Oliwia Andries

mRNA as gene therapeutic: how to control protein expression.

For many years, it was generally accepted that mRNA is too unstable to be efficiently used for gene therapy purposes. In the last decade, however, several research groups faced this challenge and not only proved the feasibility of mRNA-mediated transfection with surprising results regarding transfection efficiency and duration of protein expression, but also were able to demonstrate major advantages over the use of pDNA. These advantages will be the first issue discussed in this review, which first of all addresses the notions that mRNA does not need to cross the nuclear barrier to exert its biological activity and in addition lacks CpG motifs, which reduces its immunogenicity. Secondly, it provides insight in the (in)stability of the mRNA molecule, in how mRNA can be modified to increase its half-life and in the necessities of exogenously produced mRNA to be successfully used in transfection protocols. Furthermore, this review gives an in-depth overview of the different techniques and vehicles for intracellular mRNA delivery exploited by us and other groups, comprising electroporation, gene gun injection, lipo- and polyplexes. Finally, it covers recent literature describing specific applications for mRNA based gene delivery, showing that until now most attention has been paid to vaccination strategies. This review offers a comprehensive overview of current knowledge of the major theoretical as well as practical aspects of mRNA-mediated transfection, showing both its possibilities and its pitfalls and should therefore be useful for a diverse scientific audience.

N(1)-methylpseudouridine-incorporated mRNA outperforms pseudouridine-incorporated mRNA by providing enhanced protein expression and reduced immunogenicity in mammalian cell lines and mice.

Messenger RNA as a therapeutic modality is becoming increasingly popular in the field of gene therapy. The realization that nucleobase modifications can greatly enhance the properties of mRNA by reducing the immunogenicity and increasing the stability of the RNA molecule (the Kariko paradigm) has been pivotal for this revolution. Here we find that mRNAs containing the N(1)-methylpseudouridine (m1Ψ) modification alone and/or in combination with 5-methylcytidine (m5C) outperformed the current state-of-the-art pseudouridine (Ψ) and/or m5C/Ψ-modified mRNA platform by providing up to ~44-fold (when comparing double modified mRNAs) or ~13-fold (when comparing single modified mRNAs) higher reporter gene expression upon transfection into cell lines or mice, respectively. We show that (m5C/)m1Ψ-modified mRNA resulted in reduced intracellular innate immunogenicity and improved cellular viability compared to (m5C/)Ψ-modified mRNA upon in vitro transfection. The enhanced capability of (m5C/)m1Ψ-modified mRNA to express proteins may at least partially be due to the increased ability of the mRNA to evade activation of endosomal Toll-like receptor 3 (TLR3) and downstream innate immune signaling. We believe that the (m5C/)m1Ψ-mRNA platform presented here may serve as a new standard in the field of modified mRNA-based therapeutics.

Innate immune response and programmed cell death following carrier-mediated delivery of unmodified mRNA to respiratory cells

In this report we show that carrier-mediated delivery of mRNA may activate TLR3 signaling in respiratory cells. This activation of the innate immune system was accompanied with a massive production of type 1 interferons and other immunostimulating cytokines. The recognition of mRNA by the innate immune system was also associated with cell death, which proceeded in human respiratory cells via pyroptosis, a form of programmed cell death mediated by substantial overexpression of caspase-1. This indicated that the delivered mRNA is most likely also recognized by NOD-like receptors which regulate caspase-1 production. The viability of murine respiratory cells was less affected by mRNA transfection, which is in line with the lower transfection efficiency, lower innate immune response and the absence of a massive caspase-1 upregulation in these cells. Finally, we also demonstrated that the recognition of the delivered mRNA by the innate immune system had a negative effect on mRNA translation.

Synthetic biology devices and circuits for RNA-based ‘smart vaccines’: a propositional review

Nucleic acid vaccines have been gaining attention as an alternative to the standard attenuated pathogen or protein based vaccine. However, an unrealized advantage of using such DNA or RNA based vaccination modalities is the ability to program within these nucleic acids regulatory devices that would provide an immunologist with the power to control the production of antigens and adjuvants in a desirable manner by administering small molecule drugs as chemical triggers. Advances in synthetic biology have resulted in the creation of highly predictable and modular genetic parts and devices that can be composed into synthetic gene circuits with complex behaviors. With the recent advent of modified RNA gene delivery methods and developments in the RNA replicon platform, we foresee a future in which mammalian synthetic biologists will create genetic circuits encoded exclusively on RNA. Here, we review the current repertoire of devices used in RNA synthetic biology and propose how programmable ‘smart vaccines’ will revolutionize the field of RNA vaccination.

Comparison of the Gene Transfer Efficiency of mRNA/GL67 and pDNA/GL67 Complexes in Respiratory Cells

Complexes between mRNA and GL67:DOPE:DMPE-PEG5000 (GL67) liposomes were formulated and characterized. Subsequently, the in vitro and in vivo expression characteristics of mRNA/GL67 complexes and pDNA/GL67 complexes, each produced at their optimal ratio, were compared in respiratory cells. Transfection of A549 cells with mRNA/GL67 complexes resulted in a much faster expression than after transfection with pDNA/GL67 complexes. The percentage of GFP-positive cells after mRNA and pDNA transfection peaked after 8 and 24 h, respectively. At these time points the percentage of GFP-positive cells was two times higher after mRNA transfection than after pDNA transfection. Furthermore, the efficacy of mRNA/GL67 complexes was independent of the cell cycle. This was in sharp contrast with pDNA/GL67 complexes that caused only a weak expression in nondividing cells. This confirms that the nuclear barrier is a crucial obstacle for pDNA but not for mRNA. Finally, mRNA/GL67 and pDNA/GL67 complexes encoding luciferase were administered intranasally to the lungs of mice. The mRNA/GL67 complexes did not give rise to a measurable luciferase expression in the murine lungs. In contrast, a detectable bioluminescent signal was present in the lungs of mice that received the pDNA/GL67 complexes. We showed that mRNA/GL67 complexes have a lower stability in biological fluids. Consequently, this may be an explanation for their lower performance in vivo.

T cell epitope mapping of the e-protein of West Nile virus in BALB/c mice.

West Nile virus (WNV) is a zoonotic virus, which is transmitted by mosquitoes. It is the causative agent of the disease syndrome called West Nile fever. In some human cases, a WNV infection can be associated with severe neurological symptoms. The immune response to WNV is multifactorial and includes both humoral and cellular immunity. T-cell epitope mapping of the WNV envelope (E) protein has been performed in C57BL/6 mice, but not in BALB/c mice. Therefore, we performed in BALB/c mice a T-cell epitope mapping using a series of peptides spanning the WNV envelope (E) protein. To this end, the WNV-E specific T cell repertoire was first expanded by vaccinating BALB/c mice with a DNA vaccine that generates subviral particles that resemble West Nile virus. Furthermore, the WNV structural protein was expressed in Escherichia coli as a series of overlapping 20-mer peptides fused to a carrier-protein. Cytokine-based ELISPOT assays using these purified peptides revealed positive WNV-specific T cell responses to peptides within the different domains of the E-protein.