DMF-DM-seq: Digital-Microfluidics Enabled Dual-Modality Sequencing of Single-Cell mRNA and microRNA with High Integration, Sensitivity, and Automation

• Published in: Analytical chemistry (Washington) Vol. 96; no. 31; pp. 12916 - 12926
• Main Authors: Chen, Yingwen, Wang, Xuanqun, Na, Xing, Zhang, Yingkun, Cai, Linfeng, Song, Jia, Yang, Chaoyong
• Format: Journal Article
• Language: English
• Published: United States American Chemical Society 06.08.2024
• Subjects: Automation; Biological activity; Biological effects; Gene expression; Gene sequencing; Heterogeneity; Lysis; Magnetic fields; Measuring instruments; Metastases; Microfluidics; MicroRNAs; miRNA; mRNA; Regulatory mechanisms (biology); Ribonucleic acid; RNA; Sensory integration; Separation; Signal transduction
• ISSN: 0003-2700; 1520-6882; 1520-6882
• DOI: 10.1021/acs.analchem.4c03378

Multimodal measurement of single cells provides deep insights into the intricate relationships between individual molecular layers and the regulatory mechanisms underlying intercellular variations. Here, we reported DMF-DM-seq, a highly integrated, sensitive, and automated platform for single-cell mRNA and microRNA (miRNA) co-sequencing based on digital microfluidics. This platform first integrates the processes of single-cell isolation, lysis, component separation, and simultaneous sequencing library preparation of mRNA and miRNA within a single DMF device. Compared with the current half-cell measuring strategy, DMF-DM-seq enables complete separation of single-cell mRNA and miRNA via a magnetic field application, resulting in a higher miRNA detection ability. DMF-DM-seq revealed differential expression patterns of single cells of noncancerous breast cells and noninvasive and aggressive breast cancer cells at both mRNA and miRNA levels. The results demonstrated the anticorrelated relationship between miRNA and their mRNA targets. Further, we unravel the tumor growth and metastasis-associated biological processes enriched by miRNA-targeted genes, along with important miRNA-interaction networks involved in significant signaling pathways. We also deconstruct the miRNA regulatory mechanisms underlying different signaling pathways across different breast cell types. In summary, DMF-DM-seq offers a powerful tool for a comprehensive study of the expression heterogeneity of single-cell mRNA and miRNA, which will be widely applied in basic and clinical research.