Activation of RegIIIbeta/gamma and interferon gamma expression in the intestinal tract of SCID mice: an innate response to bacterial colonisation of the gut

BACKGROUND AND AIMS

The mechanisms by which commensal bacteria provoke intestinal inflammation in animal models of inflammatory bowel disease (IBD) remain incompletely defined, leading to increasing interest in the innate immune response of the colonic mucosa to bacterial colonisation.

METHODS

Using gene expression profiling of colonic RNA from C.B17.SCID germ free mice and those colonised with altered Schaedler's flora, we investigated the innate immune response to bacterial colonisation in vivo. The two most consistently induced gene groups were RegIIIbeta and gamma as well as interferon gamma (IFN-gamma) response genes.

RESULTS

Using quantitative reverse transcription-polymerase chain reaction, we showed that RegIIIbeta, RegIIIgamma, and IFN-gamma were constitutively expressed in the colon of conventionally housed SCID mice compared with either germ free SCID or conventionally housed BALB/c mice. Induction of these genes was reproduced by chronic monoassociation of germ free SCID mice with either of two separate gut commensal bacterial species-segmented filamentous bacteria and Schaedler's Escherichia coli. The cellular source for IFN-gamma on monoassociation of SCID mice with Schaedler's E coli was localised to a subset of intraepithelial natural killer (IENK) cells that express asialo-GM1. In vivo IFN-gamma immunoneutralisation studies failed to demonstrate any alteration in RegIIIbeta or gamma expression.

CONCLUSIONS

Thus bacterial colonisation of the colon independently activates two distinct innate immune cell types at the mucosal interface with the colonic lumen, intestinal epithelial cells, and IENK cells, a response that may be regulated by the adaptive immune system. These innate immune responses may play a role in the pathogenesis of colitis in SCID adoptive transfer models in mice and possibly in patients with IBD.

Interactions of commensal gut microbes with subsets of B- and T-cells in the murine host

Although mechanisms operative in the induction and maintenance of specific, adaptive immunity, including 'cognate' B/T interactions, have been extensively studied and defined, we still know little about the mechanisms operative in developing and maintaining B- and T-cell dependent 'natural' immunity. Particularly, we are still rather ignorant concerning gut microbial/gut or systemic APC, T cell and B cell interactions that lead to lymphoid cell mediated 'natural' immunity: specific or broadly reactive, activation via TCR and BCR and/or via other receptors such as the TLR series, and whether T/B interactions are operative at this level? Here we will address: (1) the general role of gut microbes in the development and maintenance of the intestinal, humoral immune system; (2) the general role of gut microbes in the development of B1 cell mediated, 'natural' gut IgA and the dependence of these B1 cells on bystander T cell help; (3) the relative contributions of B1 versus B2 cells to gut 'natural' and specific IgA responses; (4) the role for particular 'normal' gut microbes in the initiation of inflammatory bowel diseases (IBD) in mice with a dysregulated immune system; and (5) the possible roles of gut microbes in facilitating oral tolerance, a mechanism likely operative in forestalling or ameliorating IBD. A central theme of this paper is to attempt to define the specificities of activated, functional CD4+ T cells in the gut for Ags of particular, usually benign gut microbes. We will also consider the still-unresolved issue of whether the contributions of B1-derived IgA in the gut to the 'natural' Ab pool are Ag-selected and driven to proliferation/differentiation or whether the main stimuli are not via BCRs but rather other receptors (TLRs, etc.). The main experimental approach has been to use antigen-free, germ-free, or gnotobiotic (mono- or oligo-associated with precisely known bacterial species) mice.

Morphine inhibits mucosal antibody responses and TGF-beta mRNA in gut-associated lymphoid tissue following oral cholera toxin in mice

In this study, we investigated the effect of morphine on the mucosal immune system using fragment cultures of ileal segments, Peyer's patches (PPs), and mesenteric lymph nodes. Mice were implanted s.c. with a morphine slow release pellet. Control groups received a naltrexone slow release pellet, a placebo pellet, or both a morphine and a naltrexone pellet. After 48 h, mice were orally immunized with cholera toxin (CT) and were boosted orally 1 wk later. Animals were sacrificed 1 wk after the booster immunization, and PPs, mesenteric lymph nodes, and ileal segments were cultured in 24-well plates for 12 days. Morphine resulted in a highly significant inhibition of CT-specific IgA and IgG production in fragment culture supernatants of all three tissues compared with placebo. Naltrexone blocked the reduction in Ab levels induced by morphine, indicating that the effect is opioid receptor mediated. Morphine did not significantly alter total IgA levels in any of the tissue culture supernatants. Morphine also inhibited CT-specific IgA and IgG levels in serum. By flow cytometry, morphine did not alter the lymphoid cell composition in PPs compared with placebo. The effect of morphine on TGF-beta, IL-5, and IL-6 mRNA expression in PPs and ileal segments was determined following oral immunization with CT. Morphine significantly decreased TGF-beta mRNA compared with that in the placebo group, and naltrexone blocked this effect. These results indicate that morphine inhibits Ag-specific IgA responses in gut-associated lymphoid tissue at least partially through the inhibition of TGF-beta, a putative IgA switch factor, in the gastrointestinal tract.

B2 but not B1 cells can contribute to CD4+ T-cell-mediated clearance of rotavirus in SCID mice

Studies utilizing various immunodeficient mouse models of rotavirus (RV) infection demonstrated significant roles of RV-specific secretory immunoglobulin A (IgA), CD4+ T cells, and CD8+ T cells in the clearance of RV and protection from secondary infection. Secretion of small but detectable amounts of IgA in RV-infected alphabeta T-cell receptor knockout mice (11) and distinctive anatomical localization and physiology of B1 cells suggested that B1 cells might be capable of producing RV-specific intestinal IgA in a T-cell-independent fashion and, therefore, be responsible for ablation of RV shedding. We investigated the role of B1 cells in the resolution of primary RV infection using a SCID mouse model. We found that the adoptive transfer of unseparated peritoneal exudate cells ablates RV shedding and leads to the production of high levels of RV-specific intestinal IgA. In contrast, purified B1 cells do not ablate RV shedding and do not induce a T-cell-independent or T-cell-dependent, RV-specific IgA response but do secrete large amounts of polyclonal (total) intestinal IgA. Cotransfer of mixtures of purified B1 cells and B1-cell-depleted peritoneal exudate cells differing in IgA allotypic markers also demonstrated that B2 cells (B1-cell-depleted peritoneal exudate cells) and not B1 cells produced RV-specific IgA. To our knowledge, this is the first observation that B1 cells are unable to cooperate with CD4+ T cells and produce virus-specific intestinal IgA antibody. We also observed that transferred CD4+ T cells alone are capable of resolving RV shedding, although no IgA is secreted. These data suggest that RV-specific IgA may not be obligatory for RV clearance but may protect from reinfection and that effector CD4+ T cells alone can mediate the resolution of primary RV infection. Reconstitution of RV-infected SCID mice with B1 cells results in the outgrowth of contaminating, donor CD4+ T cells that are unable to clear RV, possibly because their oligoclonal specificities may be ineffective against RV antigens.

