A lipopolysaccharide-induced DNA-binding protein for a class II gene in B cells is distinct from NF-kappa B.

Class II (Ia) major histocompatibility complex molecules are cell surface proteins normally expressed by a limited subset of cells of the immune system. These molecules regulate the activation of T cells and are required for the presentation of antigens and the initiation of immune responses. The expression of Ia in B cells is determined by both the developmental stage of the B cell and by certain external stimuli. It has been demonstrated previously that treatment of B cells with lipopolysaccharide (LPS) results in increased surface expression of Ia protein. However, we have confirmed that LPS treatment results in a significant decrease in mRNA encoding the Ia proteins which persists for at least 18 h. Within the upstream regulatory region of A alpha k, an NF-kappa B-like binding site is present. We have identified an LPS-induced DNA-binding protein in extracts from athymic mice whose spleens consist predominantly of B cells. Binding activity is present in low levels in unstimulated spleen cells and is increased by LPS treatment. This protein binds to two sites in a regulatory region of the Ia A alpha k gene, one of which contains the NF-kappa B-like binding site. DNA fragments containing these sites cross-compete for protein binding. Analysis by DNase I footprinting identified a target binding sequence, named the LPS-responsive element. Although this target sequence contains an NF-kappa B-like binding site, competition with a mutant oligonucleotide demonstrated that bases critical for NF-kappa B binding are not required for binding of the LPS-inducible protein. Therefore, we hypothesized that this inducible protein represents a new mediator of LPS action, distinct from NF-kappa B, and may be one mechanism to account for the decrease in mRNA encoding the Ia proteins.     

Three classes of signalling molecules on B-cell membranes

The question of whether surface immunoglobulin and Ia molecules have a signalling function in helper T cell-dependent activation of B cells has been evaluated. Two sources of B cells have been used, one a purified population of hapten-binding B cells, the other a B-cell lymphoma, CH12, with known antigen specificity. Evidence is presented that both immunoglobulin and Ia molecules are receptors actively involved in the initial activation of resting B cells. Nevertheless, the requirements for ligand binding to either receptor can be bypassed under appropriate conditions, and the implications of this result for the function of these molecules is discussed. With respect to B-cell Ia, the authors present data that demonstrate two distinct functions of this molecule, one as a restricting element for T-cell activation, the second as a signalling receptor for B-cell excitation. On the CH12 surface, the I-A molecule fulfills the former function, but T-cell interactions with I-A fail to result in B-cell stimulation, suggesting that B-cell Ia may limit helper T cell-B cell interactions. We suggest that the binding of antigen surface immunoglobulin and binding of helper T-cell receptors to the appropriate Ia molecule(s) results in the activation of genes that encode for a third class of membrane B-cell receptors, those that bind B-cell stimulating factors.     

Presentation of antigen by B cells: functional dependence on radiation dose, interleukins, cellular activation, and differential glycosylation

Whether resting B cells can present antigen to T cells is controversial. Several factors can influence the outcome of an assessment of the presenting function of resting B cells: the method of purifying resting B cells and maintaining them in culture without altering their resting state, the sensitivity of resting B cells to gamma-irradiation, the activation state of the T cells used to assess presenting function, and the requirement for exogenous interleukin 1. We have examined all of these variables and find that one adherent antigen-presenting cell is functionally equivalent to four LPS-activated B cells and to 1000 resting B cells. In addition, we have examined the potential functional relevance of the differential glycosylation of Ia molecules on resting B cells compared with adherent antigen-presenting cells. Altering the surface glycosylation of resting B cells by neuraminidase treatment results in a 25-fold increase in B cell antigen presentation without altering their resting state. More important, among antigen-presenting cells the effect of neuraminidase is limited to resting B cells. It also appears to involve a restricting element such as the Ia molecule rather than total cell surface charge, because neuraminidase treatment has no effect on the capacity of resting B cells to serve as accessory cells in the Con A response.     

