Kohtaro Fujihashi

Alternate Mucosal Immune System: Organized Peyer’s Patches Are Not Required for IgA Responses in the Gastrointestinal Tract

The progeny of mice treated with lymphotoxin (LT)-β receptor (LTβR) and Ig (LTβR-Ig) lack Peyer’s patches but not mesenteric lymph nodes (MLN). In this study, we used this approach to determine the importance of Peyer’s patches for induction of mucosal IgA Ab responses in the murine gastrointestinal tract. Immunohistochemical analysis revealed that LTβR-Ig-treated, Peyer’s patch null (PP null) mice possessed significant numbers of IgA-positive (IgA+) plasma cells in the intestinal lamina propria. Further, oral immunization of PP null mice with OVA plus cholera toxin as mucosal adjuvant resulted in Ag-specific mucosal IgA and serum IgG Ab responses. OVA-specific CD4+ T cells of the Th2 type were induced in MLN and spleen of PP null mice. In contrast, when TNF and LT-α double knockout (TNF/LT-α−/−) mice, which lack both Peyer’s patches and MLN, were orally immunized with OVA plus cholera toxin, neither mucosal IgA nor serum IgG anti-OVA Abs were induced. On the other hand, LTβR-Ig- and TNF receptor 55-Ig-treated normal adult mice elicited OVA- and cholera toxin B subunit-specific mucosal IgA responses, indicating that both LT-αβ and TNF/LT-α pathways do not contribute for class switching for IgA Ab responses. These results show that the MLN plays a more important role than had been appreciated until now for the induction of both mucosal and systemic Ab responses after oral immunization. Further, organized Peyer’s patches are not a strict requirement for induction of mucosal IgA Ab responses in the gastrointestinal tract.

Therapeutic manipulation of the immune system: enhancement of innate and adaptive mucosal immunity.

The mucosal immune system has evolved alongside, but separate, from the general systemic immune system. As a major consequence of this dichotomy, only immune responses initiated in mucosal inductive sites can result in effective immunity in mucosal tissues themselves. Oral tolerance, as usually assessed as orally-induced systemic unresponsiveness, contributes to mucosal homoeostasis by preventing unwanted immune reactions to food or environmental antigens. It is now established that tolerance can also be induced by the nasal route and mucosally-induced tolerance is being actively investigated for immune therapy against a number of diseases. Nontoxic derivatives of cholera toxin and the heat labile toxin of Escherichia coli as well as chimeric enterotoxins have been developed. These molecules retain the mucosal adjuvant activity of native enterotoxins and are effective at inducing targeted Th1 or Th2- type immune responses. Mucosal delivery of cytokines as adjuvants represents a safer alternative to parenteral cytokine injection. Nasally administered cytokines such as IL-1 and IL-12 or chemokines including RANTES, lymphotactin, MIP-1 beta, all act as mucosal adjuvants for co-administered antigens. Each of these cytokines promote specific pattern of CD4(+) T helper cell cytokine responses that could be exploited for targeted immune therapy. Although GALT and NALT are both parts of the Common Mucosal Immune System, there are major differences between orally and nasally induced immune responses. Nasal vaccines more effectively promote protective immunity in the genitourinary tract than do oral vaccines. In addition, aging affects mucosal tolerance or immunity in GALT more than is seen in NALT. Therapeutic manipulation of mucosal immunity involves regulation of CD4(+) T cell cytokine responses and thus, should require a careful examination of the host status, including the occurrence of inflammatory bowel diseases.

19 – Host defenses at mucosal surfaces

Abstract The inner body or systemic compartment of mammals is maintained sterile and free of microbes, foreign antigens, and altered or dead cells through the action of mucosal epithelia as well as that of immune cells present in the bloodstream. Mammals have large surfaces that are in constant contact with the outside world, which allows basic functions (e.g., uptake of air and food, reproduction, and vision) to occur. To accommodate these functions, mucosal surfaces have evolved unique and sophisticated immune mechanisms of defense capable of recognizing and tolerating beneficial exogenous toxins and pathogens while reacting against and removing potentially harmful products and microbes. It is increasingly recognized that commensal microbes play a central role in the development and regulation of mucosal immunity and that these lines of defense are particularly affected by aging. A better understanding of the regulation of mucosal immune cells and molecules and the connectivity between different mucosal sites will guide the development of future vaccines against pathogens causing infectious diseases.