Giulio Alberini scite author profile

The scientific community has witnessed an exponential increase in the applications of graphene and graphene-based materials in a wide range of fields, from engineering to electronics to biotechnologies and biomedical applications. For what concerns neuroscience, the interest raised by these materials is two-fold. On one side, nanosheets made of graphene or graphene derivatives (graphene oxide, or its reduced form) can be used as carriers for drug delivery. Here, an important aspect is to evaluate their toxicity, which strongly depends on flake composition, chemical functionalization and dimensions. On the other side, graphene can be exploited as a substrate for tissue engineering. In this case, conductivity is probably the most relevant amongst the various properties of the different graphene materials, as it may allow to instruct and interrogate neural networks, as well as to drive neural growth and differentiation, which holds a great potential in regenerative medicine. In this review, we try to give a comprehensive view of the accomplishments and new challenges of the field, as well as which in our view are the most exciting directions to take in the immediate future. These include the need to engineer multifunctional nanoparticles (NPs) able to cross the blood-brain-barrier to reach neural cells, and to achieve on-demand delivery of specific drugs. We describe the state-of-the-art in the use of graphene materials to engineer three-dimensional scaffolds to drive neuronal growth and regeneration in vivo, and the possibility of using graphene as a component of hybrid composites/multi-layer organic electronics devices. Last but not least, we address the need of an accurate theoretical modeling of the interface between graphene and biological material, by modeling the interaction of graphene with proteins and cell membranes at the nanoscale, and describing the physical mechanism(s) of charge transfer by which the various graphene materials can influence the excitability and physiology of neural cells.

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Molecular Dynamics Simulations of Ion Selectivity in a Claudin-15 Paracellular Channel

Alberini

2018

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Claudins are tissue-specific transmembrane proteins able to form junctions between two cells and regulate the flow of physiological solutes parallel to the cell walls, that is, the paracellular transport. Claudin-15 is highly expressed in the intestine where it forms efficient Na + channels and Cl − barriers. However, the molecular details of these biological complexes are still unclear. Here, the permeation process of Na + , K + , and Cl − ions inside a refined structural model of a claudin-15 paracellular channel is investigated using all-atom molecular dynamics simulations in a double-bilayer and explicit solvent. One-dimensional potential of mean force (PMF) profiles, calculated using umbrella sampling (US) simulations, show that the channel allows the passage of the two physiological cations while excluding chloride. These features are generated by the action of several acidic residues, in particular the ring of D55 residues which is located at the narrowest region of the pore, in correspondence with the energy minimum for cations and the peak for chloride. We also used the Voronoi-tessellated milestoning method to obtain additional PMF profiles and the permeation timescale of the three ions. The milestoning PMFs agree well with those obtained by US, and the rate calculation reveals that the passage of chloride is almost 30 times slower than that of sodium. Our results are consistent with the known ability of claudin-15 to regulate tight junction selectivity and with the experimentally determined role of the acidic residues. This further validates our structural model and provides insights into the atomistic details of ion transport in paracellular channels that could be shared by other claudin-based architectures.

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A refined model of claudin-15 tight junction paracellular architecture by molecular dynamics simulations

2017

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Tight-junctions between epithelial cells of biological barriers are specialized molecular structures that regulate the flux of solutes across the barrier, parallel to cell walls. The tight-junction backbone is made of strands of transmembrane proteins from the claudin family, but the molecular mechanism of its function is still not completely understood. Recently, the crystal structure of a mammalian claudin-15 was reported, displaying for the first time the detailed features of transmembrane and extracellular domains. Successively, a structural model of claudin-15-based paracellular channels has been proposed, suggesting a putative assembly that illustrates how claudins associate in the same cell (via cis interactions) and across adjacent cells (via trans interactions). Although very promising, the model offers only a static conformation, with residues missing in the most important extracellular regions and potential steric clashes. Here we present detailed atomic models of paracellular single and double pore architectures, obtained from the putative assembly and refined via structural modeling and all-atom molecular dynamics simulations in double membrane bilayer and water environment. Our results show an overall stable configuration of the complex with a fluctuating pore size. Extracellular residue loops in trans interaction are able to form stable contacts and regulate the size of the pore, which displays a stationary radius of 2.5–3.0 Å at the narrowest region. The side-by-side interactions of the cis configuration are preserved via stable hydrogen bonds, already predicted by cysteine crosslinking experiments. Overall, this work introduces an improved version of the claudin-15-based paracellular channel model that strengthens its validity and that can be used in further computational studies to understand the structural features of tight-junctions regulation.

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Giulio Alberini

Interfacing Graphene-Based Materials With Neural Cells

Molecular Dynamics Simulations of Ion Selectivity in a Claudin-15 Paracellular Channel

A refined model of claudin-15 tight junction paracellular architecture by molecular dynamics simulations

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