The development and function of mucosal lymphoid tissues: a balancing act with micro-organisms.

Mucosal surfaces are constantly exposed to environmental antigens, colonized by commensal organisms and used by pathogens as points of entry. As a result, the immune system has devoted the bulk of its resources to mucosal sites to maintain symbiosis with commensal organisms, prevent pathogen entry, and avoid unnecessary inflammatory responses to innocuous antigens. These functions are facilitated by a variety of mucosal lymphoid organs that develop during embryogenesis in the absence of microbial stimulation as well as ectopic lymphoid tissues that develop in adults following microbial exposure or inflammation. Each of these lymphoid organs samples antigens from different mucosal sites and contributes to immune homeostasis, commensal containment, and immunity to pathogens. Here we discuss the mechanisms, mostly based on mouse studies, that control the development of mucosal lymphoid organs and how the various lymphoid tissues cooperate to maintain the integrity of the mucosal barrier.

Interleukin-17-dependent CXCL13 mediates mucosal vaccine-induced immunity against tuberculosis.

The variable efficacy of tuberculosis (TB) vaccines and the emergence of drug-resistant strains of Mycobacterium tuberculosis (Mtb) emphasize the urgency for not only generating new and more effective vaccines against TB but also understanding the underlying mechanisms that mediate vaccine-induced protection. We demonstrate that mucosal adjuvants, such as type II heat labile enterotoxin (LT-IIb), delivered through the mucosal route induce pulmonary Mtb-specific T helper type 17 (Th17) responses and provide vaccine-induced protection against Mtb infection. Importantly, protection is interferon-γ (IFNγ)-independent but interleukin-17 (IL-17)-dependent. Our data show that IL-17 mediates C-X-C motif chemokine ligand 13 (CXCL13) induction in the lung for strategic localization of proinflammatory cytokine-producing CXCR5+ (C-X-C motif chemokine receptor 5-positive) T cells within lymphoid structures, thereby promoting early and efficient macrophage activation and the control of Mtb. Our studies highlight the potential value of targeting the IL-17-CXCL13 pathway rather than the IFNγ pathway as a new strategy to improve mucosal vaccines against TB.

Colonic patch and colonic SILT development are independent and differentially regulated events.

Intestinal lymphoid tissues have to simultaneously ensure protection against pathogens and tolerance toward commensals. Despite such vital functions, their development in the colon is poorly understood. Here, we show that the two distinct lymphoid tissues of the colon-colonic patches and colonic solitary intestinal lymphoid tissues (SILTs)-can easily be distinguished based on anatomical location, developmental timeframe, and cellular organization. Furthermore, whereas colonic patch development depended on CXCL13-mediated lymphoid tissue inducer (LTi) cell clustering followed by LTα-mediated consolidation, early LTi clustering at SILT anlagen did not require CXCL13, CCR6, or CXCR3. Subsequent dendritic cell recruitment to and gp38(+)VCAM-1(+) lymphoid stromal cell differentiation within SILTs required LTα; B-cell recruitment and follicular dendritic cell differentiation depended on MyD88-mediated signaling, but not the microflora. In conclusion, our data demonstrate that different mechanisms, mediated mainly by programmed stimuli, induce the formation of distinct colonic lymphoid tissues, therefore suggesting that these tissues may have different functions.

Role of lymphotoxin and homeostatic chemokines in the development and function of local lymphoid tissues in the respiratory tract

Los órganos linfoides secundarios tienen una posición anatómica estratégica, con la finalidad de reclutar células presentadoras de antígeno activadas, células "naïve" y poblaciones de células T y B que se encuentran recirculando en la periferia. La estructura de los órganos linfoides secundarios, la cual incluye zonas definidas de células T y B, poblaciones especiales de células estromales, vénulas del endotelio alto y vasos linfáticos, ha evolucionado para facilitar los encuentros entre células presentadoras de antígeno y linfocitos, facilitando la proliferación y diferenciación de células B y T estimuladas por antígenos. La mayoría de los mecanismos que rigen el desarrollo y organización de los órganos linfoides secundarios han sido descubiertos en la década pasada y, ayudan a concluir que las interacciones celulares y moleculares específicas para el desarrollo y organización de los órganos linfoides secundarios son ligeramente diferentes y reflejan probablemente la presencia de poblaciones celulares específicas en un lugar y tiempo adecuados. En esta revisión se discuten los mecanismos involucrados en el desarrollo, organización y función de tejidos linfoides locales del tracto respiratorio, incluidos el tejido linfoide asociado a la nariz (NALT) y el tejido linfoide inducible asociado al bronquio (iBALT)

