Co-reporter:Jingjing Hui;Lei Bao;Siqiao Li;Yi Zhang;Yimei Feng; Dr. Lin Ding; Dr. Huangxian Ju
Angewandte Chemie 2017 Volume 129(Issue 28) pp:8251-8255
Publication Date(Web):2017/07/03
DOI:10.1002/ange.201703406
AbstractLive 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.
Co-reporter:Jingjing Hui;Lei Bao;Siqiao Li;Yi Zhang;Yimei Feng; Dr. Lin Ding; Dr. Huangxian Ju
Angewandte Chemie International Edition 2017 Volume 56(Issue 28) pp:8139-8143
Publication Date(Web):2017/07/03
DOI:10.1002/anie.201703406
AbstractLive 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.
Co-reporter:Kaili Yang;Min Huo;Yuehua Guo;Yizhuo Yang;Jie Wu;Huangxian Ju
Analyst (1876-Present) 2017 vol. 142(Issue 19) pp:3740-3746
Publication Date(Web):2017/09/25
DOI:10.1039/C7AN00413C
A target-induced cyclic strategy for DNAzyme formation was proposed to achieve simple, sensitive and universal detection of protein biomarkers with convenient colorimetric or chemiluminescence imaging readout. In the assay, the target protein was recognized by a pair of DNA-labeled antibodies (Ab1-DNA1 and Ab2-DNA2) to form a proximate complex, which could hybridize with the conjugate DNA3/DNA4 to release the guanine-rich DNA4 and thus formed G-quadruplex/hemin horseradish peroxidase-mimicking DNAzyme. The process could be further recycled with Exonuclease III by cleaving DNA3 to free the proximate complex, resulting in the cyclic formation of DNAzyme. The G-quadruplex/hemin DNAzyme could catalyze the H2O2-mediated oxidation of 3,3,5,5-tetramethylbenzidine to produce the color change from colorless to blue or enhance the chemiluminescence of a luminol–H2O2 system. Thus the signal could be read out with the naked eye, and by colorimetry and chemiluminescence imaging. Using a carcinoembryonic antigen as a model target, the proposed assay showed a detection range of 4 orders of magnitude along with detection limits of 170 and 16 pg mL−1 for colorimetric and chemiluminescence imaging assays respectively. This assay had the advantages of easy operation, sensitive detection, target flexibility and diversified signal readout, providing a great opportunity for commercial application.
Co-reporter:Na Wu;Lei Bao;Dr. Lin Ding;Dr. Huangxian Ju
Angewandte Chemie International Edition 2016 Volume 55( Issue 17) pp:5220-5224
Publication Date(Web):
DOI:10.1002/anie.201601233
Abstract
This work develops a site-specific duplexed luminescence resonance energy transfer system on cell surface for simultaneous imaging of two kinds of monosaccharides on a specific protein by single near-infrared excitation. The single excitation-duplexed imaging system utilizes aptamer modified upconversion luminescent nanoparticles as an energy donor to target the protein, and two fluorescent dye acceptors to tag two kinds of cell surface monosaccharides by a dual metabolic labeling technique. Upon excitation at 980 nm, only the dyes linked to protein-specific glycans can be lit up by the donor by two parallel energy transfer processes, for in situ duplexed imaging of glycoforms on specific protein. Using MUC1 as the model, this strategy can visualize distinct glycoforms of MUC1 on various cell types and quantitatively track terminal monosaccharide pattern. This approach provides a versatile platform for profiling protein-specific glycoforms, thus contributing to the study of the regulation mechanisms of protein functions by glycosylation.
Co-reporter:Na Wu;Lei Bao;Dr. Lin Ding;Dr. Huangxian Ju
Angewandte Chemie 2016 Volume 128( Issue 17) pp:5306-5310
Publication Date(Web):
DOI:10.1002/ange.201601233
Abstract
This work develops a site-specific duplexed luminescence resonance energy transfer system on cell surface for simultaneous imaging of two kinds of monosaccharides on a specific protein by single near-infrared excitation. The single excitation-duplexed imaging system utilizes aptamer modified upconversion luminescent nanoparticles as an energy donor to target the protein, and two fluorescent dye acceptors to tag two kinds of cell surface monosaccharides by a dual metabolic labeling technique. Upon excitation at 980 nm, only the dyes linked to protein-specific glycans can be lit up by the donor by two parallel energy transfer processes, for in situ duplexed imaging of glycoforms on specific protein. Using MUC1 as the model, this strategy can visualize distinct glycoforms of MUC1 on various cell types and quantitatively track terminal monosaccharide pattern. This approach provides a versatile platform for profiling protein-specific glycoforms, thus contributing to the study of the regulation mechanisms of protein functions by glycosylation.
