Lead influences translational or posttranslational regulation of Ia expression and increases invariant chain expression in mouse B cells.

The molecular mechanisms governing the increased cell surface expression of major histocompatibility complex (MHC) class II molecules (Ia) on lead-treated mouse B cells was investigated. Lead has been shown to directly cause a selective, two-fold increase in the B cell's surface density of both products of the I region of the mouse MHC, I-A and I-E. In the present study, Western blot analysis showed that Pb increases the total cellular pool of I-A beta-chain by twofold. The increase in cellular I-A was not found to be due to increased messenger RNA (mRNA) for either the alpha- or the beta-chain of I-A. Biosynthetic labeling studies showed that Pb increases the translation or the stability of the Ia-associated invariant chain (Ii or gamma) and possibly the beta-chain of Ia. Collectively these results suggest that Pb increases the B cell's surface Ia by influencing translational or posttranslational regulation of Ia and/or Ia-associated chains.     

Structure, regulatory polymorphisms, and allelic hypervariability regions in murine I-A alpha

Class II major histocompatibility complex (MHC) molecules, the Ia antigens, are intimately involved in regulating the intensity and specificity of the cellular and humoral responses to T cell-dependent antigens. One approach to understanding the mechanism of this regulation is to analyze the structure and allelic polymorphism of Ia molecules. In addition there are regulatory polymorphisms in the expression of the I-E alpha and I-E beta class II MHC polypeptide chains. Analysis of the cDNA sequence indicates that I-A and I-E alpha chains are similar with short stretches of homology and other regions of nonhomology. Analysis of Northern blots of mRNA indicates that at least three separate types of regulatory polymorphisms result in failure of expression of I-E alpha. Comparison of allelic sequences of six alleles of the I-A alpha chain shows that almost all of the allelic polymorphism is in the first domain and that within the first domain it is clustered in three allelic hypervariable regions within the first domain of I-A alpha. The structural and functional implications of these findings are discussed.     

Lead influences translational or posttranslational regulation of ia expression and increases invariant chain expression in mouse B cells

The molecular mechanisms governing the increased cell surface expression of major histocompatibility complex (MHC) class II molecules (Ia) on lead-treated mouse B cells was investigated. Lead has been shown to directly cause a selective, two-fold increase in the B cell's surface density of both products of the I region of the mouse MHC, I-A and I-E. In the present study, Western blot analysis showed that Pb increases the total cellular pool of I-A β-chain by twofold. The increase in cellular I-A was not found to be due to increased messenger RNA (mRNA) for either the α- or the β-chain of I-A. Biosynthetic labeling studies showed that Pb increases the translation or the stability of the Ia-associated invariant chain (Ii or γ) and possibly the β-chain of Ia. Collectively these results suggest that Pb increases the B cell's surface Ia by influencing translational or posttranslational regulation of Ia and/or Ia-associated chains.     

Suppressed expression of surface Ia on macrophages by lipopolysaccharide: evidence for regulation at the level of accumulation of mRNA

The surface expression of class II major histocompatibility molecules (immune associated or Ia antigens) is an acquired property of macrophages, essential to their ability to interact effectively with T lymphocytes. Surface expression of Ia is induced by stimulants such as interferon-gamma and is suppressed by agents such as lipopolysaccharide (LPS). Recent studies on several cultured cell lines indicate that interferon-gamma can heighten cellular levels of mRNA encoding Ia, and the level of such mRNA may represent an important regulatory focus for controlling expression of surface Ia. Murine peritoneal macrophages were treated with interferon-gamma and/or LPS and expression of Ia mRNA determined by Northern blot analysis with a probe specific for the murine beta-chain of I-A. mRNA specific for I-A beta was not detectable in explanted macrophages obtained from sites of sterile inflammation but was induced by treatment of purified recombinant interferon-gamma. This effect was dose dependent and was optimal by 24 hr after stimulation. Ia-specific mRNA preceded the surface expression of Ia as monitored by a radioimmunoassay using a monoclonal antibody specific for I-A beta. When a physiologic dose of LPS was added concomitantly with the interferon-gamma, the time course of induction if Ia-specific mRNA was not altered, but the amount of such mRNA detected was suppressed 40 to 80%. This effect was dependent on the dose of LPS, and the levels of mRNA correlated closely with subsequent surface expression of Ia. The ability of LPS to suppress both mRNA and cell surface Ia expression required that the suppressive agent be added within 12 hr of the inducing stimulus. This is the time frame during which accumulation of mRNA occurs. Thus the data demonstrates that accumulation of specific mRNA is a major regulatory focus governing expression of Ia both by interferon-gamma and LPS.     

