Litcius/Paper detail

Computational Assessment of Different Structural Models for Claudin-5 Complexes in Blood–Brain Barrier Tight Junctions

Alessandro Berselli, Giulio Alberini, Fabio Benfenati, Luca Maragliano

2022ACS Chemical Neuroscience21 citationsDOIOpen Access PDF

Abstract

interactions across two contiguous cells. Despite the relevant biological function of Cldn5 proteins and their role as targets of brain drug delivery strategies, the molecular details of their assembly within TJs are still unclear. Two different structural models have been recently introduced, in which Cldn5 dimers belonging to opposite cells join to generate paracellular pores. However, a comparison of these models in terms of ionic transport features is still lacking. In this work, we used molecular dynamics simulations and free energy (FE) calculations to assess the two Cldn5 pore models and investigate the thermodynamic properties of water and physiological ions permeating through them. Despite different FE profiles, both structures present single/multiple FE barriers to ionic permeation, while being permissive to water flux. These results reveal that both models are compatible with the physiological role of Cldn5 TJ strands. By identifying the protein-protein surface at the core of TJ Cldn5 assemblies, our computational investigation provides a basis for the rational design of synthetic peptides and other molecules capable of opening paracellular pores in the BBB.

Topics & Concepts

Paracellular transportClaudinTight junctionBlood–brain barrierChemistryBiophysicsMolecular dynamicsCell biologyBiologyBiochemistryMembraneNeuroscienceCentral nervous systemComputational chemistryPermeability (electromagnetism)Barrier Structure and Function StudiesDrug Transport and Resistance MechanismsBiochemical effects in animals