Gut colonization of mice with actA-negative mutant of Listeria monocytogenes can stimulate a humoral mucosal immune response

We used Listeria monocytogenes, a gram-positive, facultative intracellular bacterium, to study the gut mucosal immune responses following oral infection. We employed a germfree (GF) mouse model to try to accentuate the development of a humoral mucosal immune response in the gut, and we used oral colonization with one of the mutants, actA-negative (DeltaactA) L. monocytogenes, to restrict infection largely to the gut. The DeltaactA mutant was able to colonize the intestinal mucosa of formerly GF mice for long periods of time without causing disease while eliciting secretory immunoglobulin A (IgA) responses, as evidenced by gut tissue fragment culture assays. Flow cytometric analyses and immunohistochemical methods showed the development of only minimal germinal center reactions (GCR) in Peyer's patches and more robust GCR in mesenteric lymph nodes. Pronounced increases in total (natural) IgA production occurred in gut tissues by day 7 and were maintained for up to 90 days. Levels of specific IgA were modest in gut tissues on day 14, increased until day 76, and stabilized at day 90. We also observed a significant rise in serum IgA and IgG1 levels following oral infection by listeriae. Upon colonization, the organisms mainly infected the intestines and intestinal lumen, and we only sporadically observed few colony-forming bacteria in the liver and spleen. We observed a marked rise in IgA-secreting cells, including listeria-specific IgA antibody-secreting cells, in the lamina propria of the small intestine by enzyme-linked immunospot assays. To ascertain whether some of the IgA was specific for listeriae, we performed Western blot analysis to test the reactivity of IgA from fragment cultures to antigens in sonicates of L. monocytogenes. We detected IgA binding to antigenic proteins with molecular masses of 96, 60, 40, and 14 kDa in the Listeria sonicates.

Timing, localization, and persistence of colonization by segmented filamentous bacteria in the neonatal mouse gut depend on immune status of mothers and pups

As a member of the indigenous gut mucosal microbiota, segmented filamentous bacteria (SFB) colonize the guts of a variety of vertebrates and invertebrates. They are potent microbial stimuli of the gut mucosal immune system. In the small intestines of mice and rats, it has been observed that SFB are absent during the suckling period and appear in high numbers shortly after weaning, then quickly retreat to the cecum and large intestine. In this study, we explored whether this microecological phenomenon resulted from the interaction between SFB and the passively acquired maternal mucosal immunity and/or the actively acquired mucosal immunity. We set up a mouse model by reciprocal crossings and backcrossings of SFB-monoassociated, formerly germ-free, immunocompetent (+/+) BALB/c mice and immunodeficient (scid/scid) mice to produce pups which are either immunocompetent (scid/+) or immunodeficient (scid/scid) and are born either to immunocompetent (scid/+) mothers or to immunodeficient (scid/scid) mothers. We monitored the number of SFB on the mucosa of the small intestine in the four different groups of mice after birth, as well as the level of passively acquired antibodies, the active gut mucosal immune responses, and immunoglobulin A (IgA) coating of SFB in the gut. The results showed that, irrespective of whether the pups were scid/scid or scid/+, SFB could be found earlier on the mucosa of the small intestine in pups born to scid/scid mothers, appearing from day 13 and rapidly reaching a climax around weaning time on day 28, compared to the significantly delayed colonization in the pups of scid/+ mothers, starting from day 16 and peaking around days 28 to 32. After the climax, SFB quickly declined to very low levels in the small intestines of scid/+ pups of either scid/scid mothers or scid/+ mothers, whereas they remained at high levels in scid/scid pups at least until day 70, the last observation time in this study. The dynamic changes in SFB colonization of the small intestines of the different groups of pups may be related to the dynamic changes in the levels of SFB coated with secretory IgA (sIgA), which resulted from the significantly different levels of sIgA obtained from the mothers' milk during the suckling period and, later, of self-produced sIgA in the small intestine. Nevertheless, it is evident that the timing, localization, and persistence of colonization of the neonatal gut by SFB depends on the immune status of both mothers and pups.

Respiratory mucosal immunization with reovirus serotype 1/L stimulates virus-specific humoral and cellular immune responses, including double-positive (CD4(+)/CD8(+)) T cells

Respiratory virus infections are a serious health challenge. A number of models that examine the nature of the respiratory immune response to particular pathogens exist. However, many pathogens that stimulate specific immunity in the lung are frequently not effective immunogens at other mucosal sites. A pathogen that is an effective respiratory as well as gastrointestinal immunogen would allow studies of the interaction between the mucosal sites. Reovirus (respiratory enteric orphan virus) serotype 1 is known to be an effective gut mucosal immunogen and provides a potential model for the relationship between the respiratory and the gut mucosal immune systems. In this study, we demonstrate that intratracheal immunization with reovirus 1/Lang (1/L) in C3H mice resulted in high titers of virus in the respiratory tract-associated lymphoid tissue (RALT). High levels of reovirus-specific immunoglobulin A were determined in the RALT fragment cultures. The major responding components of the bronchus-associated lymphoid tissue were the CD8(+) T lymphocytes. Cells from draining lymph nodes also exhibited lysis of reovirus-infected target cells after an in vitro culture. The present study also describes the distribution of transiently present CD4(+)/CD8(+) double-positive (DP) T cells in the mediastinal and tracheobronchial lymph nodes of RALT. CD4(+)/CD8(+) DP lymphocytes were able to proliferate in response to stimulation with viral antigen in culture. Furthermore, these cells exhibited lysis of reovirus-infected target cells after in vitro culture. These results establish reovirus 1/L as a viable model for future investigation of the mucosal immune response in the RALT and its relationship to the common mucosal immune system.

