Multiplexing Imaging of Closely Located Single-Nucleotide Mutations in Single Cells via Encoded in situ PCR.
Yao RenKerui LiuHao YangYong ZhangSha DengJijuan CaoXuhan XiaRuijie DengPublished in: ACS sensors (2024)
Mutation accumulation in RNAs results in closely located single-nucleotide mutations (SNMs), which is highly associated with the drug resistance of pathogens. Imaging of SNMs in single cells has significance for understanding the heterogeneity of RNAs that are related to drug resistance, but the direct "see" closely located SNMs remains challenging. Herein, we designed an encoded ligation-mediated in situ polymerase chain reaction method (termed enPCR), which enabled the visualization of multiple closely located SNMs in bacterial RNAs. Unlike conventional ligation-based probes that can only discriminate a single SNM, this method can simultaneously image different SNMs at closely located sites with single-cell resolution using modular anchoring probes and encoded PCR primers. We tested the capacity of the method to detect closely located SNMs related to quinolone resistance in the gyrA gene of Salmonella enterica ( S. enterica ), and found that the simultaneous detection of the closely located SNMs can more precisely indicate the resistance of the S. enterica to quinolone compared to the detection of one SNM. The multiplexing imaging assay for SNMs can serve to reveal the relationship between complex cellular genotypes and phenotypes.
Keyphrases
- single cell
- high resolution
- induced apoptosis
- cell cycle arrest
- real time pcr
- fluorescence imaging
- small molecule
- single molecule
- genome wide
- antimicrobial resistance
- deep learning
- oxidative stress
- loop mediated isothermal amplification
- machine learning
- cell proliferation
- mass spectrometry
- signaling pathway
- photodynamic therapy
- gram negative
- label free
- drug induced