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.     

Inhibition of MHC class II expression and immune responses by c-MIR

We previously reported a novel E3 ubiquitin ligase (E3), designated as c-MIR, which targets B7-2 to lysosomal degradation and down-regulates the B7-2 surface expression through ubiquitination of its cytoplasmic tail. B7-2 is well known as a costimulatory molecule for Ag presentation, suggesting that the manipulation of c-MIR expression modulates immune responses in vivo. To examine this hypothesis, we generated genetically modified mice in which c-MIR was expressed under an invariant chain (Ii) promoter. Dendritic cells derived from genetically engineered mice showed low ability to present Ags. In addition, these mice showed resistance to the onset of experimental autoimmune encephalomyelitis and an impaired development of CD4 T cells in the thymus and the periphery. These findings led us to conclude that MHC class II (MHC II) is an additional target for c-MIR. Indeed, forced expression of c-MIR in several B cell lines down-regulated the surface expression of MHC II, and down-regulation was found to depend on the presence of a single lysine residue in the cytoplasmic tail of the I-A beta-chain. In a reconstitution system using 293T cells, we found that the lysine residue at position 225 in the I-A beta-chain was ubiquitinated by c-MIR. To our knowledge, c-MIR is the first example of an E3 that is capable of inhibiting MHC II expression. Our findings suggest that c-MIR might potently regulate immune responses in vivo.     

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.     

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.     

Differential expression of the invariant chain in mouse tumor cells: relationship to B lymphoid development

We have examined 25 cultured lines of mouse tumor cells for synthesis of the Ii, an Ia-associated polypeptide, by using an anti-Ii monoclonal antibody. Six of the T lymphomas tested did not produce detectable levels of Ii or of surface Ia antigens. Three B lymphomas and two plasmacytomas that express surface Ia antigens were found to synthesize the Ii. In addition, Ii was immunoprecipitated from two of five Ia- pre-B lymphomas, two of four Ia- plasmacytomas, two Ia- myeloid tumors, and two fibroblast cell lines including LM(TK-). Because Ia antigens have so far been found only on cells that also synthesize Ii, we suggest that the Ii is a marker of those cells that in certain states of development or activation express Ia antigens.     

Differential expression of Ia and Ia-associated invariant chain in mouse tissues after in vivo treatment with IFN-gamma

B10.BR mice were injected i.v. with varying doses of recombinant IFN-gamma on three consecutive days. In tissue sections of 13 organs, the distribution of Ia antigens and Ia-associated invariant chain (Ii) was studied by using an immunoperoxidase technique. In the control animal, Ia and Ii were shown to be co-expressed in most tissues. However, on Kupffer cells, a small number of hepatocytes, and a subset of lymphocytes in lymph nodes and in the splenic red pulp only Ii, and no Ia, was detectable. In contrast, strongly Ia+ interdigitating reticulum cells of T-dependent areas of lymph nodes and spleen were only weakly stained for Ii. IFN-gamma treatment resulted in a dramatic increase of MHC antigen expression throughout the body, with striking differences in the inducibility of certain tissues for Ia and Ii: Bronchial epithelium was clearly induced to express the invariant chain, whereas Ia antigens remained entirely absent. Moreover, in kidney tubules and colon epithelium, Ii was induced more broadly than Ia. In contrast to the induction of Ii on endothelial cells of larger vessels in kidney, heart, and lungs, no de novo expression of Ia or Ii in capillary endothelial cells was observed. The number of detectable Ia+/Ii+ interstitial dendritic cells considerably increased upon exposure to IFN-gamma. Neither neurons nor glial cells were induced to MHC antigen expression. Our data demonstrate that IFN-gamma applied i.v. is a potent inducer or enhancer of Ia antigens and invariant chain in a variety of cell types.     

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.     

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.     

The I-A beta b region (65-85) is a binding site for the superantigen, staphylococcal enterotoxin A

Ia antigen is a receptor for the superantigen staphylococcal enterotoxin A (SEA). Peptides I-A beta b(30-60), I-A beta b(50-70), I-A beta b(65-85), and I-A beta b(80-100) of the MHC class II antigen beta chain on mouse (H-2b) accessory cells were synthesized. Only I-A beta b(65-85) inhibited SEA binding to the mouse B-cell lymphoma line, A20 (H-2d) and the human Burkitt's lymphoma line, Raji (HLA-DR). The I-A beta b(65-85) sequence is a predicted alpha-helix along the hypothetical antigen binding cleft of the Ia molecule. I-A beta b(65-85) also directly and specifically bound both the intact SEA molecule and its Ia binding site, represented by the peptide SEA(1-45). The results suggest that I-A beta b region (65-85) is a necessary site for Ia molecular interaction with the superantigen SEA. Further, the data suggest that the same helical region of other Ia antigens binds SEA irrespective of haplotype and species.     

