In red fluorescent proteins such as DsRed, an acylimine is formed from the Phe65-Gln66 linkage in GFP-like immature form, while it shows a cis configuration in its mature state. To date, the relationship between acylimine formation and trans-cis isomerization is still unresolved. We have calculated bond rotation profiles for mature and immature chromophores within the protein using our own n-layered integrated molecular orbital and molecular mechanism (ONIOM) approach. The results suggested that the isomerization is barrierless in acylimine formed in the mature state, suggesting that the acylimine formation precedes the trans-cis isomerization in DsRed chromophores. Further decomposition analysis of electrostatic contributions from individual residues has identified several residues and a specific water molecule which could play key roles in controlling the rate of the trans-cis isomerization of peptide bond in immature GFP-like protein. The results also highlight the importance of Gln66-like of tripeptide motif (chromophore) in the maturation of red fluorescent proteins. In view of the considerable interest in developing red fluorescent proteins for numerous biotechnological applications, these results should be useful for design of novel fluorescent proteins.
© 2011 American Chemical Society