Inducer T-cell-mediated killing of antigen-presenting cells

L3T4+ inducer/helper T-cell clones, once activated by antigen-presenting cells (APC) expressing the appropriate Ia allele and antigen, autonomously kill their target APC. All 13 L3T4+ inducer T-cell clones tested demonstrated this cytolytic activity. In addition, 11 different target cells representing the three major APC types, namely, macrophages, B cells, and dendritic cells, were all sensitive to this cytolytic activity. Moreover, normal macrophages which were treated with interferon-gamma to increase Ia expression were also killed. These observations convincingly demonstrate that the cytolytic activity of L3T4+ inducer T-cell clones is a general phenomenon. In contrast to other reports, lysis of target APC could not be detected following 4-6 hr of incubation. Marginal lysis was observed after 9 hr and a 20-hr incubation period was required to achieve maximal killing. The kinetics of killing paralleled other parameters of T-cell activation such as IL-2 release and cell proliferation. Activation of T cells for cytolysis of APC requires the interaction of T-cell receptors with Ia and antigen. Monoclonal antibody to Ia, L3T4 and the T-cell receptor inhibited the cytolysis of APC. The ability to mediate nonspecific bystander killing was variable depending on both the T-cell clone and the target. The implications of these findings to immune regulation and autoimmunity are discussed.     

Interleukin 4 enhances the ability of antigen-specific B cells to form conjugates with T cells

T cell-B cell conjugates are formed when trinitrophenyl-specific B cells are exposed to trinitrophenyl-ovalbumin and ovalbumin-specific T hybridoma cells. The proportion of conjugates was increased two- to threefold when antigen-pulsed trinitrophenyl-specific B cells, but not T cells, were pre-exposed to interleukin 4. Antigen-specific B cells pretreated with antigen and interleukin 4 and cultured in the presence of specific T helper cells also produced a larger proportion of antibody-secreting cells as compared to cells pretreated with antigen alone. The interleukin 4-induced enhancement of T/B conjugate formation occurred over a wide range of antigen concentrations, was dependent on the concentration of interleukin 4, and was inhibited by the monoclonal anti-interleukin 4 antibody, 11B11. The importance of Ia antigens in the enhancement of conjugate formation and generation of antibody-secreting cells is suggested by a) the fact that the interleukin 4-mediated increase in the density of Ia antigens on the antigen-specific B cells correlated with their enhanced ability to form T/B conjugates, b) the kinetics of the interleukin 4-mediated increase in conjugate formation and surface Ia expression were similar, c) 10- to 20-fold higher concentrations of anti-I-A antibody were required to inhibit T/B conjugate formation by 50% with interleukin 4-treated antigen-specific B cells compared with untreated antigen-specific B cells, and d) interferon-gamma, which inhibits the interleukin 4-mediated increase in Ia antigens, inhibited the interleukin 4-induced enhancement of T/B conjugate formation. These results indicate that the interleukin 4-induced increase in the expression of Ia antigens on B cells plays an important role in the enhancement of T/B cell interactions and the subsequent differentiation of antigen-specific B cells into antibody-secreting cells.     

MLC-derived human helper factor(s) that promote B cell differentiation: induction, functional characterization, and role of Ia antigens

Utilizing a PFC assay to quantitate the polyclonal activation of human peripheral blood B lymphocytes, we have investigated the induction and functional activity of MLC-derived human helper factor(s). Our data demonstrate that highly purified responder T cells, but not B or null cells, are required for the elaboration of MLC helper factor(s) that trigger the in vitro differentiation of B lymphocytes into PFC. Helper factor can trigger B cell maturation in the absence of helper T cells, since complement- (C) mediated lysis of the small (less than 5%) fraction of T cells present in anti-F(ab)2 immunoabsorbent column purified B cell population eliminates the PWM induced, but not the helper factor-induced PFC response. Responder T cells required for helper factor production do not bear surface membrane Ia, since alpha p23,30 + C treatment of this population does not affect helper factor generation. In contrast, alpha p23,30 + C treatment of the allogeneic stimulator cell population eliminates helper factor production. Taken together, these results demonstrate that interaction between Ia-bearing stimulator cells and Ia- responder T cells is required for the production of MLC-derived helper factor. In additional experiments, we determined that alpha p23,30, in the absence of C, totally abrogates the PFC response triggered by MLC helper factors. This result suggests an important role for Ia antigens in the functional activity of preformed helper factor molecules.     

