Cell engineering with microfluidic squeezing preserves functionality of primary immune cells in vivo

DiTommaso, Tia; Cole, Julie M.; Cassereau, Luke; Buggé, Joshua; Hanson, Jacquelyn L.; Bridgen, Devin; Stokes, Brittany; Loughhead, Scott; Beutel, Bruce A.; Gilbert, Jonathan B.; Nussbaum, Kathrin; Sorrentino, Antonio; Toggweiler, Janine; Schmidt, Tobias; Gyuelveszi, Gabor; Bernstein, Howard; Sharei, Armon

doi:10.1073/pnas.1809671115

Cited by 137 publications

(190 citation statements)

References 34 publications

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“…Electroporation and viral-based transduction of human T cells has been shown to induce significant and dramatic changes in gene expression profiles, including genes related to T cell activation and survival 11,13,39 . Therefore, we evaluated if processing cells via μVS would alter the expression levels of canonical T cell activation markers compared to non-processed cells.…”

Section: µVs Results In Negligible Perturbation Of the T Cell Statementioning

confidence: 99%

“…These markers included CCR7, a chemokine receptor involved in T cell homing following antigen stimulation, CD69, an early activation marker necessary for Th17 differentiation, and the leukocyte adhesion molecule, CD44. Interestingly, changes to these markers, as well as genes involved in DNA damage, cell proliferation, and growth factor production, were detected in genetically-modified T cells as a result of electroporation and dramatically reduced their capacity to suppress tumor growth in vivo 11,13 . Collectively, our results indicate the μVS -based delivery does not perturb the native state of transfected cells, highlighting its potential to maintain the functionality and desired therapeutic effects of engineered cells upon administration.…”

Section: Discussionmentioning

confidence: 99%

“…Unlike viral-based methods, electroporation can be used to deliver a broader range of bioactive constructs into a variety of cell types, while bypassing the extensive safety and regulatory requirements for GMCT manufacturing using viruses 8,9 . However, the significant reductions in cell numbers and viabilities, accompanied by changes in gene expression profiles that negatively impact cell function, make physical transfection methods like electroporation less than ideal for GMCT applications 2,3,9,[11][12][13] . Therefore, the ideal intracellular delivery method to generate GMCTs would permit transfection of various constructs to multiple cell types while having minimal effects on cell viability and cell recovery, and minimal perturbation to normal and/or desired (i.e.…”

Section: Introductionmentioning

confidence: 99%

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Intracellular delivery of mRNA to human primary T cells with microfluidic vortex shedding

Twite¹,

Lau²,

Kashani

et al. 2018

Preprint

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Intracellular delivery of functional macromolecules, such as DNA and RNA, across the cell membrane and into the cytosol, is a critical process in both biology and medicine. Herein, we develop and use microfluidic chips containing post arrays to induce microfluidic vortex shedding, or μVS, for cell membrane poration that permits delivery of mRNA into primary human T lymphocytes. We demonstrate transfection with μVS by delivery of a 996-nucleotide mRNA construct encoding enhanced green fluorescent protein (EGFP) and assessed transfection efficiencies by quantifying levels of EGFP protein expression. We achieved high transfection efficiency (63.6 ± 3.44% EGFP+ viable cells) with high cell viability (77.3 ± 0.58%) and recovery (88.7 ± 3.21%) in CD3+ T cells 19 hrs after μVS processing.Importantly, we show that processing cells via μVS does not negatively affect cell growth rates or alter cell states. We also demonstrate processing speeds of greater than 2.0 x 10 6 cells s -1 at volumes ranging from 0.1 to 1.5 milliliters.Altogether, these results highlight the use of μVS as a rapid and gentle delivery method with promising potential to engineer primary human cells for research and clinical applications.

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Section: µVs Results In Negligible Perturbation Of the T Cell Statementioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Intracellular delivery of mRNA to human primary T cells with microfluidic vortex shedding

Twite¹,

Lau²,

Kashani

et al. 2018

Preprint

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“…113 Considering its ability to deliver diverse loads into various types of cells with relatively low cellular toxicity, development of a suitable squeeze protocol for genome editing is valuable. 115 Hydrodynamic injection causes transient deformation of the cell membrane to facilitate entry of nucleic acids into hepatocytes in vivo. 116 Hydrodynamic injection of a plasmid DNA expressing CRISPR-Cas9 and a single-stranded DNA donor resulted in the correction of a point mutation of fumarylacetoacetate hydrolase (Fah) in hepatocytes in a mouse model of hereditary tyrosinemia.…”

Section: Physical and Combinational Methodsmentioning

confidence: 99%

Genome Editing with mRNA Encoding ZFN, TALEN, and Cas9

2019

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Genome-editing technologies based on programmable nucleases have significantly broadened our ability to make precise and direct changes in the genomic DNA of various species, including human cells. Delivery of programmable nucleases into the target tissue or cell is one of the pressing challenges in transforming the technology into medicine. In vitro-transcribed (IVT) mRNA-mediated delivery of nucleases has several advantages, such as transient expression with efficient in vivo and in vitro delivery, no genomic integration, a potentially low off-target rate, and high editing efficiency. This review focuses on key barriers related to IVT mRNA delivery, on developed modes of delivery, and on the application and future prospects of mRNA encoding nuclease-mediated genome editing in research and clinical trials. Principles of Genome Editing Genome-Editing Nucleases CRISPR-Cas systems are essentially RNA-guided nucleases. Unlike the aforementioned nucleases that recognize the target sequence

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“…A notable difference, however, is observable in how cells respond to these treatments, microfluidic squeezing being markedly less disruptive to cells. In particular, genome‐wide profiling shows that 34% of genes are misexpressed 6 h after electroporation of T cells (8141 transcripts out of 23 786 probed) while only 9% are affected 6 h after squeezing (2211/23 766) …”

Section: Introductionmentioning

confidence: 99%

Efficient and Innocuous Live‐Cell Delivery: Making Membrane Barriers Disappear to Enable Cellular Biochemistry

Pellois

2019

BioEssays

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The confluence of protein engineering techniques and delivery protocols are providing new opportunities in cell biology. In particular, techniques that render the membrane of cells transiently permeable make the introduction of nongenetically encodable macromolecular probes into cells possible. This, in turn, can enable the monitoring of intracellular processes in ways that can be both precise and quantitative, ushering an area that one may envision as cellular biochemistry. Herein, the author reviews pioneering examples of such new cell‐based assays, provides evidence that challenges the paradigm that cell penetration is a necessarily damaging and stressful event for cells, and highlights some of the challenges that should be addressed to fully unlock the potential of this nascent field.

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Cell engineering with microfluidic squeezing preserves functionality of primary immune cells in vivo

Cited by 137 publications

References 34 publications

Intracellular delivery of mRNA to human primary T cells with microfluidic vortex shedding

Intracellular delivery of mRNA to human primary T cells with microfluidic vortex shedding

Genome Editing with mRNA Encoding ZFN, TALEN, and Cas9

Efficient and Innocuous Live‐Cell Delivery: Making Membrane Barriers Disappear to Enable Cellular Biochemistry

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