Cellular Transfection Using Rapid Decrease in Hydrostatic Pressure

Overview

Journal Sci Rep

Specialty Science

Date 2024 Feb 26

PMID 38409237

Authors

Shudi Huang

Nan Ji Suo

Tyler R Henderson

Robert B Macgregor Jr

Jeffrey T Henderson

Affiliations

Soon will be listed here.

Abstract

Of all methods exercised in modern molecular biology, modification of cellular properties through the introduction or removal of nucleic acids is one of the most fundamental. As such, several methods have arisen to promote this process; these include the condensation of nucleic acids with calcium, polyethylenimine or modified lipids, electroporation, viral production, biolistics, and microinjection. An ideal transfection method would be (1) low cost, (2) exhibit high levels of biological safety, (3) offer improved efficacy over existing methods, (4) lack requirements for ongoing consumables, (5) work efficiently at any scale, (6) work efficiently on cells that are difficult to transfect by other methods, and (7) be capable of utilizing the widest array of existing genetic resources to facilitate its utility in research, biotechnical and clinical settings. To address such issues, we describe here Pressure-jump-poration (PJP), a method using rapid depressurization to transfect even difficult to modify primary cell types such as embryonic stem cells. The results demonstrate that PJP can be used to introduce an array of genetic modifiers in a safe, sterile manner. Finally, PJP-induced transfection in primary versus transformed cells reveals a surprising dichotomy between these classes which may provide further insight into the process of cellular transformation.

Citing Articles

Boosting Lipofection Efficiency Through Enhanced Membrane Fusion Mechanisms.

Pavlov R, Akimov S, Dashinimaev E, Bashkirov P Int J Mol Sci. 2025; 25(24.

PMID: 39769303 PMC: 11677079. DOI: 10.3390/ijms252413540.

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