Biochemical models of interferon-gamma-mediated macrophage activation: independent regulation of lymphocyte function associated antigen (LFA)-1 and I-A antigen on murine peritoneal macrophages

IFN-gamma can induce the expression of both class II histocompatibility antigens (Ia) and the lymphocyte function associated (LFA)-1 antigen on murine peritoneal macrophages. We have examined the molecular changes which lead to altered expression of these two cell surface proteins to determine whether they are regulated by similar or independent mechanisms. While I-A antigen expression can be induced or enhanced by treatment of macrophages with either phorbol diesters and/or the Ca2+ ionophore A23187, these agents had no effect upon expression of LFA-1 under similar conditions. Macrophages from the A/J strain mouse exhibit a deficiency in their sensitivity to IFN-gamma which is seen in our studies as an inability of IFN-gamma to elevate I-A antigen expression. However, expression of I-A could be modulated in these cells by treatment with either phorbol diesters or A23187. In contrast, IFN-gamma could induce LFA-1 antigen on A/J derived macrophages and this was not affected by either phorbol or A23187. Thus these two antigens, despite coordinate expression in response to IFN-gamma in normal mouse strains, are clearly regulated independently. These results suggest that IFN-gamma generates at least two independent molecular events in macrophages which ultimately modulate the expression of cell surface proteins important to the performance of activated functions.     

Bone marrow-derived macrophage expression of endogenous and transfected class II MHC genes during differentiation in vitro

C57BL/6 (H-2b) mice fail to express I-E molecules on the surface of their cells and thus are unable to respond to I-E-restricted antigens such as GL phi and cytochrome c. Previous experiments in our laboratory have involved developing a system for studying differentiation of bone marrow cells into mature macrophage to gain a better understanding of class II MHC gene expression and function. In this study, we have used this system to transfect the E alpha d gene (cosmid 17.2) into C57BL/6 bone marrow cells and subsequently observed I-E expression on bone marrow-derived macrophages (BMDM) after differentiation in vitro. By using a modified calcium phosphate protocol, we found that the optimal period for transfection of the bone marrow cells was after 2 days of culture in vitro. By using the anti-I-E monoclonal antibody (Ia.7) derived from hybridoma 14-4-4, we detected the I-E molecule on the surface of transfected macrophages by a radiobinding assay and immunoprecipitation. BMDM expressed the I-E product maximally at 5 days of differentiation, and expression then declined. Furthermore, we have found that the expression of the I-E molecule on transfected macrophage was dependent upon exposure to interferon-gamma. Expression of I-E molecules was also detected by the generation of an allogeneic response. Transfected BMDM were compared with (CB6)F1 BMDM for their ability to stimulate C57BL/6 T cells and they were found to be equally effective. By using these initial findings, we hope to further optimize the conditions for insertion and expression of class II MHC genes in bone marrow cells.     

A single monoclonal anti-Ia antibody inhibits antigen-specific T cell proliferation controlled by distinct Ir genes mapping in different H-2 I subregions

