Yawei Shi

Simultaneous Fluorescence Sensing of Cys and GSH from Different Emission Channels

A chlorinated coumarin-hemicyanine dye with three potential reaction sites was exploited as fluorescent probe for biothiols. The Cys-induced substitution-rearrangement-cyclization, Hcy-induced substitution-rearrangement, and GSH-induced substitution-cyclizatioin cascades lead to the corresponding amino-coumarin, amino-coumarin-hemicyanine, thiol-coumarin with distinct photophysical properties, enabling Cys and GSH to be selectively detected from different emission channels at two different excitation wavelengths.

Simultaneous fluorescent imaging of Cys/Hcy and GSH from different emission channels

A 4-methoxythiophenol-substituted pyronin dye 1 was exploited as reaction-type fluorescent probe for biothiols Cys/Hcy and GSH. The probe itself is nonfluorescent due to the photoinduced electron transfer (PET) process. The Cys (or Hcy)-induced substitution–rearrangement cascade reaction and GSH-induced substitution reaction with the probe lead to the corresponding aminopyronin and thiopyronin dyes with distinct photophysical properties, enabling Cys/Hcy and GSH to be detected from visible and near-infrared (NIR) emission channels, respectively, in pure PB buffer with relatively fast kinetics and obvious fluorescence turn-on response. Assisted by laser scanning confocal microscope, we also demonstrated that probe 1 could simultaneously sense Cys/Hcy and GSH in B16 cells in multicolor imaging.

A Mitochondria-Targetable Fluorescent Probe for Dual-Channel NO Imaging Assisted by Intracellular Cysteine and Glutathione

A mitochondria-specific fluorescent probe for NO (1) was synthesized by the direct conjugation of a pyronin dye with one of the amino groups of o-phenylenediamino (OPD). The probe could selectively detect NO over dehydroascorbic acid (DHA), ascorbic acid (AA), and methylglyoxal (MGO) as well as the reactive oxygen/nitrogen species (ROS/RNS) with the significant off-on response due to the production of a red-emission triazole 2. In the presence of cysteine/glutathione (Cys/GSH), 2 could be further transformed into a green-emission aminopyronin 4 and a red-emission thiopyronin 5, respectively. Assisted by intracellular Cys and GSH, the probe demonstrated its potential to monitor mitochondrial NO in a dual-channel mode.

Selective Fluorescence Detection of Cysteine over Homocysteine and Glutathione Based on a Cysteine-Triggered Dual Michael Addition/Retro-aza-aldol Cascade Reaction.

In this work, a cysteine (Cys)-triggered dual Michael addition/retro-aza-aldol cascade reaction has been exploited and utilized to construct a fluorescent probe for Cys for the first time. The resulting fluorescent probe 8-alkynylBodipy 1 contains an activated alkynyl unit as Michael receptor and a Bodipy dye as fluorescence reporter and can highly selectively detect Cys over homocysteine (Hcy)/glutathione (GSH) as well as other amino acids with a significant fluorescence off-on response (∼4500-fold) and an ultralow detection limit (0.38 nM). The high selectivity of 1 for Cys could be attributed to a kinetically favored five-membered cyclic intermediate produced by the dual Michael addition of Cys with the activated alkynyl unit of 1. The big fluorescence off-on response is due to the subsequent retro-aza-aldol reaction of the five-membered cyclic intermediate that results in the release of a highly fluorescent 8-methylBodipy dye 2. The probe has been successfully used to detect and image Cys in serum and cells, respectively.

A carboxylic acid-functionalized coumarin-hemicyanine fluorescent dye and its application to construct a fluorescent probe for selective detection of cysteine over homocysteine and glutathione

A carboxylic acid-functionalized coumarin-hemicyanine near-infrared (NIR) dye 1 was exploited, which possesses good water solubility (more than 50 μM) and favorable photophysical properties, especially a large Stokes shift (around 90 nm), and has been proved to be a suitable imaging agent for targeting mitochondria. With the dye platform, fluorescent probe 2, a thioester derivative of 1, was constructed for biothiols. Probe 2 can react with cysteine (Cys) via the native-chemical-ligation (NCL) and cyclization cascade reactions to lead to coumarin 2-Cys. However, the reaction of 2 with homocysteine (Hcy) or glutathione (GSH) only stays at the stage of the initial transthioesterification reaction, producing coumarin-hemicyanines 2-Hcy or 2-GSH, due to an electrostatic interaction in 2-Hcy and an unstable macrocyclic transition state in 2-GSH, both inhibiting their subsequent S,N-acyl shift. Given the distinct photophysical properties between 2-Cys and 2-Hcy (or 2-GSH), probe 2 could highly selectively discriminate Cys from Hcy/GSH. Even in the presence of Hcy or GSH, probe 2 still works well for Cys due to the reversible transthioesterification and the irreversible S,N-acyl shift in the NCL reaction. The cell imaging assays revealed that probe 2 is cell permeable and could selectively image Cys in living cells.

