Litcius/Paper detail

Computing Metal‐Binding Proteins for Therapeutic Benefit

Angelo Spinello, Jure Borišek, Matic Pavlin, Pavel Janoš, Alessandra Magistrato

2021ChemMedChem16 citationsDOI

Abstract

Over one third of biomolecules rely on metal ions to exert their cellular functions. Metal ions can play a structural role by stabilizing the structure of biomolecules, a functional role by promoting a wide variety of biochemical reactions, and a regulatory role by acting as messengers upon binding to proteins regulating cellular metal-homeostasis. These diverse roles in biology ascribe critical implications to metal-binding proteins in the onset of many diseases. Hence, it is of utmost importance to exhaustively unlock the different mechanistic facets of metal-binding proteins and to harness this knowledge to rationally devise novel therapeutic strategies to prevent or cure pathological states associated with metal-dependent cellular dysfunctions. In this compendium, we illustrate how the use of a computational arsenal based on docking, classical, and quantum-classical molecular dynamics simulations can contribute to extricate the minutiae of the catalytic, transport, and inhibition mechanisms of metal-binding proteins at the atomic level. This knowledge represents a fertile ground and an essential prerequisite for selectively targeting metal-binding proteins with small-molecule inhibitors aiming to (i) abrogate deregulated metal-dependent (mis)functions or (ii) leverage metal-dyshomeostasis to selectively trigger harmful cells death.

Topics & Concepts

BiomoleculeChemistryComputational biologyNanotechnologyBiophysicsBiologyBiochemistryMaterials scienceTrace Elements in HealthMetal complexes synthesis and propertiesDrug Transport and Resistance Mechanisms