Induction of protective immunity against Eimeria tenella, Eimeria maxima, and Eimeria acervulina infections using dendritic cell-derived exosomes

Recent progress in host immunity to avian coccidiosis: IL-17 family cytokines as sentinels of the intestinal mucosa

The molecular and cellular mechanisms leading to immune protection against coccidiosis are complex and include multiple aspects of innate and adaptive immunities. Innate immunity is mediated by various subpopulations of immune cells that recognize pathogen associated molecular patterns (PAMPs) through their pattern recognition receptors (PRRs) leading to the secretion of soluble factors with diverse functions. Adaptive immunity, which is important in conferring protection against subsequent reinfections, involves subtypes of T and B lymphocytes that mediate antigen-specific immune responses. Recently, global gene expression microarray analysis has been used in an attempt to dissect this complex network of immune cells and molecules during avian coccidiosis. These new studies emphasized the uniqueness of the innate immune response to Eimeria infection, and directly led to the discovery of previously uncharacterized host genes and proteins whose expression levels were modulated following parasite infection. Among these is the IL-17 family of cytokines. This review highlights recent progress in IL-17 research in the context of host immunity to avian coccidiosis.

Eimeria maxima: efficacy of recombinant Mycobacterium bovis BCG expressing apical membrane antigen1 against homologous infection

Coccidiosis is one of the most important protozoan diseases and inflicts severe economic losses on the poultry industry. The aim of this study was to evaluate the capacity of Bacillus Calmette-Guerin (BCG) to deliver apical membrane antigen1 (AMA1) of Eimeria maxima to stimulate specific cellular and humoral immune responses in chickens. Day-old birds were immunized twice with rBCG/pMV261-AMA1, rBCG/pMV361-AMA1, or BCG via oral, intranasal, and subcutaneous routes and then orally challenged with homologous E. maxima sporulated oocysts. Gain of body weight, fecal oocyst output, lesion scores, serum antibody responses, numbers of splenocyte CD4(+) and CD8(+) T cells, and gut cytokine transcript levels were assessed as measures of protective immunity. Challenge experiments demonstrated that rBCG vaccination via intranasal or subcutaneous routes could increase weight gain, decrease intestinal lesions, and reduce fecal oocyst shedding, and the subcutaneous and intranasal routes were superior to the oral route based on the immune effects. Furthermore, intranasal rBCG immunization could also lead to a significant increase in serum antibody, the percentage of CD4+ and CD8+ T lymphocyte cells, and the levels of IL-1β, IFN-γ, IL-15, and IL-10 mRNAs compared with the control group. These results suggested that intranasal rBCG immunization could induce a strong humoral and cellular response directed against homologous E. maxima infection. This study provides data for the use of rBCG to develop a prophylactic vaccine against coccidiosis.

Tetraspanin-3 regulates protective immunity against Eimeria tenella infection following immunization with dendritic cell-derived exosomes

The effects of immunization with dendritic cell (DC) exosomes, which had been incubated with a tetraspanin-3 (Tspan-3) blocking antibody (Ab) or with an isotype-matched non-immune IgG, were studied using an experimental model of Eimeria tenella avian coccidiosis. Purified exosomes from cecal tonsil and splenic DCs expressed Tspan-3 protein. Chickens injected with exosomes incubated with the control IgG and derived from cecal tonsil DCs preloaded in vitro with E. tenella Ag had Ag-immunostaining cells in the ceca, but not the spleen. Conversely, Ag-containing cells were found only in the spleen, but not the ceca, of chickens given IgG treated splenic DC exosomes. Interestingly, chickens that received exosomes incubated with Tspan-3 Ab had Ag-containing cells observed in both lymphoid organs following administration of exosomes from either DC population. After injection of exosomes non-incubated with Tspan-3 Ab, greater numbers of cells secreting interleukin-2 (IL-2), IL-16, interferon-γ, and E. tenella-reactive Abs were observed in the cecal tonsils of chickens immunized with cecal DC exosomes compared with the spleen. By contrast, more cytokine-and Ab-producing cells were present in the spleen of chickens given splenic DC exosomes compared with the ceca. Incubation with Tspan-3 Ab gave similar numbers of cytokine- and Ab-producing cells in the cecal tonsils and spleen regardless of the source of exosomes. Immunization with E. tenella Ag-loaded cecal tonsil DC exosomes increased in vivo resistance against subsequent E. tenella infection. Increased protection against infection following cecal DC exosome immunization was partially blocked by incubation of exosomes with Tspan-3 Ab. These results suggest that Tspan-3 is involved in the tissue distribution, as well as cytokine and Ab production, following DC exosome administration, and that Tspan-3 contributes to in vivo protection against experimental E. tenella challenge infection following exosomal immunization.

