The murine Kupffer cell. II. Accessory cell function in in vitro primary antibody responses, mitogen-induced proliferation, and stimulation of mixed lymphocyte responses

The ability of murine Kupffer cells to function in several in vitro immunologic systems was investigated. These cells have been shown previously to function as accessory cells in antigen-stimulated T cell proliferation in response to protein antigens. In the present study it has been demonstrated that murine Kupffer cells also are competent as accessory cells in in vitro primary antibody responses to TNP-KLH and for T cell proliferative responses to concanavalin A. In addition, murine Kupffer cells were found to be potent stimulators of mixed lymphocyte responses. These studies extend previous observations by demonstrating that Kupffer cells are competent accessory cells in several distinct in vitro correlates of in vivo immune responses. The role of Kupffer cells in in vivo immune responses, particularly those to enterically derived antigens, may require re-evaluation in the light of these findings.     

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)     

T cell responses to select Ia determinants using the I-A mutant mouse strain B6.C-H-2bm12

The T cell repertoire of B6.C-H-2bm12 mice (an I-A mutant mouse strain) to wild-type Iab antigens was investigated using both secondary proliferative cultures and cloned T cell lines. Because bm12 mice have a gain-loss mutation of their gene encoding the Ia beta-chain polypeptide, bm12 anti-B6 T cell responses are specific for the select component of Iab specificities that was lost as a result of the mutation. Although stimulator cells bearing Iab antigens elicited the strongest responses, Iaq, d, and s antigens also resulted in reproducible stimulations of these bm12 anti-B6-primed T cells. Cloned T cell lines isolated from bm12 anti-b6 cultures revealed similar findings, with most clones recognizing determinants unique for Iab antigens; however, clones showing cross-reactions with Iad and/or q were also selected. Using F1 hybrid responder T cells (mutant x cross-reactive strain), we further dissected this cross-reactivity into several distinct cross-reactive determinants. Because bm12 mice lack the serologically defined Ia differentiation antigen W39, T cell recognition of this determinant was investigated by using bm12 anti-B6-primed cells. Stimulation by Ia.W39+ cells was appreciably better than by Ia.W39- (Xid-defective) cells, suggesting that bm12 T cells recognize an Xid-regulated, W39-like Ia differentiation antigen.     

Activated T cells in vivo and in vitro: divergence in expression of Tac and Ia antigens in the nonblastoid small T cells of inflammation and normal T cells activated in vitro

Elevated numbers of non-blastoid T cells expressing either the Tac or Ia antigens were found on separate cell populations in inflammatory synovial tissues and fluids of individuals with arthritis. Those synovial T cell preparations containing Tac+ cells exhibited marked proliferation upon the addition of IL 2 without concomitant mitogen stimulation; T cell eluates containing Ia+ but not Tac+ T cells did not show significantly increased levels of blastogenesis. Paired T cell preparations from blood had only minor increases in the number of Tac+ T cells and moderate increases in the number of Ia+ cells. The blood cells did not exhibit significant proliferation to IL 2. In contrast mitogen or allogeneic activation of T cells induced blastoid cells that expressed abundant per cell amount of Ia or Tac antigens. These blastoid cells resembled the small T cells of inflammation in having only very limited overlap between the population that bore Ia antigens and those with the Tac antigen; however, there was a preponderance of Tac-bearing cells.     

Expression of I-A and I-E,C region-coded Ia antigens on functional B cell subpopulations.

Ia antigens from specific subregions have been examined on functional B cell populations. Expression of both I-A and I-E,C region antigens was demonstrated on cells required for both lipopolysaccharide mitogenesis and polyclonal activation. Similar I-A and I-E,C subregion expression was found on cells required for response to the T-independent antigen, polyvinylpyrrolidone. TNP-specific IgM and hen egg lysozyme-specific IgG plaque-forming cells also express I-A and I-E,C region antigens. No evidence was found for an Ia- population responsive in the systems tested. Further, no evidence of preferential expression of I-A or I-E,C region antigens was observed in any system examined. Therefore, it appears that B cells express both I-A and I-E,C region-coded Ia antigens.     

