Ultrafluorogenic Monochromophore-Type BODIPY-Tetrazine Series for Dual-Color Bioorthogonal Imaging with a Single Probe.

Various fluorogenic probes utilizing tetrazine (Tz) as a fluorescence quencher and bioorthogonal reaction partner have been extensively studied over the past few decades. Herein, we synthesized a series of boron-dipyrromethene (BODIPY)-Tz probes using monochromophoric design strategy for bioorthogonal cellular imaging. The BODIPY-Tz probes exhibited excellent bicyclo[6.1.0]nonyne (BCN)-selective fluorogenicity with three- to four-digit-fold enhancements in fluorescence over a wide range of emission wavelengths, including the far-red region. Furthermore, we demonstrated the applicability of BODIPY-Tz probes in bioorthogonal fluorescence imaging of cellular organelles without washing steps. We also elucidated the aromatized pyridazine moiety as the origin of BCN-selective fluorogenic behavior. Additionally, we discovered that the fluorescence of the trans-cyclooctene (TCO) adducts was quenched in aqueous media via photoinduced electron transfer (PeT) process. Interestingly, we observed a distinctive recovery of the initially quenched fluorescence of BODIPY-Tz-TCO upon exposure to hydrophobic media, accompanied by a significant bathochromic shift of its emission wavelength relative to that exhibited by the corresponding BODIPY-Tz-BCN. Leveraging this finding, for the first time, we achieved dual-color bioorthogonal cellular imaging with a single BODIPY-Tz probe.

Systematic Exploration of Furoindolizine-Based Molecular Frameworks towards a Versatile Fluorescent Platform.

The photophysical behaviors of fluorescent molecules largely determine their major utility in biological studies. Despite their well-defined characteristics, classical fluorophores have often been challenged by their limited synthetic methodology and tunability in adjusting intrinsic optical properties. A novel heterocyclic core equipped with modular functional groups could offer the flexibility to control its photophysical properties with a minimum synthetic effort. By conducting a systematic analysis guided by quantum calculations, we proposed the furoindolizine-based molecular framework as a unique fluorescent platform capable of providing versatile photophysical properties with minimal structural modification. A broad tunability of furoindolizine derivatives' photophysical properties such as emission wavelength, Stokes shift, fluorescent brightness, and charge transfer characteristics was achieved through synergistic interaction between two functional moieties. Furthermore, this modular platform led to live-cell imaging probes with two distinct optical features simply by reorganizing a pair of functional moieties.

Two-Photon and Multicolor Fluorogenic Bioorthogonal Probes Based on Tetrazine-Conjugated Naphthalene Fluorophores.

Herein, we report the use of two-photon fluorogenic probes using tetrazine-based bioorthogonal reactions with multicolor emissions that cover nearly all of the visible region. New fluorogenic probes were designed based on donor-acceptor-type naphthalene structures conjugated with a fluorescence-quenching tetrazine moiety for turn-on properties in one- and two-photon fluorescence. Our fluorescent probes showed a moderate to good turn-on ratio after bioorthogonal inverse electron demand Diels-Alder cycloaddition with trans-cyclooctenol in one- and two-photon fluorescence. We successfully applied our probes to mitochondria- and lysosome-selective bioorthogonal imaging in live cells with one-/two-photon and one-photon microscopy, respectively.