MHC-chromosome dosage effects: evidence for increased expression of Ia glycoprotein and alteration of B cell subpopulations in neonatal aneuploid chickens

Quantitative variation in the expression of MHC-encoded class II (Ia) glycoproteins has been associated with stages of lymphocyte development and a number of disease conditions. We have used an avian MHC dosage model to study the regulation of Ia expression and the effects of quantitative variation in membrane Ia on B-cell development. Lymphocyte membrane expression of Ia glycoprotein molecules and the frequency of small-versus-large lymphocytes were examined in trisomic line chickens containing either two (disomic), three (trisomic), or four (tetrasomic) copies of the microchromosome encoding the MHC. This was accomplished by quantitative laser flow cytometry analysis of bursa-resident B lymphocytes from neonatal trisomic line chickens. The aneuploids (trisomics and tetrasomics) expressed more cell surface Ia than did normal disomic birds. Furthermore, the aneuploids exhibited a greater frequency of small B lymphocytes as compared to disomic chickens. Dual parameter analysis of Ia. quantity and cell size was undertaken to study B lymphocyte subpopulations in these birds. It was observed that the aneuploids had altered frequencies of two distinct subpopulations of cells: (1) an increased percentage of small cells which express high levels of Ia antigen and (2) a decreased percentage of large cells which express medium levels of Ia antigen. These findings support the view that MHC class II genes are regulated and expressed in a dosage-dependent manner. Therefore, increases in the number of MHC copies per cell result in the increased expression of Ia glycoprotein on bursa-resident B cells. The stepwise increase in membrane Ia on trisomic and tetrasomic B cells is correlated, and perhaps casually linked, with progressive degrees of alteration of developing B cell subpopulations in the bursa of aneuploid chicks. These events may ultimately alter the humoral immunity of the aneuploid animals.     

Modeling of T cell contact-dependent B cell activation. IL-4 and antigen receptor ligation primes quiescent B cells to mobilize calcium in response to Ia cross-linking.

The generation of antibody secretory cells from resting B lymphocytes after immunization with most protein Ag requires B cell signaling by Ag, direct Th cell contact and lymphokines. Previous studies suggest that cell contact-mediated signals may be transduced by Ia after Ia binding by alpha beta TCR and/or CD4. Seemingly inconsistent with this concept are findings that cross-linking of Ia molecules on quiescent B cells leads to cAMP generation that is antagonistic for B cell mitogenesis. Here we show that ligand binding to IL-4 and Ag receptors on quiescent B cells induce transition of these cells into a competent state in which Ia molecules transduce signals via a distinct mechanism. This mechanism involves the tyrosine kinase-dependent activation of phospholipase C leading to Ca2+ mobilization from intracellular stores and the extracellular space. This competence, which is seen within 4 h of priming, is not simply a function of increased Ia expression by the B cell because the response can be induced by cross-linking of less than 5% of cell surface Ia molecules on primed cells. Finally, cross-linking of Ia molecules leads to more than fivefold greater increase in [Ca2+]i than is induced by membrane Ig ligation. These findings are consistent with alpha beta TCR/CD4 delivery via Ia of proliferative signals mediated by tyrosine kinase activation, phosphoinositide hydrolysis and Ca2+ mobilization.     

T lymphocyte heterogeneity in the rat. III. Autoreactive T cells are activated by B cells

Evidence has been presented to show that CD4+ autoreactive T cell lines (ATs)2 in the rat require periodic stimulation with syngeneic spleen cells for in vitro proliferation. This proliferation can be blocked by treatment of the stimulator (spleen) cells with mAb to Ia antigens. Although ATs are Ia+ and can activate the allogeneic MLR, they fail to be autostimulatory. Fractionation of the spleen cells revealed that ATs can be stimulated with B cells and not by macrophages, although the latter were efficient in several accessory cell functions, including antigen presentation, lectin-dependent T cell activation and allogenic MLR response. Moreover, B cells proliferated and differentiated in response to AT cells. These data are compatible with a model in which ATs respond to hitherto undetermined B cell membrane antigen(s) in association with MHC class II antigens. These results may have important implications in understanding autoimmune responses.     