Influences of microbiota on intestinal immune system development

The normal colonization of the mammalian intestine with commensal microbes is hypothesized to drive the development of the humoral and cellular mucosal immune systems during neonatal life and to maintain the physiologically normal steady state of inflammation in the gut throughout life. Neonatal conventionally reared mice and germ-free, deliberately colonized adult mice (gnotobiotic mice) were used to examine the efficacy of certain intestinal microbes.

Segmented filamentous bacteria are potent stimuli of a physiologically normal state of the murine gut mucosal immune system

Segmented filamentous bacteria (SFB) are autochthonous bacteria inhabiting the intestinal tracts of many species, including humans. We studied the effect of SFB on the mucosal immune system by monoassociating formerly germfree C3H/HeN mice with SFB. At various time points during 190 days of colonization, fragment cultures of small intestine and Peyer's patches (PP) were analyzed for total immunoglobulin A (IgA) and SFB-specific IgA production. Also, phenotypic changes indicating germinal center reactions (GCRs) and the activation of CD4(+) T cells in PP were determined by using fluorescence-activated cell sorter analyses. A second group of SFB-monoassociated mice was colonized with a gram-negative commensal, Morganella morganii, to determine if the mucosal immune system was again stimulated and to evaluate the effect of prior colonization with SFB on the ability of M. morganii to translocate to the spleen and mesenteric lymph nodes. We found that SFB stimulated GCRs in PP from day 6 after monoassociation, that GCRs only gradually waned over the entire length of colonization, that natural IgA production was increased to levels 24 to 63% of that of conventionally reared mice, and that SFB-specific IgA was produced but accounted for less than 1.4% of total IgA. Also, the proportion of CD4(+), CD45RBlow T cells, indicative of activated cells, gradually increased in the PP to the level found in conventionally reared mice. Secondary colonization with M. morganii was able to stimulate GCRs anew, leading to a specific IgA antibody response. Previous stimulation of mucosal immunity by SFB did not prevent the translocation of M. morganii in the double-colonized mice. Our findings generally indicate that SFB are one of the single most potent microbial stimuli of the gut mucosal immune system.

Interactions between gut-associated lymphoid tissue and colonization levels of indigenous, segmented, filamentous bacteria in the small intestine of mice

Unlike most other indigenous bacteria, segmented filamentous bacteria (SFB) are potent activators of the mucosal immune system. SFB are strongly anchored to the epithelial cells of the small intestine where they have a preference for mucosal lymphoid epithelium. Since SFB are only present in high numbers shortly after weaning, it was investigated whether an SFB-induced immune reaction results in the removal of these bacteria from the small intestine. A correlation was found between age and colonization levels in the small intestines of SFB monoassociated Swiss mice. Five-week-old athymic BALB/c (nu/nu) mice showed lower colonization levels than their heterozygous littermates, but the opposite was found at the age of 12 weeks. However, SFB inoculation of germfree Swiss mice resulted in higher colonization levels in 5-week-old mice when compared with 4-month-old mice. We conclude that SFB colonization levels in the small intestine are likely influenced by the activity of the mucosal immune system. However, an additional age-dependent factor that modulates SFB colonization levels cannot be excluded.Key words: segmented filamentous bacteria, small intestine, gut-associated lymphoid tissue.

Interactions between gut-associated lymphoid tissue and colonization levels of indigenous, segmented, filamentous bacteria in the small intestine of mice

Unlike most other indigenous bacteria, segmented filamentous bacteria (SFB) are potent activators of the mucosal immune system. SFB are strongly anchored to the epithelial cells of the small intestine where they have a preference for mucosal lymphoid epithelium. Since SFB are only present in high numbers shortly after weaning, it was investigated whether an SFB-induced immune reaction results in the removal of these bacteria from the small intestine. A correlation was found between age and colonization levels in the small intestines of SFB monoassociated Swiss mice. Five-week-old athymic BALB/c (nu/nu) mice showed lower colonization levels than their heterozygous littermates, but the opposite was found at the age of 12 weeks. However, SFB inoculation of germfree Swiss mice resulted in higher colonization levels in 5-week-old mice when compared with 4-month-old mice. We conclude that SFB colonization levels in the small intestine are likely influenced by the activity of the mucosal immune system. However, an additional age-dependent factor that modulates SFB colonization levels cannot be excluded.

Development and maintenance of the gut-associated lymphoid tissue (GALT): the roles of enteric bacteria and viruses

GALT can be subdivided into several compartments: (a) Peyer's patches (PP); (b) lamina propria (LP); and (c) intraepithelial leukocyte (IEL) spaces. The B-cell follicles of PP are quiescent in neonatal and germ-free (GF) adult mice. Germinal centers (GC), including sIgA+ blasts, appear in the B follicles of formerly GF adult mice about 10-14 days after monoassociation with various gut commensal bacteria. The GC wax and wane over about a 3-week period, although the bacterial colonizers remain in the gut at high density. Neonatal mice, born of conventionally reared (CV), immunocompetent mothers, display GC reactions in PP postweaning, although pups of SCID mothers display precocious GC reactions at about 14 days of life. Normally, gut colonization of neonates with segmented filamentous bacteria (SFB) leads to explosive development of IgA plasmablasts in LP shortly after weaning. Commensal gut bacteria and the immunocompetency of mothers also appears to control the rate of accumulation of primary B cells from "virgin" B cells in neonates. Enteric reovirus infection by the oral route can cause the activation of CD8+ T cells in the interfollicular regions of PP and the appearance of virus-specific precursor cytotoxic T lymphocytes (pCTL) in the IEL spaces. Such oral stimulation can also lead to "activation" of both CTL and natural killer (NK) cells in the IEL spaces. More normally, colonization of the gut with SFB also leads to similar activations of NK cells and "constitutively" cytotoxic T cells.