A novel combined adjuvant strongly enhances mucosal and systemic immunity to low pathogenic avian influenza after oral immunization in ducks

As natural reservoirs of avian influenza viruses, waterfowl play an important role in the generation, spread, and enzootic transmission of avian influenza. To prevent avian influenza in waterfowl through a simple, noninvasive, and needle-free route, ducks were immunized orally with an inactivated avian influenza virus (H9N2, IAIV) combined with CpG DNA and high-dose glucose, and then the local and systemic immune responses of these ducks were investigated. In addition, the immune protection was assayed after viral challenge. After the oral administration of IAIV combined with CpG DNA and glucose, the expression levels of interleukin-2 and interleukin-6 in the small intestine tissues increased significantly in the early period after booster immunization relative to the levels after immunization with IAIV and a single adjuvant. Significant increases were also observed in the IgA and IgG antibody levels in the local intestinal tract tissues and serum at wk 3, 5, and 7 after the first immunization. Furthermore, enhanced hemagglutination inhibition titers were also detected in serum samples taken between the third and seventh weeks after immunization with IAIV and both adjuvants. In the viral challenge and transmission study, the prior administration of IAIV combined with both CpG DNA and glucose reduced the viral titers observed for the cloaca swabs and colon tissues of challenged ducks and prevented virus transmission between ducks. Our study suggests that the combination of CpG DNA and high-dose glucose can improve immunization with inactivated H9N2 virus by enhancing the local and systemic immune responses and reducing viral shedding.

Immature dendritic cell-derived exosomes: a promise subcellular vaccine for autoimmunity

Exosomes, 60-90-nm-sized vesicles, are produced by a large number of cell types, including tumor cells, neurons, astrocytes, hemocytes, intestinal epithelial cells, and so on. Dendritic cell (DC), the most potent professional antigen-presenting cell in the immune system, produces exosomes in the course of maturation. Mature DCs produce exosomes with the ability to elicit potent immunoactivation, resulting in tumor eradication and bacterial or virus elimination. Given the notion that exosomes are stable and easy to be modified artificially, autologous mature DC-derived exosomes have been vaccinated into patients with malignant diseases. In clinical trials utilizing exosomes as therapeutic approaches, researchers observed considerable curative effect with little side effect. However, immature or suppressive DC-derived exosomes harbor anti-inflammatory properties distinct from mature DC-derived exosomes. In murine models of autoimmune disease and transplantation, immature DC-derived exosomes reduced T cell-dependent immunoactivation, relieved clinical manifestation of autoimmune disease, and prolonged survival time of transplantation. Although the exact mechanism of how immature DC-derived exosomes function in vivo is still unclear, and there are no clinical trials regarding application of exosome vaccine into patients with autoimmune disease, we will analyze the promise of immature DC-derived exosomes as a subcellular vaccine in autoimmunity in this review.

The cardiovascular exosome: current perspectives and potential

The exosome is a secreted microvesicle that has been shown to contain genetic material and proteins and is involved in multiple levels of cellular communication. The cardiovascular exosome proteome is a promising subproteome that warrants investigation since a detailed understanding of its role in the heart should improve our comprehension of intercellular communication in the heart, and may even assist in biomarker discovery. Indeed, uncovering the role of the exosome in cardiovascular physiology could be accomplished with the application of scientific approaches and insights gained from studies of exosomes in other fields, such as cancer biology and immunology, where much of the established knowledge of the exosome has been generated. In the present review, we discuss the relevant literature and examine areas of investigation that would bring the cardiovascular exosome to the forefront of intercellular communication in the heart.