A xenogeneic rat anti-mouse Ia monoclonal antibody, M5/114 (gamma 2b, kappa), was studied for its effects in vitro on T cell proliferative responses. Strain distribution studies revealed that M5/114 could inhibit I-A subregion-restricted T cell responses of the H-2b,d,q,u but not the H-2f,k,s haplotypes, indicating that this xenoantibody recognizes a polymorphic determinant on mouse Ia molecules. This same monoclonal antibody was found to inhibit BALB/c (H-2d) T cell proliferation to both G60A30T10 and G58L38 phi 4. The Ir genes regulating responses to these antigens map to either the I-A subregion (GAT), or the I-A and I-E subregions (GL phi), raising the possibility that M5/114 recognizes both I-A and I-E subregion-encoded Ia glycoproteins. It could be shown, using appropriate F1 responding cells, that M5/114 does in fact affect GAT and GL phi responses by interaction with both the I-A and the I-E subregion products, and not by any nonspecific effect resulting from binding to the I-A subregion product alone. These results are consistent with genetic and biochemical studies directly demonstrating that M5/114 recognizes A alpha A beta and E alpha E beta molecular complexes. The existence of a shared epitope on I-A and I-E subregion products suggests the possibility that these molecules arose by gene duplication. Finally, the precise correlation between the Ia molecules recognized by M5/114 and the ability of this antibody to block T cell responses under Ir gene control strengthens the hypothesis that Ia antigens are Ir gene products.     

The Ia.2 epitope defines a subset of lipid raft-resident MHC class II molecules crucial to effective antigen presentation

Previous work established that binding of the 11-5.2 anti-I-A(k) mAb, which recognizes the Ia.2 epitope on I-A(k) class II molecules, elicits MHC class II signaling, whereas binding of two other anti-I-A(k) mAbs that recognize the Ia.17 epitope fail to elicit signaling. Using a biochemical approach, we establish that the Ia.2 epitope recognized by the widely used 11-5.2 mAb defines a subset of cell surface I-A(k) molecules predominantly found within membrane lipid rafts. Functional studies demonstrate that the Ia.2-bearing subset of I-A(k) class II molecules is critically necessary for effective B cell-T cell interactions, especially at low Ag doses, a finding consistent with published studies on the role of raft-resident class II molecules in CD4 T cell activation. Interestingly, B cells expressing recombinant I-A(k) class II molecules possessing a β-chain-tethered hen egg lysosome peptide lack the Ia.2 epitope and fail to partition into lipid rafts. Moreover, cells expressing Ia.2(-) tethered peptide-class II molecules are severely impaired in their ability to present both tethered peptide or peptide derived from exogenous Ag to CD4 T cells. These results establish the Ia.2 epitope as defining a lipid raft-resident MHC class II conformer vital to the initiation of MHC class II-restricted B cell-T cell interactions.     

Mouse B lymphocyte specific endocytosis and recycling of MHC class II molecules

In B lymphocytes, the processing of exogenous proteins and the subsequent binding of antigenic peptides to class II molecules encoded by the major histocompatibility complex (MHC) occurs most likely within endocytic compartments. To examine the endocytic transport of MHC class II molecules, we used (i) surface iodination followed by internalization, pronase treatment and immunoprecipitation, (ii) in situ iodination of endosomal compartments, and (iii) confocal microscopy to visualize the fate of fluorescence coupled Fab fragments. In murine I-Ak, I-Ek positive B lymphoma cells, cell surface MHC class II molecules are partially protected from pronase digestion after 15 min at 37 degrees C and recycled back to the cell surface within the next 30 min. The fluorescence coupled Fab fragments are delivered to juxtanuclear endocytic compartments in 15 min. In contrast to the murine B cells, L fibroblasts transfected with either I-A alpha beta k or I-E alpha k beta k,d fail to internalize their surface class II molecules. A fraction of class II molecules, however, is still present in endosomal compartments as detected after in situ iodination in L fibroblasts. We conclude that the recipient L fibroblasts lack one or several factors needed for the transport of MHC class II molecules from the cell surface to the endosomes. We suggest that in murine B lymphoma cells, antigenic peptides can gain access to a pool of recycling class II molecules whereas in L cells they meet newly synthesized class II molecules targeted to the endosomal compartments.     

