<HashMap><database>biostudies-literature</database><scores/><additional><submitter>List NH</submitter><funding>Svenska Forskningsrådet Formas</funding><funding>Villum Fonden</funding><funding>National Science Foundation (NSF)</funding><funding>Villum Fonden (Villum Foundation)</funding><funding>Svenska Forskningsrådet Formas (Swedish Research Council Formas)</funding><funding>National Science Foundation</funding><pagination>25</pagination><full_dataset_link>https://www.ebi.ac.uk/biostudies/studies/S-EPMC10844232</full_dataset_link><repository>biostudies-literature</repository><omics_type>Unknown</omics_type><volume>7(1)</volume><pubmed_abstract>Controlling excited-state reactivity is a long-standing challenge in photochemistry, as a desired pathway may be inaccessible or compete with other unwanted channels. An important example is internal conversion of the anionic green fluorescent protein (GFP) chromophore where non-selective progress along two competing torsional modes (P: phenolate and I: imidazolinone) impairs and enables Z-to-E photoisomerization, respectively. Developing strategies to promote photoisomerization could drive new areas of applications of GFP-like proteins. Motivated by the charge-transfer dichotomy of the torsional modes, we explore chemical substitution on the P-ring of the chromophore as a way to control excited-state pathways and improve photoisomerization. As demonstrated by methoxylation, selective P-twisting appears difficult to achieve because the electron-donating potential effects of the substituents are counteracted by inertial effects that directly retard the motion. Conversely, these effects act in concert to promote I-twisting when introducing electron-withdrawing groups. Specifically, 2,3,5-trifluorination leads to both pathway selectivity and a more direct approach to the I-twisted intersection which, in turn, doubles the photoisomerization quantum yield. Our results suggest P-ring engineering as an effective approach to boost photoisomerization of the anionic GFP chromophore.</pubmed_abstract><journal>Communications chemistry</journal><pubmed_title>Chemical control of excited-state reactivity of the anionic green fluorescent protein chromophore.</pubmed_title><pmcid>PMC10844232</pmcid><funding_grant_id>2018-05973</funding_grant_id><funding_grant_id>Graduate Research Fellow</funding_grant_id><funding_grant_id>VKR023371</funding_grant_id><pubmed_authors>Jones CM</pubmed_authors><pubmed_authors>List NH</pubmed_authors><pubmed_authors>Martinez TJ</pubmed_authors></additional><is_claimable>false</is_claimable><name>Chemical control of excited-state reactivity of the anionic green fluorescent protein chromophore.</name><description>Controlling excited-state reactivity is a long-standing challenge in photochemistry, as a desired pathway may be inaccessible or compete with other unwanted channels. An important example is internal conversion of the anionic green fluorescent protein (GFP) chromophore where non-selective progress along two competing torsional modes (P: phenolate and I: imidazolinone) impairs and enables Z-to-E photoisomerization, respectively. Developing strategies to promote photoisomerization could drive new areas of applications of GFP-like proteins. Motivated by the charge-transfer dichotomy of the torsional modes, we explore chemical substitution on the P-ring of the chromophore as a way to control excited-state pathways and improve photoisomerization. As demonstrated by methoxylation, selective P-twisting appears difficult to achieve because the electron-donating potential effects of the substituents are counteracted by inertial effects that directly retard the motion. Conversely, these effects act in concert to promote I-twisting when introducing electron-withdrawing groups. Specifically, 2,3,5-trifluorination leads to both pathway selectivity and a more direct approach to the I-twisted intersection which, in turn, doubles the photoisomerization quantum yield. Our results suggest P-ring engineering as an effective approach to boost photoisomerization of the anionic GFP chromophore.</description><dates><release>2024-01-01T00:00:00Z</release><publication>2024 Feb</publication><modification>2025-04-22T05:37:21.46Z</modification><creation>2025-04-05T21:23:40.305Z</creation></dates><accession>S-EPMC10844232</accession><cross_references><pubmed>38316834</pubmed><doi>10.1038/s42004-024-01099-1</doi></cross_references></HashMap>