle autocorrelation functions; effect of compaction on individual dihedral angles; waiting time estimation protocol.
AUTHOR INFORMATION Corresponding Author *E-mail:
[email protected]. Notes
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The authors declare no competing financial interest. Author Contributions The manuscript was written through contributions of both authors. Both authors have given approval to the final version of the manuscript.
ACKNOWLEDGMENT We are indebted to Haw Yang for providing us with his change point detection code and for help with this code, and to Hagen Hofmann, Rohit Satija, and Benjamin Schuler for comments and discussions. This work was supported by the Robert A. Welch Foundation (Grant No. F-1514) and the National Science Foundation (Grant No. CHE 1566001).
REFERENCES (1) Hagen, S. J.; Hofrichter, J.; Szabo, A.; Eaton, W. A. Diffusion-limited contact formation in unfolded cytochrome c: Estimating the maximum rate of protein folding. Proc. Natl. Acad. Sci. U. S. A. 1996, 93, 11615-11617. (2) Bieri, O.; Kiefhaber, T. Elementary steps in protein folding. Biol. Chem. 1999, 380 (7-8), 923-929. (3) Bieri, O.; Wirz, J.; Hellrung, B.; Schutkowski, M.; Drewello, M.; Kiefhaber, T. The speed limit for protein folding measured by triplet-triplet energy transfer. Proc. Natl. Acad. Sci. U. S. A. 1999, 96 (17), 9597-9601.
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Page 28 of 46
(4) Lipman, E. A.; Schuler, B.; Bakajin, O.; Eaton, W. A. Single-molecule measurement of protein folding kinetics. Science 2003, 301 (5637), 1233-1235. (5) Schuler, B.; Lipman, E. A.; Eaton, W. A. Probing the free-energy surface for protein folding with single-molecule fluorescence spectroscopy. Nature 2002, 419 (6908), 743-747. (6) Buscaglia, M.; Lapidus, L. J.; Eaton, W. A.; Hofrichter, J. Effects of denaturants on the dynamics of loop formation in polypeptides. Biophys. J. 2006, 91, 276-288. (7) Lapidus, L. J.; Eaton, W. A.; Hofrichter, J. Measuring the rate of intramolecular contact formation in polypeptides. Proc. Natl. Acad. Sci. U. S. A. 2000, 97 (13), 7220-7225. (8) Lapidus, L. J.; Steinbach, P. J.; Eaton, W. A.; Szabo, A.; Hofrichter, J. Effects of chain stiffness on the dynamics of loop formation in polypeptides. Appendix: Testing a 1-dimensional diffusion model for peptide dynamics. J. Phys. Chem. B 2002, 106, 11628-11640. (9) Waldauer, S. A.; Bakajin, O.; Lapidus, L. J. Extremely slow intramolecular diffusion in unfolded protein L. Proc. Natl. Acad. Sci. U. S. A. 2010, 107 (31), 13713-13717. (10) Fierz, B.; Kiefhaber, T. End-to-end vs interior loop formation kinetics in unfolded polypeptide chains. . J. Am. Chem. Soc. 2007, 129, 672-679. (11) Krieger, F.; Moglich, A.; Kiefhaber, T. Effect of proline and glycine residues on dynamics and barriers of loop formation in polypeptide chains. J. Am. Chem. Soc. 2005, 127 (10), 33463352.
ACS Paragon Plus Environment
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Page 29 of 46 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
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(12) Moglich, A.; Joder, K.; Kiefhaber, T. End-to-end distance distributions and intrachain diffusion constants in unfolded polypeptide chains indicate intramolecular hydrogen bond formation. Proc. Natl. Acad. Sci. U. S. A. 2006, 103 (33), 12394-12399. (13) Moglich, A.; Krieger, F.; Kiefhaber, T. Molecular basis for the effect of urea and guanidinium chloride on the dynamics of unfolded polypeptide chains. J. Mol. Biol. 2005, 345 (1), 153-162. (14) Haas, E.; Steinberg, I. Z. Intramolecular dynamics of chain molecules monitored by fluctuations in efficiency of excitation energy transfer. A theoretical study. Biophys. J. 1984, 46, 429-437. (15) Ratner, V.; Sinev, M.; Haas, E. Determination of intramolecular distance distribution during protein folding on the millisecond timescale. J. Mol. Biol. 2000, 299, 1363-1371. (16) Sherman, E.; Itkin, A.; Kuttner, Y. Y.; Rhoades, E.; Amir, D.; Haas, E.; Haran, G. Using fluorescence correlation spectroscopy to study conformational changes in denatured proteins. Biophys. J. 2008, 94 (12), 4819-4827. (17) Shoemaker, B. A.; Portman, J. J.; Wolynes, P. G. Speeding molecular recognition by using the folding funnel: the fly-casting mechanism. Proc. Natl. Acad. Sci. U. S. A. 2000, 97 (16), 88688873. (18) de Gennes, P. Kinetics of diffusion‐controlled processes in dense polymer systems. I. Nonentangled regimes. J. Chem. Phys. 1982, 76, 3316-3321.
