Lymphocyte subpopulations in high endothelial venules and lymphatic capillaries of bronchus-associated lymphoid tissue (BALT) in the rat

The subpopulations of lymphocytes and non-lymphoid cells in high endothelial venules (HEV) and in lymphatic capillaries surrounding lymphoid follicles in bronchus-associated lymphoid tissue (BALT) were examined by electron microscopy after preembedding the tissue and staining with an immunoperoxidase technique. The results were compared with those obtained in gut-associated lymphoid tissue (GALT) reported previously. Monoclonal mouse-anti-rat T cell, IgG, IgM, IgA, and Ia antisera were used. Plasma cells that were reactive to anti-IgG, anti-IgM, and anti-IgA were detected as cells in which the 3',3'-diaminobenzidine tetrahydroxychloride reaction product was localized in rough endoplasmic reticulum and perinuclear spaces but not on plasma membranes. These plasma cells did not occur in either lymphatic capillaries or HEV in BALT as they did in GALT. Cells with surface Ig (sIg cells), T-cell antigen (T cells), and Ia antigen (Ia cells) were present in BALT. T cells were located predominantly in the follicular area opposite the bronchial epithelium; IgM- and IgG-reactive cells were found in the follicular area adjacent to the bronchial epithelium; and IgA-positive cells were found in the lateral part of the area where the T cells were localized (T-cell area). Ia cells were abundant throughout BALT and in moderate numbers in the epithelium. A striking observation was the presence of "nurse-cell"-like structures in the periphery of BALT. The percentages of T, sIgG, sIgM, and sIgA cells in the HEV were 54.7%, 2.4%, 28.9%, and 27.3%, respectively, and in the lymphatic capillaries, 41.2%, 3.8%, 38.2%, and 21.2%, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Organ and isotype distribution of plasma cells producing specific antibody after oral immunization: evidence for a generalized secretory immune system.

Mice were induced to produce IgA antibodies against ferritin after oral immunization. Such antibodies were detected by immunofluorescence in plasma cells in the intestinal mucosa as well as in secretory sites located elsewhere, such as the lactating mammary gland, salivary gland, and respiratory tract. The observation suggested that cells immunized locally via the gut could home to distant secretory sites. To confirm this hypothesis, lymphocyte transfer studies were done with mesenteric node (MN) versus peripheral node (PN) cells from orally immunized donors into nonimmunized recipients. IgA anti-ferritin cells from MN homed to exocrine targets, whereas IgM and IgG anti-ferritin cells homed to PN. The findings overall support the concept of a generalized and interrelated secretory immune system.     

Differentiated implication of Lactobacillus GG and L. gasseri TMC0356 to immune responses of murine Peyer's patch

Lactobacillus GG and L. gasseri TMC0356 were examined for their potential to alter the immune responses of murine PP cells in vitro and in vivo. Lactobacillus GG and L. gasseri TMC0356 characteristically stimulated the production of IL-12, IL-6, IFN-γ and IgA from isolated PP cells in vitro . Anatomical analysis indicated uptake of these bacteria by the PP tissue after giving orally in mice. Isolated PP cells exposed to Lactobacillus GG in vivo secreted more IFN-γ, IL-6 and total IgA, whereas those exposed to L. gasseri TMC0356 in vivo did not exhibit altered immune responses in terms of cytokine and IgA production. Therefore, these two bacteria might exhibit different immunodulatory effects in host animals by strain-dependent interaction with gut-associated lymphoid tissues in vivo .     

Induction by cells of immune responses to intestinal epithelial cell-associated components (ECAC): transfer with cultured murine mesenteric and popliteal/axillary lymph node cells