Secondary lymphoid organs are strategically placed to recruit locally activated antigen presenting cells (APCs) as well as naïve, recirculating T and B cells. The structure of secondary lymphoid organs - separated B and T zones, populations of specialized stromal cells, high endothelial venules and lymphatic vessels - has also evolved to maximize encounters between APCs and lymphocytes and to facilitate the expansion and differentiation of antigen- stimulated T and B cells. Many of the general mechanisms that govern the development and organization of secondary lymphoid organs have been identified over the last decade. However, the specific cellular and molecular interactions involved in the development and organization of each secondary lymphoid organ are slightly different and probably reflect the cell types available at that time and location. Here we review the mechanisms involved in the development, organization and function of local lymphoid tissues in the respiratory tract, including Nasal Associated Lymphoid Tissue (NALT) and inducible Bronchus Associated Lymphoid Tissue (iBALT)

Cyclic ADP-ribose production by CD38 regulates intracellular calcium release, extracellular calcium influx and chemotaxis in neutrophils and is required for bacterial clearance in vivo.

Cyclic ADP-ribose is believed to be an important calcium-mobilizing second messenger in invertebrate, mammalian and plant cells. CD38, the best-characterized mammalian ADP-ribosyl cyclase, is postulated to be an important source of cyclic ADP-ribose in vivo. Using CD38-deficient mice, we demonstrate that the loss of CD38 renders mice susceptible to bacterial infections due to an inability of CD38-deficient neutrophils to directionally migrate to the site of infection. Furthermore, we show that cyclic ADP-ribose can directly induce intracellular Ca++ release in neutrophils and is required for sustained extracellular Ca++ influx in neutrophils that have been stimulated by the bacterial chemoattractant, formyl-methionyl-leucyl-phenylalanine (fMLP). Finally, we demonstrate that neutrophil chemotaxis to fMLP is dependent on Ca++ mobilization mediated by cyclic ADP-ribose. Thus, CD38 controls neutrophil chemotaxis to bacterial chemoattractants through its production of cyclic ADP-ribose, and acts as a critical regulator of inflammation and innate immune responses.

Cyclophosphamide/granulocyte colony-stimulating factor causes selective mobilization of bone marrow hematopoietic stem cells into the blood after M phase of the cell cycle.

Cytokine-mobilized peripheral blood hematopoietic stem cells (MPB HSC) are widely used for transplantation in the treatment of malignancies, but the mechanism of HSC mobilization is unclear. Although many HSC in bone marrow (BM) cycle rapidly and expand their numbers in response to cytoreductive agents, such as cyclophosphamide (CY), and cytokines, such as granulocyte colony-stimulating factor (G-CSF), MPB HSC are almost all in the G(0) or G(1) phase of the cell cycle. This has raised the question of whether a subset of noncycling BM HSC is selectively released, or whether cycling BM HSC are mobilized after M phase, but before the next S phase of the cell cycle. To distinguish between these possibilities, mice were treated with one dose of CY followed by daily doses of G-CSF, and dividing cells were marked by administration of bromodeoxyuridine (BrdU) during the interval that BM HSC are expanding. After CY and 4 days of G-CSF, 98.5% of the 2n DNA content long-term repopulating MPB (LT)-HSC stained positively for BrdU, and therefore derived from cells that divided during the treatment interval. Next, LT-HSC from mice previously treated with a single dose of CY, which kills cycling cells, and 3 daily doses of G-CSF, were nearly all killed by a second dose of CY, suggesting that CY/G-CSF causes virtually all LT-HSC to cycle. Analysis of cyclin D2 messenger RNA (mRNA) expression and total RNA content of MPB HSC suggests that these cells are mostly in G(1) phase. After CY/G-CSF treatment, virtually all BM LT-HSC enter the cell cycle; some of these HSC then migrate into the blood, specifically after M phase, and are rapidly recruited to particular hematopoietic organs.

Transfer of primitive stem/progenitor bone marrow cells from LT alpha-/- donors to wild-type hosts: implications for the generation of architectural events in lymphoid B cell domains.

