Evidence that IFN-gamma does not affect MHC class II gene expression at the post-transcriptional level in a mouse macrophage cell line

MHC Class II levels and intracellular localization in human dendritic cells are regulated by calmodulin kinase II

Dendritic cells (DC) are professional APC, which activate the adaptive immune response. A Ca2+-calmodulin (CaM)-CaM kinase II (CaMKII) pathway regulates maturation and MHC Class II antigen presentation in human DC. The objective of this study was to characterize the mechanisms by which CaMKII modulates the levels and subcellular distribution of MHC Class II molecules. Inhibition of CaMKII via the highly specific, autoinhibitory peptide derived from the enzyme's regulatory domain resulted in rapid (60 min) and sustained (24 h) reduction of MHC Class II levels in antigen-stimulated, primary, human DC. The initial depletion of intracellular and cell surface MHC Class II was associated with its enhanced lysosomal trafficking and increased activity of specific proteases in the absence of effects on other transmembrane proteins (CD1b and CD34) or a detectable change in lysosomal degradation of exogenous protein. Inhibition of CaMKII also resulted in significant reductions in the level and stability of MHC Class II mRNA and the levels and nucleocytosolic localization of its major transcriptional regulator CIITA. These data support a model in which CaMKII regulates the levels and localization of MHC Class II protein in human DC via transcriptional, post-transcriptional, and post-translational mechanisms. These pathways are likely important to the physiologic regulation of MHC Class II as well as to its dysregulation in disease states associated with altered CaMKII function.

Downregulation of CIITA function by protein kinase a (PKA)-mediated phosphorylation: mechanism of prostaglandin E, cyclic AMP, and PKA inhibition of class II major histocompatibility complex expression in monocytic lines

Prostaglandins, pleiotropic immune modulators that induce protein kinase A (PKA), inhibit gamma interferon induction of class II major histocompatibility complex (MHC) genes. We show that phosphorylation of CIITA by PKA accounts for this inhibition. Treatment with prostaglandin E or 8-bromo-cyclic AMP or transfection with PKA inhibits the activity of CIITA in both mouse and human monocytic cell lines. This inhibition is independent of other transcription factors for the class II MHC promoter. These same treatments also greatly reduced the induction of class II MHC mRNA by CIITA. PKA phosphorylation sites were identified using site-directed mutagenesis and phosphoamino acid analysis. Phosphorylation at CIITA serines 834 and 1050 accounts for the inhibitory effects of PKA on CIITA-driven class II MHC transcription. This is the first demonstration that the posttranslational modification of CIITA mediates inhibition of class II MHC transcription.

LPS upregulates MHC class II I-A expression in B lymphocytes at transcriptional and at translational levels

Major histocompatibility complex (MHC) class II molecules are expressed in a limited number of cell types, including B lymphocytes, dendritic cells and macrophages. Lipopolysaccharide (LPS) increases the surface expression of class II molecules in a murine B-cell line by inducing an increase in I-A protein and I-A mRNA levels. LPS does not modify the rate of mRNA degradation; therefore, the increase in mRNA is due to an increase in transcription. In addition, LPS increases the levels of I-Aalpha protein, which correlates with an increase in ribosome loading for I-Aalpha but not for I-Abeta mRNA after treatment with LPS. Interestingly, in non-induced cells, I-Aalpha messenger RNA shows a significant peak of free mRNA. Therefore, LPS regulates the expression of MHC class II molecules at translational level in B cells, in addition to the transcriptional control. The actual mechanism implies changes of translation initiation rates, as shown by an increase ribosome loading in polysome gradients.

Translational Control of MHC Class II I-A Molecules by IFN-γ

MHC class II molecules are expressed in a limited number of cell types, including B lymphocytes and macrophages (Mφ). IFN-γ increases the surface expression of class II molecules in a murine B cell line without inducing detectable changes in either I-A or I-A mRNA levels. In bone marrow-derived Mφ, IFN-γ causes an increase in class II expression at both the mRNA and surface levels. In addition to the increase in transcription rates described for Mφ, IFN-γ increases the rate of synthesis of IAα and IAβ proteins and the ribosome loading for both mRNA molecules in both cell types. Interestingly, there is a significant peak of free I-A mRNA in noninduced cells. Therefore, IFN-γ regulates the expression of MHC class II molecules at the translational level in both B cells and Mφ and, as already reported, at the transcriptional level only in Mφ. The actual mechanism of regulation causes changes in the translation initiation rates in both cell types, as demonstrated by an increase in ribosome loading in polysome gradients.

