Transcript ADJUVANTS
Alum adjuvants : discovering their hidden secrets Ana Carolina Pagliarone Everton dos Santos Giuliano Bonfá Non-living antigens vaccines (purified or recombinant subunits) Advantage : safety (no possibility of disease development) Adjuvants enhance the strength and duration of Disadvantage: immunogenicity immunepoor responses and modulates the type of immune response to the vaccine antigen ADJUVANTS !!!! Adjuvant : additional vaccines component that enhances the immune response to antigens in vivo . Vaccine antigen Adjuvant amplification of immune cells signals Immune response A B Signal 0 : antigen recognition by DC leads to cell activation and maturation Signal 1 : DC presents antigen peptides through MHC class II molecule to the TCR of naive CD4+T cell Signal 2: DC expresses high levels of MHC, co-stimulatory (CD40, CD80 and CD86) and adhesion molecules (CD54 and CD58). C CD4+ T cell differentiation Signal 3 : DC secretes high amounts of cytokines that are crucial for inflammation and differentiation of CD4+ T cells. (modified) ADJUVANTS DELIVERY SYSTEMS -“Antigen vehicles” -Carriers to which antigens are associated by way of adsorption,co-precipitation or encapsulation. -Immunogenicity : - antigen retention at site of injection (antigen depot effect); - increase of uptake by DC cells and macrophages (slow release of antigen) IMMUNOMODULATORS -Tipically small molecules with adjuvant funtions through other mechanisms than antigen retention; -Immununogenecity: Direct stimulation of innate immune cells through interaction with PRRs TLRs,NLRs, RLRs and C-type lectins. * * More used in human vaccines Adjuvant action of aluminium salts Adjuvant mechanism of aluminium salts : antigen precipitaded onto insoluble particles of these salts are released slowly in the body (“depot effect”-Alexander Glenny, 1926). HOWEVER ..... Studies have shown that the adjuvant activity of aluminium is more complex than this..... Human macrophages pre-immunized with toxoid tetanus + aluminium hydroxide and further co-cultured with autologous T cells Increased IL-1 production and T cell proliferation Aluminium can activate antigen-specific immune response by activating APCs! How aluminium salts can stimulate APCs and adaptive immune responses ? - In culture of lymph node cells from mice immunized with alum it was observed increased IL-1 and IL-4 production and proliferation of T cells. Treatment with anti-IL-4 decreased the proliferation (GRUN & MAURER, 1989) -Immunization with alum in mice enhaced only Th2 antibodies (IgG1 and IgE). However, IL-4-/- mice presented induced IgG2a and Th1 cytokines production (BREWER et al.,1996) Aluminium hydroxide induced chemokines secretion ( CCL2/3 and 4 and CXCL-8) and inhibited CD14 expression in human monocytes and enhances MHC II and CD86 expression in DCs (monocyte activation, recruitment to blood and differentiation toward DCs.) (SEUBERT et al., 2008). DCs activation by aluminium salts occurs through specific receptors??????? MyD88-deficient mice immunized with antigen and aluminum salts produced IgG1 and specially more IgE, comparing to control mice. Deficient micefor both MyD88 and TRIF immmunized with alum + TNP-Hy showed Th2-induced IgG1 and IgE responses comparable to those observed in control mice. According to these observations, aluminium salts are both delivery systems and immunomodulators adjuvants, although their activities do not occur through TLRs.... IMMUNOMODULATORS - Are tipically small molecules that exert their adjuvant funtions through mechanisms other than antigen retention Direct stimulation of innate immune cells (monocytes, macrophages, NK and NKT cells and DCs) specially through interaction with PRRs of these cells (TLRs, NLRs, RLRs and C-type lectins PAMPs However, its known that there are ENDOGENOUS compounds which are also able to be