Although systemic and mucosal immune responses to intestinal epithelial self-antigens occur in several human disorders, there is no model system with which to study the physiology and regulation of the underlying cellular events. Therefore, we undertook to induce an immune response to purified epithelial macromolecules in the Lewis rat; characterize in vitro the reactive cells; and then transfer with immunocytes this antiepithelial reactivity to naive syngeneic rats, identifying the fine specificity and site of humoral and cell-mediated immunity induced in the cell recipient. Donor animals sensitized systemically (via footpad) or locally in gut mucosa (via Peyer's patches) to syngeneic or xenogeneic epithelial antigens generated specific immunoglobulin and were found to have T lymphocytes in the draining nodal areas (including the mesenteric nodes) which were (a) antigen-specific, having a [3H]thymidine uptake in the presence of antigen 30-fold the control; (b) generally of the Thelper/inducer subclass (W3/25+) which, upon further culture, developed phenotype surface markers for activation (IL-2R+); (c) able to induce an antigen-specific humoral and cell-mediated responses upon intravenous injection into naive syngeneic hosts; and (d) demonstrable in gut-associated lymphoid tissue (mesenteric lymph nodes) and, to a lesser extent in spleen, of the cell recipient. Further, lymphocytes cloned from reactive mesenteric lymph node cells demonstrated specificity for a gel-purified subfraction of epithelial antigen, designated P1, containing highly conserved organ-specific macromolecules thought to be autoantigenic for gut.     

Antibodies to quinolinic acid and the determination of its cellular distribution within the rat immune system

Antibodies to quinolinic acid were produced in rabbits with protein-conjugated and gold particle-adsorbed quinolinic acid. Quinolinic acid immunoreactivity was below detection limits in carbodiimide-fixed rat brain. In contrast, strong quinolinic acid immunoreactivity was observed in spleen cells with variable, complex morphology located predominantly in the periarterial lymphocyte sheaths. In the thymus, quinolinic acid immunoreactivity was observed in cells with variable morphology, located almost exclusively in the medulla. Lymph nodes and gut-associated lymphoid tissue contained many, strongly stained cells of similar complex morphology in perifollicular areas. Immunoreactivity in liver and lung was restricted to widely scattered, perivascular cells and alveolar cells respectively. Additional stained cells with complex morphology were observed in bronchus-associated lymphoid tissue, in skin, and in the lamina propria of intestinal villi. Follicles in all secondary lymphoid organs were diffusely stained, ranging from mildly to moderately immunoreactive in spleen, to intensely immunoreactive in gut-associated lymphoid tissue. These results suggest that quinolinic acid is an immune system-specific molecule. Two hypothetical schemes are proposed to account for high levels of quinolinic acid in specific cells of the immune system.     

Specific attachment of mesenteric IgA lymphoblasts to specialized endothelium of intestinal mucosa lamina propria capillaries

The bulk of IgA secreted in the gut is mostly contributed by locally dwelling plasma cells derived from B cells originating in the gut-associated lymphoid tissues (GALT). These IgA cells originate in Peyer's patches and recirculate, returning to the gut upon maturity. The precise mechanism of homing to secretory mucosae is to date not fully understood. It has been demonstrated, however, that specialized endothelium of small vascular spaces in peripheral nodes (PN) and endothelia of mucosal vessels are the site of receptor recognition for B and T cells. In their sojourn, IgA blasts have been shown to stop momentarily in mesenteric nodes (MN) before proceeding to their final destination, the lamina propria (LP) of the gut mucosa. They then develop into IgA-secreting plasma cells. In the present work, we show that IgA MN lymphoblasts, when compared to PN lymphoblasts, attach preferentially to LP venule and capillary endothelium, The B-cell maturation in the mesenteric lymph nodes, where IgA is the sole membrane-bound immunoglobulin, allows attachment of most of these cells. Our work suggests that the site of exit of IgA cells from the circulation are these specialized lamina propria venules and capillaries.     

Different subclass distribution of IgA-producing cells in human lymphoid organs and various secretory tissues

A highly reproducible paired immunofluorescence staining method was used to map the relative distribution of IgA1- and IgA2-producing cells in peripheral lymphoid organs and various secretory tissues. Spleen, peripheral lymph nodes, and tonsils all contained a marked predominance (91 to 95%) of IgA1 immunocytes. However, striking variations were demonstrated among the secretory tissues with regard to the median proportion of IgA1-producing cells: nasal mucosa, 96%; lacrimal glands, 81%; major salivary glands, 66%; mammary glands, 63%; gastric and proximal small intestinal mucosa, 84 to 77%; ileum, 55%; and large bowel, 41%. Thus, IgA2 production is relatively enhanced mainly in the distal gut and in mammary and salivary glands, in that order.     