ACS Paragon Plus Environment
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The Journal of Physical Chemistry 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
Page 30 of 46
(19) Borgia, A.; Borgia, M. B.; Bugge, K.; Kissling, V. M.; Heidarsson, P. O.; Fernandes, C. B.; Sottini, A.; Soranno, A.; Buholzer, K. J.; Nettels, D.; et al. Extreme disorder in an ultrahigh-affinity protein complex. Nature 2018, 555 (7694), 61-66. (20) Schuler, B.; Eaton, W. A. Protein folding studied by single-molecule FRET. Curr. Opin. Struct. Biol. 2008, 18 (1), 16-26. (21) Neupane, K.; Manuel, A. P.; Lambert, J.; Woodside, M. T. Transition-path probability as a test of reaction-coordinate quality reveals DNA hairpin folding is a one-dimensional diffusive process J. Phys. Chem. Lett. 2015, 6, 1005-1010. (22) Neupane, K.; Manuel, A. P.; Woodside, M. Protein folding trajectories can be described quantitatively by one-dimensional diffusion over measured energy landscapes. Nat. Phys. 2016, 12, 700-703. (23) Dudko, O. K.; Mathe, J.; Szabo, A.; Meller, A.; Hummer, G. Extracting kinetics from single-molecule force spectroscopy: nanopore unzipping of DNA hairpins. Biophys. J. 2007, 92 (12), 4188-4195. (24) Dudko, O. K.; Hummer, G.; Szabo, A. Theory, analysis, and interpretation of singlemolecule force spectroscopy experiments. Proc. Natl. Acad. Sci. U. S. A. 2008, 105 (41), 1575515760. (25) Chung, H. S.; Eaton, W. A. Single-molecule fluorescence probes dynamics of barrier crossing. Nature 2013, 502 (7473), 685-688. (26) Socci, N. D.; Onuchic, J. N.; Wolynes, P. G. Diffusive dynamics of the reaction coordinate for protein folding funnels. J. Chem. Phys. 1996, 104, 5860-5868.
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(27) Best, R. B.; Hummer, G. Diffusive model of protein folding dynamics with Kramers turnover in rate. Phys. Rev. Lett. 2006, 96 (22), 228104. (28) Best, R. B.; Hummer, G. Coordinate-dependent diffusion in protein folding. Proc. Natl. Acad. Sci. U. S. A. 2010, 107 (3), 1088-1093. (29) Best, R. B.; Hummer, G. Diffusion models of protein folding. Phys. Chem. Chem. Phys. 2011, 13 (38), 16902-16911. (30) Kirmizialtin, S.; Huang, L.; Makarov, D. E. Topography of the free energy landscape probed via mechanical unfolding of proteins. J. Chem. Phys. 2005, 122, 234915. (31) Li, P.-C.; Makarov, D. E. Theoretical studies of the mechanical unfolding of the muscle protein titin: Bridging the time-scale gap between simulation and experiment. J. Chem. Phys. 2003, 119, 9260. (32) Toan, N. M.; Morrison, G.; Hyeon, C.; Thirumalai, D. Kinetics of loop formation in polymer chains. J. Phys. Chem. B 2008, 112 (19), 6094-6106. (33) Hinczewski, M.; Gebhardt, J. C.; Rief, M.; Thirumalai, D. From mechanical folding trajectories to intrinsic energy landscapes of biopolymers. Proc. Natl. Acad. Sci. U. S. A. 2013, 110 (12), 4500-4505. (34) Bryngelson, J. D.; Wolynes, P. G. Intermediates and barrier crossing in a random energy Model (with applications to protein folding). J. Phys. Chem. 1989, 93, 6902-6915. (35) Szabo, A.; Schulten, K.; Schulten, Z. First passage time approach to diffusion controlled reactions. J. Chem. Phys. 1980, 72, 4350.