To analyze whether the phenotypic abnormalities observed in lymphotoxin-alpha(-/-) (LT alpha-/-) mice are intrinsic to the hemolymphoid system itself or dependent on stromal elements, wild-type (WT) mice were reconstituted with bone marrow (BM) cells enriched for hemopoietic stem cells from LT alpha-/- animals. WT mice reconstituted with LT alpha-/- c-kit+ Lin- Sca-1+ BM cells do not maintain follicular dendritic cell (FDC) networks and do not form primary follicles, while clear segregation of B and T cells could be observed. Furthermore, IgM+ IgD- B cells, MOMA-1 (anti-metallophilic macrophages), ERTR-9 (anti-marginal zone macrophages), and MECA-367 (anti-MAdCAM-1) were all absent from the splenic marginal zone. Surprisingly, however, the expression of MOMA-1, ERTR-9, and MAdCAM-1 was normal in the lymph nodes of mice reconstituted with LT alpha-/- cells. In addition, peanut agglutinin-positive germinal centers were observed in both the spleen and mesenteric lymph nodes, although in the absence of detectable FDC. Furthermore, in animals reconstituted with a mixture of LT alpha-/- and WT c-kit+ Lin- Sca-1+, GC contained either predominantly LT alpha-/- B cells or WT B cells. These results suggest that although the formation of primary follicles, FDC networks, and the splenic marginal zone are all dependent on hemopoietically derived LT alpha, germinal center formation and the expression of MAdCAM-1, MOMA-1, and ERTR-9 in lymph nodes are not. Our results also suggest that the disturbed B-T cell separation in LT alpha-/- mice is unrelated to defects in the marginal zone.

Mice deficient for the ecto-nicotinamide adenine dinucleotide glycohydrolase CD38 exhibit altered humoral immune responses.

CD38 is a membrane-associated ecto-nicotinamide adenine dinucleotide (NAD+) glycohydrolase that is expressed on multiple hematopoietic cells. The extracellular domain of CD38 can mediate the catalysis of NAD+ to cyclic adenosine diphosphoribose (cADPR), a Ca2+-mobilizing second messenger, adenosine diphosphoribose (ADPR), and nicotinamide. In addition to its enzymatic properties, murine CD38 has been shown to act as a B-cell coreceptor capable of modulating signals through the B-cell antigen receptor. To investigate the in vivo physiological function(s) of this novel class of ectoenzyme we generated mice carrying a null mutation in the CD38 gene. CD38-/- mice showed a complete loss of tissue-associated NAD+ glycohydrolase activity, showing that the classical NAD+ glycohydrolases and CD38 are likely identical. Although murine CD38 is expressed on hematopoietic stem cells as well as on committed progenitors, we show that CD38 is not required for hematopoiesis or lymphopoiesis. However, CD38-/- mice did exhibit marked deficiencies in antibody responses to T-cell-dependent protein antigens and augmented antibody responses to at least one T-cell-independent type 2 polysaccharide antigen. These data suggest that CD38 may play an important role in vivo in regulating humoral immune responses.

Arrest of B lymphocyte terminal differentiation by CD40 signaling: mechanism for lack of antibody-secreting cells in germinal centers.

Despite extensive research, the role of CD40 signaling in B cell terminal differentiation remains controversial. Here we show that CD40 engagement arrests B cell differentiation prior to plasma cell formation. This arrest is manifested at a molecular level as a reduction in mRNA levels of secretory immunoglobulin gene products such as mu(s) and J chain as well as the loss of the transcriptional regulator BLIMP-1. Furthermore, the inhibition of B cell differentiation by CD40 engagement could not be overcome by either mitogens or cytokines, but could be reversed by antibodies that interfere with the CD40/gp39 interaction. These data suggest that secretory immunoglobulin is not produced by B cells that are actively engaged by gp39-expressing T cells.

CD38: a new paradigm in lymphocyte activation and signal transduction.