Selective chemotaxis of subsets of B lymphocytes from gut-associated lymphoid tissue and its implications for the recruitment of mucosal plasma cells

As they differentiate, precursor cells from the gut-associated lymphoid tissue are known to travel via the lymphatic system to the blood and then preferentially to home to various mucosal and exocrine sites such as the lamina propria of the gut and the lactating mammary gland, where they give rise to IgA-secreting plasma cells. The present study, directed at the mechanism by which the circulating precursors of mucosal IgA plasma cells selectively lodge in characteristic locations, explored the hypothesis that such homing is due to a locally produced chemotactic factor and that milk might be a source of such a factor. Subsets of lymphocytes bearing particular surface markers and purified by panning from lymph nodes of mice were examined in a micropore chemotaxis assay to search for the presence of chemotactic activity in mouse milk. The globulin fraction of whey was shown to contain a nondialyzable factor that is chemotactic for IgA (and also IgG)-positive lymphocytes when these are obtained from mesenteric lymph nodes as a source of mucosal-associated lymphoid tissue. Lymphocytes from peripheral lymph nodes, nonmucosal associated, were unaffected as were surface IgM-positive lymphocytes and T lymphocytes obtained from mesenteric nodes. Chemotactic activity for IgA lymphocytes was undetectable in mouse serum. The data are consistent with the idea that precursors of mucosal IgA plasma cells home to mucosal and exocrine sites in response to a specific chemotactic factor elaborated by local differentiated epithelial cells.     

T-cell help for the IgA response: the function of T cells from different lymphoid organs in regulating the proportions of plasma cells expressing various isotypes

Differential distribution of IgA-specific primed Lyt 2- T cells (TH) in favor of gut-associated lymphoid tissue (GALT) has been proposed to account for the high proportion of IgA-producing plasma cells at mucosal versus nonmucosal sites. We find, however, that GALT TH primed enterically with sheep red blood cells (SRBC) contain no more help for IgA responses than peripheral lymph node (PN) TH primed subcutaneously. Moreover, GALT TH are only poorly primed by enterically administered soluble protein antigen and therefore provide less help for all isotypes than PN TH primed subcutaneously with the same antigen. On the other hand, supernatants of GALT TH stimulated with concanavalin A (Con A) in vitro do help higher IgA:IgG plaque-forming cell (PFC) ratios in cultures with 2,4, 6-trinitrophenyl-SRBC (TNP-SRBC) than supernatants from PN and spleen, indicating that, when appropriately stimulated, GALT TH are capable of promoting relatively higher IgA responses than TH from other sources. Responses elicited by either SRBC-primed TH or splenic Con A supernatants in the presence of TNP-SRBC contained higher IgA:IgG PFC ratios than those elicited by linked recognition in the presence of haptenated soluble protein carrier.     

A comparative study of the gut-associated lymphoid tissue of primates and rodents

Previous studies have suggested that the gut-associated lymphoid tissue (GALT) of man is distinct from that of laboratory animals, but it is not clear whether this is due to environmental or true species difference. We have made a comparative study of rats and baboons because, like rats, baboons are herbivorous and relatively unhygienic but they are phylogenetically much more closely related to man. The Peyer's patches of rats, baboons and man are morphologically very similar in all three species but phenotypically those of man and baboons are different to those of rats. Cells with irregular nuclei ("centrocyte-like" cells) surround the mantle zone in all three species. While these cells express surface IgD and IgM in rats, in man and baboons they express surface IgM or IgA. A population of immunoblasts which express cytoplasmic IgA are present in association with the high endothelial venules of rat Peyer's patches. These cells are not present to the same extent in man or baboons. This suggests that the events between the antigenic stimulation of Peyer's patches and the ultimate seeding of the lamina propria with IgA secreting plasma cells may be different in rodents and primates.     

