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Background & Aim: Ricin is one of the most lethal toxins, particularly if inhaled, and is considered a biological threat agent due to its wide availability and ease of production. Pulmonary ricin intoxication manifests in ARDS, cytokine storm, immune infiltration, and severe edema. Passive immunization is the preferred measure against pulmonary ricinosis, but only if administered shortly after exposure. Despite their potential to remedy pulmonary injury and inflammation, mesenchymal cell (MSC) therapies were never investigated in ricinosis. Here, we report the potential for treating pulmonary ricinosis with MesenCure, a professionalized allogeneic MSC therapy shown to reduce the mortality of patients suffering from severe pulmonary manifestations of COVID by 68%. Methods, Results & Conclusion(s): Preliminary studies demonstrated positive MesenCure effects in a sub-lethal pulmonary ricinosis model in CD1 mice. This model is regarded as highly translational due to the broad heterogeneity of these outbred mice. Positive effects included a reduction in excess protein content of the bronchoalveolar lavage fluid (BALF) by 45% when MesenCure was injected intravenously (IV) at 125k cells/animal, 48h post-exposure (PE) and evaluated one day later (p<0.05, Fig. 1A). Moreover, we found up to 52% reduction in the excess BALF leukocytes, when MesenCure was injected IV, 24h PE using the same dose (p<0.05, Fig. 1B) or 6h PE using a double dose (p<0.01, Fig. 1C), and evaluated two days PE. Optimizing the dose and administration route further improved the therapeutic outcome of MesenCure applied 6h PE as assessed by weight loss. As shown in Fig. 1D-E, IV injection of 250k-500k MesenCure cells/animal slightly protected the intoxicated animals against weight loss (p for treatment x time interaction <0.01 or <0.05 for 250k and 500k cells/animal, respectively). Interestingly, one million cells IV resulted in a lesser effect (not shown), however when injected subcutaneously (SC), 1M cells were very effective (p<0.001, Fig. 1F), seemingly even more effective than 2M cells/animal SC (Fig. 1G). Surprisingly, 2M thawed cells/animal injected SC protected the animals against weight loss almost completely (p<0.0001, Fig. H). In conclusion, we provide evidence for the potential of SC MSCs, specifically MesenCure, for treating pulmonary ricinosis and possibly other forms of ARDS. In agreement with Giri and Galipeau (2020), we provide further evidence for the dependency of MSC outcomes on their specific state and administration route. [Figure presented]Copyright © 2023 International Society for Cell & Gene Therapy
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Despite the global administration of approved COVID-19 vaccines (e.g., ChAdOx1 nCoV-19®, mRNA-1273®, BNT162b2®), the number of infections and fatalities continue to rise at an alarming rate because of the new variants such as Omicron and its subvariants. Including COVID-19 vaccines that are licensed for human use, most of the vaccines that are currently in clinical trials are administered via parenteral route. However, it has been proven that the parenteral vaccines do not induce localized immunity in the upper respiratory mucosal surface, and administration of the currently approved vaccines does not necessarily lead to sterilizing immunity. This further supports the necessity of a mucosal vaccine that blocks the main entrance route of COVID-19: nasal and oral mucosal surfaces. Understanding the mechanism of immune regulation of M cells and dendritic cells and targeting them can be another promising approach for the successful stimulation of the mucosal immune system. This paper reviews the basic mechanisms of the mucosal immunity elicited by mucosal vaccines and summarizes the practical aspects and challenges of nanotechnology-based vaccine platform development, as well as ligand hybrid nanoparticles as potentially effective target delivery agents for mucosal vaccines.