CD38 is a type II transmembrane glycoprotein that is extensively expressed on cells of hematopoietic and non-hematopoietic lineage. Although the intracellular domain of CD38 is not homologous to any known proteins, the extracellular domain of CD38 is structurally related to enzymes in the ADP-ribosyl cyclase family. The structural homology between CD38 and the cyclase family members extends to functional homology, as the extracellular domain of CD38 can mediate the catalysis of beta-NAD+ into nicotinamide, ADP-ribose (ADPR) and, to a lesser extent, into cyclic ADPR-ribose (cADPR). Extensive investigation in other systems has shown that cADPR is an important regulator of intracellular Ca2+ release. Since engagement of CD38 on hematopoietic cells with anti-CD38 Abs has been shown to have potent effects on a number of in vitro cellular responses, we have speculated that cADPR might control CD38-mediated signal transduction. However, it has been difficult to understand how a mediator which is typically an intracellular signaling molecule could potentiate its effects from an extracellular location, thus posing a dilemma which pertains to all ecto-enzymes and the mechanisms by which they regulate signal transduction and cellular processes. This review describes the biologic properties of murine CD38, its role in humoral immunity, and its signal transduction properties in B lymphocytes. We suggest that signaling through CD38 represents a new paradigm in lymphocyte signal transduction and is predicated upon extracellular, rather than intracellular, crosstalk.

Characterization of a population of cells in the bone marrow that phenotypically mimics hematopoietic stem cells: resting stem cells or mystery population?

We have identified a population of cells in murine bone marrow that has many of the phenotypic characteristics attributed to resting hematopoietic stem cells but does not reconstitute irradiated mice. These cells express high levels of Sca-1, H-2K and CD38 and low levels of Thy-1.1, but do not express CD34 nor any of the lineage markers including CD3, CD4, CD5, CD8 NK1.1, I-A, B220, Ig(MGA), CD40, kappa, Mac-1, Gr-1 or Ter119. In addition, this population can be found at normal frequency in nu/nu as well as rag-1-/- mice. These cells incorporate only low levels of Rh123, are resistant to the cytotoxic effects of 5-fluorouracil and, consistent with their resting phenotype, less than 2% of these cells are in the S/G2/M phases of the cell cycle. The only phenotypic characteristic that distinguishes these cells from the lineage- Sca-1+, Thy-1.1low long-term reconstituting hematopoietic stem cell population is their lack of c-kit expression. Here we have explored the possibility that these cells represent a truly resting population of hematopoietic stem cells. We found that the lineage-, Sca-1+, c-kit- cells do not respond to hematopoietic growth factors in vitro, either alone or in combination with stromal layers. Furthermore, these cells do not form in vivo spleen colonies nor do they have the ability to reconstitute irradiated mice. Thus, this population may represent either a population of resting stem cells for which we lack the appropriate activating stimulus, or simply represent a "mystery population" that phenotypically mimics most of the physical properties of resting stem cells. Given the close phenotypic similarity of the c-kit- mystery population cells to the c-kit+ long-term reconstituting stem cells, investigators must be rigorous to exclude their effects from other stem cell assays.

Phenotypic and functional changes induced at the clonal level in hematopoietic stem cells after 5-fluorouracil treatment.

A significant fraction of hematopoietic stem cells (HSCs) have been shown to be resistant to the effects of cytotoxic agents such as 5-fluorouracil (5-FU), which is thought to eliminate many of the rapidly dividing, more committed progenitors in the bone marrow and to provide a relatively enriched population of the most primitive hematopoietic progenitor cells. Although differences between 5-FU-enriched progenitor populations and those from normal bone marrow have been described, it remained unclear if these differences reflected characteristics of the most primitive stem cells that were revealed by 5-FU, or if there were changes in the stem-cell population itself. Here, we have examined some of the properties of the stem cells in the bone marrow before and after 5-FU treatment and have defined several activation-related changes in the stem-cell population. We found that long-term reconstituting stem cells decrease their expression of the growth factor receptor c-kit by 10-fold and increase their expression of the integrin Mac-1 (CD11b). These changes begin as early as 24 hours after 5-FU treatment and are most pronounced within 2 to 3 days. This activated phenotype of HSCs isolated from 5-FU-treated mice is similar to the phenotype of stem cells found in the fetal liver and to the phenotype of transiently repopulating progenitors in normal bone marrow. We found that cell cycle is induced concomitantly with these physical changes, and within 2 days as many as 29% of the stem-cell population is in the S/G2/M phases of the cell cycle. Furthermore, when examined at a clonal level, we found that 5-FU did not appear to eliminate many of the transient, multipotent progenitors from the bone marrow that were found to be copurified with long-term repopulating, activated stem cells. These results demonstrate the sensitivity of the hematopoietic system to changes in its homeostasis and correlate the expression of several important surface molecules with the activation state of HSCs.