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Page 32 of 46
(36) Kramers, H. A. Brownian motion in a field of force and the diffusion model of chemical reactions. Physica 1940, 7, 284-304. (37) Peters, B., Reaction rate theory and rare events Elsevier: 2017; p 634. (38) Berezhkovskii, A. M.; Szabo, A. Diffusion along the splitting/commitment probability reaction coordinate. J. Phys. Chem. B 2013, 117 (42), 13115-13119. (39) Lu, J.; Vanden-Eijnden, E. Exact dynamical coarse-graining without time-scale separation. J. Chem. Phys. 2014, 141 (4), 044109. (40) Krivov, S. V. Is protein folding sub-diffusive? PLoS Comput. Biol. 2010, 6 (9), 1000921. (41) Hinczewski, M.; von Hansen, Y.; Dzubiella, J.; Netz, R. R. How the diffusivity profile reduces the arbitrariness of protein folding free energies. J. Chem. Phys. 2010, 132 (24), 245103. (42) Lannon, H.; Haghpanah, J. S.; Montclare, J. K.; Vanden-Eijnden, E.; Brujic, J. Force-clamp experiments reveal the free-energy profile and diffusion coefficient of the collapse of protein molecules. Phys. Rev. Lett. 2013, 110 (12), 128301. (43) Zhang, Q.; Brujic, J.; Vanden-Eijnden, E. Reconstructing free energy profiles from nonequilibrium relaxation trajectories. J. Stat. Phys. 2011, 144 (2), 344-366. (44) Berezhkovskii, A. M.; Makarov, D. E. Communication: Coordinate-dependent diffusivity from single molecule trajectories. J. Chem. Phys. 2017, 147 (20), 201102. (45) Mugnai, M. L.; Elber, R. Extracting the diffusion tensor from molecular dynamics simulation with Milestoning. J. Chem. Phys. 2015, 142 (1), 014105.
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(46) Neupane, K.; Foster, D. A.; Dee, D. R.; Yu, H.; Wang, F.; Woodside, M. T. Direct observation of transition paths during the folding of proteins and nucleic acids. Science 2016, 352 (6282), 239-242. (47) Yu, H.; Dee, D. R.; Liu, X.; Brigley, A. M.; Sosova, I.; Woodside, M. T. Protein misfolding occurs by slow diffusion across multiple barriers in a rough energy landscape. Proc. Natl. Acad. Sci. U. S. A. 2015, 112 (27), 8308-8313. (48) Yu, H.; Gupta, A. N.; Liu, X.; Neupane, K.; Brigley, A. M.; Sosova, I.; Woodside, M. T. Energy landscape analysis of native folding of the prion protein yields the diffusion constant, transition path time, and rates. Proc. Natl. Acad. Sci. U. S. A. 2012, 109 (36), 14452-14457. (49) Chung, H. S.; Eaton, W. A. Protein folding transition path times from single molecule FRET. Curr. Opin. Struct. Biol. 2018, 48, 30-39. (50) Hagen, S. J. Solvent viscosity and friction in protein folding dynamics. Curr. Protein Pept. Sci. 2010, 11 (5), 385-395. (51) Hagen, S. J.; Qiu, L.; Pabit, S. A. Diffusional limits to the speed of protein folding: fact or friction? J. Phys.: Condens. Matter 2005, 17, S1503-S1514. (52) Ansari, A.; Jones, C. M.; Henry, E. R.; Hofrichter, J.; Eaton, W. A. The role of solvent viscosity in the dynamics of protein conformational changes. Science 1992, 256 (5065), 17961798. (53) Sagnella, D. E.; Straub, J. E.; Thirumalai, D. Time scales and pathways for kinetic energy relaxation in solvated proteins: Application to carbonmonoxy myoglobin. J. Chem. Phys. 2000, 113, 7702.
