In vivo metabolic labeling of sialoglycans in the mouse brain by using a liposome-assisted bioorthogonal reporter strategy

Mammalian brains are highly enriched with sialoglycans, which have been implicated in brain development and disease progression. However, in vivo labeling and visualization of sialoglycans in the mouse brain remain a challenge because of the blood−brain barrier. Here we introduce a liposome-assisted...

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Published inProceedings of the National Academy of Sciences - PNAS Vol. 113; no. 19; pp. 5173 - 5178
Main Authors Xie, Ran, Dong, Lu, Du, Yifei, Zhu, Yuntao, Hua, Rui, Zhang, Chen, Chen, Xing
Format Journal Article
LanguageEnglish
Published United States National Academy of Sciences 10.05.2016
Subjects
Animals
Biological Sciences
Biosynthesis
Brain
Brain - metabolism
Fluorescence
Genes, Reporter - physiology
Liposomes - chemistry
Male
Mammals
Mice
Mice, Inbred BALB C
Microscopy, Fluorescence - methods
Molecular Imaging - methods
Physical Sciences
Polysaccharides - metabolism
Proteins
Proteomics
Recombinant Proteins - metabolism
Rodents
Sialic Acids - metabolism
Staining and Labeling - methods
Tissue Distribution
live imaging
glycoproteomics
brain
histochemistry
sialic acid
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Summary:Mammalian brains are highly enriched with sialoglycans, which have been implicated in brain development and disease progression. However, in vivo labeling and visualization of sialoglycans in the mouse brain remain a challenge because of the blood−brain barrier. Here we introduce a liposome-assisted bioorthogonal reporter (LABOR) strategy for shuttling 9-azido sialic acid (9AzSia), a sialic acid reporter, into the brain to metabolically label sialoglycoconjugates, including sialylated glycoproteins and glycolipids. Subsequent bioorthogonal conjugation of the incorporated 9AzSia with fluorescent probes via click chemistry enabled fluorescence imaging of brain sialoglycans in living animals and in brain sections. Newly synthesized sialoglycans were found to widely distribute on neuronal cell surfaces, in particular at synaptic sites. Furthermore, large-scale proteomic profiling identified 140 brain sialylated glycoproteins, including a wealth of synapse-associated proteins. Finally, by performing a pulse−chase experiment, we showed that dynamic sialylation is spatially regulated, and that turnover of sialoglycans in the hippocampus is significantly slower than that in other brain regions. The LABOR strategy provides a means to directly visualize and monitor the sialoglycan biosynthesis in the mouse brain and will facilitate elucidating the functional role of brain sialylation.
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Edited by Carolyn R. Bertozzi, Stanford University, Stanford, CA, and approved March 18, 2016 (received for review August 19, 2015)
Author contributions: X.C. designed research; R.X., L.D., Y.D., and Y.Z. performed research; R.H. and C.Z. contributed new reagents/analytic tools; R.X., L.D., Y.D., and X.C. analyzed data; and R.X., L.D., Y.D., and X.C. wrote the paper.
1R.X. and L.D. contributed equally to this work.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1516524113