Macrophage Ia antigens. I. macrophage populations differ in their expression of Ia antigens

By indirect immunofluorescence and microcytotoxicity it was demonstrated that different populations of murine macrophages bear different amounts of Ia antigens on their membranes. At least three subpopulations could be distinguished: those that lack Ia antigens and predominate in peritoneal exudate; cells bearing I-A antigens that are the majority of splenic macrophages and a minor population in the peritoneum; and cells bearing I-C antigens that are a minor population in both spleen and peritoneum. Internal radioisotope labeling studies confirmed that the I region molecules are synthesized by the macrophages. It is suggested that these different macrophage subpopulations may play distinct roles in the immune response.     

The immunobiology of T cell responses to Mls-locus-disparate stimulator cells. II. Effects of Mls-locus-disparate stimulator cells on cloned, protein antigen-specific, Ia-restricted T cell lines

Cloned, protein antigen-specific, Ia-restricted T cell lines frequently (approximately 20%) also respond strongly to stimulator cells from strains expressing stimulatory alleles at the chromosome 1-encoded Mls-locus. Furthermore, such responses are blocked by monoclonal antibodies specific for Ia antigens expressed by the stimulator rather than the responder cells. However, such responses show no specificity for polymorphic determinants on Ia molecules, although in such responses, as in primary and secondary T cell responses to stimulating Mls-locus alleles, I-E molecules appear to play a central role. These results, combined with the unique immunobiology of the primary T cell proliferative response to Mls-locus-disparate stimulator cells, suggest to us that this response involves the interaction of the receptor on T cells for antigen:self Ia with a relatively nonpolymorphic region of Ia glycoproteins. This hypothesis is supported by the observation that a monoclonal antibody to the T cell receptor will inhibit both responses, although the response to Mls-locus-disparate stimulators appears to be more sensitive to these antibodies. We propose that the interaction of the T cell receptor with Ia is stabilized by a cell interaction molecule encoded or regulated by the Mls-locus gene product permitting the T cell receptor:Ia glycoprotein interaction to lead to T cell activation.     

Ia-specific mixed leukocyte reactive T cell hybridomas: analysis of their specificity by using purified class II MHC molecules in synthetic membrane system

This study was undertaken to determine the nature of the antigens recognized in allogeneic and syngeneic mixed leukocyte reactions (MLR). Specifically, we wished to determine whether Ia antigens alone were recognized by MLR-reactive T cells, or whether the specificity was determined by the corecognition of non-MHC antigens together with syngeneic or allogeneic Ia. To do this we used 11 T cell hybrids that were characterized as being specific for Iad and were tested their capacity to respond to isolated I-Ad or I-Ed that had been incorporated into liposomes and had bound to the surface of glass beads. Of nine alloreactive T cell hybrids (five I-Ad-and four I-Ed-specific), seven were shown to be responsive to the relevant isolated Ia antigen on glass beads. Also, two of two syngeneic I-Ad-specific T cell hybrids responded to I-Ad on the glass beads. One of the two alloreactive T cell hybrids that failed to respond to the relevant Ia antigen on glass beads was shown to be specific for an antigen in fetal calf serum (FCS) that was recognized in the context of the allo-Ia antigen (I-Ed), because when intact accessory cells were used, a response by this hybrid was only observed when FCS was present in the assay culture medium or when the accessory cells were pre-pulsed with FCS. The possible involvement of FCS antigens and non-Ia accessory cell antigens in the stimulation of the nine T cell hybrids that responded to isolated Ia on glass beads was evaluated. T cell hybrids that were grown and were tested in serum free medium were still capable of reacting to Ia on beads. The isolated Ia preparations used were greater than 90% pure, and their capacity to stimulate the T cell hybrids did not correlate with the degree of contamination with non-Ia proteins. We conclude from these studies that the majority of T cells that respond to allogeneic or syngeneic Ia bearing stimulator cells are specific for the Ia antigens themselves, and do not require the co-recognition of other non-Ia antigens; nor is there any requirement for Ia antigen processing for this recognition.     

