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We discovered a novel fluorophore by incorporating a dimethylamino group (–NMe2) into the conformationally locked green fluorescent protein (GFP) scaffold. It exhibited a marked solvent-polarity-dependent fluorogenic behavior and can potentially find broad applications as an environment-polarity sensor in vitro and in vivo. The ultrafast femtosecond transient absorption (fs-TA) spectroscopy in combination with quantum calculations revealed the presence of a twisted intramolecular charge transfer (TICT) state, which is formed by rotation of the –NMe2 group in the electronic excited state. In contrast to the bright fluorescent state (FS), the TICT state is dark and effectively quenches fluorescence upon formation. We employed a newly developed multivariable analysis approach to the FS lifetime in various solvents and showed that the FS → TICT reaction barrier is mainly modulated by H-bonding capability instead of viscosity of the solvent, accounting for the observed polarity dependence. These deep mechanistic insights are further corroborated by the dramatic loss of fluorogenicity for two similar GFP-derived chromophores in which the rotation of the –NMe2 group is inhibited by structural locking. 

Strategic incorporation of ameta‐dimethylamino (–NMe₂) group on the conformationally locked green fluorescent protein (GFP) model chromophore (m‐NMe₂‐LpHBDI) has drastically altered molecular electronic properties, counterintuitively enhancing fluorescence of only the neutral and cationic chromophores in aqueous solution. A ~200‐fold decrease in fluorescence quantum yield ofm‐NMe₂‐LpHBDI in alcohols (e.g., MeOH, EtOH and 2‐PrOH) supports this GFP‐derived compound as a fluorescence turn‐on water sensor, with large fluorescence intensity differences between H₂O and ROH emissions in various H₂O/ROH binary mixtures. A combination of steady‐state electronic spectroscopy, femtosecond transient absorption, ground‐state femtosecond stimulated Raman spectroscopy (FSRS) and quantum calculations elucidates an intermolecular hydrogen‐bonding chain between a solvent –OH group and the chromophore phenolic ring –NMe₂and –OH functional groups, wherein fluorescence differences arise from an extended hydrogen‐bonding network beyond the first solvation shell, as opposed to fluorescence quenching via a dark twisted intramolecular charge‐transfer state. The absence of ameta‐NMe₂group twisting coordinate upon electronic excitation was corroborated by experiments on control samples without themeta‐NMe₂group or with bothmeta‐NMe₂andpara‐OH groups locked in a six‐membered ring. These deep mechanistic insights stemming from GFP chromophore scaffold will enable rational design of organic, compact and environmentally friendly water sensors.