Mucosa-associated lymphoid tissues in the aerodigestive tract: their shared and divergent traits and their importance to the orchestration of the mucosal immune system

As inductive tissues for the initiation of antigen-specific T and B cell responses, the various mucosa-associated lymphoid tissues (MALT) of the aerodigestive tract, which include gut-associated lymphoid tissue (GALT), nasopharynx-associated lymphoid tissue (NALT) and bronchus-associated lymphoid tissue (BALT), share many histological and immunological characteristics. However, recent advances in our molecular and cellular understanding of immunological development have revealed that the various types of MALT also exhibit different molecular and cellular interactions for their organogenesis. In this review, we delineate the distinctive features of GALT, NALT and BALT and seek to show the role played by those features in the regulation of mucosal tissue organogenesis, the mucosal immune system, and mucosal homeostasis, all in an attempt to provide insights which might lead to a prospective mucosal vaccine.     

Studies on the abomasal pathology of immunized and non-immunized sheep infected with Haemonchus contortus

Five adult ewes and five lambs were repeatedly immunized with weekly doses of 10,000 irradiated Haemonchus contortus L3 before challenge with 100,000 and 10,000 normal larvae respectively. Two groups of non-immunized ewes and lambs were similarly challenged and one animal from each of the four groups killed on days 3, 5, 7, 10 and 24 post-challenge. The cellular changes in the abomasal mucosa were less marked in the non-immunized groups than in the immunized animals and appeared later in the lambs than in the ewes. Thus, in the immunized ewes increases in the numbers of mast cells and eosinophils were evident within five days of challenge whereas similar changes appeared later in the immunized lambs. Also marked lymphoid aggregates at the base of the mucosa and in the submucosa were detected only in the immunized ewes. However, both immunized and non-immunized ewes showed rises in the numbers of IgA plasma cells after challenge which were not evident in either group of lambs.     

Enteric immunization reveals a T cell network for IgA responses and suggests that humans possess a common mucosal immune system

The local IgA response is a result of two related events, the induction of sensitized T and B cells in gut- or b ronchial-associated lymphoreticular tissues (GALT or BALT) and the final differentiation of IgA plasma cells in mucosal tissues where IgA is produced and transported to become secretory IgA (S-IgA) antibodies into external secretions. Oral administration of various types of antigens/vaccines may result in two types of response, i.e., S-IgA antibodies at mucosa and systemic unresponsiveness to antigen, a state termed oral tolerance. Regulatory T cells in GALT help account for both S-IgA responses and oral tolerance and thus serve to fine tune responses to orally encountered antigens. Studies in animal models and humans have shown that oral administration of antigens sensitize lymphoid cells in GALT which subsequently home to mucosa and result in S-IgA responses in several external secretions. The significant promise of oral vaccines for prevention of microbial diseases including neisserial diseases is discussed.     

Bronchus-associated lymphoid tissue (BALT) in the laboratory-bred and wild rat, Rattus norvegicus.

In juvenile wild rats, bronchus-associated lymphoid tissue (BALT) development was similar to that seen in adult specified-pathogen-free rats. In adult wild rats the BALT was widespread. In one animal infected with a mycoplasma-like organism, a region of bronchoepithelium overlying a large BALT nodule was seen, through which lymphocytes appeared able to pass to make direct contact with the bronchial lumen: the significance of this observation is discussed. There was no evidence of infection in lungs from any of the specified-pathogen-free animals, where small foci of BALT were seen.     

Distribution of T-cell subsets and immunoglobulin-containing cells in nasal-associated lymphoid tissue (NALT) of chickens

The present study demonstrated the localization of the T-cell subsets (CD4+ and CD8+) and immunoglobulin (Ig)-containing cells (IgA, IgM, and IgG) in the nasal mucosa and its accessory structures. These lymphoid structures may be compared with nasal-associated lymphoid tissue (NALT) of rats and mice. In the chicken NALT, T-cell subsets were more widely distributed than Ig-containing cells, especially in large lymphoid accumulations restricted to the respiratory mucosa in the nasal cavity and the nasolacrimal duct. These lymphoid accumulations in the mucosa of the nasal cavity and nasolacrimal duct consisted of widely distributed CD8+ cells and deeply aggregated CD4+ cells adjacent to large germinal centers. In these lymphoid accumulations, IgG-containing cells were more frequently observed than IgM- and IgA-containing cells. T-cell subsets, predominantly CD8+ cells were more widely distributed in the duct epithelium of the lateral nasal glands than Ig-containing cells. Moreover, numerous CD8+ cells and a few Ig-containing cells were found in the chicken salivary glands, especially around the orifice of their ducts into the oral cavity. Therefore, it seems likely that the chicken NALT plays an important part in the upper respiratory tract, with a close relationship to the paraocular immune system.     

