Abstract
MoS2 nanosheet, a new two-dimensional transition metal dichalcogenides nanomaterial, has attracted significant attentions lately due to many potential promising biomedical applications. Meanwhile, there is also a growing concern on its biocompatibility, with little known on its interactions with various biomolecules such as proteins. In this study, we use all-atom molecular dynamics simulations to investigate the interaction of a MoS2 nanosheet with Villin Headpiece (HP35), a model protein widely used in protein folding studies. We find that MoS2 exhibits robust denaturing capability to HP35, with its secondary structures severely destroyed within hundreds of nanosecond simulations. Both aromatic and basic residues are critical for the protein anchoring onto MoS2 surface, which then triggers the successive protein unfolding process. The main driving force behind the adsorption process is the dispersion interaction between protein and MoS2 monolayer. Moreover, water molecules at the interface between some key hydrophobic residues (e.g. Trp-64) and MoS2 surface also help to accelerate the process driven by nanoscale drying, which provides a strong hydrophobic force. These findings might have shed new light on the potential nanotoxicity of MoS2 to proteins with atomic details, which should be helpful in guiding future biomedical applications of MoS2 with its nanotoxicity mitigated.
Highlights
The most common two-dimensional (2D) nanomaterials are probably those carbon-based ones, such as graphene, graphyne and their derivatives, which have attracted tremendous interests in many fields including biomedicine since its discovery[1,2,3,4,5,6,7]
In all simulations with protein HP35, we found that the characteristic helical structures of HP35 have been severely destroyed on MoS2 surface
This is in high contrast with the control run with protein HP35 in bulk water without the MoS2 nanosheet (Fig. 1A), which displays only marginal difference from the initial crystal structure
Summary
Headpiece by MoS2 Nanosheet: Potential Molecular Origin of the received: 02 February 2016 accepted: 02 June 2016 Published: 17 June 2016. We find that MoS2 exhibits robust denaturing capability to HP35, with its secondary structures severely destroyed within hundreds of nanosecond simulations Both aromatic and basic residues are critical for the protein anchoring onto MoS2 surface, which triggers the successive protein unfolding process. It is shown that MoS2 exhibits exceptionally robust denaturation capability to HP35, with the protein secondary structures all severely destroyed within a few hundred nanosecond simulations, indicating a potentially severe nanotoxicity Both the aromatic and basic residues contribute to the initial protein anchoring on the surface of MoS2, which trigger the successive protein unfolding process, with hydrophobic residues play a key role in the denaturing process
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