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Page 34 of 46
(54) Cellmer, T.; Henry, E. R.; Hofrichter, J.; Eaton, W. A. Measuring internal friction of an ultrafast-folding protein. Proc. Natl. Acad. Sci. U. S. A. 2008, 105 (47), 18320-18325. (55) Pabit, S. A.; Roder, H.; Hagen, S. J. Internal friction controls the speed of protein folding from a compact configuration. Biochemistry 2004, 43 (39), 12532-12538. (56) Plaxco, K. W.; Baker, D. Limited internal friction in the rate-limiting step of a two-state protein folding reaction. Proc. Natl. Acad. Sci. U. S. A. 1998, 95 (23), 13591-13596. (57) Waldauer, S. A.; Bakajin, O.; Lapidus, L. J. Extremely slow intramolecular diffusion in unfolded protein L. Proc. Natl. Acad. Sci. U. S. A. 2010, 107 (31), 13713-13717. (58) Soranno, A.; Holla, A.; Dingfelder, F.; Nettels, D.; Makarov, D. E.; Schuler, B. Integrated view of internal friction in unfolded proteins from single-molecule FRET, contact quenching, theory, and simulations. Proc. Natl. Acad. Sci. U. S. A. 2017, 114 (10), E1833-E1839. (59) Soranno, A.; Zosel, F.; Hofmann, H. Internal friction in an intrinsically disordered proteinComparing Rouse-like models with experiments. J. Chem. Phys. 2018, 148 (12), 123326. (60) Borgia, A.; Wensley, B. G.; Soranno, A.; Nettels, D.; Borgia, M. B.; Hoffmann, A.; Pfeil, S. H.; Lipman, E. A.; Clarke, J.; Schuler, B. Localizing internal friction along the reaction coordinate of protein folding by combining ensemble and single-molecule fluorescence spectroscopy. Nat. Commun. 2012, 3, 1195. (61) Zwanzig, R. Diffusion in a rough potential. Proc. Natl. Acad. Sci. U. S. A. 1988, 85 (7), 2029-2030.
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(62) Hyeon, C.; Thirumalai, D. Can energy landscape roughness of proteins and RNA be measured by using mechanical unfolding experiments? Proc. Natl. Acad. Sci. U. S. A. 2003, 100 (18), 10249-10253. (63) Schulz, J. C.; Schmidt, L.; Best, R. B.; Dzubiella, J.; Netz, R. R. Peptide chain dynamics in light and heavy water: zooming in on internal friction. J. Am. Chem. Soc. 2012, 134 (14), 62736279. (64) Serr, A.; Horinek, D.; Netz, R. R. Polypeptide friction and adhesion on hydrophobic and hydrophilic surfaces: a molecular dynamics case study. J. Am. Chem. Soc. 2008, 130 (37), 1240812413. (65) Chung, H. S.; Piana-Agostinetti, S.; Shaw, D. E.; Eaton, W. A. Structural origin of slow diffusion in protein folding. Science 2015, 349 (6255), 1504-1510. (66) de Sancho, D.; Sirur, A.; Best, R. B. Molecular origins of internal friction effects on proteinfolding rates. Nat. Commun. 2014, 5, 4307. (67) Zheng, W.; De Sancho, D.; Hoppe, T.; Best, R. B. Dependence of internal friction on folding mechanism. J. Am. Chem. Soc. 2015, 137 (9), 3283-3290. (68) Avdoshenko, S. M.; Das, A.; Satija, R.; Papoian, G. A.; Makarov, D. E. Theoretical and computational validation of the Kuhn barrier friction mechanism in unfolded proteins. Sci. Rep. 2017, 7 (1), 269. (69) Echeverria, I.; Makarov, D. E.; Papoian, G. A. Concerted dihedral rotations give rise to internal friction in unfolded proteins. J. Am. Chem. Soc. 2014, 136 (24), 8708-8713.
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Page 36 of 46
(70) De Gennes, P. G., Scaling concepts in polymer physics. Cornell University Press: Ithaca, N.Y., 1979. (71) Bazua, E. R.; Williams, M. C. Molecular formulation of internal viscosity in polymer dynamics, and stress symmetry. J. Chem. Phys. 1973, 59 (6), 2858-2868. (72) MacInnes, D. A. Internal viscosity in the dynamics of polymer molecules. J. Polym. Sci., Part B: Polym. Phys. 1977, 15, 465-476. (73) Khatri, B. S.; Mcleish, T. C. B. Rouse model with internal friction: A coarse grained framework for single biopolymer dynamics. Macromolecules 2007, 40 (18), 6770-6777. (74) Adelman, S. A.; Freed, K. F. Microscopic theory of polymer internal viscosity: Mode coupling approximation for the Rouse model. J. Chem. Phys. 1977, 67, 1380-1393. (75) Portman, J. J.; Takada, S.; Wolynes, P. G. Microscopic theory of protein folding rates. II. Local reaction coordinates. J. Chem. Phys. 2001, 114, 5082-5096. (76) Soranno, A.; Buchli, B.; Nettels, D.; Cheng, R. R.; Muller-Spath, S.; Pfeil, S. H.; Hoffmann, A.; Lipman, E. A.; Makarov, D. E.; Schuler, B. Quantifying internal friction in unfolded and intrinsically disordered proteins with single-molecule spectroscopy. Proc. Natl. Acad. Sci. U. S. A. 2012, 109, 17800-17806. (77) Plaxco, K. W.; Gross, M. Unfolded, yes, but random? Never! Nat. Struct. Biol. 2001, 8 (8), 659-660. (78) I. S. Millet; Doniach, S.; Plaxco, K. W. Towards a taxonomy of the denatured state: small angle scattering studies of unfolded proteins. Adv. Protein Chem. 2002, 62, 241-262.
