An insight into new glycotherapeutic in glial inflammation: Understanding the role of glycosylation from acute to chronic phase of inflammation

Glycosylation plays a critical role during inflammation and glial scar formation upon spinal cord injury (SCI) disease progression. Astrocytes and microglia are involved in this cascade to modulate the inflammation and tissue remodelling from acute to chronic phases. Therefore, understating the glycan changes in these glial cells is paramount. Herein a lectin microarray was undertaken using a cytokine-driven inflammatory MGC model, revealing considerable differential glycosylation from the acute to the chronic phase in a cytokine-combination generated inflamed MGC model. It was found that several N- and O-linked glycans associated with glia during SCI were differentially regulated. Pearson's correlation hierarchical clustering showed that groups were separated into several clusters, illustrating the heterogenicity among the control, cytokine combination, and LPS treated groups and the day on which treatment was given. Control and LPS treatments were observed to be in dense clusters. This was further confirmed with lectin immunostaining in which GalNAc, GlcNAc, mannose, fucose and sialic acid-binding residues were detected in astrocytes and microglia. However, this modification (upregulation of sialic acid expression) was inhibited by the sialyltransferase inhibitor which indeed modulates the mitochondrial functions. The present study is the first functional investigation of glycosylation modulation in a MGC (MGC) model which elucidates the role of the glycome in neuroinflammation and identified potential therapeutic targets for future glycol- therapeutics in neuroinflammation

Multicomponent plasmid protects mice from spontaneous autoimmune diabetes

Type 1 diabetes is an autoimmune disease in which insulin-secreting β-cells are destroyed, leading to a life-long dependency on exogenous insulin. There are no approved disease-modifying therapies available, and future immunotherapies would need to avoid generalized immune suppression. We developed a novel plasmid expressing preproinsulin2 and a combination of immune-modulatory cytokines (transforming growth factor-beta-1, interleukin [IL] 10 and IL-2) capable of near-complete prevention of autoimmune diabetes in non-obese diabetic mice. Efficacy depended on preproinsulin2, suggesting antigen-specific tolerization, and on the cytokine combination encoded. Diabetes suppression was achieved following either intramuscular or subcutaneous injections. Intramuscular plasmid treatment promoted increased peripheral levels of endogenous IL-10 and modulated myeloid cell types without inducing global immunosuppression. To prepare for first-in-human studies, the plasmid was modified to allow for selection without the use of antibiotic resistance; this modification had no impact on efficacy. This pre-clinical study demonstrates that this multi-component, plasmid-based antigen-specific immunotherapy holds potential for inducing self-tolerance in persons at risk of developing type 1 diabetes. Importantly, the study also informs on relevant cytokine and immune cell biomarkers that may facilitate clinical trials. This therapy is currently being tested for safety and tolerability in a phase 1 trial (ClinicalTrials.gov Identifier: NCT04279613).

Multicomponent plasmid protects mice from spontaneous autoimmune diabetes

Type 1 diabetes is an autoimmune disease in which insulin-secreting β-cells are destroyed, leading to a life-long dependency on exogenous insulin. There are no approved disease-modifying therapies available, and future immunotherapies would need to avoid generalized immune suppression. We developed a novel plasmid expressing preproinsulin2 and a combination of immune-modulatory cytokines (transforming growth factor-beta-1, interleukin [IL] 10 and IL-2) capable of near-complete prevention of autoimmune diabetes in non-obese diabetic mice. Efficacy depended on preproinsulin2, suggesting antigen-specific tolerization, and on the cytokine combination encoded. Diabetes suppression was achieved following either intramuscular or subcutaneous injections. Intramuscular plasmid treatment promoted increased peripheral levels of endogenous IL-10 and modulated myeloid cell types without inducing global immunosuppression. To prepare for first-in-human studies, the plasmid was modified to allow for selection without the use of antibiotic resistance; this modification had no impact on efficacy. This pre-clinical study demonstrates that this multi-component, plasmid-based antigen-specific immunotherapy holds potential for inducing self-tolerance in persons at risk of developing type 1 diabetes. Importantly, the study also informs on relevant cytokine and immune cell biomarkers that may facilitate clinical trials. This therapy is currently being tested for safety and tolerability in a phase 1 trial (ClinicalTrials.gov Identifier: NCT04279613).