Predominant T-cell receptor Vbeta usage of intraepithelial lymphocytes during the immune response to enteric reovirus infection

Previous studies have found that intraepithelial lymphocytes (IEL) contain virus-specific cytotoxic T lymphocytes (CTL) that increase dramatically during the course of virus infection. In the present study, the T-cell receptor (TCR) V beta pattern used by IEL against reovirus enteric infection was investigated both in conventional and in germfree mice. IEL were isolated by a modified rapid method, and their expression of 13 TCR V betas was examined by flow cytometric analysis. The virus-specific CTL activity of each TCR V beta subset was assessed by subtraction with coated Dyna beads by a nonradioactive assay. There was a preferential perturbation of TCR V betas following virus challenge, including increases in cells expressing V beta7, -12, -14, and -17 in conventional mice and V beta2, -12, and -17 in germfree mice. In conventionally reared mice, IEL maintained and restimulated in culture had a preferential use of TCR V beta9, -12, and -17. TCR V beta2 and -17 subfamilies were found amplified in all conditions. Furthermore, TCR V beta12 and -17 accounted for 37 and 77% of the virus-specific CTL activity, respectively, after in vitro restimulation. This study provides evidence that virus-specific CTL activity may be due to the oligoclonal expansion of TCR V beta subfamilies in IEL. Our findings suggest that in vivo infection selectively presents few T-cell epitopes and that the correct identification of these T-cell epitopes would increase the likelihood of success when designing subunit vaccines.

Orally administered microencapsulated reovirus can bypass suckled, neutralizing maternal antibody that inhibits active immunization of neonates

Purified reovirus serotype 1, encapsulated in biodegradable aqueous microcapsules, was found to bypass maternal antibody passively transferred by suckling to neonates. Genetically identical, immunocompetent F1 scid/+ mice were generated by the reciprocal crosses of C.B17 scid/scid and normal congenic +/+ adult mice. The immunocompetent +/+ dams were either orally infected with reovirus prior to mating or not. Thus, these immunocompetent F1 pups developed either in the absence or in presence of passively transferred maternal immunity. The F1 mice were orally immunized on day 10 with either live virus, microencapsulated reovirus, or empty microcapsules plus live virus. The immune responses were assessed in the neonatal gut-associated lymphoid tissues (GALT). Examination of reovirus specific immunoglobulin A in the serum and GALT, taken on days 7, 14, and 21 postimmunization, clearly demonstrated that microencapsulated reovirus could bypass the normal effect of maternal antibodies, passively acquired by suckling, to inhibit active priming of neonates by oral route. These observations seem relevant to the development of efficacious oral vaccines that also allow passive, protective immunity via suckled maternal antibodies while permitting active oral immunization of neonates.

Problems and priorities for controlling opportunistic pathogens with new antimicrobial strategies; an overview of current literature

An International Study Group on New Antimicrobial Strategies (ISGNAS) has been formed in response to the recognition that development of microbial resistance to antibiotics is becoming a serious, world-wide problem. The group met in 1993 for the first time to discuss the feasibility of developing rational alternatives to the use of antibiotics and prepared, as a result, a comprehensive overview of normal (physiological) mechanisms involved in the control of potentially pathogenic (oppotunistic) microorganisms. One objective of ISGNAS is to understand the conditions which allow opportunistic microbes present among the symbionts to cause an infection. There is a need for more coherent information concerning the habitat, growth requirements and host and pathogen properties which allow opportunistic pathogens to cause life-threatening infections. In particular, information is urgently being sought to understand the complexity of the interactions between the vast number of microbial species, and the interactions between the microbes and their host. Another goal is to inspire and enable basic and clinical research that will lead to the development of new therapies for regulating colonization, translocation and infection by opportunistic micro-organisms in patients during periods of decreased resistance. With a sufficient amount of knowledge of how healthy individuals keep opportunistic micro-organisms under control, it may become feasible for physicians to maintain host resistance and inter-microbial factors involved in the containment of opportunistic microbes. Therapies aimed at boostering natural resistance mechanisms will be of critical importance to individuals whose resistance has been compromised as a result of another clinical condition.

Monoclonal immunoglobulin A derived from peritoneal B cells is encoded by both germ line and somatically mutated VH genes and is reactive with commensal bacteria

We transferred peritoneal cells from BALB/c mice into C.B17 scid/scid mice. Six to eight months after injection, only cells with the B1 phenotype were retained in the spleens and peritoneal cavities of these mice. The lamina propria of the intestine contained many peritoneal, donor-derived, immunoglobulin A (IgA)-producing cells. The mesenteric lymph nodes of these mice were found to be a major site of proliferation and generation of IgA plasmablasts. We established eight IgA-producing hybridomas from the mesenteric lymph nodes of such mice, and all the hybridomas reacted with different but partially overlapping fecal bacterial populations. Cloning and sequencing of the VH genes of these hybridomas showed that two hybridomas utilized germ line-encoded VH genes while the VH genes of the six hybridomas showed somatic mutations, some of which are indicative of an antigen-driven selection process.

Commensal enteric bacteria engender a self-limiting humoral mucosal immune response while permanently colonizing the gut

We have employed a germfree mouse model to study the development and persistence of a humoral mucosal immune response to a gram-negative murine commensal organism, Morganella morganii. M. morganii bacteria rapidly colonize the gut, resulting in hypertrophy of Peyer's patches (PP), including germinal center reactions (GCR), and the development of specific immunoglobulin A (IgA) responses detected in vitro in PP fragment cultures and by ELISPOT assays of lamina propria cells. The GCR peaks 14 days after infection and begins to wane thereafter. Upon colonization, the organisms successfully translocate to the mesenteric lymph node and spleen, but the number of translocating bacteria begins to drop with the onset of a specific IgA response. A clonal B-cell microculture technique was used to determine the frequency of specific IgA plasmablasts and IgA memory cells. The frequencies of preplasmablasts were seen to be higher in the earlier stages of germinal center development, whereas the frequencies of antigen-specific memory cells appeared to remain at a relatively constant level even after 193 days postmonoassociation. We suggest that a successful secretory IgA response can attenuate chronic stimulation of GCR even though the bacteria persist in the gut. The observed developing hyporesponsiveness to a chronically present commensal organism may be relevant to the use of bacterial vectors for mucosal immunization.