Gene transfer of H-2 class II genes: antigen presentation by mouse fibroblast and hamster B-cell lines

We have transferred the mouse Ak alpha and Ak beta genes, which encode the class II I-Ak molecule, into mouse L-cell fibroblasts and hamster B cells. I-Ak molecules are expressed on the surface of both cell types. The L-cell and hamster B-cell I-Ak molecules appear normal by serological analyses and two-dimensional gel electrophoresis. Furthermore, the I-Ak molecules on L cells can act as targets for the allogenic T-cell killing of the transformed L cells. The I-Ak molecules in both mouse fibroblasts and hamster B cells can present certain antigens to T-cell helper hybridomas. Thus only class II molecules are required to convert the nonantigen-presenting cell. Accordingly, it will be possible to dissect the structure-function relationships existing between Ia molecules, foreign antigen, and T-cell receptor molecules by in vitro site-directed mutagenesis and gene transfer.     

Immunogenic peptides require an undisturbed phospholipid cell membrane environment and must be amphipathic to immobilize Ia on B cells

Ia-reactive immunogenic peptides have been shown to immobilize Ia molecules on the B cell surface and to facilitate their aggregation with specific alloantibody. We show that to immobilize Ia the peptide must be amphipathic. Polar peptides appear to bind to Ia molecules as judged by competitive inhibition, but do not immobilize the MHC molecule. This suggests the possibility that peptides establish the immobilizing membrane contact via a lipophilic group. Examining the B cell membrane lipid environment, we found that treatment of B cells with phospholipase C prevents peptide-mediated immobilization of Ia. The requirement of a lipophilic peptide portion as well as of phospholipase-sensitive membrane components for effective peptide-mediated Ia aggregation on B cell membranes suggests a role for membrane phospholipids in this process. We advance the speculation that immunodominant amphipathic peptides immobilize Ia molecules by attaching them to cell surface phospholipids which we tentatively refer to as immobilizing phospholipids.     

Studies of in vitro activation and differentiation of human B lymphocytes. I. Phenotypic and functional characterization of the B cell population responding to anti-Ig antibody

Investigation of the activation of splenic B cells by anti-immunoglobulin (Ig) antibody has enabled us to characterize the anti-Ig-responsive B cell and to analyze the phenotypic changes which accompany proliferation and differentiation. The anti-Ig antibody-responsive B cell population was characterized by the expression of high levels of the B2 antigen and represented approximately 40% of splenic B cells. Brisk mitogenesis which peaked at 3 to 4 days was induced by anti-Ig antibody. The proliferative phase was characterized phenotypically by a dramatic decline in B2 antigen expression, with most cells showing no detectable B2 by 4 days post-activation. The other hallmark of this phase was de novo expression of a group of "activation antigens." These included the B cell-restricted antigens B-LAST 1, BB1, and B5, and the T cell-associated interleukin 2 receptor and T12 antigens. Concomitantly, B1, B4, and Ia expression increased, the increase being roughly proportional to the increase in cell size. After day 4, the mitogenic response progressively diminished, while Ig synthesis increased. During this differentiation phase, cell surface antigens again displayed a distinct sequence of changes. The five activation antigens and the B1, B4, and Ia antigens began to decrease. However, two markers, T10 and PCA-1, which are found on plasmacytomas, appeared and their level of expression steadily increased. These changes and the appearance of morphologically identifiable plasma cells required the presence of T cells in this system. T cell supernatants alone induced Ig secretion but did not induce expression of PCA-1 or the appearance of cells with plasma cell morphology. The culture system developed in this study has allowed us to analyze the antigenic changes following activation by anti-Ig antibody. This sequence of changes has not only permitted the identification of antigens which, by their appearance at distinct stages may have an important role in proliferation and differentiation of B cells, but also provides us with the means of studying the function of each antigen.     

