An integrated ion-exchange membrane-based microfluidic device for irreversible dissociation and quantification of miRNA from ribonucleoproteins.
Kyle P McCarthyDavid B GoSatyajyoti SenapatiHsueh-Chia ChangPublished in: Lab on a chip (2023)
Ribonucleoproteins (RNPs), particularly microRNA-induced silencing complex (miRISC), have been associated with cancer-related gene regulation. Specific RNA-protein associations in miRISC complexes or those found in let-7 lin28A complexes can downregulate tumor-suppressing genes and can be directly linked to cancer. The high protein-RNA electrostatic binding affinity is a particular challenge for the quantification of the associated microRNAs (miRNAs). We report here the first microfluidic point-of-care assay that allows direct quantification of RNP-associated RNAs, which has the potential to greatly advance RNP profiling for liquid biopsy. Key to the technology is an integrated cation-anion exchange membrane (CEM/AEM) platform for rapid and irreversible dissociation ( k = 0.0025 s -1 ) of the RNP (Cas9-miR-21) complex and quantification of its associated miR-21 in 40 minutes. The CEM-induced depletion front is used to concentrate the RNP at the depletion front such that the high electric field (>100 V cm -1 ) within the concentration boundary layer induces irreversible dissociation of the low K D (∼0.5 nM) complex, with ∼100% dissociation even though the association rate ( k on = 6.1 s -1 ) is 1000 times higher. The high field also electrophoretically drives the dissociated RNA out of the concentrated zone without reassociation. A detection limit of 1.1 nM is achieved for Cy3 labelled miR-21.
Keyphrases
- cell proliferation
- long non coding rna
- high throughput
- long noncoding rna
- single cell
- electron transfer
- high glucose
- ionic liquid
- diabetic rats
- photodynamic therapy
- loop mediated isothermal amplification
- label free
- circulating tumor cells
- crispr cas
- binding protein
- signaling pathway
- oxidative stress
- genome wide
- nucleic acid
- gene expression
- genome editing
- small molecule
- endothelial cells
- climate change
- young adults
- human health
- real time pcr