Expression of murine CD38 defines a population of long-term reconstituting hematopoietic stem cells.

Using a monoclonal antibody to murine CD38, we showed that a population of adult bone marrow cells that expressed the markers Sca-1 and c-kit but lacked the lineage markers Mac-1, GR-1, B220, IgM, CD3, CD4, CD8 and CD5 could be subdivided by the expression of CD38. We showed that CD38high c-kit+ Sca-1+, linlow/-cells sorted from adult bone marrow cultured with interleukin-3 (IL-3), IL-6, and kit-L produced much larger colonies in liquid culture at a greater frequency than their CD38low/- counterparts. In addition, we found that CD36low/ - cells contained most of the day-12 colony-forming units-spleen (CFU-S) but were not long-term reconstituting cells, whereas the population that expressed higher levels of CD38 contained few, but significant, day-12 CFU-S and virtually all the long-term reconstituting stem cells. Interestingly, the CD38high Sca-1+ c-kit+ linlow/- cells isolated from day-E14.5 fetal liver were also found to be long-term reconstituting stem cells. This is in striking contrast to human hematopoietic progenitors in which the most primitive hematopoietic cells from fetal tissues lack the expression of CD38. Furthermore, because antibodies to CD38 could functionally replace antibodies to Thy-1.1 in a stem cell purification procedure, the use of anti-CD38 may be more generally applicable to the purification of hematopoietic stem cells from mouse strains that do not express the Thy-1.1 allele.

Mechanism and subcellular localization of secretory IgM polymer assembly.

The predominant functions of secreted IgM, complement fixation and transcytosis across epithelial barriers via the poly(Ig) receptor, are properties of IgM polymers; thus, the mechanisms that regulate oligomerization are critical to immune function. We have developed methods to assess the mechanism and subcellular location of IgM polymer formation. Using denaturing agarose/SDS-polyacrylamide gel electrophoresis and sucrose gradient fractionation, we demonstrate that IgM polymers are assembled in a stepwise fashion in which primary intermediates, including heavy chain-light chain complexes, are sequentially incorporated. Assembly intermediates include both covalent and non-covalent components, suggesting that IgM subunit interactions precede covalent assembly. IgM polymers are assembled from primary intermediates containing immature N-linked oligosaccharides. Polymerization is insensitive to brefeldin A and occurs at temperatures that inhibit protein transport along the secretory pathway. Together, these data demonstrate that IgM polymerization occurs early in the secretory pathway, most likely in the endoplasmic reticulum. These results are consistent with a model in which secretory IgM represents an oligomeric protein that is retained in the endoplasmic reticulum and does not mature along the secretory pathway until complete assembly is achieved.

IgM hexamers?

There has been a universal tendency to regard IgM antibodies as pentameric molecules comprising five immunoglobulin monomeric subunits joined by a single J-chain protein. Is this the only form of secreted IgM, or are the possibilities more complex? In this article, Joseph Brewer and colleagues propose that the IgM polymers secreted in primary immune responses may be more heterogeneous than previously believed and that, as a consequence, the biological activity of IgM may have considerable flexibility.

Interleukin-5 (IL-5) and IL-6 define two molecularly distinct pathways of B-cell differentiation.

Interleukin-5 (IL-5) and IL-6 have both been reported to act as B-cell differentiation factors by stimulating activated B cells to secrete antibody. However, it has not been possible to directly compare the effects of these two lymphokines because of the lack of a suitable B-cell line capable of responding to both. We have identified a clonal, inducible B-cell lymphoma, CH12, that has this property. Both IL-5 and IL-6 can independently stimulate increases in steady-state levels of immunoglobulin and J-chain mRNA and proteins, and they both induce the differentiation of CH12 into high-rate antibody-secreting cells. Nevertheless, there are significant differences in the activities of these two lymphokines. First, while IL-6 acts only as a differentiation factor, IL-5 also augments the proliferation of CH12 cells. Second, the differentiation stimulated by IL-5 but not by IL-6 is partially inhibited by IL-4. Inhibition of IL-5-induced differentiation was not at the level of IL-5 receptor expression, since IL-4 did not inhibit IL-5-induced proliferation. Third, IL-5 but not IL-6 stimulated increased mouse mammary tumor proviral gene expression in CH12 cells. These results demonstrate that while both IL-5 and IL-6 may act as differentiation factors for B cells, they induce differentiation by using at least partially distinct molecular pathways. Our results also establish that B cells characteristic of a single stage of development can independently respond to IL-4, IL-5, and IL-6.