Functional studies on B cell hybridomas with B cell surface antigens. I. Effects of anti-immunoglobulin antibodies on proliferation and differentiation

B cell hybridomas with Ia and IgM molecules on the cell membrane were treated with either purified goat anti-mouse mu antibody (anti-mu) or monoclonal rat anti-mouse IgM antibody (anti-IgM). The spontaneous uptake of [3H] thymidine by these cells was markedly inhibited by both reagents. These hybrid cells could be induced to differentiate into IgM-secreting cells in the presence of these reagents at high frequency. Furthermore, the induction of IgM secretion by B cell hybridomas treated with these antibodies was completely T cell independent, and cell division was not required for the differentiative response to anti-mu. In addition, F(ab')2 fragments of anti-mu showed more effects on proliferation and differentiation of these cells than intact anti-mu. Interestingly, TH2.54, a subline of B cell hybridomas, could generate IgG2a production as well as IgM when incubated with anti-mu. These findings suggest very strongly that the interaction of either goat anti-mu or monoclonal rat anti-IgM with surface IgM molecules on the cell membrane of the B cell hybridomas inhibits in vitro spontaneous proliferation, and results in providing signals for differentiation into Ig-secreting cells without T cell factors.     

Polyclonal B cell activation by B cell differentiation factor B151-TRF2. I. Involvement of self-Ia recognition process mediated by B cells

The present study examined the functional role of Ia antigens on B cells in polyclonal B cell activation induced by a B cell differentiation factor, B151-TRF2. The polyclonal IgM PFC responses by B151-TRF2 were inhibited by monoclonal antibodies specific for class II MHC antigens (Ia antigens) but not class I MHC antigens. Such inhibition by anti-Ia antibodies was haplotype-specific and was observed in the absence of both T cells and accessory cells. Moreover, the anti-Ia antibody-induced inhibition of the B151-TRF2 responses was not due to the blocking of binding of B151-TRF2 to the corresponding B cell receptor. A series of kinetic studies revealed that some Ia-mediated cellular activation process occurs before the resting B cells become responsive to B151-TRF2. Thus, the B151-TRF2-mediated B cell responses consist of at least two distinct phases. The early phase is an Ia-dependent but B151-TRF2-independent process, whereas the late phase is an Ia-independent but B151-TRF2-dependent process. To further characterize the functional role of Ia antigens on B cells, an additional experiment was carried out by using F1 B cells which co-dominantly express both parental Ia antigens on the surface. Interestingly, it was observed that the degree of inhibition of the B151-TRF2-mediated responses of F1 B cells by anti-parental Ia antibody was, at best, one-half that of the parental B cells, suggesting that F1 B cells may be separated into two subpopulations with the restriction specificity for the respective parental Ia antigens. To examine this possibility, (B10 X B10.BR)F1 B cells were separated into adherent and nonadherent cell populations by their ability to bind to either one of the parental B cell monolayers, and the specificity of inhibition of their responses to B151-TRF2 by anti-Ia antibodies was assessed. It was found that the responses of (B10 X B10.BR)F1 B cells adherent to the B10 B cell monolayer or the B10.BR B cell monolayer were almost completely inhibited by anti-I-Ab and anti-I-Ak antibodies, whereas those of nonadherent cells were now selectively inhibited by anti-I-Ak and anti-I-Ab antibodies, respectively. These findings are interpreted as indicating that the B151-TRF2-responsive F1 B cells consist of at least two subpopulations with the restriction specificity for either one of the parental Ia antigens.(ABSTRACT TRUNCATED AT 400 WORDS)     

Immunological memory: contribution of memory B cells expressing costimulatory molecules in the resting state.

Traditionally, emphasis has been placed on the roles of Th cells in generating and amplifying both cellular and humoral memory responses. Little is known about the potential contributions of B cell subsets to immunological memory. Resting memory B cells have generally been regarded as poor APC, attributed in part to the relative paucity of costimulatory molecules identified on their surface. We describe a novel subpopulation of human memory B cells that express CD80 in their resting state, are poised to secrete particularly large amounts of class switched Igs, and can efficiently present Ag to and activate T cells. This functionally distinct B cell subset may represent an important mechanism by which quiescent human B cells can initiate and propagate rapid and vigorous immune memory responses. Finally, these studies extend recent observations in the murine system and highlight the phenotypic and functional diversity that exists within the human B cell memory compartment.     

