Deciphering the impact of parameters influencing transgene expression kinetics after repeated cell transduction with integration-deficient retroviral vectors.

Lentiviral and gammaretroviral vectors are state-of-the-art tools for transgene expression within target cells. The integration of these vectors can be deliberately suppressed to derive a transient gene expression system based on extrachromosomal circular episomes with intact coding regions. These episomes can be used to deliver DNA templates and to express RNA or protein. Importantly, transient gene transfer avoids the genotoxic side effects of integrating vectors. Restricting their applicability, episomes are rapidly lost upon dilution in dividing target cells. Addressing this limitation, we could establish comparably stable percentages of transgene-positive cells over prolonged time periods in proliferating cells by repeated transductions. Flow cytometry was applied for kinetic analyses to decipher the impact of individual parameters on the kinetics of fluoroprotein expression after episomal retransduction and to visualize sequential and simultaneous transfer of heterologous fluoroproteins. Expression windows could be exactly timed by the number of transduction steps. The kinetics of signal loss was affected by the cell proliferation rate. The transfer of genes encoding fluoroproteins with different half-lives revealed a major impact of protein stability on temporal signal distribution and accumulation, determining optimal retransduction intervals. In addition, sequential transductions proved broad applicability in different cell types and using different envelope pseudotypes without receptor overload. Stable percentages of cells coexpressing multiple transgenes could be generated upon repeated coadministration of different episomal vectors. Alternatively, defined patterns of transgene expression could be recapitulated by sequential transductions. Altogether, we established a methodology to control and adjust a temporally defined window of transgene expression using retroviral episomal vectors. Combined with the highly efficient cell entry of these vectors while avoiding integration, the developed technology is of great significance for a broad panel of applications, including transcription-factor-based induced cell fate conversion and controlled transfer of genetically encoded RNA- or protein-based drugs.

Viral and non-viral approaches for transient delivery of mRNA and proteins.

The transient delivery of gene products (RNA or proteins) is not a biotechnological invention but rather an evolutionarily conserved process underlying and regulating a variety of biological functions. On the basis of insights into the underlying mechanisms, several viral and cell-based approaches have been developed for the delivery of RNA or proteins. Prominent applications include the induction of major biological or therapeutic effects on the basis of "hit-and-run" mechanisms, such as vaccination, cell fate modification (reprogramming, differentiation), control of cell trafficking, enhancement of cell regeneration, and genome engineering using sequence-specific recombinases or nucleases. Ideally, procedures for delivery of RNA or proteins should be targeted to specific cells, overcome biophysical hurdles without harming cellular integrity, circumvent the various alarm signals of the innate immune system, allow dose-controlled delivery of functional biomacromolecules, and avoid the induction of an adaptive immune response. Here we review the current state of approaches for the delivery of mRNA and proteins with a focus on RNA viruses, virus-like particles including retrovirus particle-mediated transfer of mRNA or proteins, extracellular vesicles, and cell-penetrating peptides. The basic concepts and recent advances are put into perspective in the context of potential limitations of the technologies and strategies to overcome cellular barriers and defense mechanisms.