542 Expansion of cytotoxic NK Cells from PBMCs using individualized cytokine combination

BackgroundAdoptive immunotherapy relies on the use of T-cells to target tumour cells, through Major Histocompatibility Complex (MHC) Class I recognition(1). However, many tumours display alterations in the MHC-I pathway, a well-described immune evasion mechanism(2). Natural Killer (NK) cells recognize transformed cells independently from the presence of MHC-I and may be a reliable therapeutic option for patients with altered tumour MHC-I expression. The source of NK cells may be autologous or allogeneic and NK cells are also clinically relevant recipients of transgenic receptors (TCRs or antibodies) targeting tumour cells. NK cells have been categorized according to their CD56 and CD16 surface expression into different subpopulations: cytotoxic (CD56+CD16+) and regulatory (CD56brightCD16-)(3). Expanding cytotoxic NK cells is challenging, since the frequency of NK cells is low in peripheral blood(4) and there is also – at this point – not an optimal expansion protocol available.The goal of this project is to determine the best cytokine combination that facilitates expansion of cytotoxic NK cells that either target tumor cells directly or serve as recipients for transgenic receptors.MethodsPeripheral Blood Mononuclear Cells (PBMCs) were extracted using Ficoll methodology from blood donors and cultured in T25 flasks with Cell Genix Medium supplemented with 10% human serum and antibiotics. NK cells were expanded supplemented with feeder cells (ratio 1:1) and different cytokine combinations (1000 U/mL of IL-2, 10 U/ml of IL-12, 180 U/mL of IL-15 and/or 1 U/mL of IL-21) during 20 days. The immunophenotype of expanded NK cells was analyzed at days 0, 5, 10, 15 and 20 by flow cytometry. The cytotoxicity of NK cells was measured by a CD107a Assay or by a Total Cytotoxicity and Apoptosis Assay at days 10 and 20. Thirteen different cytokine combinations were tested.Results4/13 cytokine combinations produced a statistically significant increase of the absolute number of NK cells with a higher percentage of cytotoxic NK cells (figure 1). However, induction of cytotoxicity was not associated with a strong NK cell expansion. The regulatory NK cells subset (CD56brightCD16-) showed the highest percentage of CD107a-expressing cells, more than the CD56+CD16+, the most cytotoxic subpopulation of NK cells.Abstract 542 Figure 1Representative percentage of NK cells in total lymphocytes (A), CD56+CD16+ subpopulation in total NK cells (B), and CD56brightCD16- subpopulation amongst total NK cells (C) at different time points (5, 10, 15 and 20 days) expanded from PBMCs* p-value < 0.05ConclusionsThis work shows that we are able to grow and efficiently expand NK cells from PBMCs with different cytokine combinations leading to clinically relevant NK cell numbers as well as cytotoxic functions. This enables to produce NK cell products for therapy and as recipients for transgenic tumor antigen-specific receptors.AcknowledgementsThe authors would like to thank the Champalimaud Foundation Biobank, the Vivarium Facility and the Flow Cytometry Platform of the Champalimaud Centre for the Unknown.Ethics ApprovalThis study was approved by the Champalimaud Foundation Ethics Committee and by the Ethics Research Committee of NOVA Medical School of NOVA University of Lisbon.ConsentWritten informed consent was obtained from the blood donors to use their samples for research purposes.ReferencesRosenberg SA, Restifo NP, Yang JC, Morgan RA, Mark E. Adoptive cell transfer: a clinical path to effective cancer immunotherapy. Nat Rev Cancer 2008;8(4):299–308.Aptsiauri N, Ruiz-Cabello F, Garrido F. The transition from HLA-I positive to HLA-I negative primary tumors: the road to escape from T-cell responses. Curr Opin Immunol 2018;51:123–32.Di Vito C, Mikulak J, Mavilio D. On the way to become a natural killer cell. Front Immunol. 2019;10(August):1–15.Zotto G Del, Antonini F, Pesce S, Moretta F, Moretta L. Comprehensive phenotyping of human PB NK Cells by Flow Cytometry. 2020;1–9.

Increasing TCR Zeta Expression and Maintaining the Clonality of T Cells from AML Patients after IL-2, IL-7 and IL-12 Induction

T-cell immunodeficiency is a common feature in patients with leukemia, lower activation of T cells was one of reasons. The TCR zeta chain has emerged as a key subunit of the T-cell antigen receptor, which plays a central role in the signal-transducing events leading to T cell activation. The proliferation and activation of T cells may be inducted by T cell related cytokines. In this study, we explored the change of TCR zeta gene expression and the clonality of T cells after induction with different immune cytokines, including IL-2, IL-7 or IL-12. CD3+ T cells sorted from peripheral blood of 4 cases with AML were induced with different immune cytokines, including IL-2, IL-7, IL-12, anti-CD3 and anti-CD28 antibodies in vitro. The expression levels of TCR zeta gene and related genes in T cells before and after induction were then analyzed by fluorescence quantitative RT-PCR. The distribution and clonality of TCR Vβ subfamily T cells were analyzed by RT-PCR and Genescan techniques. Increasing expression levels of TCR zeta gene and zap-70 (TCR zeta chain associated-protein) gene in CD3+T cells from AML patients were found after induction with single stimulating factor or the combination with different cytokines, while the expression of FcεRIγ (TCR ζ gene complementary factor) was down-regulated. We further compared the T cell clonality in CD3+T cells from AML patients after cytokine induction, eight to 22 TCR V β subfamilies could be detected in T cells from AML cases, most of them displayed polyclonal expansion. The number of expressed TCR Vβ subfamilies was increased without the change of clonality in T cells induced by CD3+CD28+IL7. In conclusion, TCR zeta gene and its related genes could be upregulated through induction with different cytokine combination such as IL-2, IL-7 and IL-12, therefore to improve the T cell activation in patients with AML. And the main effect of cytokines might to maintain the T cell clonality and nonspecific amplification of T cell clones. Further investigation can be designed to amplify the specific anti-AML TCR Vβ clones using AML associated antigens and such cytokine combination. Disclosures Shi: National Natural Science Foundation of China (no. 81100353, 81270604), the Fundamental Research Funds for the Central Universities (No. 21611447, 21612116), And Medical Science Foundation of Guangdong Province(A2011325). : Research Funding.