Xiaoqiang Yu

Low molecular weight fluorescent probes with good photostability for imaging RNA-rich nucleolus and RNA in cytoplasm in living cells.

We have synthesized two low molecular weight organic molecules, PY and IN successfully, which selectively stain nucleolus and cytoplasm of living cells in 30 min, with a much lower uptake in the nucleus. Nucleic acids electrophoresis and digest test of ribonuclease indicate their markedly higher affinity for RNA, especially PY. Moreover their RNA localization in cells is further supported by digest test of ribonuclease, namely, the nucleolar fluorescence signal is distinctly lost upon treatment with RNase. And, the fact that live cells stained by PY and IN still possess physiological function can be confirmed: 1) MTT assay demonstrates that the mitochondria of cells stained remains its electron mediating ability, 2) Double assay of PY/IN and propidium iodide as well as trypan blue testing show that the membrane of cells stained still is intact. Importantly, compared with the only commercial RNA probe, SYTO RNA-Select, PY and IN exhibit much better photostability when continuously illuminated with 488 nm laser and mercury lamp. These results prove that PY and IN are very attractive staining reagents for visualizing RNA in living cells.

Two-photon fluorescence imaging of DNA in living plant turbid tissue with carbazole dicationic salt

Three carbazole dicationic salts, namely 3,6-bis(1-methyl-4-vinylpyridinium) carbazole diiodide (BMVC), 9-ethyl-3,6-bis(1-methyl-4-vinylpyridinium) carbazole diiodide (9E-BMVC) and 9-ethyl-3,6-bis(1-hydroxyethyl-4-vinylpyridinium)carbazole diiodide (9E-BHVC), were synthesized successfully. Their photophysical properties were evaluated by absorption, one- and two-photon fluorescence spectra, and their higher fluorescence intensity and larger two-photon excited fluorescence action cross-sections (Φ×δ) in the presence of DNA than those in the absence of DNA give them good DNA two-photon light-switch properties. Furthermore, their ability to image nuclei in living plant cells and turbid tissues by using two-photon excited fluorescence was carefully studied, and the experimental results indicate that these dicationic salts can exclusively label nuclei in intact living plant cells and tissues. In particular, 9E-BHVC exhibits optimized DNA labeling performance. Very importantly, compared to DAPI, 9E-BHVC can be used to carry out deeper observation using the same incident power, or can be used to obtain usable fluorescent images by using a lower incident power.

Construction of A Fluorescent Nanostructured Chitosan-Hydroxyapatite Scaffold by Nanocrystallon Induced Biomimetic Mineralization and Its Cell Biocompatibility

Biomaterial surfaces and their nanostructures can significantly influence cell growth and viability. Thus, manipulating surface characteristics of scaffolds can be a potential strategy to control cell functions for stem cell tissue engineering. In this study, in order to construct a hydroxyapatite (HAp) coated genipin-chitosan conjugation scaffold (HGCCS) with a well-defined HAp nanostructured surface, we have developed a simple and controllable approach that allows construction of a two-level, three-dimensional (3D) networked structure to provide sufficient calcium source and achieve desired mechanical function and mass transport (permeability and diffusion) properties. Using a nontoxic cross-linker (genipin) and a nanocrystallon induced biomimetic mineralization method, we first assembled a layer of HAp network-like nanostructure on a 3D porous chitosan-based framework. X-ray diffraction (XRD) and high resolution transmission electron microscopy (HRTEM) analysis confirm that the continuous network-like nanostructure on the channel surface of the HGCCS is composed of crystalline HAp. Compressive testing demonstrated that the strength of the HGCCS is apparently enhanced because of the strong cross-linking of genipin and the resulting reinforcement of the HAp nanonetwork. The fluorescence properties of genipin-chitosan conjugation for convenient monitoring of the 3D porous scaffold biodegradability and cell localization in the scaffold was specifically explored using confocal laser scanning microscopy (CLSM). Furthermore, through scanning electron microscope (SEM) observation and immunofluorescence measurements of F-actin, we found that the HAp network-like nanostructure on the surface of the HGCCS can influence the morphology and integrin-mediated cytoskeleton organization of rat bone marrow-derived mesenchymal stem cells (BMSCs). Based on cell proliferation assays, rat BMSCs tend to have higher viability on HGCCS in vitro. The results of this study suggest that the fluorescent two-level 3D nanostructured chitosan-HAp scaffold will be a promising scaffold for bone tissue engineering application.