ACS Paragon Plus Environment
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Page 37 of 46 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
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(79) Kohn, J. E.; Millett, I. S.; Jacob, J.; Zagrovic, B.; Dillon, T. M.; Cingel, N.; Dothager, R. S.; Seifert, S.; Thiyagarajan, P.; Sosnick, T. R.; et al. Random-coil behavior and the dimensions of chemically unfolded proteins. Proc. Natl. Acad. Sci. U. S. A. 2004, 101 (34), 12491-12496. (80) McCarney, E. R.; Werner, J. H.; Ruczinski, I.; Makarov, D. E.; Keller, R. A.; Goodwin, P. M.; Plaxco, K. W. Site-specific deviations from random coil dimensions in a highly denatured protein; A single molecule study. J. Mol. Biol. 2005, 352, 672-682. (81) Wang, Z.; Plaxco, K. W.; Makarov, D. E. Influence of local and residual structures on the scaling behavior and dimensions of unfolded proteins. Biopolymers 2007, 86 (4), 321-328. (82) Tran, H. T.; Wang, X.; Pappu, R. V. Reconciling observations of sequence-specific conformational propensities with the generic polymeric behavior of denatured proteins. Biochemistry 2005, 44 (34), 11369-11380. (83) Cheng, R. R.; Uzawa, T.; Plaxco, K. W.; Makarov, D. E. Universality in the timescales of internal loop formation in unfolded proteins and single-stranded oligonucleotides. Biophys. J. 2010, 99 (12), 3959-3968. (84) Cheng, R. R.; Hawk, A. T.; Makarov, D. E. Exploring the role of internal friction in the dynamics of unfolded proteins using simple polymer models. J. Chem. Phys. 2013, 138, 074112. (85) Stadler, A. M.; Stingaciu, L.; Radulescu, A.; Holderer, O.; Monkenbusch, M.; Biehl, R.; Richter, D. Internal nanosecond dynamics in the intrinsically disordered myelin basic protein. J. Am. Chem. Soc. 2014, 136 (19), 6987-6994. (86) Samanta, N.; Chakrabarti, R. End to end loop formation in a single polymer chain with internal friction. Chem. Phys. Lett. 2013, 582, 71-77.
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Page 38 of 46
(87) Makarov, D. E. Interplay of non-Markov and internal friction effects in the barrier crossing kinetics of unfolded proteins. J. Chem. Phys. 2013, 138, 014102. (88) Samanta, N.; Ghosh, J.; Chakrabarti, R. Looping and reconfiguration dynamics of a flexible chain with internal friction. AIP Adv. 2014, 4, 067102. (89) Samanta, N.; Chakrabarti, R. Looping dynamics of a flexible chain with internal friction at different degrees of compactness. Physica A 2015, 436, 377-386. (90) Bian, Y.; Li, P.; Zhao, N. Effects of internal friction on contact formation dynamics of polymer chain. Mol. Phys. 2018, 116 (7-8), 1026-1036. (91) Uzawa, T.; Isoshima, T.; Ito, Y.; Ishimori, K.; Makarov, D. E.; Plaxco, K. W. Sequence and temperature dependence of the end-to-end collision dynamics of single-stranded DNA. Biophys. J. 2013, 104 (11), 2485-2492. (92) Samanta, H. S.; Zhuravlev, P. I.; Hinczewski, M.; Hori, N.; Chakrabarti, S.; Thirumalai, D. Protein collapse is encoded in the folded state architecture. Soft Matter 2017, 13 (19), 3622-3638. (93) Hofmann, H.; Soranno, A.; Borgia, A.; Gast, K.; Nettels, D.; Schuler, B. Polymer scaling laws of unfolded and intrinsically disordered proteins quantified with single-molecule spectroscopy. Proc. Natl. Acad. Sci. U. S. A. 2012, 109 (40), 16155-16160. (94) Schuler, B.; Soranno, A.; Hofmann, H.; Nettels, D. Single-molecule FRET spectroscopy and the polymer physics of unfolded and intrinsically disordered proteins. Annu. Rev. Biophys. 2016, 45, 207-231.