Sulfone-Rhodamines: A New Class of Near-Infrared Fluorescent Dyes for Bioimaging

Given the wavelength dependence of tissue transparency and the requirement for sufficiently low background autofluorescence, the development of fluorescent dyes with excitation and emission maxima beyond 700 nm is highly desired, but it is a challenging task. Herein, a new class of fluorescent dyes, named sulfone-rhodamines (SO2Rs), was developed on the basis of the one-atom replacement of the rhodamine 10-position O atom by a sulfone group. Such a modification makes their absorption and emission maxima surprisingly reach up to 700-710 and 728-752 nm, respectively, much longer than their O-, C-, and Si-rhodamine analogs, due to the unusual d*-π* conjugation. Among these dyes, SO2R4 and SO2R5, bearing disubstituted meso-phenyl groups, show the greatest potentials for bioimaging applications in view of their wide pH range of application, high photostability, and big extinction coefficients and fluorescence quantum yields. They could quickly penetrate cells to give stable NIR fluorescence, even after continuous irradiation by a semiconductor laser, making them suitable candidates for time-lapse and long-term bioimaging applications. Moreover, they could specifically localize in lysosomes independent of alkylmorpholine targeted group, thus avoiding the problematic alkalization effect suffered by most LysoTrackers. Further imaging assays of frozen slices of rat kidney reveal that their tissue imaging depth is suprior to the widely used NIR labeling agent Cy5.5.

Aromatic primary monoamine-based fast-response and highly specific fluorescent probes for imaging the biological signaling molecule nitric oxide in living cells and organisms

Nitric oxide (NO) is an important cellular signaling molecule involved in many physiological and pathological processes. To probe its spatiotemporal information in biosystems, a large number of NO fluorescent probes have been exploited in the past ten years. Among them, the o-phenylenediamine-based probes are the earliest developed and most versatile NO fluorescent probes to date. However, there are still limitations such as relatively long response time, possible interference by dehydroascorbic acid (DHA)/methylglyoxal (MGO), and pH-sensitivity of their fluorescence signals. In this work, we present two aromatic primary monoamine-based NO fluorescent probes, MA and NIR-MA, and explore the reductive deamination reaction of the electron-rich p-methoxyaniline group with NO under aerobic conditions. The superiority of both probes is illustrated by their quick, stable, sensitive, and specific fluorescence off-on responses for NO over a series of biologically relevant interfering species, including reactive oxygen species, DHA/MGO, biothiols, and metal ions. Coupled with good cell permeability and low cytotoxicity, the two probes have successfully been applied to imaging the endogenous NO in RAW 264.7 macrophages stimulated by LPS/IFN-γ. Moreover, the fluorescence response of NIR-MA for NO occurs in the physiologically favorable NIR region, enabling its further use to image endogenous NO in an inflamed mouse model.

Self-association of L-periaxin occurs via its acidic domain and NLS2/NLS3, and affects its trafficking in RSC96 cells

Periaxin (PRX) protein was first identified in myelinating Schwann cells through the screening of cytoskeleton-associated proteins in peripheral nerve myelination. PRX plays a significant role in myelin sheath formation and myelin stability, and is closely related to tumor cell metastasis. As described, several loss-of-function mutations were linked to autosomal recessive Dejerine–Sottas neuropathy and demyelinating Charcot–Marie–Tooth disease, type 4F (CMT4F) caused by periaxin mutation. In this study, we report that L-PRX self-association occurs by head-to-tail joining of the nuclear localization signal NLS2 and NLS3 in the tripartite nuclear localization signal and acidic domains. The self-association of L-PRX in RSC96 cells is remarkably weakened by DRP2 and the synthetic NLS3 peptide. In the acidic domain of L-PRX, E1259K mutation weakens the head-to-tail interaction, causing CMT4F disease. The membrane localization of L-PRX in RSC96 was increased by the disruption of self-association by DRP2 and the synthetic NLS3 peptide. The self-association of L-PRX is a possible type of self-regulation of PRX during the localization between the cell membrane and cytoplasm or nucleus.