Induction of class I and class II MHC antigen expression on murine bone marrow-derived macrophages by IL-4 (B cell stimulatory factor 1)

We have studied the effects of IL-4 (B cell stimulatory factor 1) on the expression of MHC gene products in normal bone marrow-derived macrophages, peritoneal macrophages, and the myelomonocytic cell line WEHI-3. Using both IL-4-containing T cell supernatant and rIL-4, we have observed significant induction of both class I and class II MHC surface expression (about 1.5- to 4-fold increase) in 2-, 3-, and 4-day cultures of bone marrow-derived macrophages. This induction was also apparent at the mRNA level as assessed by Northern blot analysis using A beta, E alpha, and class I probes. Kinetic analysis revealed that induction of class II mRNA by IL-4 was slower than induction by IFN-gamma, requiring 48 h before a significant increase was noted. The magnitude of MHC induction by IL-4 was not as great as that seen with IFN-gamma, which was found to increase surface expression of MHC antigens two- to eightfold. IL-4 also differs from IFN-gamma in the repertoire of macrophages responsive to it. IL-4 was unable to induce class I or class II expression in either thioglycolate-elicited peritoneal macrophages or WEHI-3 cells whereas IFN-gamma induced MHC antigen expression on both cell types under the same conditions. These data demonstrate that IL-4 is capable of inducing both class I and class II MHC gene products in some, but not all, macrophages.     

Molecular associations of class II MHC antigens in mitogen-stimulated B cells

Previously, we showed that murine B cell membrane proteins undergo rearrangements in the plasma membrane to form new molecular associations in response to mitogenic stimulation. These complexes were covalently stabilized by photoreactive cross-linking agents and were analyzed by SDS PAGE. We have now identified certain complexes that involve class II MHC products, the Ia antigens. Upon stimulation of B cells with LPS, Ia surface molecules (as identified by radioimmunoprecipitation with polyclonal anti-Ia antiserum) enter into a molecular complex with a 95-kd membrane-associated protein (p95) to form a 200-kd complex that may be stabilized by the cross-linking agent dithiobisphenylazide (DTPA). This molecular association is not observed upon stimulation with mitogenic anti-Ig reagents, nor with the polyclonal B cell activator 8-bromoguanosine. p95 is not a disulfide-linked molecule itself, and by separate immunoprecipitation experiments we have established that it is not a component of surface Ig, transferrin receptor, the B cell Fc receptor, or CR1, the receptor for complement component C3b. Further analysis of the association of Ia antigens with surface proteins, with the use of monoclonal antibodies directed against I-A or I-E, has demonstrated that each subregion gene product forms a unique molecular association. Precipitation of radiolabeled lysates from LPS-activated B cells with anti-I-A reveals the aforementioned association with p95. In contrast, the I-E antigen apparently forms complexes with a multimer of a 15-kd protein to give complexes of 45, 60, 75, and 90 kd. When analyzed by two-dimensional diagonal gels (nonreducing/reducing), only the I-E bands are revealed by autoradiography, indicating that the putative p15 that associates with I-E may not be accessible to surface labeling. The disparate molecular associations for I-A and I-E suggest that the formation of these distinct protein complexes may be functionally related to a different role in the process of cellular activation for each of these Ia subregion gene products.     

Antagonistic effect of interferon-beta on the interferon-gamma-induced expression of Ia antigen in murine macrophages

The cell surface expression of I region-associated (Ia) antigens by murine and human macrophages has been shown by investigators from a number of laboratories to be induced in a dose-dependent fashion by IFN-gamma, which is free of other lymphokines. The experiments described in this report demonstrate that fibroblast-derived IFN-beta exerts an antagonistic effect on IFN-gamma induced Ia expression in murine macrophages. Simultaneous addition of IFN-beta and IFN-gamma to peritoneal exudate macrophages results in decreased Ia expression when compared with macrophages treated with IFN-gamma only. Different sources of highly purified IFN-beta, as well as a recombinant human IFN-alpha (A/D Bgl; shown previously to be as active as IFN-beta in several other murine systems) acted in a similar antagonistic fashion to IFN-gamma-induced Ia induction. The down-regulation of Ia expression by IFN-beta is dose-dependent over a concentration range up to 100 U/ml. Time-course experiments indicated that for IFN-beta to down-regulate IFN-gamma-induced Ia, it had to be present either before stimulation with IFN-gamma or during the first 24 hr of simultaneous stimulation. Further experiments in which a highly specific antibody against IFN-alpha/beta was added to the cultures confirmed the findings of the time-course experiments. Inhibitors of the arachidonic acid pathway failed to reverse the effect of IFN-beta to reduce Ia antigen expression, which suggests that this inhibition is not prostaglandin mediated. Thus, these findings support a role for type I IFN as naturally occurring substances that negatively regulate the expression of class II molecules.     

