posted on 2016-01-26, 00:00authored byJian Mao, Pengyu Chen, Junshi Liang, Ruohai Guo, Li-Tang Yan
Two-dimensional
nanomaterials, such as graphene and transitional
metal dichalcogenide nanosheets, are promising materials for the development
of antimicrobial surfaces and the nanocarriers for intracellular therapy.
Understanding cell interaction with these emerging materials is an
urgently important issue to promoting their wide applications. Experimental
studies suggest that two-dimensional nanomaterials enter cells mainly
through receptor-mediated endocytosis. However, the detailed molecular
mechanisms and kinetic pathways of such processes remain unknown.
Here, we combine computer simulations and theoretical derivation of
the energy within the system to show that the receptor-mediated transport
of two-dimensional nanomaterials, such as graphene nanosheet across
model lipid membrane, experiences a flat vesiculation event governed
by the receptor density and membrane tension. The graphene nanosheet
is found to undergo revolution relative to the membrane and, particularly,
unique self-rotation around its normal during membrane wrapping. We
derive explicit expressions for the formation of the flat vesiculation,
which reveals that the flat vesiculation event can be fundamentally
dominated by a dimensionless parameter and a defined relationship
determined by complicated energy contributions. The mechanism offers
an essential understanding on the cellular internalization and cytotoxicity
of the emerging two-dimensional nanomaterials.