Comparison and partial characterization of guinea pig Ia alpha- and beta-chain oligosaccharides

The structures of the N-linked oligosaccharides of mature guinea pig Ia molecules were partially characterized by serial lectin affinity analysis. Those Ia antigens that are thought to be allelic products (Ia.3,5 and Ia.4,5) were found to bear identical oligosaccharides, whereas differences in glycopeptide distribution were found for Ia antigens known to be products of separate I subregions (Ia.2 and Ia.4,5). The two predominant oligosaccharides present on alpha-chains from all three Ia molecules were of the high mannnose type and the triantennary or tetraantennary complex type. Two structurally distinct beta-chains were isolated from Ia.3,5 and Ia.4,5 molecules; beta 1 bore primarily triantennary or tetraantennary complex oligosaccharides, and beta 2 had predominantly biantennary complex-type carbohydrate chains. The composition and distribution of the oligosaccharide moieties of guinea pig Ia molecules indicate that there are structural features shared among guinea pig, murine, and human Ia antigens.     

Characterization of Ia8 antigen, thy-1.2 antigen, complement receptors, and virus production in a group of murine virus-induced leukemia cell lines.

Ia8, a cell membrane antigen controlled by gene(s) located in the I region of the H-2 complex, was found on 9 of 26 murine leukemia cell lines. Iaddition, 3 of the 9 Ia8-bearing lines had a membrane receptor for antigen-antibody-complement complexes. Six of 26 lines bore the Thy-1.2 antigen. Ia8 and Thy-1.2 antigens were mutually exclusive on the cell lines studied. The strain of virus used to induce the leukemia, the H-2 type of the cells, and the techniques of leukemia cell propagation all appeared to influence the antigenic characteristics of the cell lines obtained. Production of infectious murine leukemia virus in vitro and expression of leukemia virus-induced membrane antigens did not appear to correlate with the presence of I8 or Thy-1.2 antigens or with the H-2 type of the 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.     

Alloreactive T cells from individual soft agar colonies specific for guinea pig Ia antigens. II. Cellular and molecular requirements for optimal proliferative responses

We have investigated the cellular and molecular requirement for optimal proliferative responses of several alloreactive T cell lines that were derived from individual soft agar colonies and were specific for guinea pig Ia antigens. Optimal proliferation of several colonies was observed in cultures containing purified allogeneic macrophages and growth factor(s) present in supernatant fluids of Con A-activated T cells (Con A-S). Significant proliferative responses of these alloreactive T cell colonies were also routinely detected in cultures only supplemented with unfractionated irradiated allogeneic peritoneal exudate cell (PEC). The T cell component of the stimulator cell population was crucial for these responses by producing necessary growth factor(s) endogenously in the culture. Thus, 2 signals, allogeneic Ia antigens and growth factor(s), were required for optimal proliferative responses of these alloreactive T cell colonies. Furthermore, macrophage-associated Ia antigen was more efficient than B cell-associated Ia for these responses. The requirement for allogeneic Ia antigen was not absolute, since the colonies could easily be expanded when the cultures were supplemented with irradiated syngeneic PEC and the T cell mitogens, Con A or PHA. The effect of the mitogen was mediated via the T cells in the irradiated PEC, since removal of the T cells from these PEC markedly reduced the responses. Thus, it is likely that a nonspecific signal(s) presumably from T cells can promote proliferation of alloreactive T cell colonies in the absence of allogeneic Ia antigen. These results suggest 2 mechanisms of activation of these alloreactive T cells.     

Selective effects of anti-Ia serum and complement treatment upon polyclonal B lymphocyte responses to dextran sulfate and lipopolysaccharide.

Subpopulations of B lymphocytes have been shown to vary in their expression of Ia alloantigens and polyclonal responsiveness to thymic independent antigens. We have demonstrated that the polyclonal B cell antibody response to dextran sulfate is less sensitive to removal of Ia-positive cells than is the response to LPS. This is a consistent finding whether alloantibody and complement (C) pretreatment is directed toward cells bearing Ia antigens coded for by the entire I region or by the I-A or I-E subregions. Heterogeneity appears to exist within the dextran sulfate-sensitive population in that using high antibody; cell ratios during antibody and C-mediated cell selection results in an inhibition of the proliferative but not the antibody response. This result may indicate a differential expression of Ia antigens on dextran sulfate-sensitive B cells that respond by proliferation versus those cells that produce antibody. Alternatively, proliferative responses to dextran sulfate may be more dependent upon Ia-positive accessory cells than is the polyclonal antibody response.     

