Stéphanie Grosse scite author profile

Herpes simplex virus type 1 (HSV1) is a major health problem. As for most viral diseases, current antiviral treatments are based on the inhibition of viral replication once it has already started. As a consequence, they impair neither the viral cycle at its early stages nor the latent form of the virus, and thus cannot be considered as real preventive treatments. Latent HSV1 virus could be addressed by rare cutting endonucleases, such as meganucleases. With the aim of a proof of concept study, we generated several meganucleases recognizing HSV1 sequences, and assessed their antiviral activity in cultured cells. We demonstrate that expression of these proteins in African green monkey kidney fibroblast (COS-7) and BSR cells inhibits infection by HSV1, at low and moderate multiplicities of infection (MOIs), inducing a significant reduction of the viral load. Furthermore, the remaining viral genomes display a high rate of mutation (up to 16%) at the meganuclease cleavage site, consistent with a mechanism of action based on the cleavage of the viral genome. This specific mechanism of action qualifies meganucleases as an alternative class of antiviral agent, with the potential to address replicative as well as latent DNA viral forms.

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Potocytosis and cellular exit of complexes as cellular pathways for gene delivery by polycations

Grosse

Aron

Thévenot

et al. 2005

J. Gene Med.

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Lactosylated polyethylenimine for gene transfer into airway epithelial cells: role of the sugar moiety in cell delivery and intracellular trafficking of the complexes

Grosse

Aron

Honoré

et al. 2004

The Journal of Gene Medicine

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Stabilized Integrin-Targeting Ternary LPD (Lipopolyplex) Vectors for Gene Delivery Designed To Disassemble Within the Target Cell

et al. 2009

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Recent research in the field of nonviral gene delivery vectors has focused on preparing nanoparticles that are stabilized by the incorporation of a PEG coating and where one of the vector components is also cleavable. Here,we describe the synthesis, formulation, transfection properties, and biophysical studies of a PEG-stabilized ternary lipopolyplex vector in which, for the first time, both the lipid and peptide components are designed to be cleaved once the vector has been internalized. A series of cationic lipids, bearing short tri- or hexaethylene glycol groups, attached to the headgroup via an ester linkage, has been prepared. Trifunctional peptides have also been prepared, consisting of a Lys(16) sequence at the N-terminus (to bind and condense plasmid DNA); a spacer group (containing a sequence recognized and cleaved by endosomal enzymes) and an optional PEG4 amino acid; and an integrin-targeting cyclic peptide sequence (allowing the resulting nanoparticle to be internalized via receptor-mediated endocytosis). Differing combinations of these lipids and peptides have been formulated with DOPE and with plasmid DNA, and complex stability, transfection, and cleavage studies carried out. It was shown that optimal transfection activities in a range of cell types and complex stabilities were achieved with lipids bearing short cleavable triethylene glycol moieties, whereas the incorporation of PEG4 amino acids into the cleavable peptides had little effect. We have synthesized appropriate fluorescently labeled components and have studied the uptake of the vector, endosomal escape, peptide cleavage, and plasmid transport to the nucleus in breast cancer cells using confocal microscopy. We have also studied the morphology of these compact, stabilized vectors using cryo-EM.

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Tumor‐specific gene transfer with receptor‐mediated nanocomplexes modified by polyethylene glycol shielding and endosomally cleavable lipid and peptide linkers

et al. 2010

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Synthetic nanoparticle formulations have the potential for tumor-targeted gene delivery. Receptor-targeted nanocomplex (RTN) formulations comprise mixtures of cationic liposomes and targeting peptides that self-assemble on mixing with nucleic acids. RTN formulations were prepared containing different polyethylene glycol (PEG)ylated lipids with esterase-cleavable linkers (e.g., ME42) to promote intracellular PEG detachment and nanoparticle disassembly. In addition, integrin-targeting peptides (peptide ME27) were tested with endosomal furin- and cathepsin B-cleavable peptide linkers located between the integrin-binding ligand and the K(16) nucleic acid-binding domain to promote intracellular disengagement from the receptor. ME42/ME27 RTNs formed stable particles of <200 nm in isotonic salt buffers, compared with 4-microm particles formed by un-PEGylated RTNs. Transfection efficiency by PEG-modified, cleavable RTNs improved approximately 2-fold in 4 different cell lines, with 80% efficiency in murine neuroblastoma cells. In an in vivo model of neuroblastoma, ME42/ME27 RTNs delivering luciferase genes were tumor specific, with little expression in other organs tested. PEGylation of the RTNs enhanced luciferase transfection 5-fold over non-PEG formulations, whereas the cleavability of the peptide ME27 enhanced transfection 4-fold over that of RTNs with noncleavable peptides. Cleavability of the lipid for in vivo transfections had no effect. PEGylated, cleavable RTN formulations offer prospects for tumor-specific therapeutic gene transfer.

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Transcription of plasmid DNA: Influence of plasmid DNA/polyethylenimine complex formation

Honoré¹,

Grosse²,

Frison³

et al. 2005

Journal of Controlled Release

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Polyethylenimine (PEI) is one of the most potent non-viral vectors. We have developed a lactosylated PEI (Lac-PEI) to enhance cell-specific transfection and have shown that Lac-PEI is more efficient than unsubstituted PEI for gene transfer into immortalized cystic fibrosis airway epithelial SigmaCFTE29o-cells. As both intact PEI/plasmid and Lac-PEI/plasmid complexes are found in the cell nucleus, we have investigated the transcription efficiency of the plasmid complexed with PEI or Lac-PEI, according to the polymer nitrogen/DNA phosphate (N/P) ratio (from 0 to 20). The initiation of transgene transcription was analyzed in an acellular nuclease S1 transcription assay. For both PEI and Lac-PEI complexes, transcription efficiency varied with the N/P ratio of the complexes. Transcription inhibition was observed when plasmid DNA was either loosely (N/P<5) or tightly condensed (N/P>15). For an N/P ratio of 5 and up to 15, transcription of the complexed plasmid was as efficient as that of the free plasmid. Similar results were observed when gene expression was studied after nuclear microinjection of the complexes into SigmaCFTE29o-cells. Our study shows that condensation of DNA influences the accessibility of the plasmid to the transcription machinery. Interestingly, the charge ratios that allow the most efficient transcription are those usually known to be the most efficient for gene transfer in vitro and in vivo.

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Integrin-targeted nanocomplexes for tumour specific delivery and therapy by systemic administration

et al. 2011

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