Red-Emitting Mitochondrial Probe with Ultrahigh Signal-to-Noise Ratio Enables High-Fidelity Fluorescent Images in Two-Photon Microscopy.

Herein, we reported a red-emitting probe (E)-4-(2-(8-hydroxy-julolidine-9-yl)vinyl)-1-methylpyridin-1-ium iodide (HJVPI) on a rotor mechanism with an ultrahigh signal-to-noise ratio. HJVPI could give high-fidelity fluorescent images of mitochondria in living immortalized and normal cells and be suitable for IR excitation source of two-photon microscopy and various excitation sources of confocal microscopy. As a rotor, its single/two-photon fluorescence intensities directly depended on environmental viscosity. And, as a mitochondrial probe, it displayed much larger two-photon absorption cross sections in comparison with commercial MitoTracker Green FM and MitoTracker Red FM. Moreover, the fact that living cells stained by HJVPI still possessed physiological function could also be confirmed: (1) MTT assay demonstrated that the mitochondria of cells stained retained their electron mediating ability and (2) double assay of HJVPI and SYTOX Blue nucleic acid stain (S-11348) showed that the plasma membrane of the cells stained was still intact. In addition, HJVPI possessed a number of beneficial properties in bioimaging such as good membrane permeability, high photostability, and excellent counterstain compatibility with Hoechst 33342. Related mechanism research suggested that its localization property was dependent on the mitochondrial membrane potential in living cells. All its remarkable properties can extend the investigation on mitochondria in a biological context.

A membrane-permeable dye for living cells with large two-photon excited fluorescence action cross-sections for bioimaging

The development of two-photon fluorophores remains an important issue. Dyes that possess both large two-photon excited fluorescence action cross-sections and cell membrane permeability are especially in demand to maximize the underlying virtue of two-photon microscopy for bioimaging. Herein, a novel two-photon excited fluorescence dye has been synthesized. This V-shaped dye exhibited large two-photon excited fluorescence action cross-sections and high plasma membrane permeability. Cell imaging experiments demonstrated that the dye could stain living cells with bright two-photon excited fluorescence. All the results have indicated the potential of the dye as a basic platform for the development of two-photon excited fluorescence probes.

A two-photon ratiometric fluorescent probe enables spatial coordinates determination of intracellular pH

We reported a two-photon ratiometric fluorescent probe for detecting intracellular pH. When excited with 800 nm laser, an optimal output of laser as the routine equipment of two-photon fluorescence microscopy, the two-photon excited fluorescence of this probe showed distinct emission peak shift as large as 109 nm upon the change of pH values in vitro. Very importantly, the experiment results show that this probe has large two-photon absorption cross-section at pH 4.5 at 800 nm of 354 g, which ranks it as one of the best two-photon ratiometric fluorescent pH probes, and its working pH value is between 4.0 and 8.0 which could fit the intracellular pH range. Moreover, utilizing this probe, the two-photon ratiometric fluorescent images in living cells have been obtained, and the spatial coordinates of intracellular pH can be mapped. At the same time, the probe also exhibited selectivity, photostability and membrane permeability. And the photophysical properties of this probe in various solvents indicated that these photophysical properties variations are due to an intramolecular charge transfer process. At last, the imaging depth of the probe in liver biopsy slices was investigated. The experimental results demonstrated the maximum imaging depth can arrive 66 µm in living rat liver tissues.

Spatially Dependent Fluorescent Probe for Detecting Different Situations of Mitochondrial Membrane Potential Conveniently and Efficiently

The feedback from mitochondrial membrane potential (MMP) in different situations (normal, decreasing, and vanishing) can reflect different cellular status, which can be applied in biomedical research and diagnosis of the related diseases. Thus, the efficient and convenient detection for MMP in different situations is particularly important, yet the operations of current fluorescent probes are complex. In order to address this concern, we presented herein a spatially dependent fluorescent probe composed of organic cationic salt. The experimental results from normal and immortalized cells showed that it could accumulate in mitochondria selectively when MMP was normal. Also, it would move into the nucleus from mitochondria gradually with the decrease of MMP, and finally it targeted the nucleus exclusively when MMP vanished. According to the cell morphology, there is a straightforward spatial boundary between the nucleus and cytoplasm where mitochondria locate; thus, the three situations of MMP can be point-to-point indicated just by fluorescence images of the probe: that all probes accumulate in mitochondria corresponds to normal MMP; that probes locate both in the mitochondria and nucleus corresponds to decreasing MMP; that probes only target the nucleus corresponds to vanishing MMP. It is worth noting that counterstaining results with S-11348 indicated that the spatially dependent probe could be applied to distinguishing dead from viable cells in the same cell population. Compared with the commercial Cellstain-Double staining kit containing calcein-AM and propidium iodide (PI), this probe can address this concern by itself and shorten the testing time, which brings enormous convenience for relevant researches.