recognized by host cells, inducing the immune response even in absence of pathogens. DAMPs Damage Associated Molecular Patterns DAMPs = substances/compounds released by necrotic cells which are recognized by innate immune cells (tissue injury indicators). They activate innate immune cells according to the Danger Hypothesis. Are DAMPs endogeous adjuvants ? Dead cells co-administered with antigen induced increased antigen-specific CD4+ T cells in vivo. Moreover, dead cells could lead to DCs maturation in vitro. Uric acid stimulates DC maturation in vitro and stimulates CD8+ T cell response in antigen- immunized mice How DAMPs are recognized by DCs ? Recognition of endogenous DAMPs by TLRs There are studies that defend the idea of TLR ligands contamination (such as LPS) in studied DAMPs, others showed that TLR knockout mice presented reduction in inflammatory response to necrotic cell death in vivo (CHEN & NUÑEZ, 2010). MSU: monosodium urate Human monocytes MRU-induced peritonitis in mice Human monocytes Mechanisms for DAMPs –induced inflammation cell recruitment DAMPs and PAMPs are recognized by innate immune cells leading to further adaptive cells activation (adjuvant activity!!). Aluminium adjuvants can indirectly activate APCs by causing tissue damage due to necrosis of skeletal muscle fibers (SHY et al., 2003) Uric acid is able to induce NLRP3 (MARTINON et al., 2006) Aluminium adjuvants can activate the inflammasome NALP 3? Mice submited to OVA or OVA+alum injections i.p. Nalp 3or ASC 3 or Casp 3 deficient mice injected i.p with OVA Possible mechanisms of alum action Indirect activation ex: TLRs Direct activation Everton dos Santos Giuliano Bonfá Show that silica crystal and aluminum induces activation of MAPK beyond of NALP3 Everton dos Santos Could silica and alum induce inflamossome activation of macrophages? Primed with LPS Macrophages (5x105/mL) (1ng/mL)/3h Stimulation for 2h ELISA (IL-1β) (culture Supernatants) Macrophages - Silica ( 50 -100µg/mL) ; (5x105/mL) - Aluminium (200-400µg/mL); - ATP (1mM). Silica, alum and ATP induced inflamossome activity on LPS-primed macrophages Besides of IL-1B production, could macrophages produce others inflammatory factors? Primed with LPS Macrophages (5x105/mL) (1ng/mL)/3h Stimulation for 2h Macrophages - Silica ( 50 -100µg/mL) ; (5x105/mL) - Aluminium (200-400µg/mL); ELISA (PGE2, TNF-α, IL-1β, 6, 12, 18) (culture Supernatants) - ATP (1mM). These results showed that in addition to IL-1β and IL-18, macrophages also produce PGE2 in response to silica, alum and ATP. Can DCs produce IL-1β and PGE2 in response stimulation for silica or alum? GM-CSF (10ng/mL) DCs (5x105/mL) Stimulation for 6h ELISA (PGE2,IL-1β) - Silica (100µg/mL) ; (culture Supernatants) (1ng/mL)/3h BM cells M-CSF (10ng/mL) Primed with LPS DC cells (5x105/mL) - Aluminium (400µg/mL); Macrophages (5x105/mL) Macrophages (5x105/mL) DCs can produce IL-1β and PGE2, but macrophages produce higher amounts of PGE2 than DCs *B6/Balb; PBMC In short... Aluminium, Silica Macrophages MB; Peritoneal DC MB; Activity inflammasome; Production of IL-β Prostaglandin E2 Does is necessary the phagocytosis for production of IL-1β and prostaglandin? Could the engulfment of particulates, lysosomal rupture, and release of lysosomal enzymes induce PGE2 and IL-1β production in macrophages? Primed with LPS Macrophages (5x105/mL) (1ng/mL)/3h ELISA (PGE2, IL-1β) Stimulation for 2h - Silica (100µg/mL) ; Macrophages (5x105/mL) - Alum (400µg/mL); - Cyt D (2μM or Cat B (10μM) (culture Supernatants) Phagocytosis, lysosomal damage and release of enzymes triggers PGE2 production in macrophages. In short... Phagocytosis Aluminium, Silica Macrophages lysosomal rupture release of lysosomal enzymes prostaglandin E2 and IL-1β production Does prostaglandin production is dependent of inflammasome? The production of PGE2 is dependent of