Project description:Engineered virus-like particles (VLPs) are a promising technology for in vivo gene editing of human hematopoietic stem and progenitor cells (HSPCs). Here we design and test two different VLP envelopes for human HSPC editing in vitro and in vivo. The first is an optimized version of the baboon envelope BaEVTR, which efficiently transduces human HSPCs in vitro. We show that the optimized BaEVTR VLP enables in vivo editing of β2 microglobulin in long-term human HSPCs (31% at 8 weeks after dosing) and editing of two hemoglobinopathy-relevant loci, BCL11A and HBG1/2 (26% and 7.5%, respectively, at 5 days after dosing), inducing fetal hemoglobin. Our second VLP design uses a CD133-targeted envelope designed to reduce the transduction of mature blood cells and achieves higher in vivo specificity for HSPCs compared to the optimized BaEVTR VLP. As avoiding delivery in filter organs such as the liver would enhance efficiency and safety, we also demonstrate that both VLPs avoid human hepatocytes in a humanized liver model.

Project description:Engineered virus-like particles (VLPs) are a promising technology for in vivo gene editing of human hematopoietic stem and progenitor cells (HSPCs). Here we design and test two different VLP envelopes for human HSPC editing in vitro and in vivo. The first is an optimized version of the baboon envelope BaEVTR, which efficiently transduces human HSPCs in vitro. We show that the optimized BaEVTR VLP enables in vivo editing of β2 microglobulin in long-term human HSPCs (31% at 8 weeks after dosing) and editing of two hemoglobinopathy-relevant loci, BCL11A and HBG1/2 (26% and 7.5%, respectively, at 5 days after dosing), inducing fetal hemoglobin. Our second VLP design uses a CD133-targeted envelope designed to reduce the transduction of mature blood cells and achieves higher in vivo specificity for HSPCs compared to the optimized BaEVTR VLP. As avoiding delivery in filter organs such as the liver would enhance efficiency and safety, we also demonstrate that both VLPs avoid human hepatocytes in a humanized liver model.

Project description:Emerging molecular therapies introduce enzymatic activity into cells by delivering genes, transcripts, or proteins. Owing to their robust cell-entry capacity, virus-like particles (VLPs) represent a technology of choice in genome editing, where low doses of heterologous proteins and nucleic acids are essential. However, clinical translation of VLP vectors is hindered by inadequate purification methods. Current approaches, relying primarily on ultracentrifugation, suffer from inconsistent product quality and poor scalability. Here, we report the development of a broadly applicable purification strategy that improves the purity and therapeutic efficacy of genome-editing VLPs. Considering the characteristic properties of murine leukemia virus (MLV)-derived engineered VLPs (eVLPs) and HIV-derived engineered nucleocytosolic vehicles for loading of programmable editors (ENVLPEs+), we developed a workflow that involves single- and multi-modal chromatographic steps, effectively removing host cell proteins and cell-culture contaminants while improving VLP integrity and biological activity. Our purified VLPs displayed superior protein composition, consistency, and enhanced functional delivery compared to VLPs partially purified by conventional ultracentrifugation methods. Mass spectrometric analysis revealed a substantial decrease in contaminants, with VLP-specific proteins comprising >90% of the final product. In vivo studies confirmed improved therapeutic outcomes when chromatographically purified VLPs were used. Our scalable purification platform addresses critical manufacturing bottlenecks and constitutes a starting point for further development of VLP therapeutics, enabling robust production of pure VLPs for diverse applications such as genome editing, vaccine development, and other uses that require intracellular protein delivery.

Project description:We engineered a glycan-costumed virus-like particle (VLP) vaccine that delivers programmable peptide antigens to induce tumor-specific cellular immunity in vivo. VLPs encapsulating TLR7 agonists were decorated with a synthetic mannose-derived ligand (VLP-Man-OvaI/II) that selectively engages the lectin DC-SIGN. Lectin-TLR7 dual engagement induced robust DC activation and type 1 cellular immunity, whereas VLPs lacking this key DC-SIGN ligand (VLP-PE-OvaI/II) failed to promote DC-mediated cellular responses. We performed bulk RNA-seq experiments on moDCs treated with VLP-Man-OvaI/II and VLP-PE-OvaI/II or unstimulated control moDCs. A total of 486 genes were differentially expressed after treatment with VLP-Man-OvaI/II vs. VLP-PE-OvaI/II (log2FC >1.5 and p<0.05). The significantly upregulated genes included CXCL1, CXCL5, ISG15, IL6, CCL4, ISG20, and SOCS3, all of which are implicated in the TLR7 downstream signaling pathway, suggesting a higher extent of TLR7 activation with the VLP-Man-OvaI/II. Gene set enrichment analysis (GSEA) between VLP-Man-OvaI/II- and VLP-PE-OvaI/II-treated moDCs revealed that hallmark DC activation pathways were also upregulated in VLP-Man-OvaI/II-treated DCs, including pathways related to IFN-a, IFN-g, and TNF-a signaling via nuclear factor-κB (NF-kB). These data give insight into how lectin binding with glycan-costumed VLPs can be employed to reprogram immunity.