Antibody-dependent cellular cytotoxicity effector cells lack Ia antigens.

Surface immunoglobulin (sIg)-positive and sIg-negative subpopulations of macrophage-depleted murine splenic lymphocytes were obtained by Sephadex anti-Fab immunoabsorbent fractionation. These lymphocyte subpopulations were analyzed for the presence of Thy 1 and Ia alloantigens and also for Fc receptors by fluorescence microscopy. Concurrently, these lymphocyte subpopulations were studied for effector cell activity in antibody-dependent cellular cytotoxicity (ADCC). Effector cells mediating ADCC were contained in the sIg-negative lymphocyte subpopulation and sIg-positive lymphocytes did not mediate cytotoxicity. The majority of sIg-positive lymphocytes were found to bear Ia antigens and Fc receptors, and these cell surface structures were associated in that treatment of these cells with anti-Ia sera inhibited binding of complexed immunoglobulin to Fc receptors. In contrast, most sIg-negative, Thy 1-negative lymphocytes lacked Ia Antigens, and the Fc receptors detected on such cells were not blocked by anti-Ia sera. In addition, a small subpopulation of sIg-negative, Ia antigen-positive, Fc receptor-positive lymphocytes was found. Elimination of this subpopulation of Ia antigen-positive cells from sIg-negative lymphocytes, by treatment with anti-Ia serum and complement, did not diminish ADCC effector cell activity in the resultant cell population when compared with untreated sIg-negative lymphocytes. Thus, in murine spleen, nonphagocytic mononuclear cells that lack both sIg and Ia antigens were shown to mediate ADCC.     

Requirement for an Ia-bearing accessory cell in Con A-induced T cell proliferation.

Pretreatment of murine lymphoid cells with anti-Ia and C abrogated the proliferative response of these cells to Con A, but not to PHA. Reconstitution experiments demonstrated that T cell-enriched populations failed to restore Con A responsiveness and that T cell-depleted populations were more effective in restoring responsiveness to Con A. In particular, a population of 1000 R resistant, glass-adherent, non-T spleen cells was capable of completely restoring responsiveness to Con A when added in numbers as low as 4% of cultured cells. These splenic adherent cells were found to express Ia determinants encoded by at least two genes: one in I-A and the other in I-B, I-J, and/or I-E/C, and it was demonstrated that determinants encoded in these two regions were expressed on the same cell. These results demonstrate that non-T accessory cells may be the Ia+ cells entirely responsible for the anti-Ia and C-induced abrogation of T cell proliferative responses to Con A.     

A subpopulation of adherent accessory cells bearing both I-A and I-E or C subregion antigens is required for antigen-specific murine T lymphocyte proliferation.

A murine T lymphocyte proliferation assay that used antigen-primed lymph node T cells, was antigen specific, and required exogenous accessory cells was used to characterize the accessory cells that supported proliferation. These cells were Thy 1.2 negative, radioresistant, glass-adherent, and were functional only if alive. The accessory cell function of spleen adherent cells was much greater than that of peritoneal cells. Also, the accessory cell function of spleen adherent cells was proportional to the length of time such cells were incubated with antigen and very small numbers of such cells provided accessory cell function. Cytotoxic studies with subregion-restricted anti-Ia antibodies and complement indicated that accessory cell function resided in a subpopulation of spleen adherent cells that bore both I-A and I-E or C subregion antigens. The function of such cells was not related to a selective ability (vs other spleen adherent cells) to take up antigen. These data indicate that antigen-specific stimulation of T lymphocyte proliferation requires at least one specific subpopulation of spleen adherent cells that can be phenotypically identified by its expression of Ia antigens and are consistent with the possibility that Ia antigens may be Ir gene products.     

The function of macrophages in antigen recognition by guinea pig T lymphocytes. III. Genetic analysis of the antigens mediating macrophage-T lymphocyte interaction.