Commensal enteric bacteria engender a self-limiting humoral mucosal immune response while permanently colonizing the gut

We have employed a germfree mouse model to study the development and persistence of a humoral mucosal immune response to a gram-negative murine commensal organism, Morganella morganii. M. morganii bacteria rapidly colonize the gut, resulting in hypertrophy of Peyer's patches (PP), including germinal center reactions (GCR), and the development of specific immunoglobulin A (IgA) responses detected in vitro in PP fragment cultures and by ELISPOT assays of lamina propria cells. The GCR peaks 14 days after infection and begins to wane thereafter. Upon colonization, the organisms successfully translocate to the mesenteric lymph node and spleen, but the number of translocating bacteria begins to drop with the onset of a specific IgA response. A clonal B-cell microculture technique was used to determine the frequency of specific IgA plasmablasts and IgA memory cells. The frequencies of preplasmablasts were seen to be higher in the earlier stages of germinal center development, whereas the frequencies of antigen-specific memory cells appeared to remain at a relatively constant level even after 193 days postmonoassociation. We suggest that a successful secretory IgA response can attenuate chronic stimulation of GCR even though the bacteria persist in the gut. The observed developing hyporesponsiveness to a chronically present commensal organism may be relevant to the use of bacterial vectors for mucosal immunization.

Role of maternal antibody in the induction of virus specific and bystander IgA responses in Peyer's patches of suckling mice

Reciprocal crossings of C.B17 scid/scid and congenic BALB/c (+/+) mice generate genetically identical, immunocompetent F1 scid/+ mice that develop in either the absence or influence of passively transferred maternal immunity. By exchanging F1 scid/+ litters at birth among scid/scid, non-immune or reovirus immune BALB/c mothers we examined the relative ability of placental or colostral/milk transfer of virus specific maternal antibodies to interfere with reovirus immunization of the neonatal gut associated lymphoid tissues (GALT). Our data demonstrate that the Peyer's patches (PP) in 10-day-old mice are competent to support thymus dependent responses to acute reovirus stimulation that include the rapid (within 3 days) development of specific IgA plasma cells and the subsequent initiation of PP germinal center reactions. These neonatal mucosal immune responses occur independently of coincident specific maternal immune responses as evidenced by the identity of the reovirus specific responses engendered in F1 scid/+ pups of scid/scid versus +/+ mothers. However, transfer of pre-existing reovirus specific maternal antibody in milk via nursing on a reovirus immune (foster) mother completely abrogated reovirus specific neonatal IgA responses; while placental transfer of specific maternal antibody alone did not interfere with the immunization of the neonatal GALT with enteric reovirus. Reovirus challenge of 10-day-old mice was associated with a substantial bystander IgA response. Possible mechanisms responsible for the induction of the observed bystander IgA responses are discussed.

Characterization of cytotoxic cells from reovirus-infected SCID mice: activated cells express natural killer- and lymphokine-activated killer-like activity but fail to clear infection

Severe combined immune deficient (SCID) mice infected orally with reovirus type 1/L die of hepatitis. Leukocytes bearing the cell surface antigens Thy-1.2 and asialoGM-1 (AsGM1) accumulate in the livers of infected animals. These cells display lytic activity toward natural killer-sensitive (YAC-1) and -resistant (P815) cell lines and murine hepatoma line Hepa 1/A1. Although these cells have the capacity to lyse infected hepatoma targets, they cannot clear the virus.

Early appearance of "natural" mucosal IgA responses and germinal centers in suckling mice developing in the absence of maternal antibodies

We have examined the role of passively transferred maternal Abs in the ontogeny of "natural" mucosal IgA responses before weaning of suckling mice by comparing the immune status of gut-associated lymphoid tissue (GALT) (Peyer's patches, mesenteric lymph nodes, and lamina propria) in 7- to 25-day-old F1 severe combined immunodeficient (scid)/+ mice generated through reciprocal crosses of C.B17 scid/scid and normal congenic (+/+) adult mice. We have also examined the ability of prenatal vs postnatal transfer of maternal immunity to forestall the development of natural neonatal mucosal IgA responses by swapping litters of F1 scid/+ pups at birth between +/+ and scid/scid mothers. Our results demonstrate that F1 scid/+ pups born to or nursed by scid/scid mothers undergo an accelerated development of natural IgA responses that include germinal center reactions in both Peyer's patches and mesenteric lymph nodes. These early IgA responses are evident as: 1) increased frequencies of IgA-producing GALT organ cultures; 2) increased mean IgA output by GALT organ cultures; 3) increased frequencies (> 1 log) of IgA-secreting cells from GALT detected by ELISPOT at 16 days of age; and 4) germinal center development by 17 days of age detected by in vivo bromodeoxyuridine incorporation. Finally, FACS analyses of enteric bacteria isolated from F1 scid/+ pups and stained for the presence of surface-bound mouse IgA demonstrate that the bacterial flora is a major target of both maternal secretory IgA and of the earliest IgA Abs produced in the neonatal GALT of pups deprived of maternal immunity.

Early appearance of "natural" mucosal IgA responses and germinal centers in suckling mice developing in the absence of maternal antibodies

We have examined the role of passively transferred maternal Abs in the ontogeny of "natural" mucosal IgA responses before weaning of suckling mice by comparing the immune status of gut-associated lymphoid tissue (GALT) (Peyer's patches, mesenteric lymph nodes, and lamina propria) in 7- to 25-day-old F1 severe combined immunodeficient (scid)/+ mice generated through reciprocal crosses of C.B17 scid/scid and normal congenic (+/+) adult mice. We have also examined the ability of prenatal vs postnatal transfer of maternal immunity to forestall the development of natural neonatal mucosal IgA responses by swapping litters of F1 scid/+ pups at birth between +/+ and scid/scid mothers. Our results demonstrate that F1 scid/+ pups born to or nursed by scid/scid mothers undergo an accelerated development of natural IgA responses that include germinal center reactions in both Peyer's patches and mesenteric lymph nodes. These early IgA responses are evident as: 1) increased frequencies of IgA-producing GALT organ cultures; 2) increased mean IgA output by GALT organ cultures; 3) increased frequencies (> 1 log) of IgA-secreting cells from GALT detected by ELISPOT at 16 days of age; and 4) germinal center development by 17 days of age detected by in vivo bromodeoxyuridine incorporation. Finally, FACS analyses of enteric bacteria isolated from F1 scid/+ pups and stained for the presence of surface-bound mouse IgA demonstrate that the bacterial flora is a major target of both maternal secretory IgA and of the earliest IgA Abs produced in the neonatal GALT of pups deprived of maternal immunity.