Turn-on fluorescent probes that can light up endogenous RNA in nucleoli and cytoplasm of living cells under a two-photon microscope

We have synthesized two-photon organic molecule probes (IMT-E and IMT-M), which selectively stain endogenous RNA in the nucleolus and cytoplasm of living cells in a short incubation time. Using these probes, bright two-photon excitation fluorescence (TPEF) images of living cells have been developed. Titrations and digest tests of ribonuclease indicate the markedly higher affinity of these probes for RNA, especially when using IMT-E. Upon binding to RNA, the fluorescence intensity of IMT-E increases by about 15-fold, showing that IMT-E is a turn-on probe for the detection of RNAs. MTT assays demonstrate that the mitochondria of cells maintain their electron mediating ability after being stained with the probes. These results demonstrate that IMT-E is an attractive two-photon turn-on fluorescent probe for visualizing RNA in living cells.

Phospholipid-Biomimetic Fluorescent Mitochondrial Probe with Ultrahigh Selectivity Enables In Situ and High-Fidelity Tissue Imaging

In situ and directly imaging mitochondria in tissues instead of isolated cells can offer more native and accurate information. Particularly, in the clinical diagnose of mitochondrial diseases such as mitochondrial myopathy, it is a routine examination item to directly observe mitochondrial morphology and number in muscle tissues from patients. However, it is still a challenging task because the selectivity of available probes is inadequate for exclusively tissue imaging. Inspired by the chemical structure of amphiphilic phospholipids in mitochondrial inner membrane, we synthesized a phospholipid-biomimetic amphiphilic fluorescent probe (Mito-MOI) by modifying a C18-alkyl chain to the lipophilic side of carbazole-indolenine cation. Thus, the phospholipid-like Mito-MOI locates at mitochondrial inner membrane through electrostatic interaction between its cation and inner membrane negative charge. Simultaneously, the C18-alkyl chain, as the second targeting group, is deeply embedded into the hydrophobic region of inner membrane through hydrophobic interaction. Therefore, the dual targeting groups (cation and C18-alkyl chain) actually endow Mito-MOI with ultrahigh selectivity. As expected, high-resolution microscopic photos showed that Mito-MOI indeed stained mitochondrial inner membrane. Moreover, in situ and high-fidelity tissue imaging has been achieved, and particularly, four kinds of mitochondria and their crystal-like structure in muscle tissues were visualized clearly. Finally, the dynamic process of mitochondrial fission in living cells has been shown. The strategy employing dual targeting groups should have reference value for designing fluorescent probes with ultrahigh selectivity to various intracellular membranous components.

Two-photon fluorescent probe for detecting cell membranal liquid-ordered phase by an aggregate fluorescence method

The cell membranal liquid-ordered (Lo) phase can control the structure and function of cell membranes. In this study, we have engineered a novel two-photon (TP) fluorescent probe, TP-HVC18, which remarkably displayed two different fluorescence emission profiles in the aggregate and solution states in distinct polar environments. In accordance with its aggregate fluorescence, TP-HVC18 also can emit a red fluorescence signal in Lo phase vesicles. Taking advantage of this unique feature, we have demonstrated that the new TP probe TP-HVC18 is suitable for imaging membranal Lo phase by an aggregate fluorescence method. Furthermore, the robust probe also exhibited uncontinuous red fluorescence distribution in the cell membranal Lo phase. Based on this intriguing character, we also successfully showed that the novel probe can be employed to exhibit uncontinuous distribution of cell membranal Lo phase by a 3D imaging technique. We expect that this aggregation-based fluorescent platform may be extended for the development of a wide variety of TP fluorescent probes for detecting several biological species.