Responsabile Scientifico

• GUIDO Ciro Achille (DiSIT)

Partecipanti al progetto

• D'AMORE Maddalena (DiSIT)

Titolo del progetto

• EnvELOP: Environmental tuning of microbial rhodopsins Electronic Landscape for New Optogenetic Potentialities

Ente finanziatore

• 
  MUR - Ministero dell'Università e Ricerca

Programma di finanziamento

• PRIN - Progetti di Ricerca di Rilevante Interesse Nazionale (dal 2020)

Bando di riferimento

• PRIN 2022

Anno di presentazione del progetto

• 2022

Anno di approvazione del progetto

• 2023

Acronimo del progetto

• EnvELOP

Project ID / numero contratto

• 2022WS44W4

Durata del progetto

• 24 mesi

Inizio del progetto

• 28/09/2023

Fine del progetto

• 28/02/2026

Ente capofila

• UNIUPO - Universita Degli Studi del Università del Piemonte Orientale "Amedeo Avogadro"

Progetto approvato - Contributo unità di ricerca del Dipartimento

• €119.836,00

Sustainable Development Goals - Agenda 2030

Keyword

• optogenetics, quantum chemistry, photochemistry, Photophysics

Settore ERC

• PE Mathematics, physical sciences, information and communication,engineering, universe and earth sciences
  
  PE4 Physical and Analytical Chemical sciences: analytical chemistry, chemical theory, physical chemistry/chemical physics
  
   PE4_18 Photochemistry

Stato del progetto

• Approvato

Abstract

• The emerging field of optogenetics exploits the genetic encoding of photoactive proteins to control physiological processes: the final goal is to switch on and off specific molecular events in a controlled way, with a high spatiotemporal resolution and in a wavelength-dependent fashion. Microbial rhodopsins (mRh) are the main tools of optogenetics as their light-gated channel or light-driven pumping functions are used to regulate neuronal activity with light. Protein engineering of mRh, and in particular structure-guided mutagenesis, has only been partially successful in the design of optogenetic devices with improved properties: their potential applications are thus far from being fully realized and key limitations still exist. The present inability to overcome such limitations mainly arises from the lack of understanding of the relationship between structure and molecular mechanism in mRhs, as a prerequisite for the engineering of the next generation of optogenetics tools. In this proposal we focus on the role of the chromophore binding cavity hydrogen bonding network (HBN) as a critical but substantially unexplored structural To this end, we develop and apply a theoretical-computational factor affecting the mRh photochemistry. machinery able to rationalize the light activation step in different microbial rhodopsins as a function of their HBN variations. More in general, EnvELOP will focus on the systematic investigation of a suitable set of wild-type mRhs and of their mutants to establish relationships between structural changes (in terms of HBN, chromophore cavity dimension, protein environment effects) and mRh photoreactivity (in terms of absorption wavelength, excited state lifetime, photoisomerization dynamics). These quantities have been shown to be substantially different from one mRh to another, yet the origin of these differences is still unclear. EnvELOP proposes an effective method to simulate infrared spectra before and after the photoisomerization and to access atomistic and mechanistic information on the effects of different HBNs on mRh photochemical reactivity. To gain insights into the HBN regulated photoisomerization process and the associated excited state lifetime, we will implement an original multireference QM/MM methodology that includes mutual polarization and dispersion interactions between the protein and the chromophore in an automated mRhs model building generator that would make it possible to investigate full sets of variants in a systematic and highly informative fashion.