Spleen cells from antigen-minimized mice are superior to spleen cells from germ-free and conventional mice in the stimulation of primary in vitro proliferative responses to nominal antigens

T lymphocytes from mice reared under conditions of differential exposure to food, environmental and microbial antigens were compared for phenotypic shifts that may be associated with prior exposure to antigens as well as functional variations in the ability to respond to antigens de novo. While the intra-epithelial CD8 T cell compartment was found to differ significantly in the type of T cell receptor predominantly expressed, CD4 T cells from various lymphoid organs of conventionally reared specific pathogen-free (CL-SPF) mice showed only subtle phenotypic differences from cells obtained from antigen-minimized germ-free (AF) and germ-free (GF) mice. Cells derived from mice exposed to a reduced antigen load exhibited primary in vitro proliferative responses to antigens such as dinitrophenyl-keyhole limpet hemocyanin which were significantly enhanced when compared with similar responses of cells from conventional mice. In cell mixing experiments, differences in the reactivity of T cells from the spleens of AF, GF and CL-SPF mice were dependent on the source of the spleen cells employed as antigen-presenting cells (APC). Experiments in which the T cell population was held constant revealed that, as APC, spleen cells from AF mice were most often superior to spleen cells from GF mice which were in turn considerably better than a similar population from SPF mice. We conclude that the enhanced primary reactivity of spleen cells from AF mice to nominal antigen in vitro is likely to be the result of a difference in the function and/or regulatory activities of the cell population employed as APC in this investigation.

Sea star factor blocks development of T-dependent antibody secreting clones by preventing lymphokine secretion

Sea star factor (SSF), a protein of 39 kDa purified from macrophage-like coelomocytes of the echinoderm Asterias forbesi, has potent immunosuppressive effects on T-dependent but not T-independent antibody responses in vivo. SSF at a concentration of 0.5 microgram/ml markedly inhibits T-dependent antibody production in vitro by fluorescein (Flu)-specific B cells responding in clonal microculture to antigenic stimulation with Flu-conalbumin via the conalbumin-specific T cells D10.G4.1 (D10). At this concentration of SSF, Ig secretion induced by a T cell-independent stimulus, lipopolysaccharide (LPS), is not affected. Inhibition of antibody production in T-dependent microcultures by SSF can be completely overcome in a dose-dependent fashion by addition of lymphokine-rich supernatants from stimulated cultures of D10 cells. The possibility that SSF suppresses production of requisite cytokine growth factors from T cells was substantiated by the finding that SSF diminishes concentrations of stimulatory cytokines detectable in supernatants from antigen-stimulated cultures. Nevertheless, levels of intracytoplasmic mRNA for IL-4 and IL-5 are not detectably altered by concentrations of SSF that suppress antibody production. Furthermore, when cultures of D10 cells stimulated in the presence of SSF are subjected to freezing and thawing to release intracytoplasmic lymphokines, total levels of stimulatory cytokines are not lower than those in cultures without SSF. These results suggest that SSF inhibits antibody responses by limiting the availability of lymphokines produced by helper T cells. The mechanism for this inhibition may involve either direct effects of SSF on T cells or a block in effective T cell-B cell interaction.

Spontaneous proliferation of Peyer's patch cells in vitro

Under normal circumstances most lymphoid cell populations do not exhibit strong proliferative reactions in culture unless provoked by antigen or mitogen. The autologous mixed lymphocyte reaction (AMLR) mediated by adult T cells is a relatively weak proliferative response that occurs in the absence of known heterologous stimuli. In this investigation we demonstrate that Peyer's patch (PP) cells possess an inherent capacity to commence dividing in vitro and to display an exceptionally vigorous AMLR. The magnitude and kinetics of this spontaneous proliferation resemble that of a secondary response to a strong mucosal immunogen such as reovirus type 1/Lang. Analysis of the cellular components of the PP cultures implicates CD4+CD8- T cells as the major responding population and dendritic cells (DC) as stimulators. Mixing experiments indicate that spleen contains a cell population which can stimulate PP T cells, albeit to a lesser extent than PP cells. Similarly, splenic T cells have a reduced but significant capacity to respond to PP DC, in comparison to PP T cells. These differences suggest the possibility that there may be a decreasing gradient of antigenicity between the gut and the spleen which is reflected in the spontaneous activity of PP versus splenic T cells in vitro. We propose that PP cells are in fact responding in vitro to heterologous antigens derived from food, enteric microbes and other environmental sources. This notion is supported by the observation that PP cells from antigen-minimized germ-free mice fail to proliferate spontaneously in culture.

Developmental relationship between cytotoxic alpha/beta T cell receptor-positive intraepithelial lymphocytes and Peyer's patch lymphocytes

Following intraduodenal priming of mice with reovirus, precursor cytotoxic T lymphocytes (pCTL) rapidly appear in intraepithelial lymphocytes (IEL) and Peyer's patches. These cells express CTL activity after secondary in vitro stimulation with reovirus-infected cells. Adoptive transfer of Peyer's patch lymphocytes from normal BALB/c mice into reovirus-infected CB.17 severe combined immunodeficiency mice results in the infection-dependent appearance of large numbers of both CD8+Thy-1+ and CD8-Thy-1+, IEL that express the alpha/beta T cell receptor (TcR). Phenotypic and functional characterization of IEL derived from conventionally reared, reovirus-infected mice also points to extensive similarities in the pCTL derived from Peyer's patches and IEL. As in the Peyer's patches, pCTL are persistent in the IEL compartment for up to 4 weeks after infection. A large percentage of IEL that are recovered from reovirus-primed mice after in vitro culture are CD8+Thy-1+ cells that express alpha/beta TcR. Furthermore, depletion experiments demonstrate that the CD8+Thy-1+ population mediates the virus-specific CTL activity. Using limiting dilution analyses, it was estimated that 7 days after intraduodenal infection the average frequency of virus-specific pCTL was 197/10(6) CD8+Thy-1+ IEL and 190/10(6) CD8+Thy-1+ Peyer's patch lymphocytes. Taken together, these observations provide evidence that specific cellular immunity to reovirus in IEL is mediated at least in part, by conventional cytotoxic T lymphocytes and that these cells are functionally and phenotypically similar to the pCTL derived from the Peyer's patches.

