Siqiao Li scite author profile

Live cell imaging of protein-specific glycoforms is important for the elucidation of glycosylation mechanisms and identification of disease states. The currently used metabolic oligosaccharide engineering (MOE) technology permits routinely global chemical remodeling (GCM) for carbohydrate site of interest, but can exert unnecessary whole-cell scale perturbation and generate unpredictable metabolic efficiency issue. A localized chemical remodeling (LCM) strategy for efficient and reliable access to protein-specific glycoform information is reported. The proof-of-concept protocol developed for MUC1-specific terminal galactose/N-acetylgalactosamine (Gal/GalNAc) combines affinity binding, off-on switchable catalytic activity, and proximity catalysis to create a reactive handle for bioorthogonal labeling and imaging. Noteworthy assay features associated with LCM as compared with MOE include minimum target cell perturbation, short reaction timeframe, effectiveness as a molecular ruler, and quantitative analysis capability.

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A Hierarchical Coding Strategy for Live Cell Imaging of Protein‐Specific Glycoform

Liu

et al. 2018

Angew Chem Int Ed

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Live cell imaging of protein-specific glycoforms holds great promise for revolutionizing the study of glycochemistry. The imaging protocols developed thus far build upon the paired interplay of probe units, thus limiting the number of monosaccharide identification channels. A hierarchical coding (HieCo) imaging strategy, with DNA coding and decoding of protein and monosaccharides executed in fidelity to the hierarchical order of target glycoprotein, is reported herein and features expandable monosaccharide identification channels. A proof-of-concept protocol has been developed for MUC1-specific imaging of terminal sialic acid (Sia) and fucose (Fuc) on MCF-7, T47D, MDA-MB-231, and PANC-1 cells, revealing distinct monosaccharide patterns for four types of cells. The protocol also permits dynamic monitoring of changes in MUC1-specific monosaccharide patterns associated with both the alteration of cellular physiological states and the occurrence of a biologically important process.

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Zippered G-quadruplex/hemin DNAzyme: exceptional catalyst for universal bioanalytical applications

Yan

et al. 2021

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G-quadruplex (G4)/hemin DNAzyme is promising horseradish peroxidase (HRP)-mimic candidate in the biological field. However, its relatively unsatisfactory catalytic capacity limits the potential applications. Inspired by nature protease, we conducted a proximity-enhanced cofactor assembly strategy (PECA) to form an exceptional HRP mimic, namely zippered G4/hemin DNAzyme (Z-G4/H). The hybridization of short oligonucleotides induced proximity assembly of the DNA-grafted hemin (DGH) with the complementary G4 sequences (cG4s), mimicking the tight configuration of protease cofactor and apoenzyme. The detailed investigations of catalytic efficiency and mechanism verified the higher activity, more rapid catalytic rate and high environmental tolerance of the Z-G4/H than the classical G4/hemin DNAzymes (C-G4/H). Furthermore, a proximity recognition transducer has been developed based on the PECA for sensitive detection of gene rearrangement and imaging human epidermal growth factor receptor 2 protein (HER2) dimerization on cell surfaces. Our studies demonstrate the high efficiency of Z-G4/H and its universal application potential in clinical diagnostics and biomolecule interaction research. It also may offer significant opportunities and inspiration for the engineering of the protease-free mimic enzyme.

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Nanoamplicon Comparator for Live-Cell MicroRNA Imaging

Huo

Zhang

et al. 2019

Anal. Chem.

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As an investigative tool, live-cell imaging requires superior probe design to guarantee imaging quality and data validity. The ability to simultaneously address the robustness, sensitivity, and consistency issues in a single-assay system is highly desired, but it remains a largely unsolved challenge. We describe herein a probe-design strategy called a nanoamplicon comparator (NAC) and demonstrate its proofof-concept utility in intracellular microRNA (miRNA) imaging. This novel designer architecture builds upon spherical nucleic acids (SNAs) for robustness, catalytic hairpin assembly (CHA) for sensitivity, and upconversion nanoparticles (UNPs) for consistency. A catalytic circuit comprising a UNP−hairpin-DNA (UNP-HDNA) conjugate and a hairpin-DNA−organic-fluorophore (HDNA-F) conjugate as probe responds to target miRNA and generates the UNP-HDNA−HDNA-F complex as an NAC for quantitative UNP-to-organic-fluorophoreluminescence-resonance-energy-transfer (LRET) imaging against a native UNP-emission reference channel. An imaging application with miR21 shows the ability to monitor miRNA-expression levels across different cell lines and under an external stimulus.

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Caenorhabditis elegans-Based Aspergillus fumigatus Infection Model for Evaluating Pathogenicity and Drug Efficacy

Ahamefule

Qin

Odiba

et al. 2020

Front. Cell. Infect. Microbiol.

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Aspergillus fumigatus is the most reported causative pathogen associated with the increasing global incidences of aspergilloses, with the health of immunocompromised individuals mostly at risk. Monitoring the pathogenicity of A. fumigatus strains to identify virulence factors and evaluating the efficacy of potent active agents against this fungus in animal models are indispensable in current research effort. Caenorhabditis elegans has been successfully utilized as an infection model for bacterial and dimorphic fungal pathogens because of the advantages of being time-efficient, and less costly. However, application of this model to the filamentous fungus A. fumigatus is less investigated. In this study, we developed and optimized a stable and reliable C. elegans model for A. fumigatus infection, and demonstrated the infection process with a fluorescent strain. Virulence results of several mutant strains in our nematode model demonstrated high consistency with the already reported pathogenicity pattern in other models. Furthermore, this C. elegans-A. fumigatus infection model was optimized for evaluating the efficacy of current antifungal drugs. Interestingly, the azole drugs in nematode model prevented conidial germination to a higher extent than amphotericin B. Overall, our established C. elegans infection model for A. fumigatus has potential applications in pathogenicity evaluation, antifungal agents screening, drug efficacy evaluation as well as host-pathogen interaction studies.

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Siqiao Li

Localized Chemical Remodeling for Live Cell Imaging of Protein‐Specific Glycoform

A Hierarchical Coding Strategy for Live Cell Imaging of Protein‐Specific Glycoform

Zippered G-quadruplex/hemin DNAzyme: exceptional catalyst for universal bioanalytical applications

Nanoamplicon Comparator for Live-Cell MicroRNA Imaging

Caenorhabditis elegans-Based Aspergillus fumigatus Infection Model for Evaluating Pathogenicity and Drug Efficacy

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