MHC class II limits the functional expression of endogenous superantigens in B cells.

The open reading frames of the 3' long terminal repeat of mouse mammary tumor viruses (MMTV) encode superantigens. When expressed with MHC class II molecules on the surface of B cells, superantigens stimulate T cells expressing receptors with particular V beta elements. By using B cell lymphomas as model systems, we demonstrate that stimuli, including certain lymphokines (IL-2 and IL-5) and LPS, that lead to increased MMTV transcript levels in B cells did not increase functional superantigen presentation. Furthermore, stimulation of BCL1 and CH12 cells with LPS resulted in a pronounced reduction in superantigen presentation, even though MMTV transcript levels were increased. In contrast to these effects, functional superantigen expression was increased under conditions in which class II levels were increased, even when MMTV levels remained constant, indicating that the levels of newly synthesized class II are important for functional superantigen expression. These data together imply that the amount of cell surface class II limits superantigen presentation and/or that superantigens can associate only with a limited pool of class II.

Mouse mammary tumor proviral gene expression in cells of the B lineage.

Mouse mammary tumor proviruses (MMTV) use a common enhancer/promoter region to accommodate their transcription in two different cellular environments. In mammary tissue, transcription is regulated through the hormone response element located in the 5' LTR. In B cells, transcription is hormone independent, can be stimulated following B cell activation, and is distinct from the transcription of other known inducible genes, including immunoglobulin. The open reading frame (ORF) in the viral 3' LTR has at least two functions. Its gene product(s) acts as a viral superantigen, but also has autoregulatory properties, leading to MMTV transactivation. We propose a scheme suggesting that MMTV evolved to use the B cell as an intermediary in its viral life cycle.

Direct evidence that J chain regulates the polymeric structure of IgM in antibody-secreting B cells.

IgM is secreted in two functional polymeric forms. Secreted IgM was originally thought to be exclusively a pentameric molecule containing J (joining) chain, but many B cells also secrete hexameric IgM lacking J chain. Hexameric IgM may play an important role in the immune system, since it is up to 20 times more active than pentameric IgM in initiating the complement cascade. The predominant polymeric form of IgM secreted by B cell lines, either pentameric or hexameric, correlates with the concentration of J chain present during polymerization, and cells that express high levels of J chain secrete mostly IgM pentamers. The B cell lymphoma WEHI-231 does not express J chain, and the majority of its secreted IgM is polymerized as hexamers. When a J chain-encoding cDNA was expressed in these cells, the secreted IgM was found to be almost exclusively pentameric. However, although the expression of J chain dramatically altered the phenotype of the IgM secreted by these cells, it had little effect on their secretory rate. We conclude that J chain regulates the structure and function of the IgM polymers secreted by B cells, but it is not necessary for either IgM polymerization or secretion.

J chain synthesis and secretion of hexameric IgM is differentially regulated by lipopolysaccharide and interleukin 5.

Two functional polymeric forms of IgM can be produced by antibody-secreting B cells. Hexameric IgM lacks detectable J (joining) chain and activates complement 17-fold better than pentameric IgM, which usually contains one J chain per pentamer. Using the inducible B-cell lymphoma CH12, we determined if the synthesis of a particular polymeric form of IgM is a fixed property of B cells or can be altered. Lipopolysaccharide (LPS)-stimulated CH12 cells produced mixtures of IgM hexamers and pentamers, resulting in antibody with high complement-fixing activity. In contrast, interleukin-5-stimulated CH12 cells secreted predominantly pentameric IgM, with a correspondingly lower lytic activity. Differences in lytic activity were due only to the amount of hexameric IgM in the secreted antibody. Interleukin 5 stimulated higher production of J chain RNA and protein than LPS, while LPS induced the highest levels of the secretory form of mu protein. The amount of hexameric IgM secreted was therefore inversely proportional to the level of intracellular J chain protein in the responding B cells. We conclude that the biologic function of IgM produced by B cells differs depending on how they are stimulated and that this difference may be regulated by the relative availabilities of J chain and secretory mu proteins during IgM polymerization.