Turnover and fate of I-Ak antigen on the murine macrophage cell surface

The macrophage plasma membrane is a major site of the cell's activities, including phagocytosis, antibody-dependent cellular cytotoxicity, and antigen presentation. To present antigen, the expression by the macrophage of immune region-associated (Ia) antigen is required. The turnover and fate of this cell surface constituent was studied in macrophages cultured with lymphokine or recombinant interferon-gamma. Surface-labeled subregion I-Ak antigen was lost from the cell surface at a rapid rate, with a half-life of approximately 24 hours. However, the shedding of I-A antigen into the culture fluid was not detected. Therefore, the loss of I-A antigen from the macrophage surface is most likely by its degradation. Upon removal of lymphokine or interferon from macrophage cultures, I-A antigen expression declined, with an apparent half-life of 2 days.     

Characterization of a spontaneous murine B cell leukemia (BCL1). I. Cell surface expression of IgM, IgD, Ia, and FcR.

The surface marker expression of a spontaneous B lymphocyte leukemia discovered in a BALB/c mouse (BCL1) was examined and found to include a subset of markers known to occur on normal B lymphocytes. The tumor cells bore surface Ig that included both mu- and delta-chains associated with the lambda light chain. Alloantigens coded for within the murine MHC, including H-2D, H-2K, and I-region products, were identified on the tumor cells. Although normal B lymphocytes are thought to express products coded for within both the I-A and I-E subregions, the BCL1 expressed only normal amounts of I-E subregion products. In addition, the H-2 and Ia antigens revealed by 2-dimensional gel electrophoresis exhibited an abnormal pattern of post-translational modifications. The Fc, but not the complement-receptor, was present on the surface of tumor cells. The presence of IgD, Ia antigens, and the responsiveness to lipopolysaccharide (see subsequent paper) have led us to postulate that the BCL1 tumor represents a later differentiative stage than murine B lymphocyte tumors previously described.     

H2-Mbeta 1 and H2-Mbeta 2 heterodimers equally promote clip removal in I-A(q) molecules from autoimmune-prone DBA/1 mice

Antigen-presenting cells degrade endocytosed antigens, e.g. collagen type II, into peptides that are bound and presented to arthritogenic CD4(+) helper T cells by major histocompatibility complex (MHC) class II molecules. Efficient loading of many MHC class II alleles with peptides requires the assistance of H2-M (HLA-DM in humans), a heterodimeric MHC class II-like molecule that facilitates CLIP removal from MHC class II molecules and aids to shape the peptide repertoire presented by MHC class II to CD4(+) T cells. In contrast to the HLA-DM region in humans, the beta-chain locus is duplicated in mice, with the H2-Mb1 beta-chain distal to H2-Mb2 and the H2-Ma alpha-chain gene. H2-M alleles appear to be associated with the development of autoimmune diseases. Recent data showed that Mbeta1 and Mbeta2 isoforms are differentially expressed in isolated macrophages and B cells, respectively. The tissue expression and functional role of these heterodimers in promoting CLIP removal and peptide selection have not been addressed. We utilized the human T2 cell line, which lacks part of chromosome 6 encompassing the MHC class II and DM genes, to construct transgenic cell lines expressing the MHC class II heterodimer I-A(q) alone or in the presence of H2-Malphabeta1 or H2-Malphabeta2 heterodimers. Both H2-M isoforms facilitate the exchange of CLIP for cognate peptides on I-A(q) molecules from arthritis-susceptible DBA/1 mice and induce a conformational change in I-A(q) molecules. Moreover, I-A(q) cell-surface expression is not absolutely dependent on H2-M molecules. These data suggest that I-A(q) exhibits a high affinity for CLIP since virtually all I-A(q) molecules on T2 cells were found to be associated with CLIP in the absence of both H2-M isoforms.     

Role of I-A molecules in early stages of B cell maturation.

The role of the Ia molecule in the early phase of B cell development remains controversial. In contrast to previous studies, we have detected minute amounts of Ia (I-A) molecule on early B lineage (B220+IgM-) cells from normal bone marrow, using ELISA. The presence of the I-A molecule even on pro-B cells was deduced from experiments in which a monoclonal anti-I-A antibody completely blocked the generation of pre-B cells from B progenitor (B220-) cells in stromal cell-dependent B cell culture. Inasmuch as this antibody did not inhibit the maturation of pre-B cells to IgM+ B cells in culture, the I-A molecule on early B lineage cells probably plays a role in their maturation. We also examined the role of the I-A molecule in early B cell development, using transgenic mice harboring the antisense DNA to I-A beta-chain gene. The amount of I-A molecule on splenic B cells from the young transgenic mice decreased in the presence of abundant amounts of the antisense RNA. B cell development was perturbed in spleen from the transgenic mice. Stromal cell-dependent B cell cultures from these mice clearly showed that the maturation of B lineage cells was delayed at a very early stage of development (B220- to B220+). We propose that the I-A molecule on early B lineage cells may play an essential role in their maturation.     

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.     

