191 research outputs found
Urea impedes the hydrophobic collapse of partially unfolded proteins.
AbstractProteins are denatured in aqueous urea solution. The nature of the molecular driving forces has received substantial attention in the past, whereas the question how urea acts at different phases of unfolding is not yet well understood at the atomic level. In particular, it is unclear whether urea actively attacks folded proteins or instead stabilizes unfolded conformations. Here we investigated the effect of urea at different phases of unfolding by molecular dynamics simulations, and the behavior of partially unfolded states in both aqueous urea solution and in pure water was compared. Whereas the partially unfolded protein in water exhibited hydrophobic collapses as primary refolding events, it remained stable or even underwent further unfolding steps in aqueous urea solution. Further, initial unfolding steps of the folded protein were found not to be triggered by urea, but instead, stabilized. The underlying mechanism of this stabilization is a favorable interaction of urea with transiently exposed, less-polar residues and the protein backbone, thereby impeding back-reactions. Taken together, these results suggest that, quite generally, urea-induced protein unfolding proceeds primarily not by active attack. Rather, thermal fluctuations toward the unfolded state are stabilized and the hydrophobic collapse of partially unfolded proteins toward the native state is impeded. As a result, the equilibrium is shifted toward the unfolded state
Heterogeneous and rate-dependent streptavidin-biotin unbinding revealed by high-speed force spectroscopy and atomistic simulations
Receptor-ligand interactions are essential for biological function and their
binding strength is commonly explained in terms of static lock-and-key models
based on molecular complementarity. However, detailed information of the full
unbinding pathway is often lacking due, in part, to the static nature of atomic
structures and ensemble averaging inherent to bulk biophysics approaches. Here
we combine molecular dynamics and high-speed force spectroscopy on the
streptavidin-biotin complex to determine the binding strength and unbinding
pathways over the widest dynamic range. Experiment and simulation show
excellent agreement at overlapping velocities and provided evidence of the
unbinding mechanisms. During unbinding, biotin crosses multiple energy barriers
and visits various intermediate states far from the binding pocket while
streptavidin undergoes transient induced fits, all varying with loading rate.
This multistate process slows down the transition to the unbound state and
favors rebinding, thus explaining the long lifetime of the complex. We provide
an atomistic, dynamic picture of the unbinding process, replacing a simple
two-state picture with one that involves many routes to the lock and
rate-dependent induced-fit motions for intermediates, which might be relevant
for other receptor-ligand bonds.Comment: 21 pages, 4 figure
A Molecular Dynamics Simulation of the Human Lysozyme ā Camelid VHH HL6 Antibody System
Amyloid diseases such as Alzheimerās and thrombosis are characterized by an aberrant assembly of specific proteins or protein fragments into fibrils and plaques that are deposited in various tissues and organs. The single-domain fragment of a camelid antibody was reported to be able to combat against wild-type human lysozyme for inhibiting in-vitro aggregations of the amyloidogenic variant (D67H). The present study is aimed at elucidating the unbinding mechanics between the D67H lysozyme and VHH HL6 antibody fragment by using steered molecular dynamics (SMD) simulations on a nanosecond scale with different pulling velocities. The results of the simulation indicated that stretching forces of more than two nano Newton (nN) were required to dissociate the proteinantibody system, and the hydrogen bond dissociation pathways were computed
Mechanical Stretching of Proteins: Calmodulin and Titin
Mechanical unfolding of several domains of calmodulin and titin is studied
using a Go-like model with a realistic contact map and Lennard-Jones contact
interactions. It is shown that this simple model captures the experimentally
observed difference between the two proteins: titin is a spring that is tough
and strong whereas calmodulin acts like a weak spring with featureless
force-displacement curves. The difference is related to the dominance of the
alpha secondary structures in the native structure of calmodulin. The tandem
arrangements of calmodulin unwind simultaneously in each domain whereas the
domains in titin unravel in a serial fashion. The sequences of contact events
during unraveling are correlated with the contact order, i.e. with the
separation between contact making amino acids along the backbone in the native
state. Temperature is found to affect stretching in a profound way.Comment: To be published in a special bio-issue of Physica A; 14 figure
Constraint methods for determining pathways and free energy of activated processes
Activated processes from chemical reactions up to conformational transitions
of large biomolecules are hampered by barriers which are overcome only by the
input of some free energy of activation. Hence, the characteristic and
rate-determining barrier regions are not sufficiently sampled by usual
simulation techniques. Constraints on a reaction coordinate r have turned out
to be a suitable means to explore difficult pathways without changing potential
function, energy or temperature. For a dense sequence of values of r, the
corresponding sequence of simulations provides a pathway for the process. As
only one coordinate among thousands is fixed during each simulation, the
pathway essentially reflects the system's internal dynamics. From mean forces
the free energy profile can be calculated to obtain reaction rates and insight
in the reaction mechanism. In the last decade, theoretical tools and computing
capacity have been developed to a degree where simulations give impressive
qualitative insight in the processes at quantitative agreement with
experiments. Here, we give an introduction to reaction pathways and
coordinates, and develop the theory of free energy as the potential of mean
force. We clarify the connection between mean force and constraint force which
is the central quantity evaluated, and discuss the mass metric tensor
correction. Well-behaved coordinates without tensor correction are considered.
We discuss the theoretical background and practical implementation on the
example of the reaction coordinate of targeted molecular dynamics simulation.
Finally, we compare applications of constraint methods and other techniques
developed for the same purpose, and discuss the limits of the approach
How the biotināstreptavidin interaction was made even stronger: investigation via crystallography and a chimaeric tetramer
The interaction between SA (streptavidin) and biotin is one of the strongest non-covalent interactions in Nature. SA is a widely used tool and a paradigm for proteināligand interactions. We previously developed a SA mutant, termed Tr (traptavidin), possessing a 10-fold lower off-rate for biotin, with increased mechanical and thermal stability. In the present study, we determined the crystal structures of apo-Tr and biotināTr at 1.5Ā Ć
resolution. In apo-SA the loop (L3/4), near biotin's valeryl tail, is typically disordered and open, but closes upon biotin binding. In contrast, L3/4 was shut in both apo-Tr and biotināTr. The reduced flexibility of L3/4 and decreased conformational change on biotin binding provide an explanation for Tr's reduced biotin off- and on-rates. L3/4 includes Ser45, which forms a hydrogen bond to biotin consistently in Tr, but erratically in SA. Reduced breakage of the biotināSer45 hydrogen bond in Tr is likely to inhibit the initiating event in biotin's dissociation pathway. We generated a Tr with a single biotin-binding site rather than four, which showed a simi-larly low off-rate, demonstrating that Tr's low off-rate was governed by intrasubunit effects. Understanding the structural features of this tenacious interaction may assist the design of even stronger affinity tags and inhibitors
Mesodynamics in the SARS nucleocapsid measured by NMR field cycling
Protein motions on all timescales faster than molecular tumbling are encoded in the spectral density. The dissection of complex protein dynamics is typically performed using relaxation rates determined at high and ultra-high field. Here we expand this range of the spectral density to low fields through field cycling using the nucleocapsid protein of the SARS coronavirus as a model system. The field-cycling approach enables site-specific measurements of R1 at low fields with the sensitivity and resolution of a high-field magnet. These data, together with high-field relaxation and heteronuclear NOE, provide evidence for correlated rigid-body motions of the entire Ī²-hairpin, and corresponding motions of adjacent loops with a time constant of 0.8Ā ns (mesodynamics). MD simulations substantiate these findings and provide direct verification of the time scale and collective nature of these motions
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