Frontiers in Drug Delivery (Mar 2024)

Single cell phototransfection of mRNAs encoding SARS-CoV2 spike and nucleocapsid into human astrocytes results in RNA dependent translation interference

  • Hyun-Bum Kim,
  • Quentin Brosseau,
  • Julia Radzio,
  • Jinhui Wang,
  • Hiromi Muramatsu,
  • Da Kuang,
  • M. Sean Grady,
  • H. Isaac Chen,
  • John A. Wolf,
  • Alexandra V. Ulyanova,
  • Tamas Bartfai,
  • Junhyong Kim,
  • Norbert Pardi,
  • Jai-Yoon Sul,
  • Paulo Arratia,
  • James Eberwine

DOI
https://doi.org/10.3389/fddev.2024.1359700
Journal volume & issue
Vol. 4

Abstract

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Multi-RNA co-transfection is starting to be employed to stimulate immune responses to SARS-CoV-2 viral infection. While there are good reasons to utilize such an approach, there is little background on whether there are synergistic RNA-dependent cellular effects. To address this issue, we use transcriptome-induced phenotype remodeling (TIPeR) via phototransfection to assess whether mRNAs encoding the Spike and Nucleocapsid proteins of SARS-CoV-2 virus into single human astrocytes (an endogenous human cell host for the virus) and mouse 3T3 cells (often used in high-throughput therapeutic screens) synergistically impact host cell biologies. An RNA concentration-dependent expression was observed where an increase of RNA by less than 2-fold results in reduced expression of each individual RNAs. Further, a dominant inhibitory effect of Nucleocapsid RNA upon Spike RNA translation was detected that is distinct from codon-mediated epistasis. Knowledge of the cellular consequences of multi-RNA transfection will aid in selecting RNA concentrations that will maximize antigen presentation on host cell surface with the goal of eliciting a robust immune response. Further, application of this single cell stoichiometrically tunable RNA functional genomics approach to the study of SARS-CoV-2 biology promises to provide details of the cellular sequalae that arise upon infection in anticipation of providing novel targets for inhibition of viral replication and propagation for therapeutic intervention.

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