activity of inflammasome? Primed with LPS Macrophages (5x105/mL) (1ng/mL)/3h Stimulation for 2h - Silica (100µg/mL) ; Macrophages (5x105/mL) - TiO2 (100µg/mL); ELISA (PGE2, IL-1β) (culture Supernatants) The production of PGE2 is dependent of activity of inflammasome? Primed with LPS M-CSF (10ng/mL) WT; Nalp3, Asc, Casp1 (-/-) (1ng/mL)/3h BM cells ELISA (PGE2) Stimulation for 6h Macrophages (5x105/mL) - Silica (50μg/mL) - -Alum (200μg/mL) (culture Supernatants) Aluminium, Silica Macrophages MB; Peritoneal PGE2 production in macrophages is independent of inflammasome Activity inflammasome; Production of IL-β Prostaglandin E2 In short... Phagocytosis Aluminium, Silica Macrophages lysosomal rupture release of lysosomal enzymes prostaglandin E2 and IL-1β production The PGE2 production was independent of inflammasome activity. Prostaglandin E2 (PGE2) is generated by the sequential metabolism of arachidonic acid by cyclo-oxygenase and prostaglandin E synthase (Needleman et al., 1986; Smith. 1992). Could alum and silica induce the activity of cyclooxygenase (COX) and synthase PGE? Could silica and alum induce activity of COX or PGE synthase enzymes? Primed with LPS WT PTGES (+/+; Macrophages (5x105/mL) (1ng/mL)/3h Stimulation for 2h - Silica (100µg/mL) ; Macrophages (5x105/mL) ELISA (PGE2, IL-1β) (culture Supernatants) - COX-2 inhibitor (1µM); -/-) Silica- and alum-induce PGE2 production in macrophages mediated by the COX-2 and PTGES. In short... Phagocytosis Aluminium, Silica Macrophages lysosomal rupture release of lysosomal enzymes COX-2 and PTGES Activation of the inflammasome Prostaglandin E2 production IL-1β production Which signaling pathway is involved in this process? Which signaling pathway is involved in the production of PGE2? Primed with LPS Macrophages (5x105/mL) (1ng/mL)/3h ELISA (PGE2, IL-1β) Stimulation for 2h - Silica (100µg/mL) ; Macrophages (5x105/mL) - (culture Supernatants) Absence of inhibitors were used as the 100% controls Inhibitors These results showed that P38 MAP kinase is involved with in the PGE2 production and rupture necessary is activation. the lysosomal for your In short... Phagocytosis Aluminium, Silica lysosomal rupture Macrophages release of lysosomal enzymes Phospholipase A2??? P38 MAPK phosphorilation COX-2 and PTGES Prostaglandin E2 production Activation of the inflammasome IL-1β production Phosphorylation of p38 MAPK could activate phospholipase A2 after phagocytosis of silica or aluminium by macrophages? Primed with LPS Macrophages (5x105/mL) (1ng/mL)/3h Stimulation for 2h - Silica (100µg/mL) ; Macrophages (5x105/mL) - Inhibitors ELISA (PGE2, IL-1β) (culture Supernatants) Absence of inhibitors were used as the 100% controls Phosphorylation of p38 MAPK active phospholipase A2 The Syk can be activated by phagocytosis de silica or aluminum?? The Syk can be activated by phagocytosis de silica or aluminum? Primed with LPS Macrophages (5x105/mL) (1ng/mL)/3h Stimulation for 2h - Silica (100µg/mL) ; Macrophages (5x105/mL) - ELISA (PGE2, IL-1β) or blot Inhibitors These results suggest that lysosomal damage triggers Syk activation, and then activated Syk upregulates cPLA2 activity via the phosphorylation of p38 MAP kinase. Phagocytosis In short... lysosomal rupture Aluminium, Silica Macrophages release of lysosomal enzymes Syk P38 MAPK phosphorilation Phospholipase A2 COX-2 and PTGES Prostaglandin E2 production Activation of the inflammasome IL-1β production - PGE2 inhibits production of cytokines such as TNF-α, and IL-12 (Scales et al., 1989; Van der Pouw Kraan et al., 1995). - PGE2 may polarize cellular response toward a Th2 phenotype enhancing IL-4 and IL-5 production (Betz Prostaglandin synthases and Fox, 1991; Katamura et al., 1995) and facilitating immunoglobulin class switching to IgE (Roper et al., 1995). - PGE2 modulates the functions of cell populations, such as T