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Page 39 of 46 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
The Journal of Physical Chemistry
(95) Millet, I. S.; Doniach, S.; Plaxco, K. W. Towards a taxonomy of the denatured state: small angle scattering studies of unfolded proteins. Adv. Protein Chem. 2002, 62, 241-262. (96) Camacho, C. J.; Thirumalai, D. Kinetics and thermodynamics of folding in model proteins. Proc. Natl. Acad. Sci. U.S.A 1993, 90, 6369-6372. (97) Thirumalai, D. From minimal models to real proteins: Time scales for proteinfolding kinetics. J. Phys. 1995, 5, 1457-1467. (98) Fuertes, G.; Banterle, N.; Ruff, K. M.; Chowdhury, A.; Mercadante, D.; Koehler, C.; Kachala, M.; Estrada Girona, G.; Milles, S.; Mishra, A.; Onck, P. R.; et al. Decoupling of size and shape fluctuations in heteropolymeric sequences reconciles discrepancies in SAXS vs. FRET measurements. Proc. Natl. Acad. Sci. U. S. A. 2017, 114, E6342-E6351. (99) Ziv, G.; Thirumalai, D.; Haran, G. Collapse transition in proteins. Phys. Chem. Chem. Phys. 2009, 11 (1), 83-93. (100) O'Brien, E. P.; Ziv, G.; Haran, G.; Brooks, B. R.; Thirumalai, D. Effects of denaturants and osmolytes on proteins are accurately predicted by the molecular transfer model. Proc. Natl. Acad. Sci. U. S. A. 2008, 105 (36), 13403-13408. (101) Morrison, G.; Hyeon, C.; Hinczewski, M.; Thirumalai, D. Compaction and tensile forces determine the accuracy of folding landscape parameters from single molecule pulling experiments. Phys. Rev. Lett. 2011, 106 (13), 138102. (102) Luo, G.; Andricioaei, I.; Xie, X. S.; Karplus, M. Dynamic distance disorder in proteins is caused by trapping. J. Phys. Chem. B 2006, 110 (19), 9363-9367.
ACS Paragon Plus Environment
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Page 40 of 46
(103) Meroz, Y.; Ovchinnikov, V.; Karplus, M. Coexisting origins of subdiffusion in internal dynamics of proteins. Phys. Rev. E 2017, 95 (6-1), 062403. (104) Cote, Y.; Senet, P.; Delarue, P.; Maisuradze, G. G.; Scheraga, H. A. Anomalous diffusion and dynamical correlation between the side chains and the main chain of proteins in their native state. Proc. Natl. Acad. Sci. U. S. A. 2012, 109 (26), 10346-10351. (105) Sangha, A. K.; Keyes, T. Proteins fold by subdiffusion of the order parameter. J. Phys. Chem. B 2009, 113 (48), 15886-15894. (106) Satija, R.; Das, A.; Makarov, D. E. Transition path times reveal memory effects and anomalous diffusion in the dynamics of protein folding. J. Chem. Phys. 2017, 147 (15), 152707. (107) Gowdy, J.; Batchelor, M.; Neelov, I.; Paci, E. Nonexponential kinetics of loop formation in proteins and peptides: a signature of rugged free energy landscapes? J. Phys. Chem. B 2017, 121 (41), 9518-9525. (108) Cheng, R. R.; Makarov, D. E. Failure of one-dimensional Smoluchowski diffusion models to describe the duration of conformational rearrangements in floppy, diffusive molecular systems: a case study of polymer cyclization. J. Chem. Phys. 2011, 134 (8), 085104. (109) Hu, X.; Hong, L.; Smith, M. D.; Neusius, T.; Cheng, X.; Smith, J. C. The dynamics of single protein molecvules is non-equilibrium and self-similar over thirteen decades in time. Nat. Phys. 2016, 12, 171-174. (110) Volk, M.; Milanesi, L.; Waltho, J. P.; Hunter, C. A.; Beddard, G. S. The roughness of the protein energy landscape results in anomalous diffusion of the polypeptide backbone. Phys. Chem. Chem. Phys. 2015, 17 (2), 762-782.
