2 research outputs found
An updated database of virus circular RNAs provides new insights into the biogenesis mechanism of the molecule
Virus circular RNAs (circRNA) have been reported to be extensively expressed and play important roles in viral infections. Previously we build the first database of virus circRNAs named VirusCircBase which has been widely used in the field. This study significantly improved the database on both the data quantity and database functionality: the number of virus circRNAs, virus species, host organisms was increased from 46440, 23, 9 to 60859, 43, 22, respectively, and 1902 full-length virus circRNAs were newly added; new functions were added such as visualization of the expression level of virus circRNAs and visualization of virus circRNAs in the Genome Browser. Analysis of the expression of virus circRNAs showed that they had low expression levels in most cells or tissues and showed strong expression heterogeneity. Analysis of the splicing of virus circRNAs showed that they used a much higher proportion of non-canonical back-splicing signals compared to those in animals and plants, and mainly used the A5SS (alternative 5’ splice site) in alternative-splicing. Most virus circRNAs have no more than two isoforms. Finally, human genes associated with the virus circRNA production were investigated and more than 1000 human genes exhibited moderate correlations with the expression of virus circRNAs. Most of them showed negative correlations including 42 genes encoding RNA-binding proteins. They were significantly enriched in biological processes related to cell cycle and RNA processing. Overall, the study provides a valuable resource for further studies of virus circRNAs and also provides new insights into the biogenesis mechanisms of virus circRNAs.</p
Enhanced Imaging of Specific Cell-Surface Glycosylation Based on Multi-FRET
Cell-surface glycosylation
contains abundant biological information
that reflects cell physiological state, and it is of great value to
image cell-surface glycosylation to elucidate its functions. Here
we present a hybridization chain reaction (HCR)-based multifluorescence
resonance energy transfer (multi-FRET) method for specific imaging
of cell-surface glycosylation. By installing donors through metabolic
glycan labeling and acceptors through aptamer-tethered nanoassemblies
on the same glycoconjugate, intramolecular multi-FRET occurs due to
near donor–acceptor distance. Benefiting from amplified effect
and spatial flexibility of the HCR nanoassemblies, enhanced multi-FRET
imaging of specific cell-surface glycosylation can be obtained. With
this HCR-based multi-FRET method, we achieved obvious contrast in
imaging of protein-specific GalNAcylation on 7211 cell surfaces. In
addition, we demonstrated the general applicability of this method
by visualizing the protein-specific sialylation on CEM cell surfaces.
Furthermore, the expression changes of CEM cell-surface protein-specific
sialylation under drug treatment was accurately monitored. This developed
imaging method may provide a powerful tool in researching glycosylation
functions, discovering biomarkers, and screening drugs