Differential regulation of class II MHC determinants on macrophages by IFN-gamma and IL-4

Initiation of an immune response depends upon expression of class II MHC determinants on plasma membranes of APC. Murine peritoneal macrophages treated with either rIFN-gamma or rIL-4 display significantly more class II MHC determinants than untreated control cells. Analysis of the induction of macrophage Ia Ag by these cytokines showed considerable quantitative and qualitative differences. Maximal levels of Ia Ag induced in macrophages and detected by ELISA after IL-4 treatment at 48 h was about 80% of that induced by IFN-gamma. However, the frequency of Ia+ cells in replicate macrophage populations cultured for 48 h in excess concentrations of cytokine was 60 to 80% with IFN-gamma, 30 to 40% with IL-4, and 5% with medium alone. Thus, the subpopulation of macrophages able to respond to IL-4 for induction of Ia Ag expression was less than that able to respond to IFN-gamma. Expression of Ia Ag on macrophages continuously exposed to IFN-gamma was maximal at 48 h and remained at this high level through 6 days. Maximal Ia Ag expression for IL-4-treated cells was also detected at 48 h, but was not sustained with time in culture, and returned to base line by 4 days. A similar time course for levels of Ia-specific message in macrophages at various times after IFN-gamma and IL-4 treatment was detected by Northern dot blot analysis. Loss of Ia mRNA and Ag with time in culture in the IL-4 treated cells was not due to macrophage cell death, depletion of active cytokine, or presence of fluid-phase inhibitors. IL-4 unresponsive cells were fully capable of maximal response to IFN-gamma for Ia Ag induction. These findings suggest that IL-4 and IFN-gamma induce class II MHC determinants through different mechanisms which may provide discrete regulatory control of APC function.     

Lack of MHC-II expression in activated mouse T cells correlates with DNA methylation at the CIITA-PIII region

In contrast to activated human T cells, activated mouse T cells fail to express MHC class II molecules (MHC-II) at their cell surface. This is because mouse T cells hardly produce mRNA encoding the MHC-II molecules I-A and I-E, due to severely impaired expression levels upon T-cell activation of the mhc2ta gene, encoding the class II transactivator (CIITA). In humans, activated T cells express exclusively the CIITA promoter III (CIITA-PIII) isoform, which results in cell surface expression of all MHC-II isotypes (HLA-DR, -DP and -DQ). In this study, we demonstrate that methylation of CIITA-PIII contributes to the failure of mouse T cells to transcribe the mhc2ta and the resulting I-A/E genes, explaining the lack of I-A/E molecule expression at the cell surface following activation.     

Coordinate induction of Ia alpha, beta, and Ii mRNA in a macrophage cell line

We demonstrated a tightly coordinated timing in the appearance of mRNA for the four class II (Ia) MHC chains, A alpha, A beta, E alpha, and E beta, and the Ia-associated invariant chain in a murine macrophage cell line after the addition of immune interferon (IFN-gamma) or of IFN-gamma-containing supernatants from Con A-stimulated spleen cells. The marked increase in mRNA levels for these molecules at approximately 8 hr after IFN-gamma addition contrasts sharply with the earlier, more gradual kinetics observed for class I (H-2) and beta 2-microglobulin mRNA. The difference in kinetics of IFN-gamma induction of class I and class II mRNA suggests differential regulation of the expression of Ia and H-2 antigens. The long lag period preceding detection of Ia mRNA raises the possibility that IFN-gamma may not directly mediate the increase in mRNA expression, but may act through an additional cellular intermediate.