cells and macrophages (Nataraj et al., 2001). Silica- and Alum-Induced Production of PGE2 by Macrophages Regulates Immune Responses In Vivo? Silica- and Alum-Induced Production of PGE2 by Macrophages Regulates Immune Responses In Vivo? OVA+Alum or OVA+Silica 0 7 17 Sera collected Days Ptges +/+ or Ptges ELISA IgG1, IgG2c, IgE -/- PGE2 production but not inflammasome activation in macrophages, positively regulates the generation of IgE antibodies in vivo. Phagocytosis Conclusion lysosomal rupture Aluminium, Silica Macrophages release of lysosomal enzymes Syk P38 MAPK phosphorilation Activation of the inflammasome IL-1β production Phospholipase A2 A.A COX-2 PTGES Prostaglandin E2 production IgE Aim: To identify the citotoxic and adjuvant effect of alum on immune responses Is alum cytotoxic on local of injection? i.m. and i.p. OVA + Alum days 0, 14 and 21 Peritoneal lavage fluid Muscle lavage fluid Cell death rate i.p. Alum induce cell death and release of host DNA at sites of injection! Can DNA act as an adjuvant? i.p. OVA OVA + Alum OVA + DNA i.p. ELISA days 0, 14 and 21 OVA OVA + Alum days 0 and 10 DNase I (3 and 8h) ELISA Can DNA act as an adjuvant? OVA-specific CD4+ CFSE i.p. OT-II OVA OVA + Alum OVA + DNA DNase I (3 and 8h) 3d Cells on the bronchial lymph nodes (BLNs) WT Host DNA released by alum cytotoxicity mediates alum activity on humoral and TH2 cell responses! What’s the mechanism? • TLR9-/- mice develop humoral responses similar to those of their WT counterpart in response to alum immunization; NALP3-/- and CASP1-/-? Nature Reviews Immunology 10, 123-130 (February 2010) | doi:10.1038/nri2690 What’s the mechanism? i.p. OVA OVA + Alum OVA + DNA days 0, 14 and 21 i.p. ELISA Peritoneal lavage fluid NALP3 independent OVA OVA + Alum OVA + DNA ELISA (serum) days 0, 14 and 21 WT and IRF3-/- What’s the mechanism? i.p. OVA OVA + Alum ELISA (serum) days 0, 14 and 21 TBK1+/-/TNF-/and TBK1-/-/TNF-/- Alum and host genomic DNA trigger type I IFN secretion and IgE responses through activation of the TBK1-IRF3 axis! Have IRF3 deficiency an effect on Th2 responses after alum imunization? OVA-specific CD4+ CFSE i.p. OT-II OVA OVA + Alum OVA + DNA 3d Cells on the bronchial lymph nodes (BLNs) WT and IRF3-/- IRF3 is essential for the boosting of canonical TH2 cells by alum and genomic DNA! There is an effect during experimental asthma? i.p. OVA OVA + Alum days 0 and 14 WT and Bronchoalveolar lavage fluid (BALF) IRF3-/Airway sensitization d 21 to 25 IRF3 absence protect mice from allergic airway inflammation! IRF3 deficiency changes DCs migration? i.p. OVA OVA + Alum OVA + DNA 24 - 48 h WT and IRF3-/- FACs (peritoneal lavage fluid and BLNs) • iMonos (F4/80int CD11b+ Ly6C+ Ly6G- cells) • cDCs (MHCII+ CD11c+ F4/80low Ly6C- cells) • pDCs (B220+ Ly6G+ CD11cint F4/80low cells) BLNs The recruitment of iDCs to the BLNs of alum-treated mice strongly correlated with the percentage of cell death and DNA release and that it was reduced after Dnase I treatment. IRF3 is essential for the triggering of iDC recruitment by alum! Deficiency on DCs recruitment alter the Th2 response? OVA-specific CD4+ i.p. CFSE OT-II OVA OVA + Alum Cells on the bronchial lymph nodes (BLNs) WT and IRF3-/WT immunized iMonos IgE increase IgG1 not affected Deficient migration of inflammatory monocites (iMonos) impair alum-induced Th2 and IgE responses in IRF3-/- mice! IRF3 deficiency changes iDCs activation? i.p. OVA OVA + Alum FACs and ELISA (peritoneal lavage fluid and serum) days 0, 14 and 21 WT and IRF3-/- iMonos (F4/80int CD11b+ Ly6C+ Ly6G- cells) BLNs IgE attenuated IgG1 not affected Alum-induced iMono migration depends on IL-12p40 homodimer signaling! Conclusion DAMP DAMP Journal Conclusion Alum NALP3 Independent NALP3 Dependent PGE2 Dependent Host DNA (DAMP) Uric acid crystals (IRF3-TBK1 axis) Syk and p38 MAP kinase Th2 responses – IgE and IgG1