Subpopulations of the T4+ inducer T cell subset in man: evidence for an amplifier population preferentially expressing Ia antigen upon activation

Prior studies demonstrated that Ia molecules were expressed on a fraction of human peripheral T4+ inducer cells upon stimulation by soluble antigen. In the present study, we utilized a fluorescence-activated cell sorter to separate antigen-activated T4+,Ia+ and T4+,Ia- populations and characterized their function. It was found that the T4+,Ia+ population contained the majority of proliferating T cells as assessed by tritiated thymidine incorporation. This proliferation largely appeared to be nonspecific. Despite macrophage repletion, elimination of the Ia+ subset of T cells with monoclonal anti-Ia antibody and complement treatment equally diminished subsequent proliferation to both the triggering antigen and an unrelated antigen. Moreover, the antigen-induced Ia+ subset of T cells alone produced a nonspecific helper factor, LMF. In contrast, the the T4+,Ia- population showed minimal proliferation to soluble antigen and did not generate LMF. Nevertheless, both T4+,Ia+ and T4+,Ia- inducer T cells were required to generate maximal immunoglobulin production by B cells in an antigen-driven system. We conclude that the human T4+ inducer T cell subset is comprised of at least 2 functionally distinct subpopulations, which are capable of acting in a synergistic fashion to provide help to B cells.     

Characterization of the effector mechanism of help for antigen-presenting and bystander resting B cell growth mediated by Ia-restricted Th2 helper T cell lines

The mechanism of help for resting B cell growth in MHC-restricted T-B collaboration was investigated using an in vitro polyclonal model for these T cell-B cell interactions. In the presence of rabbit anti-mouse Ig, small, size-selected B cells elicit help from syngeneic Ia-restricted Th2 cell lines specific for F(ab')2 rabbit globulin. Both Ag-presenting and bystander B cells receive signals from stimulated Th cells that lead to B cell proliferation. The results suggest that the direct activation of resting Ag-presenting and bystander B cells by Th2 cells is mediated by a similar effector mechanism. Although proliferative responses by Ag-presenting B cells are of greater magnitude, help for both Ag-presenting and bystander B cell populations is characterized by the lack of a requirement for membrane Ig cross-linking, by identical kinetics, and by the necessity for direct cell contact or close proximity with Th cells. B cell proliferation is not induced by exposure to the sequence of diffusable mediators released from a synchronized Ag-specific T-B interaction. The T cell-dependent proliferation by both B cell populations can be inhibited by excess mitomycin C-treated syngeneic "cold target" B cells, demonstrating a requirement for a short-range T cell-B cell interaction. mAb inhibition experiments fail to identify a role for class II, LFA-1, or CD4 membrane molecules in the delivery of help to bystander B cells. Antibody against H2d bystander class II molecules has no effect on bystander B cell proliferation at concentrations that completely block Ag presentation by H2d B cells to an H2d-restricted Th cell line. Antibodies against the cell adhesion molecule LFA-1 or the Th cell molecule CD4 do inhibit bystander B cell proliferation, but only to the extent that they block T cell activation and the induction of help. The inductive stimulus leading to resting B cell growth results from an early, short-range interaction with Th cells. B cell proliferation is supported by T cell soluble mediators as a consequence of this interaction, which is required for at least 8 hr after T cell recognition of Ag/Ia on the surface of Ag-presenting B cells.     

Clonal analysis of antigen-specific interactions between T cells and genetically engineered B cells

In order to investigate T cell-B cell interactions we constructed monoclonal, antigen-specific T- and B-cell populations. The Ia+ B-cell lymphoma A20-2J was transfected with trinitrophenyl (TNP)-specific heavy (mu) and light (kappa) chain Ig genes. A hapten-carrier complex (TNP-keyhole limpet hemocyanin (KLH)) bound to the surface Ig expressed on the transfectant and was presented to carrier-specific T-cell hybridoma clones at markedly low doses of antigen (0.01 microgram/ml) and in an Ia-restricted fashion. Two responses were elicited in the responding T-cell clones: (i) high levels of IL-2 secretion (320 units/ml), and (ii) cytotoxicity directed against the antigen-presenting B cell. This cytotoxicity was inhibited by D-mannose and was directed against innocent bystander cells, unlike cytotoxicity mediated by NK cells or alloreactive cytotoxic T lymphocyte. Helper and cytotoxic functions were often present in different T-cell hybridomas but some clones exhibited both activities. One representative T-cell hybridoma exhibited strong helper function for TNP-primed splenic B cells as detected in a plaque-forming cell assay, but was cytotoxic toward antigen-presenting B cells. Such monoclonal assay systems for studying cognate interactions of heterogeneous T cells and specific antigen-presenting cells will provide us with valuable new approaches for the study of antigen-specific T-cell regulation of B-cell activation in immune responses.     