Induction of IgE-secreting cells and IgE isotype-specific suppressor T cells in the respiratory lymph nodes of rats in response to antigen inhalation

Repeated exposure of high-IgE-responder Brown Norway (BN) rats to an aerosol of ovalbumin (OVA) once weekly triggered progressively increasing levels of OVA-specific IgG in serum. In contrast, responses in the IgE class were transient, declining from peak titers during the third week to background levels by Week 5, despite continuing aerosol exposure. Subsequent parenteral challenge of these animals revealed a state of antigen- and IgE isotype-specific tolerance. Adoptive transfer of splenocytes or pooled respiratory tract lymph node (RTLN) cells from aerosol-exposed animals to naive rats abrogated subsequent OVA-specific primary IgE responses in the recipients, but did not affect specific IgG responses, and kinetic studies indicated that these suppressor cells arose first in the RTLN. Transfer studies employing individual lymph node groups which constituted the RTLN pool pinpointed the superficial cervical nodes, which drain the uppermost portion of the respiratory tract, as the major source of suppressor cells. Fractionation of cell populations before adoptive transfer employing monoclonal antibodies directed against T-cell markers, defined a population of suppressor cells generated by aerosol exposure which expressed both the W3/13 (pan T-cell) and OX8 (cytotoxic/suppressor T-cell) antigens, but which was negative for the W3/25 (helper T-cell) marker. Analysis of the IgE and IgG responses induced by OVA inhalation was performed employing the ELISA plaque technique, recently developed in this laboratory. These studies revealed the parathymic and posterior mediastinal nodes draining the lower lung, as the major sites of specific IgE and IgG production; smaller numbers of OVA-specific IgG-secreting cells (but none secreting specific IgE) were detected in the nodes draining the upper respiratory tract, while antibody secretion outside the respiratory tract was restricted to comparatively few cells in the spleen. The ELISA plaque assay was also employed to enumerate total numbers of cells secreting the IgE isotype in aerosol-exposed and control rats, employing samples from 10 different lymphoid organs. Approximately 50% of the IgE-secreting cells in these animals were localized in RTLN, as opposed to 25% in gut-associated lymphoid tissues. These data are discussed in relation to the pivotal role of respiratory-tract associated lymphoid tissues in regulation of IgE responses to aeroallergens.     

Identification and characterization of a novel regulatory factor: IgA-inducing protein

IgA is the predominant Ig isotype in mucosal secretions and thus plays a pivotal role in host defense. The mechanisms by which IgA expression is regulated may differ among species and involve multiple pathways. Various cytokines and costimulators have been identified which regulate expression of this isotype, including IL-10, IL-2, vasoactive intestinal peptide, and TGF-beta. We have tested a wide array of known factors, but only under very limited conditions do these factors mediate substantial IgA production in vitro from bovine B cells. In response to these findings, we generated a cDNA library in a mammalian expression vector from activated cells derived from bovine gut-associated lymphoid tissues (Peyer's patch and mesenteric lymph node cells) as a source of soluble factor(s) that may regulate IgA production. We have identified a novel factor, IgA-inducing protein, which stimulates relatively high levels of IgA production in vitro following CD40 stimulation in coculture with IL-2. Our data suggest that IgA-inducing protein regulates IgA by acting as a switch or differentiation factor and is expressed in a variety of lymphoid and nonlymphoid tissues.     

