Proteins are located in the twilight zone between chemistry and biology, where a peculiar kind of complexity starts. Proteins are the smallest ‘devices’ showing a sensible adaptation to their environment by the production of appropriate behavior when facing a specific stimulus. This fact qualifies (from the ‘effector’ side) proteins as nanomachines working as catalysts, motors, or switches. However (from the sensor side), the need to single out the ‘specific stimulus’ out of thermal noise qualifies proteins as information processing devices. Allostery corresponds to the modification of the configuration (in a broad sense) of the protein molecule in response to a specific stimulus in a non-strictly local way, thereby connecting the sensor and effector sides of the nanomachine. This is why the ‘disclosing’ of allostery phenomenon is at the very heart of protein function; in this chapter, we will demonstrate how a network-based representation of protein structure in terms of nodes (aminoacid residues) and edges (effective contacts between residues) is the natural language for getting rid of allosteric phenomena and, more in general, of protein structure/function relationships.
Di Paola, L., Mei, G., Di Venere, A., Giuliani, A. (2021). Disclosing Allostery Through Protein Contact Networks. In Methods in Molecular Biology (pp. 7-20). Humana Press Inc. [10.1007/978-1-0716-1154-8_2].
Disclosing Allostery Through Protein Contact Networks
Mei G.
;Di Venere A.;Giuliani A.
2021-01-01
Abstract
Proteins are located in the twilight zone between chemistry and biology, where a peculiar kind of complexity starts. Proteins are the smallest ‘devices’ showing a sensible adaptation to their environment by the production of appropriate behavior when facing a specific stimulus. This fact qualifies (from the ‘effector’ side) proteins as nanomachines working as catalysts, motors, or switches. However (from the sensor side), the need to single out the ‘specific stimulus’ out of thermal noise qualifies proteins as information processing devices. Allostery corresponds to the modification of the configuration (in a broad sense) of the protein molecule in response to a specific stimulus in a non-strictly local way, thereby connecting the sensor and effector sides of the nanomachine. This is why the ‘disclosing’ of allostery phenomenon is at the very heart of protein function; in this chapter, we will demonstrate how a network-based representation of protein structure in terms of nodes (aminoacid residues) and edges (effective contacts between residues) is the natural language for getting rid of allosteric phenomena and, more in general, of protein structure/function relationships.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
