The seeming contradiction that K channels conduct K ions at maximal throughput rates while not permeating slightly smaller Na ions has perplexed scientists for decades. Although numerous models have addressed selective permeation in K channels, the combination of conduction efficiency and ion selectivity has not yet been linked through a unified functional model. Here, we investigate the mechanism of ion selectivity through atomistic simulations totalling more than 400 μs in length, which include over 7,000 permeation events. Together with free-energy calculations, our simulations show that both rapid permeation of K and ion selectivity are ultimately based on a single principle: the direct knock-on of completely desolvated ions in the channels' selectivity filter. Herein, the strong interactions between multiple 'naked' ions in the four filter binding sites give rise to a natural exclusion of any competing ions. Our results are in excellent agreement with experimental selectivity data, measured ion interaction energies and recent two-dimensional infrared spectra of filter ion configurations.
In the field of self-assembly,
the quest for gaining control over
the supramolecular architecture without affecting the functionality
of the individual molecular building blocks is intrinsically challenging.
By using a combination of synthetic chemistry, cryogenic transmission
electron microscopy, optical absorption measurements, and exciton
theory, we demonstrate that halogen exchange in carbocyanine dye molecules
allows for fine-tuning the diameter of the self-assembled nanotubes
formed by these molecules, while hardly affecting the molecular packing
determined by hydrophobic/hydrophilic interactions. Our findings open
a unique way to study size effects on the optical properties and exciton
dynamics of self-assembled systems under well-controlled conditions.
Self-replication
at the molecular level is often seen as essential
to the early origins of life. Recently a mechanism of self-replication
has been discovered in which replicator self-assembly drives the process.
We have studied one of the examples of such self-assembling self-replicating
molecules to a high level of structural detail using a combination
of computational and spectroscopic techniques. Molecular Dynamics
simulations of self-assembled stacks of peptide-derived replicators
provide insights into the structural characteristics of the system
and serve as the basis for semiempirical calculations of the UV–vis,
circular dichroism (CD) and infrared (IR) absorption spectra that
reflect the chiral organization and peptide secondary structure of
the stacks. Two proposed structural models are tested by comparing
calculated spectra to experimental data from electron microscopy,
CD and IR spectroscopy, resulting in a better insight into the specific
supramolecular interactions that lead to self-replication. Specifically,
we find a cooperative self-assembly process in which β-sheet
formation leads to well-organized structures, while also the aromatic
core of the macrocycles plays an important role in the stability of
the resulting fibers.
In this paper, we present a novel benchmarking method for validating the modelling of vibrational spectra for the amide I region of proteins. We use the linear absorption spectra and two-dimensional infrared spectra of four experimentally well-studied proteins as a reference and test nine combinations of molecular dynamics force fields, vibrational frequency mappings, and coupling models. We find that two-dimensional infrared spectra provide a much stronger test of the models than linear absorption does. The best modelling approach in the present study still leaves significant room for future improvement. The presented benchmarking scheme, thus, provides a way of validating future protocols for modelling the amide I band in proteins.
We present a benchmark study of spectral simulation protocols for the amide I band of proteins. The amide I band is widely used in infrared spectroscopy of proteins due to the large signal intensity, high sensitivity to hydrogen bonding, and secondary structural motifs. This band has, thus, proven valuable in many studies of protein structure-function relationships. We benchmark spectral simulation protocols using two common force fields in combination with several electrostatic mappings and coupling models. The results are validated against experimental linear absorption and two-dimensional infrared spectroscopy for three well-studied proteins. We find two-dimensional infrared spectroscopy to be much more sensitive to the simulation protocol than linear absorption and report on the best simulation protocols. The findings demonstrate that there is still room for ideas to improve the existing models for the amide I band of proteins.
Supramolecular aggregates of synthetic dye molecules offer great perspectives to prepare biomimetic functional materials for light-harvesting and energy transport. The design is complicated by the fact that structure-property relationships are...
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<p>Supramolecular aggregates of synthetic dye molecules offer great perspectives to prepare biomimetic functional materials for light-harvesting and energy transport. The design is complicated by the fact that structure-property relationships are hard to establish, because the molecular packing results from a delicate balance of interactions and the excitonic properties that dictate the optics and excited state dynamics, in turn sensitively depend on this packing. Here we show how an iterative multiscale approach combining molecular dynamics and quantum mechanical exciton modeling can be used to obtain accurate insight into the packing of thousands of cyanine dye molecules in a complex double-walled tubular aggregate in close interaction with its solvent environment. Our approach allows us not only to answer open questions on the structure of these prototypical aggregates, but also about their molecular-scale structural and energetic heterogeneity, and the microscopic origin of their photophysical properties. This opens the route to accurate predictions of energy transport and other functional properties.<br></p>
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