The preference for switching to IgA expression by Peyer's patch germinal center B cells is likely due to the intrinsic influence of their microenvironment

This study was aimed at determining whether the chronically activated physiologic state of Peyer's patch (PP) tissue is primarily responsible for the IgA isotype preference expressed by PP germinal centers (GC) and memory B cells. We have used reovirus type 1/Lang to stimulate acute, de novo GC reactions in lymph nodes (LN) or PP to test the possibility that the surface (s)IgA component of enteric responses is peculiar to the local gut microenvironment whether or not PP are in a state of chronic activation. GC were raised in PP of germ-free mice by oral administration of virus and in lymph nodes (LN) of conventionally reared mice by local parenteral infection. Transient GC reactions were found to develop with similar time courses in both PP and LN after both primary and secondary local infections with reovirus. sIgA+ B cells, which were the major non-sIgM+/sIgD+ population found to arise in GC of PP, were not found in the LN. In LN, sIgG1+ B cells comprised the predominant non-IgM/IgD bearing population that arise after local infection. Lymphoid fragment cultures of PP initiated in vitro as early as 5 days after in vivo infection contained detectable secreted reovirus-specific IgA, whereas IgG1 but no IgA was found in LN cultures. Northern blot analysis to detect C alpha and C gamma 1 germline transcripts further substantiated a site-related bias in the expression of non-IgM/IgD isotypes that was manifest within a few days after infection. In summation, these observations taken together suggest that the preference for generating sIgA+ B cells in PP may be the result of intrinsic features of their gut microenvironment.

The preference for switching to IgA expression by Peyer's patch germinal center B cells is likely due to the intrinsic influence of their microenvironment

This study was aimed at determining whether the chronically activated physiologic state of Peyer's patch (PP) tissue is primarily responsible for the IgA isotype preference expressed by PP germinal centers (GC) and memory B cells. We have used reovirus type 1/Lang to stimulate acute, de novo GC reactions in lymph nodes (LN) or PP to test the possibility that the surface (s)IgA component of enteric responses is peculiar to the local gut microenvironment whether or not PP are in a state of chronic activation. GC were raised in PP of germ-free mice by oral administration of virus and in lymph nodes (LN) of conventionally reared mice by local parenteral infection. Transient GC reactions were found to develop with similar time courses in both PP and LN after both primary and secondary local infections with reovirus. sIgA+ B cells, which were the major non-sIgM+/sIgD+ population found to arise in GC of PP, were not found in the LN. In LN, sIgG1+ B cells comprised the predominant non-IgM/IgD bearing population that arise after local infection. Lymphoid fragment cultures of PP initiated in vitro as early as 5 days after in vivo infection contained detectable secreted reovirus-specific IgA, whereas IgG1 but no IgA was found in LN cultures. Northern blot analysis to detect C alpha and C gamma 1 germline transcripts further substantiated a site-related bias in the expression of non-IgM/IgD isotypes that was manifest within a few days after infection. In summation, these observations taken together suggest that the preference for generating sIgA+ B cells in PP may be the result of intrinsic features of their gut microenvironment.

Molecular genetic features reflecting the preference for isotype switching to IgA expression by Peyer's patch germinal center B cells

It has proven difficult to evaluate the functional potential of germinal center (GC) B cells, including those from Peyer's patches (PP), by either in vivo or in vitro methods. Thus, rather than assess secreted Ig product as an indicator of functional potential we have instead sought to detect mRNAs related to the various Ig heavy chains in GC B cells from PP by in situ hybridization. We have found that the GCs of PP contain the vast majority of B cells with easily detectable levels of mRNA alpha. These levels are intermediate between those of small resting B cells and plasmablasts. When PP B cells are enriched for cells bearing GC markers, approximately 50% contain mRNA mu and 40% mRNA alpha. Similar enrichment for sIgA+ B cells gave 50% of cells with easily detectable mRNA alpha and few if any positive for mRNA mu. The sizes of these mRNAs were similar to those encoding the membrane and secretory form of mu and alpha chains. No C alpha germ-line transcripts could be detected by Northern analyses using a probe for sequences 5' to the alpha switch regions. Finally, GC and sIgA+ cells from PP also showed the absence of a portion of their genomic DNA for CH genes 5' of C alpha. Thus, it seems likely that most of the GC cells expressing mRNA alpha have undergone conventional VDJ recombination to C alpha at the DNA level in order to switch to the expression of IgA. Our findings reflect the extraordinary preference for switching to IgA by GC cells in PP.

Use of Peyer's patch and lymph node fragment cultures to compare local immune responses to Morganella morganii

Lymphoid tissue fragment cultures were established to analyze the differentiative processes among B cells in Peyer's patches (PP) and peripheral lymph nodes (PLN), especially those in germinal centers. PP cultures from both conventionally reared mice and formerly germ-free mice colonized with Morganella morganii could be maintained for greater than 12 days with continued B-cell division, especially among cells binding high levels of peanut agglutinin, a characteristic of germinal center cells. PLN cultures from conventionally reared mice injected with a heat-killed vaccine of M. morganii could be maintained for the same amount of time. Over this period, PP cultures continued to secrete immunoglobulin A (IgA) as well as smaller amounts of IgM. PP cultures from formerly germ-free mice colonized with M. morganii showed net increases of IgA antiphosphocholine (anti-PC) antibodies with avidities as high as those of the prototypic T15 monoclonal antibody. Similar PLN fragment cultures from conventionally reared mice given footpad injections of M. morganii showed net increases of IgM and IgG anti-PC antibodies in the culture fluid. Thus, although M. morganii stimulated lymphoid tissues in vivo to produce an anti-PC response in vitro when given by either the oral or the parenteral route, the antibody isotypes differed between PP and PLN fragment cultures. Fragment culturing may offer a complementary and simpler way to detect a local secretory IgA response than does either measuring IgA antibody in secretions or detecting IgA antibody in the cytoplasm of plasma cells in the lamina propria of gastrointestinal or respiratory tissue.

Responses of single germinal-center B cells in T-cell-dependent microculture

B cells purified from the germinal centers (GCs) of murine Peyer's patches can be stimulated in a clonal microculture containing helper T cells and dendritic cells to divide and secrete immunoglobulin. Intraclonal isotype switching occurs, and a variety of immunoglobulin isotypes, including IgA, is secreted. Memory cells, which generate clones secreting IgA exclusively, are only rarely identified in the GC B-cell subset. Such memory cells can, however, be readily identified among unfractionated Peyer's patch B cells, and in non-GC subsets of B cells. The results suggest that the GC does not contain IgA memory cells that can be restimulated in vitro to secrete only IgA. When division of GC B cells is prevented by irradiation or aphidicholin treatment, a large subset that secretes IgA as the sole immunoglobulin isotype is seen, and the output of presumably single B cells is large enough to be scored by RIA. Both helper T cells and dendritic cells are required for the phenomenon. The data indicate that commitment to IgA secretion occurs in Peyer's patch GCs and suggest that the prolific cell division known to be supported in GCs may forestall terminal differentiation of preplasmablasts to immunoglobulin secretion.