Increased membrane immunoglobulin capping of B cells from C57Bl/6 lpr/lpr and C57Bl/6 nu/nu mice

When the capping of membrane immunoglobulin on spleen B cells from normal C57Bl/6 mice (B6) is taken as reference, a faster capping rate is found for cells of age-matched B6 mice which are congenic at the lymphoproliferation (lpr) or nude (nu) loci. Though both congenic strains can be characterized by an abnormal T-lineage cell content, the nature of the abnormality itself is very different since B6 nudes lack thymus-processed/influenced lymphocytes whereas B6 mice with the lpr phenotype suffer from an invasion of all lymphoid organs with cells of a particular T-cell subset. Moreover, the more "normal" capping rate of B cells from the double congenic B6 mice (nu/nu, lpr/lpr) is intriguing. Since other mice homozygous at the lpr locus (MRL-1) or at the nu locus (BALB/c nude) also cap faster than their congenic controls (MRL-n and BALB/c, respectively), the observed effects do not appear to depend on a peculiarity of the B6 genetic background. If the faster capping of B cells of nu congenic and of lpr congenic mice had a common origin, it might be that T cells would control in some way the mobility of B-cell membrane immunoglobulins: both congenic mice have in their spleen a very low proportion of mature T cells together with a very high proportion of prethymic/thymic immature T-cell types, either of which might affect B-cell behavioral responses to membrane immunoglobulin clustering.     

Ia-restricted B-B cell interaction. I. The MHC haplotype of bone marrow cells present during B cell ontogeny dictates the self-recognition specificity of B cells in the polyclonal B cell activation by a B cell differentiation factor, B151-TRF2

We have demonstrated that B cell recognition of Ia molecules is involved in polyclonal B cell differentiation by B151-TRF2. The present study was undertaken to examine the Ia recognition specificity of B151-TRF2-responsive B cells in fully major histocompatibility complex (MHC)-allogeneic P1----P2, semiallogeneic P1----(P1 x P2)F1, and double donor (P1 + P2)----(P1 x P2)F1 and (P1 + P2)----P1 radiation bone marrow chimeras. The B cells from both P1----P2 and P1----(P1 x P2)F1 chimeras could give rise to in vitro immunoglobulin M-producing cells upon stimulation with B151-TRF2 comparable in magnitude to that of normal P1 B cells, and their responses were inhibited by anti-I-AP1 but not by anti-I-AP2 monoclonal antibody even in the presence of mitomycin C-treated T cell-depleted P2 spleen cells as auxiliary cells. In contrast, the B151-TRF2 responses of P1 B cells isolated from both (P1 + P2)----(P1 x P2)F1 and (P1 + P2)----P1 double bone marrow chimeras became sensitive to the inhibition of not only anti-I-AP1 but also anti-I-AP2 monoclonal antibody only when the culture was conducted in the presence of P2 auxiliary cells, demonstrating that they adaptively differentiate to recognize as self-structures allogeneic as well as syngeneic Ia molecules. Moreover, the experiments utilizing B cells from H-2-congenic mice and B cell hybridoma clones as auxiliary cells revealed that B151-TRF2-responsive B cells recognize Ia molecules expressed on B cells. Taken together, these results demonstrate that B151-TRF2-responsive B cells recognize Ia molecules expressed by B cells as self-structures and that their self-recognition specificity is dictated by the MHC haplotype of bone marrow cells present during the B cell ontogeny but not by the MHC haplotype of a radiation-resistant host environment.