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Mesenchymal stromal cells (MSC) are widely investigated for treating ARDS in Covid-19. Nonetheless, these efforts are overshadowed by studies predating the pandemic that mostly failed to show MSC efficacy in ARDS and recent disappointments with repurposed MSC products. Relying on years of MSC-related experience, Bonus BioGroup developed MesenCure: An enhanced allogeneic MSC therapy for Covid-19, professionalized by a unique combination of culture conditions and optimized in ARDS-relevant models. MesenCure is currently evaluated in a Phase II study in severe Covid-19 patients and administered (IV) in three doses (1.5M cells/kg, d1, d3, d5). A Phase I/II study on ten severe patients demonstrated a significant improvement in ARDS-related parameters following MesenCure treatment. Patients were discharged within one day (median) following treatment, requiring no respiratory support. Speedy recovery from local inflammation was observed in these patients, demonstrated by a rapid reduction in diffuse lung pneumonia, from 55% of the lung area to 15% within 5-6 days from the first dose (p<0.01, Fig. A-C). A corresponding drop in CRP was detected (p<0.01), which returned to normal. A multivariate regression analysis revealed that the reduction in CRP was mainly associated with the number of doses administered and not and the time elapsed since the first dose. MesenCure efficacy may be attributable to the cells' de novo expression of the gene encoding for the IL-6 receptor, making them more responsive to inflammation than non-professionalized naïve MSC (NA-MSC);as well as >8-fold upregulation of the EDIL3 gene, encoding for an endogenous inhibitor of immune infiltration. A corresponding immunosuppressive effect of MesenCure MSCs was demonstrated in vitro, showing their ability to suppress T cells activation twice more effectively than NA-MSC. In this study, MesenCure inhibited the proliferation of primary CD4 T cells in a concentration-depended manner following non-specific activation. Over 98% inhibition was achieved in co-culture of 1:10 MSC-to-PBMC with an IC 50 of 6k MSC/200k PBMCs (r 2=1.00) compared to 12k NA-MSC/200k PBMCs (r 2=0.95). Comparable results were also obtained for CD8 T cells. Similarly, MesenCure inhibited ROS production by primary neutrophils remarkably fast and by up to 80% within less than 40 minutes following their activation (IC 50 = 19k MSC/200k neutrophils, r 2=1.00). In addition to local immunosuppressive outcomes, a significant increase in blood leukocytes was observed in patients treated with MesenCure (p<0.05, Fig. D-F). Further analysis suggested that the increase in total WBCs and neutrophils was associated with the number of MesenCure doses administered (p<0.05, Fig. G-H). In contrast, the increase in lymphocytes was time-dependent (R=0.72, Fig. I). The seemingly exclusively localized anti-inflammatory effects seen in severe patients treated with MesenCure were also observed in animal (murine) studies. An in vivo study in an acute lung injury model demonstrated a dose-dependent localized reduction in leukocyte counts in the lung fluids of animals treated with MesenCure (IV) using two dose levels. Relative to untreated animals, MesenCure reduced lung leukocyte counts by 35%-43% in animals treated with the low dose and by 62%-67% following high-dose MesenCure treatment (p<0.05). The leukocytes' clearance from the lungs was accompanied by a 41%-57% reduction in lung edema (p<0.05) following MesenCure treatment. Notably, NA-MSC did not achieve the same effect. Similar to our clinical findings, a significant increase was measured in neutrophil counts in animals treated with low-dose MesenCure (p<0.05), which decreased dramatically (p< 0.01) in animals treated with a four-times higher dose. MesenCure is administered at a much lower dose compared to other MSC products administered at up to 10M cells/kg. Considering the increase in blood leukocytes measured in patients treated with low-dose MesenCure and comparable preclinical findings, our data suggest that low-dose MesenCure could elicit a potent ocal anti-inflammatory effect without suppressing, and even enhancing, peripheral immunity that is needed to fight the virus. Further research is inevitably required into the mechanism behind this phenomenon. However, our results indicate MesenCure's potential in relieving local inflammation while giving the patient a fighting chance against viremia. [Formula presented] Disclosures: Bronshtein: Bonus BioGroup: Current Employment. Ben David: Bonus BioGroup: Current Employment. Novak: Bonus BioGroup: Current Employment. Kivity: Bonus BioGroup: Current Employment. Meretzki: Bonus BioGroup: Current Employment. Rozen: Bonus BioGroup: Consultancy.
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This study focused on intestinal restitution including phenotype switching of absorptive enterocytes and the abundance of different enterocyte subtypes in weaned pigs after porcine epidemic diarrhea virus (PEDV) infection. At 10 days post-PEDV-inoculation, the ratio of villus height to crypt depth in both jejunum and ileum had restored, and the PEDV antigen was not detectable. However, enterocytes at the villus tips revealed epithelial-mesenchymal transition (EMT) in the jejunum in which E-cadherin expression decreased while expression of N-cadherin, vimentin, and Snail increased. Additionally, there was reduced expression of actin in microvilli and Zonula occludens-1 (ZO-1) in tight junctions. Moreover, the protein concentration of transforming growth factor ß1 (TGFß1), which mediates EMT and cytoskeleton alteration, was increased. We also found a decreased number of Peyer's patch M cells in the ileum. These results reveal incomplete restitution of enterocytes in the jejunum and potentially impaired immune surveillance in the ileum after PEDV infection.