Cellular and subcellular distribution of PBP72/74, a peptide-binding protein that plays a role in antigen processing

A 72/74-kDa peptide binding protein (PBP72/74) was previously described which plays a role in the processing and/or presentation of Ag, possibly by facilitating the association of processed Ag with the MHC class II molecules. PBP72/74 was recently shown to be related to the 70-kDa family of heat shock proteins (hsp70), whose members show the general characteristic of binding to denatured or inappropriately folded proteins. Here we describe the cellular and subcellular distribution of PBP72/74. By flow cytometry with PBP72/74-specific rabbit antisera, PBP72/74 is detected on the surfaces of mouse Ig+ B cells and MAC-1+ macrophages. PBP72/74 74 was not detected on the surfaces of Thy-1+ T cells or NK1.1+ NK cells. The cell surface expression of PBP72/74 does not require MHC class II expression. Indeed, the Ia- variant B cell lymphoma cell line, M12.C3, expresses PBP72/74 at levels equivalent to that of the Ia+ parent cell line, M12.4.1, from which it was derived. Furthermore, the fibroblast L cell line, DAP.3, shows no cell surface expression of PBP72/74, nor do DAP.3 lines transfected with and expressing genes encoding the alpha- and beta-chain of the I-Ad and I-Ed molecules. Moreover, treatment of B cells with either IL-4 or LPS, which increases Ia expression severalfold, does not affect PBP72/74 expression. Thus, PBP72/74 cell surface expression appears to be a property of B cells and macrophages, independent of Ia expression. In addition, the B cell surface expression of PBP72/74 is not altered by stress in the form of heat shock. Thus, PBP72/74 appears to be a constitutive noninducible member of the hsp70 family. By immunoelectron microscopy, PBP72/74 is detected in approximately 36% of early endocytic vesicles into which surface Ig is internalized after binding to anti-Ig antibodies. This compartment was previously shown to contain class II en route to the cell surface associated with invariant chain and the proteases cathepsin B and D and is suggested to be a subcellular site of antigen processing. PBP72/74 is also found associated with the plasma membrane, endoplasmic reticulum, and membranes proximal to the Golgi stacks. The cellular and subcellular distribution of PBP72/74 is consistent with its playing a role in the processing of presentation of Ag with the MHC class II molecules.     

Activation of dense human tonsilar B cells. Induction of c-myc gene expression via two distinct signal transduction pathways.

Antibodies to surface Ig or to the B cell marker CD20 trigger resting human B cells in similar yet distinct ways. Either antibody induces five-fold increases in the expression of the protooncogene, c-myc, as detected with semi-quantitative Northern blot assays. The induction of c-myc mRNA by anti-IgM or anti-CD20 is blocked by inhibitors of protein kinase C (PKC) such as staurosporine and by pretreatment of B cells with phorbol esters to reduce cellular PKC levels. This suggests that PKC is involved in the pathways stimulated by both anti-IgM and anti-CD20. However, anti-CD20, unlike anti-IgM, does not activate significant increases in inositol triphosphate or intracellular-free calcium. Further, anti-CD20-triggered elevation of c-myc mRNA is inhibited by pertussis and cholera toxins, whereas the pathway initiated by anti-IgM if anything is stimulated by pertussis toxin and unchanged by cholera toxin. Further differences in the nature of these two signals were seen when the expression of adhesion/recognition molecules were examined. Anti-IgM consistently induces increased expression of the adhesion molecules CD54 (I-CAM-1) and B7/BB-1 on B cells, but anti-CD20 does not. Yet both anti-CD20 and anti-IgM increase class II MHC, CD18 (LFA-1 beta-chain) and LFA-3 levels. These data suggest that the way in which B cells are activated may influence their surface phenotype and possibly subsequent migration or cell-cell interactions.     

Changes in Ia expression in mouse kidney during acute graft-vs-host disease

We induced graft-vs-host disease (GVHD) in mice to determine whether immunologic stimuli could alter renal Ia expression. Two strain combinations were used: B6.C-H-2bm12 into C57BL/6, an I-A mutation difference, and A.SW into A.TL, differing in the I and D regions of H-2. By day 10 after allogeneic reconstitution of lethally irradiated recipients with bone marrow and spleen cells, the recipients had developed acute GVHD, as measured by their spleen to body weight ratio. Histologic examination revealed focal interstitial infiltrates of mononuclear cells in the kidneys. The expression of host Ia in these kidneys was increased up to 10-fold, as measured by absorption, and indirect immunofluorescence indicated that certain renal tubule cells had become strongly positive, suggesting that these were the principal sites of the increase in Ia expression. Similar increases were not observed in donor Ia. Tubule cells may have become Ia positive by passive uptake, or more probably, by the increase of Ia biosynthesis in cells that usually synthesize little or no Ia. Lethal irradiation without reconstitution tended to decrease renal Ia expression, as assessed by absorption and immunofluorescence. The results indicate that renal Ia expression, particularly in renal tubules, can be altered by changes in the immune system, raising the possibility of a role for such altered Ia expression in autoimmune or alloimmune responses involving the kidney.