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The Journal of Physical Chemistry
(111) Grossman-Haham, I.; Rosenblum, G.; Namani, T.; Hofmann, H. Slow domain reconfiguration causes power-law kinetics in a two-state enzyme. Proc. Natl. Acad. Sci. U. S. A. 2018, 115 (3), 513-518. (112) Piana, S.; Lindorff-Larsen, K.; Shaw, D. E. Protein folding kinetics and thermodynamics from atomistic simulation. Proc. Natl. Acad. Sci. U. S. A. 2012, 109 (44), 17845-17850. (113) Panja, D. Generalized Langevin equation formulation for anomalous polymer dynamics. J. Stat. Mech: Theory Exp. 2010, L02001. (114) Kantor, Y.; Kardar, M. Anomalous diffusion with absorbing boundary. Phys. Rev. E 2007, 76 (6 Pt 1), 061121. (115) Chen, X.; Zaro, J. L.; Shen, W.-C. Fusion protein linkers: property, design and functionality. Adv. Drug Delivery Rev. 2013, 65 (10), 1357-1369. (116) Pronk, S.; Pall, S.; Schulz, R.; Larsson, P.; Bjelkmar, P.; Apostolov, R.; Shirts, M. R.; Smith, J. C.; Kasson, P. M.; van der Spoel, D.; et al. GROMACS 4.5: a high-throughput and highly parallel open source molecular simulation toolkit. Bioinformatics 2013, 29 (7), 845-854. (117) Duan, Y.; Wu, C.; Chowdhury, S.; Lee, M. C.; Xiong, G.; Zhang, W.; Yang, R.; Cieplak, P.; Luo, R.; Lee, T.; Caldwell, J.; Wang, J.; et al. A point-charge force field for molecular mechanics simulations of proteins based on condensed-phase quantum mechanical calculations. J. Comput. Chem. 2003, 24 (16), 1999-2012. (118) Piana, S.; Donchev, A. G.; Robustelli, P.; Shaw, D. E. Water dispersion interactions strongly influence simulated structural properties of disordered protein States. J. Phys. Chem. B 2015, 119 (16), 5113-5123.
ACS Paragon Plus Environment
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Page 42 of 46
(119) Darden, T.; York, D.; Pedersen, L. Particle mesh Ewald: An N⋅ log (N) method for Ewald sums in large systems. J. Chem. Phys. 1993, 98 (12), 10089-10092. (120) Hess, B. P-LINCS: A parallel linear constraint solver for molecular simulation. J. Chem. Theory Comput. 2008, 4 (1), 116-122. (121) Bussi, G.; Donadio, D.; Parrinello, M. Canonical sampling through velocity rescaling. J. Chem. Phys. 2007, 126 (1), 014101. (122) Parinello, M.; Rahman, A. Polymorphic transitions in single crystals: A new molecular dynamics method. J. Appl. Phys. 1981, 52 (12), 7182-7190. (123) Jorgensen, W. L.; Maxwell, D. S.; Tirado-Rives, J. Development and testing of the OPLS all-atom force field on conformational energetics and properties of organic liquids. J. Am. Chem. Soc 1996, 118 (45), 11225-11236. (124) Kaminski, G. A.; Friesner, R. A.; Tirado-Rives, J.; Jorgensen, W. L. Evaluation and reparametrization of the OPLS-AA force field for proteins via comparison with accurate quantum chemical calculations on peptides. J. Phys. Chem. B 2001, 105 (28), 6474-6487. (125) van der Spoel, D.; Berendsen, H. Molecular dynamics simulations of Leu-enkephalin in water and DMSO. Biophys. J. 1997, 72 (5), 2032-2041. (126) Plotkin, S. S.; Wolynes, P. G. Non-Markovian configurational diffusion and reaction coordinates for protein folding. Phys. Rev. Lett. 1998, 80, 5015.
ACS Paragon Plus Environment
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The Journal of Physical Chemistry
(127) Senet, P.; Maisuradze, G. G.; Foulie, C.; Delarue, P.; Scheraga, H. A. How main-chains of proteins explore the free-energy landscape in native states. Proc. Natl. Acad. Sci. U. S. A. 2008, 105 (50), 19708-19713. (128) Berezhkovskii, A. M.; Makarov, D. E. Single-molecule test for markovianity of the dynamics along a reaction coordinate. J. Phys. Chem. Lett. 2018, 2190-2195. (129) Metzler, R.; Jeon, J. H.; Cherstvy, A. G.; Barkai, E. Anomalous diffusion models and their properties: non-stationarity, non-ergodicity, and ageing at the centenary of single particle tracking. Phys. Chem. Chem. Phys. 2014, 16 (44), 24128-24164. (130) Makarov, D. E. Computer simulations and theory of protein translocation. Acc. Chem. Res. 2009, 42 (2), 281-289. (131) Huang, L.; Makarov, D. E. The rate constant of polymer reversal inside a pore. J. Chem. Phys. 2008, 128 (11), 114903. (132) Metzler, R.; Klafter, J. The random walk's guide to anomalous diffusion: a fractional dynamics approach. Phys. Rep. 2000, 339, 1-77. (133) Bahar, I.; Erman, B.; Haliloglu, T.; Jernigan, R. Efficient characterization of collective motions and interresidue correlations in proteins by low-resolution simulations. Biochemistry 1997, 36 (44), 13512-13523. (134) Watkins, L. P.; Yang, H. Detection of intensity change points in time-resolved singlemolecule measurements. J. Phys. Chem. B 2005, 109 (1), 617-628.