CD8 lymphocyte subpopulations in Peyer's patches induced by reovirus serotype 1 infection

CD8 lymphocyte population heterogeneity has been examined by using reovirus serotype 1, strain Lang (reovirus 1/L) as a model infection. We have previously reported that gut mucosal infection with reovirus stimulates the appearance of virus-specific cytotoxic T cell precursors (pCTL) in Peyer's patches (PP). The effectors that mediate reovirus-specific cytotoxicity were found to express both the Thy-1 and CD8 Ag and were MHC-restricted in their recognition of reovirus Ag. To further characterize the virus-specific precursor and effector cells we have analyzed PP cells for the expression of a novel surface Ag (termed germinal center and T cell Ag (GCT)) found on germinal center B cells and a subpopulation of CD8+ T cells. Gut mucosal infection with reovirus 1/L is capable of increasing the proportion of GCT+ CD8+ T cells in PP. Positive selection as well as depletion of GCT+ cells has demonstrated that pCTL can express this Ag, and depletion experiments have demonstrated that effector CTL express the GCT Ag. Thus, a subpopulation of GCT+ cells have been identified as Ag-specific precursor and effector CTL. These observations indicate that the expression of the GCT Ag may provide a means to identify recently stimulated pCTL or effector CTL in gut mucosal tissues.

CD8 lymphocyte subpopulations in Peyer's patches induced by reovirus serotype 1 infection

CD8 lymphocyte population heterogeneity has been examined by using reovirus serotype 1, strain Lang (reovirus 1/L) as a model infection. We have previously reported that gut mucosal infection with reovirus stimulates the appearance of virus-specific cytotoxic T cell precursors (pCTL) in Peyer's patches (PP). The effectors that mediate reovirus-specific cytotoxicity were found to express both the Thy-1 and CD8 Ag and were MHC-restricted in their recognition of reovirus Ag. To further characterize the virus-specific precursor and effector cells we have analyzed PP cells for the expression of a novel surface Ag (termed germinal center and T cell Ag (GCT)) found on germinal center B cells and a subpopulation of CD8+ T cells. Gut mucosal infection with reovirus 1/L is capable of increasing the proportion of GCT+ CD8+ T cells in PP. Positive selection as well as depletion of GCT+ cells has demonstrated that pCTL can express this Ag, and depletion experiments have demonstrated that effector CTL express the GCT Ag. Thus, a subpopulation of GCT+ cells have been identified as Ag-specific precursor and effector CTL. These observations indicate that the expression of the GCT Ag may provide a means to identify recently stimulated pCTL or effector CTL in gut mucosal tissues.

Passive immunity to fatal reovirus serotype 3-induced meningoencephalitis mediated by both secretory and transplacental factors in neonatal mice

The role of passively acquired immunity to reovirus-induced meningoencephalitis in neonatal mice was examined. It was determined that female mice were capable of conferring protection against viral infection and meningoencephalitis in neonates depending on the route by which the dams were immunized and the serotype of the immunizing virus. Female mice immunized with homotypic virus via the oral route developed the most potent response. Infected neonates born and nursed by these females developed no signs of disease, and no virus was recoverable from their small intestines, livers, or brains following infection. Neonates born to females immunized with homotypic virus by the subcutaneous route manifested no evidence of meningoencephalitis or virus dissemination, yet virus was recovered from neonatal intestines. Mice immunized with heterotypic virus by either the subcutaneous or the oral route also conferred protection against disease; however, virus was recovered in small intestines and livers of infected neonates. Based on results from foster-nursing experiments, it appears that factors obtained both during suckling and by transplacental transfer contribute to protection. Passive transfer of reovirus-immune mouse serum also protected neonates from disease. These results demonstrate that passive immune mechanisms can mediate the protection of neonates against reovirus infection and provide further evidence of the importance of the mucosal immune response in protection against pathogens that invade the host via mucosal tissues.

Reovirus-induced liver disease in severe combined immunodeficient (SCID) mice. A model for the study of viral infection, pathogenesis, and clearance

Adult severe combined immunodeficient (SCID) mice can be infected by the oral route with reovirus, and a systemic infection can be established. Infectious virus is recovered from all internal organs, and the mice die in 4-6 wk. Chronic, discrete inflammatory lesions appear in the liver of infected mice, and are associated with hepatocytes containing demonstrable levels of viral antigen. The adoptive transfer of Peyer's patch (PP) cells from congenic mice before infection protects the SCID mice against disease and death. Immune donor PP cells can be distinguished from nonimmune cells by their ability to contain and resolve infection by 1 wk after challenge.

Dendritic cells support production of IgA and other non-IgM isotypes in clonal microculture

Microcultures of helper T (Th) cells and a few appropriately primed murine B cells can be used to detect cognate T-B interactions which lead to clonal production of IgM, IgG1, and IgE. However, IgG2, IgG3, and IgA are very rarely expressed. We have found that the addition of dendritic cells to such cultures creates an extremely supportive environment for clones expressing IgA with other isotypes, as well as clones expressing only detectable IgA. Typically, 400 dendritic cells were added to 3000 conalbumin-specific Th cells (D10.G4.1) and 30 hapten-specific Peyer's patch (PP) B cells with antigen in 15 microliters. The response was antigen dependent and clonal. Almost half of the clones expressed only non-IgM isotypes, 43% expressed some IgA, and 14% expressed some IgG3; isotype diversity increased over time. Dendritic cells from PP and spleen were found to be equally supportive, and allowed the number of T cells required in microculture to be decreased from 3000 to 400. However, T cell proliferation was not required for the supportive effect of dendritic cells. Surface IgD-bearing cells were also found to switch to IgA production in microculture as judged by their generating clones expressing IgM along with IgA and other isotypes. Again, IgA was usually expressed only in the presence of dendritic cells. The mechanism may involve dendritic cell-induced T cell activation and/or dendritic cell factors, and is under investigation.