Nasal-associated lymphoid tissue is a mucosal inductive site for virus-specific humoral and cellular immune responses

Peyer's patches are known as mucosal inductive sites for humoral and cellular immune responses in the gastrointestinal tract. In contrast, functionally equivalent structures in the respiratory tract remain elusive. It has been suggested that nasal-associated lymphoid tissue (NALT) might serve as a mucosal inductive site in the upper respiratory tract. However, typical signs of mucosal inductive sites like development of germinal center reactions after Ag stimulation and isotype switching of naive B cells to IgA production have not been directly demonstrated. Moreover, it is not known whether CTL can be generated in NALT. To address these issues, NALT was structurally and functionally analyzed using a model of intranasal infection of C3H mice with reovirus. FACS and histological analyses revealed development of germinal centers in NALT in parallel with generation and expansion of IgA(+) and IgG2a(+) B cells after intranasal reovirus infection. Reovirus-specific IgA was produced in both the upper respiratory and the gastrointestinal tract, whereas production of reovirus-specific IgG2a was restricted to NALT, submandibular, and mesenteric lymph nodes. Moreover, virus-specific CTL were detected in NALT. Limiting dilution analysis showed a 5- to 6-fold higher precursor CTL frequency in NALT compared with a cervical lymph node. Together these data provide direct evidence that NALT is a mucosal inductive site for humoral and cellular immune responses in the upper respiratory tract.     

B cells in the appendix and other lymphoid organs of the rabbit: Stimulation of DNA synthesis by anti-immunoglobulin

Lymphocytes from rabbit lymphoid organs were cultured in the presence of class specific anti-immunoglobulin sera and of anti-allotype sera. Stimulation of tritiated thymidine uptake into DNA was taken to indicate the presence of the corresponding immunoglobulins on the cell surfaces. Thymus and bone marrow lymphocytes were unresponsive to all reagents tested. Popliteal lymph node contained cells responsive to anti-μ, anti-γ, and anti-α and therefore presumably bearing IgM, IgG, and IgA. Spleen had only IgM- and IgG-bearing-cells, and the appendix contained cells with IgM and IgA receptors only. The lymph node, spleen, and appendix cells of rabbits depleted of B lymphocytes by irradiation (900 R) and injection of thymocytes were unresponsive to anti-immunoglobulin but were stimulated at almost normal levels by PHA and Con A. T cell-depleted animals (thymectomy, irradiation with three divided doses of 450 R and bone marrow shielding) had immunoglobulin-bearing lymphocytes but were unresponsive to the mitogens. However a moderate level of mitogen-responsiveness reappeared by 3–4 wk after irradiation. Cells of morphologically distinct regions of the appendix, separated manually, showed different responses corresponding to the inferred origins of these anatomic areas. The “dome” and “corona” contained functional IgM- and IgA-bearing cells. The “TDA” reacted well to PHA, Con A, and PWM, but was depleted of immunoglobulin-bearing cells. The “follicle” cells, which are almost all in active DNA synthesis or mitosis, were relatively unresponsive to either T or B cell stimuli. Anti-allotype serum stimulated the same populations which responded to class-specific heteroantisera but at a slightly lower level. It was inferred that gut-associated lymphoid tissues like the appendix may play a special role as an amplification site for B-cells destined to produce IgM and IgA elsewhere in the organism.     

Border Patrol Gone Awry: Lung NKT Cell Activation by Francisella tularensis Exacerbates Tularemia-Like Disease

The respiratory mucosa is a major site for pathogen invasion and, hence, a site requiring constant immune surveillance. The type I, semi-invariant natural killer T (NKT) cells are enriched within the lung vasculature. Despite optimal positioning, the role of NKT cells in respiratory infectious diseases remains poorly understood. Hence, we assessed their function in a murine model of pulmonary tularemia—because tularemia is a sepsis-like proinflammatory disease and NKT cells are known to control the cellular and humoral responses underlying sepsis. Here we show for the first time that respiratory infection with Francisella tularensis live vaccine strain resulted in rapid accumulation of NKT cells within the lung interstitium. Activated NKT cells produced interferon-γ and promoted both local and systemic proinflammatory responses. Consistent with these results, NKT cell-deficient mice showed reduced inflammatory cytokine and chemokine response yet they survived the infection better than their wild type counterparts. Strikingly, NKT cell-deficient mice had increased lymphocytic infiltration in the lungs that organized into tertiary lymphoid structures resembling induced bronchus-associated lymphoid tissue (iBALT) at the peak of infection. Thus, NKT cell activation by F. tularensis infection hampers iBALT formation and promotes a systemic proinflammatory response, which exacerbates severe pulmonary tularemia-like disease in mice.