Activation of immune T lymphocytes by antigen-pulsed macrophages is mediated by the Ia antigens of the guinea pig MHC or the products of closely linked genes. Studies using combinations of macrophages and T cells derived from outbred animals with different Ia antigens and/or Ir gene products have demonstrated that sharing of Ir gene products between macrophage and T cells is not sufficient for effective macrophage-T cell interaction. The role of the Ia antigens in the absence of the linked Ir gene products could not be directly examined because we were unable to identify an animal which bore the full complement of Ia antigens in the absence of the Ir gene that is normally associated with them. The results of these studies support the concept of the functional expression of the Ir gene product in the macrophage.     

Ia antigens in mouse skin are predominantly expressed on Langerhans cells.

We have investigated the expression of products of the mouse major histocompatibility complex (MHC) on BALB/c and A/J epidermal cells. By using reagents with specificity for various products of the MHC in an indirect immunofluorescence procedure, we found that H-2 antigens are expressed on the vast majority of epidermal cells. Ia antigens, by contrast, are present on only 2.4 to 6.9% of all epidermal cells. These Ia-bearing cells bear a receptor for the Fc portion of IgG and ultrastructurally exhibit the characteristics of Langerhans cells. Ia antigens on Langerhans cells are encoded for by at least the I-A and I-E/C subregions of the MHC.     

Tri-iodothyronine differentially induces Kupffer cell ED1/ED2 subpopulations

Thyroid calorigenesis is carried out by activation of cytochrome-c oxidase, as well as by induction of mitochondrial and nuclear genes that code for cell respiratory apparatus components and uncoupling proteins. These effects operate increments in basal metabolic rate and also lead to increased production of oxygen and nitrogen reactive species in liver parenchymal cells. The hepatic antioxidant system is also compromised, since superoxide dismutase and catalase activities, glutathione content and lipid soluble antioxidants are reduced. Liver macrophages contribute to the hepatic oxidative stress observed in T(3)-treated rats, and both Kupffer cell hyperplasia and hypertrophy are reported. Kupffer cells constitute the main fixed macrophage population in the body and are a heterogeneous group of cells, derived from a less numerous population of local precursors, which are morphologically fairly distinguishable from the mature lineage elements. ED1 and ED2 antigens have been particularly useful in the characterization of Kupffer cell subpopulations. In particular, antibodies against these antigens provided evidence that T(3)- induced Kupffer cell hyperplasia causes a shift on liver macrophage population phenotype, leaning towards younger cell types. Despite the fact that sinusoidal environment itself stimulates the proliferation of macrophage precursors and their differentiation into Kupffer cells, increased Kupffer cell turnover rates modify the sinusoidal environment and may imply further functional effects. Thus, Kupffer cell hyperplasia secondary to increased T(3) levels is potentially a pro-inflammatory event, which involves both, the expansion of Kupffer cell precursor population by means of circulating monocyte recruitment, and the differentiation of preexisting local Kupffer cell precursors into mature liver macrophages.     

Mouse T lymphocytes proliferative responses specific for human MHC products in mouse anti-human xenogeneic MLR

It has been reported that human T cells recognize the polymorphism of murine Ia antigens in the human anti-mouse xenogeneic mixed lymphocyte reactions (MLR). In this study, murine T cell recognition of human Class II antigens of the major histocompatibility complex (MHC) was analyzed in mouse anti-human xenogeneic MLR responses. The xenoreactive murine T cell proliferative response was blocked by adding anti-HLA-DR monoclonal antibody to the xenogeneic MLR culture. The specificity of xenoreactive murine T cells was examined with regard to the secondary and tertiary xenogeneic MLR system. The xenoreactive murine T cells were restimulated by distinct human stimulator cells that had no shared HLA antigens with the stimulator used in the primary MLR. The data presented here show that the murine xenoreactive T cells recognize the shared determinant(s) of HLA-DR antigen on non-T, non-B stimulator cells. The xenoreactive murine T cell proliferative responses were mediated by Thy-1+, Lyt-1+, and Lyt-2- cells. Furthermore, the xenoreactive T cell responses required Ia+ cells, and Ia antigen on accessory cells plays a crucial role in eliciting the xenoreactive responses against human stimulator cells, while Ia+ accessory cells in the responding cell population are not essential for the elicitation of allogeneic MLR responses, as reported previously.