Network analysis of a proposed exit pathway for protons to the P-side of cytochrome c oxidase.

Cytochrome c Oxidase (CcO) reduces O2, the terminal electron acceptor, to water in the aerobic, respiratory electron transport chain. The energy released by O2 reductions is stored by removing eight protons from the high pH, N-side, of the membrane with four used for chemistry in the active site and four pumped to the low pH, P-side. The proton transfers must occur along controllable proton pathways that prevent energy dissipating movement towards the N-side. The CcO N-side has well established D- and K-channels to deliver protons to the protein interior. The P-side has a buried core of hydrogen-bonded protonatable residues designated the Proton Loading Site cluster (PLS cluster) and many protonatable residues on the P-side surface, providing no obvious unique exit. Hydrogen bond pathways were identified in Molecular Dynamics (MD) trajectories of Rb. sphaeroides CcO prepared in the PR state with the heme a3 propionate and Glu286 in different protonation states. Grand Canonical Monte Carlo sampling of water locations, polar proton positions and residue protonation states in trajectory snapshots identify a limited number of water mediated, proton paths from PLS cluster to the surface via a (P-exit) cluster of residues. Key P-exit residues include His93, Ser168, Thr100 and Asn96. The hydrogen bonds between PLS cluster and P-exit clusters are mediated by a water wire in a cavity centered near Thr100, whose hydration can be interrupted by a hydrophobic pair, Leu255B (near CuA) and Ile99. Connections between the D channel and PLS via Glu286 are controlled by a second, variably hydrated cavity. SIGNIFICANCE STATEMENT: Cytochrome C oxidase plays a crucial role in cellular respiration and energy generation. It reduces O2 to water and uses the released free energy to move protons across mitochondrial and bacterial cell membranes adding to the essential electrochemical gradient. Energy storage requires that protons are taken up from the high pH, N-side and released to the low pH, P-side of the membrane. We identify a potential proton exit from a buried cluster of polar residues (the proton loading site) to the P-side of CcO via paths made up of waters and conserved residues. Two water cavities connect the proton exit pathway to the surface only when hydrated. Changing the degree of hydration may control otherwise energetically favorable proton backflow from the P-side.

Contrasting effects of nanoparticle-protein attraction on amyloid aggregation.

Nanoparticles (NPs) have been experimentally found to either promote or inhibit amyloid aggregation of proteins, but the molecular mechanisms for such complex behaviors remain unknown. Using coarse-grained molecular dynamics simulations, we investigated the effects of varying the strength of nonspecific NP-protein attraction on amyloid aggregation of a model protein, the amyloid-beta peptide implicated in Alzheimer's disease. Specifically, with increasing NP-peptide attraction, amyloid aggregation on the NP surface was initially promoted due to increased local protein concentration on the surface and destabilization of the folded state. However, further increase of NP-peptide attraction decreased the stability of amyloid fibrils and reduced their lateral diffusion on the NP surface necessary for peptide conformational changes and self-association, thus prohibiting amyloid aggregation. Moreover, we found that the relative concentration between protein and NPs also played an important role in amyloid aggregation. With a high NP/protein ratio, NPs that intrinsically promote protein aggregation may display an inhibitive effect by depleting the proteins in solution while having a low concentration of the proteins on each NP's surface. Our coarse-grained molecular dynamics simulation study offers a molecular mechanism for delineating the contrasting and seemingly conflicting effects of NP-protein attraction on amyloid aggregation and highlights the potential of tailoring anti-aggregation nanomedicine against amyloid diseases.

Effect of fullerenol surface chemistry on nanoparticle binding-induced protein misfolding.

Fullerene and its derivatives with different surface chemistry have great potential in biomedical applications. Accordingly, it is important to delineate the impact of these carbon-based nanoparticles on protein structure, dynamics, and subsequently function. Here, we focused on the effect of hydroxylation - a common strategy for solubilizing and functionalizing fullerene - on protein-nanoparticle interactions using a model protein, ubiquitin. We applied a set of complementary computational modeling methods, including docking and molecular dynamics simulations with both explicit and implicit solvent, to illustrate the impact of hydroxylated fullerenes on the structure and dynamics of ubiquitin. We found that all derivatives bound to the model protein. Specifically, the more hydrophilic nanoparticles with a higher number of hydroxyl groups bound to the surface of the protein via hydrogen bonds, which stabilized the protein without inducing large conformational changes in the protein structure. In contrast, fullerene derivatives with a smaller number of hydroxyl groups buried their hydrophobic surface inside the protein, thereby causing protein denaturation. Overall, our results revealed a distinct role of surface chemistry on nanoparticle-protein binding and binding-induced protein misfolding.

Direct observation of a single nanoparticle-ubiquitin corona formation.

The advancement of nanomedicine and the increasing applications of nanoparticles in consumer products have led to administered biological exposure and unintentional environmental accumulation of nanoparticles, causing concerns over the biocompatibility and sustainability of nanotechnology. Upon entering physiological environments, nanoparticles readily assume the form of a nanoparticle-protein corona that dictates their biological identity. Consequently, understanding the structure and dynamics of a nanoparticle-protein corona is essential for predicting the fate, transport, and toxicity of nanomaterials in living systems and for enabling the vast applications of nanomedicine. Here we combined multiscale molecular dynamics simulations and complementary experiments to characterize the silver nanoparticle-ubiquitin corona formation. Notably, ubiquitins competed with citrates for the nanoparticle surface, governed by specific electrostatic interactions. Under a high protein/nanoparticle stoichiometry, ubiquitins formed a multi-layer corona on the particle surface. The binding exhibited an unusual stretched-exponential behavior, suggesting a rich binding kinetics. Furthermore, the binding destabilized the α-helices while increasing the ß-sheet content of the proteins. This study revealed the atomic and molecular details of the structural and dynamic characteristics of nanoparticle-protein corona formation.

Competitive binding of natural amphiphiles with graphene derivatives.

Understanding the transformation of graphene derivatives by natural amphiphiles is essential for elucidating the biological and environmental implications of this emerging class of engineered nanomaterials. Using rapid discrete-molecular-dynamics simulations, we examined the binding of graphene and graphene oxide with peptides, fatty acids, and cellulose, and complemented our simulations by experimental studies of Raman spectroscopy, FTIR, and UV-Vis spectrophotometry. Specifically, we established a connection between the differential binding and the conformational flexibility, molecular geometry, and hydrocarbon content of the amphiphiles. Importantly, our dynamics simulations revealed a Vroman-like competitive binding of the amphiphiles for the graphene oxide substrate. This study provides a mechanistic basis for addressing the transformation, evolution, transport, biocompatibility, and toxicity of graphene derivatives in living systems and the natural environment.

Formation and cell translocation of carbon nanotube-fibrinogen protein corona.

The binding of plasma fibrinogen with both single-walled and multi-walled carbon nanotubes (SWNTs and MWNTs) has been examined. Specifically, our absorbance study indicated that MWNTs were coated with multi-layers of fibrinogen to render a "hard protein corona," while SWNTs were adsorbed with thin layers of the protein to precipitate out of the aqueous phase. In addition, static quenching as a result of energy transfer from fluorescently labeled fibrinogen to their nanotube substrates was revealed by Stern-Volmer analysis. When exposed to HT-29 cells, the nanotubes and fibrinogen could readily dissociate, possibly stemming from their differential affinities for the amphiphilic membrane bilayer.