Co-reporter:Yunlong Chen, Lin Ding and Huangxian Ju
Chemical Communications 2013 vol. 49(Issue 9) pp:862-864
Publication Date(Web):30 Nov 2012
DOI:10.1039/C2CC37761F
A density tunable dendrimeric array was designed for assembly of a gold nanocluster probe, which was unloaded by its chemoselective recognition to cell surface sialic acid for in situ tracing of sialic acid density.
Co-reporter:Yunlong Chen, Lin Ding and Huangxian Ju
Chemical Communications 2013 - vol. 49(Issue 9) pp:NaN864-864
Publication Date(Web):2012/11/30
DOI:10.1039/C2CC37761F
A density tunable dendrimeric array was designed for assembly of a gold nanocluster probe, which was unloaded by its chemoselective recognition to cell surface sialic acid for in situ tracing of sialic acid density.
![D-Galactopyranose, 2-[(2-azidoacetyl)amino]-2-deoxy-, 1,3,4,6-tetraacetate](/data/chemimg/115200/653600-56-7.png)
![D-Galactopyranose, 2-[(2-azidoacetyl)amino]-2-deoxy-, 1,3,4,6-tetraacetate](/data/chemimg/115200/653600-56-7_b.png)
![D-Mannopyranose, 2-[(2-azidoacetyl)amino]-2-deoxy-, 1,3,4,6-tetraacetate](/data/chemimg/106600/361154-30-5.png)
![D-Mannopyranose, 2-[(2-azidoacetyl)amino]-2-deoxy-, 1,3,4,6-tetraacetate](/data/chemimg/106600/361154-30-5_b.png)
![(2S,4S,5R,6R)-5-acetamido-4-hydroxy-2-(4-methyl-2-oxo-chromen-7-yl)oxy-6-[(2R)-1,2,3-trihydroxypropyl]tetrahydropyran-2-carboxylic acid](http://img.cochemist.com/ccimg/59400/59322-44-0.png)
![(2S,4S,5R,6R)-5-acetamido-4-hydroxy-2-(4-methyl-2-oxo-chromen-7-yl)oxy-6-[(2R)-1,2,3-trihydroxypropyl]tetrahydropyran-2-carboxylic acid](http://img.cochemist.com/ccimg/59400/59322-44-0_b.png)
![N-[9-(2-carboxy-4-thiocyanatophenyl)-6-(dimethylamino)-3H-xanthen-3-ylidene]-N-methylmethanaminium chloride](/data/chemimg/56300/4158-89-8.png)
![N-[9-(2-carboxy-4-thiocyanatophenyl)-6-(dimethylamino)-3H-xanthen-3-ylidene]-N-methylmethanaminium chloride](/data/chemimg/56300/4158-89-8_b.png)
![2-[(2-AMINOPHENYL)DIAZENYL]ANILINE](http://img.cochemist.com/ccimg/600/554-55-2.png)
![2-[(2-AMINOPHENYL)DIAZENYL]ANILINE](http://img.cochemist.com/ccimg/600/554-55-2_b.png)
![3H-Indolium, 2-[5-[1-[6-[(2,5-dioxo-1-pyrrolidinyl)oxy]-6-oxohexyl]-1,3-dihydro-3,3-dimethyl-5-sulfo-2H-indol-2-ylidene]-1,3-pentadien-1-yl]-1-ethyl-3,3-](/data/chemimg/105700/146368-14-1.png)
![3H-Indolium, 2-[5-[1-[6-[(2,5-dioxo-1-pyrrolidinyl)oxy]-6-oxohexyl]-1,3-dihydro-3,3-dimethyl-5-sulfo-2H-indol-2-ylidene]-1,3-pentadien-1-yl]-1-ethyl-3,3-](/data/chemimg/105700/146368-14-1_b.png)
![3',6'-Dihydroxy-3H-spiro[isobenzofuran-1,9'-xanthen]-3-one](http://img.cochemist.com/ccimg/2400/2321-07-5.png)
![3',6'-Dihydroxy-3H-spiro[isobenzofuran-1,9'-xanthen]-3-one](http://img.cochemist.com/ccimg/2400/2321-07-5_b.png)
![2H-Dibenzo[e,g]isoindole](http://img.cochemist.com/ccimg/300/235-93-8.png)
![2H-Dibenzo[e,g]isoindole](http://img.cochemist.com/ccimg/300/235-93-8_b.png)