Project description:Mounting evidence suggests the high immunogenicity of virus-like particle (VLPs) based vaccines. Although VLP vaccines can be effective, they have not been compared to an envelope glycoprotein (GP)-only vaccine for filoviruses. We conducted a detailed side-by-side comparison of the immunogenicity and protective efficacy of mRNA vaccines encoding for the Marburg virus (MARV) full length GP delivered alone or as a VLP. As expected, co-formulation of the MARV GP and matrix protein VP40 resulted in the formation of VLPs readily detected by electron microscopy after purification from cell supernatants. We vaccinated guinea pigs with a two-component mRNA vaccine encoding for GP and VP40 (from now on referred as VLP vaccine) or a monovalent mRNA vaccine encoding for GP alone. At high vaccine doses, the VLP group demonstrated reduced humoral response as compared to the GP-only group, but both mRNA vaccines fully protected guinea pigs against lethal MARV infection. However, at low doses, GP-only mRNA conferred a 100% protection, whereas the VLP exhibited only a partial protection. In mice the VLP mRNA vaccine was more efficient at inducing GP-specific CD8+ T cells co-expressing IFN-γ and TNF-α, whereas the GP-only mRNA vaccine better induced CD4+ T cells expressing IFN-γ, IL-2 and TNF-α. In addition, in guinea pigs, the VLP vaccine was associated with down-regulation of genes associated with various biological and metabolic processes, including the NF-κB signaling pathway, post-transcriptional silencing of small RNAs, and upregulation of genes involved in the mitochondrial respiratory chain complex. In contrast, the GP-only vaccine upregulated genes involved in interferon signaling. Overall, the VLP mRNA vaccine was less immunogenic and protective, whereas the GP-only mRNA vaccine conferred a robust protection by as little as one µg dose in guinea pigs.

Project description:During the first hours after infection, before SV40 DNA enters the nucleus, empty capsids (VLPs) and the wild-type virus have the same effect on cellular signaling. VLPs were previously found to ameliorate toxic acute kidney injury (AKI) in a mouse model, counteracting apoptosis by inducing the Akt-1 survival pathway. Here we tested their effect on severe sepsis in rats. VLP pre-treatment increased survival and recovery from zero to 75%. RNAseq studies demonstrated that unlike AKI, here the VLPs did not induce survival pathways. Instead they affected thousands of genes and many cellular functions, eliminating deleterious pathways and inducing beneficial ones: immune response, resolution of inflammation, regeneration and cell and system homeostasis. In contrast, only four genes were affected following VLP administration to healthy rats. We propose that SV40 VLPs respond specifically to perturbation in cellular activities. The study suggests that diseases with complex pathophysiology may require treatments affecting wide-spectrum functions.

Project description:During the first hours after infection, before SV40 DNA enters the nucleus, empty capsids (VLPs) and the wild-type virus have the same effect on cellular signaling. VLPs were previously found to ameliorate toxic acute kidney injury (AKI) in a mouse model, counteracting apoptosis by inducing the Akt-1 survival pathway. Here we tested their effect on severe sepsis in rats. VLP pre-treatment increased survival and recovery from zero to 75%. RNAseq studies demonstrated that unlike AKI, here the VLPs did not induce survival pathways. Instead they affected thousands of genes and many cellular functions, eliminating deleterious pathways and inducing beneficial ones: immune response, resolution of inflammation, regeneration and cell and system homeostasis. In contrast, only four genes were affected following VLP administration to healthy rats. We propose that SV40 VLPs respond specifically to perturbation in cellular activities. The study suggests that diseases with complex pathophysiology may require treatments affecting wide-spectrum functions.

Project description:A growing body of evidence supports the importance of T cell responses to protect against severe influenza, promote viral clearance and ensure long-term immunity. Plant-derived virus-like particle (VLP) vaccines bearing influenza hemagglutinin (HA) have been shown to elicit strong humoral and CD4+ T cell responses in both pre-clinical and clinical studies. To better understand the immunogenicity of theses vaccines, we tracked the intracellular fate of a model HA (A/California/07/2009 H1N1) in human monocyte-derived macrophages (MDMs) following delivery either as VLPs (H1-VLP) or in soluble form. High-resolution tandem mass spectrometry identified 131 HA-derived peptides associated with MHC I in the H1-VLP-treated MDMs. Together with immunostaining and microscopy results, these data suggest that HA delivery to antigen-presenting cells on plant-derived VLPs facilitates antigen uptake, endosomal processing and cross-presentation. These observations may help explain the broad and cross-reactive immune responses generated by these vaccines.

Project description:Ex-vivo gene editing in T cells and hematopoietic stem/progenitor cells (HSPCs) holds promise for treating diseases by non-homologous end joining (NHEJ) gene disruption or homology-driven repair (HDR) gene correction. Gene editing encompasses delivery of nucleases by electroporation and, when aiming to HDR, of a DNA template often provided by viral vectors. Whereas HSPCs activate robust p53-dependent DNA damage response (DDR) upon editing, the responses triggered in T cells remain poorly characterized. Here, we performed comprehensive multi-omics analyses and found that electroporation is the culprit of cytotoxicity in T cells, causing death and cell cycle delay, perturbing metabolism and inducing inflammatory response. Nuclease delivery by lipid nanoparticles (LNPs) nearly abolished cell death and ameliorated cell growth, improving tolerance to the procedure and yielding higher number of edited cells compared to electroporation. Transient transcriptomic changes upon LNP treatment were mostly caused by cellular loading with exogenous cholesterol, whose potentially detrimental impact could be overcome by limiting exposure. Notably, LNP-based HSPC editing dampened p53 pathway induction and supported higher reconstitution by long-term repopulating HSPCs compared to electroporation, reaching similar editing efficiencies. Overall, LNPs may allow efficient and stealthier ex-vivo gene editing in hematopoietic cells for treatment of human diseases.

Project description:The composition and biotic nature of wasp VLPs has remained uncharacterized. VLP proteomics have contributed to a new understanding of their unusual organelle nature and mechanism of action in suppressing host defense responses.