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Page 44 of 46
(135) Goh, K.-I.; Barabási, A.-L. Burstiness and memory in complex systems. Europhys. Lett. 2008, 81 (4), 48002. (136) Hoffmann, A.; Kane, A.; Nettels, D.; Hertzog, D. E.; Baumgartel, P.; Lengefeld, J.; Reichardt, G.; Horsley, D. A.; Seckler, R.; Bakajin, O.; et al. Mapping protein collapse with singlemolecule fluorescence and kinetic synchrotron radiation circular dichroism spectroscopy. Proc. Natl. Acad. Sci. U. S. A. 2007, 104 (1), 105-110. (137) Nettels, D.; Muller-Spath, S.; Kuster, F.; Hofmann, H.; Haenni, D.; Ruegger, S.; Reymond, L.; Hoffmann, A.; Kubelka, J.; Heinz, B.; et al. Single-molecule spectroscopy of the temperatureinduced collapse of unfolded proteins. Proc. Natl. Acad. Sci. U. S. A. 2009, 106, 20740-20745. (138) Wang, Z.; Makarov, D. E. Nanosecond dynamics of single polypeptide molecules revealed by photoemission statistics of fluorescence resonance energy transfer: A theoretical study. J. Phys. Chem. B 2003, 107, 5617-5622. (139) Gopich, I. V.; Nettels, D.; Schuler, B.; Szabo, A. Protein dynamics from single-molecule fluorescence intensity correlation functions. J. Chem. Phys. 2009, 131 (9), 095102. (140) Nettels, D.; Gopich, I. V.; Hoffmann, A.; Schuler, B. Ultrafast dynamics of protein collapse from single-molecule photon statistics. Proc. Natl. Acad. Sci. U. S. A. 2007, 104 (8), 26552660. (141) Nettels, D.; Hoffmann, A.; Schuler, B. Unfolded protein and peptide dynamics investigated with single-molecule FRET and correlation spectroscopy from picoseconds to seconds. J. Phys. Chem. B 2008, 112 (19), 6137-6146.
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(142) Schuler, B.; Hofmann, H. Single-molecule spectroscopy of protein folding dynamics-expanding scope and timescales. Curr. Opin. Struct. Biol. 2013, 23 (1), 36-47. (143) Doi, M.; Edwards, S. F., The theory of polymer dynamics. Clarendon Press ; Oxford University Press: Oxford [Oxfordshire], New York, 1986; p xiii, 391 p. (144) Makarov, D. E. Spatiotemporal correlations in denatured proteins: The dependence of fluorescence resonance energy transfer (FRET)-derived protein reconfiguration times on the location of the FRET probes. J. Chem. Phys. 2010, 132 (3), 035104. (145) Chaudhury, S.; Cherayil, B. J. A model of anomalous chain translocation dynamics. J. Phys. Chem. B 2008, 112 (50), 15973-15979. (146) Okuyama, S.; Oxtoby, D. W. Non-Markovian dynamics and barrier crossing rates at high viscosity. J. Chem. Phys. 1986, 84, 5830-5835. (147) Okuyama, S.; Oxtoby, D. W. The generalized Smoluchowski equation and non-Markovian dynamics. J. Chem. Phys. 1986, 84, 5824-5829.
TOC. Effect of confinement on peptide conformation.
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Biographies Atanu Das received his B.S. and M. S. degrees from University of Calcutta in West Bengal, India. He earned his Ph.D. in 2010 from University of Calcutta in the group of Chaitali Mukhopadhyay. He is currently a postdoctoral fellow in the Department of Chemistry at the University of Texas at Austin. Dmitrii E. Makarov graduated from the Moscow Institute of Physics and Technology in 1990 and earned a PhD in theoretical physics from the Institute of Chemical Physics in 1992. He is currently a Professor of Chemistry at the University of Texas at Austin. His expertise is in theoretical and computational chemical physics and in biophysics.
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