Stabilization of invariant chain mRNA by 12-O-tetradecanoylphorbol-13-acetate is blocked by IFN-gamma in a murine B lymphoma cell line

Activation of protein kinase C (PKC) by 12-O-tetradecanoylphorbol-13-acetate (TPA) increased steady-state levels of mRNA encoding the major histocompatibility complex (MHC) class II antigen I-A beta and the class II antigen-associated invariant chain (Ii, CD74) in A20 B lymphoma cells and in normal mouse B cells. The increase in Ii mRNA levels appeared to be due to a slight increase in the rate of gene transcription and an increase in the stability of Ii mRNA. The half-life of Ii mRNA increased from 12 h to >24 h following treatment with TPA, as determined by Northern blot analysis following actinomycin D treatment or by the [3H]-uridine pulse-chase method. Interferon-gamma (IFN-gamma), which has been well characterized as a cytokine that induces class II antigens and the Ii, increased Ii expression slightly in A20 cells. However, cotreatment of cells with TPA and IFN-gamma resulted in a block in the TPA-induced increase in Ii expression. Transcription of the Ii gene was minimally affected following treatment with IFN-gamma alone, and cells treated with both TPA and IFN-gamma had the same transcription rate as the control cells. IFN-gamma did, however, block stabilization of Ii mRNA by TPA. Activation of PKC by TPA, which was previously shown to lead to membrane translocation and downregulation, was not inhibited by IFN-gamma. Therefore, IFN-gamma appeared to block a downstream signal transduction pathway activated by PKC that controls stability of Ii mRNA.

I-A beta gene expression regulation in macrophages derived from mice susceptible or resistant to infection with M. bovis BCG

The innate capacity of mice to control mycobacterial multiplication early after infection is controlled by the resistant allele of the Nramp-1/Bcg gene. The Bcg gene seems to be involved in a pathway leading to macrophage activation. It differentially affects the ability of BCG-resistant and -susceptible strains of mice to express important macrophage genes including Major Histocompatibility Complex (MHC) class II genes. An inhibition of Nramp1 gene by Nramp1-ribozyme transfection in macrophages resulted in the impairment of MHC class II gene induction by IFN gamma. In this study, we have investigated the molecular mechanisms involved in IFN-gamma-induced MHC class II expression using macrophages derived from mice resistant or susceptible to mycobacterial infections (B10R and B10S, respectively). We have found that the difference in the IFN gamma-induced Ia surface protein expression between B10R and B10S macrophages correlate with a higher rate of I-A beta gene transcription. We have also studied the binding of proteins prepared from nuclear extracts of non-stimulated and IFN-gamma-stimulated B10R and B10S macrophages to the S, X and Y cis-acting elements of the I-A beta promoter. Differences observed in protein binding to the X box may explain the difference in transcription activation of the I-A beta gene. We have also found that I-A alpha and I-A beta mRNA half-lives measured in IFN gamma-stimulated cells are significantly longer in B10R, compared to B10S macrophages. Overall, our data suggest that both transcriptional and posttranscriptional regulatory mechanisms are responsible for the more efficient expression of I-A beta gene in macrophages carrying a resistant allele of Nramp1 gene.

Uncoordinate induction and differential regulation of HLA class-I and class-II expression by gamma-interferon in differentiating human neuroblastoma cells

Recombinant gamma-interferon (IFN-gamma) has recently been shown to be one of the most effective inducers of neuroblastoma (NB) cell differentiation. Since increasing evidence indicates that expression of MHC class-I and class-II antigens by tumour cells is important for immunorecognition and cell targeting, we tested whether induction of NB cell differentiation by IFN-gamma is followed by expression of HLA class-I and class-II molecules. LAN-5 human NB cell line completely lacks HLA class-I antigens. Their expression was induced in a dose-dependent manner by IFN-gamma. HLA class-II molecules are also absent on LAN-5 cells, but only DP antigens were dose-dependently induced by IFN-gamma, while DR and DQ molecules were unaffected by the treatment. To confirm and extend the immunological data to all the class-II molecules, we performed Northern blot analysis, observing that DP alpha mRNA was induced in a dose- and time-dependent manner. DO beta and DZ alpha genes were also induced peaking after 3 days of IFN-gamma treatment. DR beta and DQ beta genes, which were not induced by IFN-gamma, gave a normal pattern of enzyme restriction by Southern blot. To get an insight into the regulation of HLA class-II gene expression in the neuronal model, we measured the decline of the steady-state HLA class-II mRNA. DO beta mRNA rapidly returned to baseline level after removing IFN-gamma, while the decay rates of DP alpha and DZ alpha mRNA were very slow. This might indicate different regulation at the post-transcriptional level for DO beta mRNA with respect to DP alpha and DZ alpha mRNA. To strengthen these findings we evaluated the half-lives of the mRNA after IFN-gamma induction by means of actinomycin D treatment. HLA-DO beta mRNA had a shorter half-life, while DZ alpha and DP alpha had a longer decay rate. Finally, we report that treatment of LAN-5 cells with cycloheximide did not alter the rate of transcription of the HLA-DP alpha gene, suggesting that no protein factor(s) is/are needed to maintain DP alpha gene expression.

Distinct IL-4 response mechanisms of the MHC gene A alpha in different mouse B cell lines

Interleukin-4 (IL-4) is a multipotent cytokine which stimulates proliferation of B and T lymphocytes, induces B lymphocyte expression of major histocompatibility complex (MHC) class II molecules and Fc epsilon R II (CD23) molecules, and promotes immunoglobulin class switching to IgE and IgG1. The mechanisms by which IL-4 induces these changes are unclear. To study the basis for heterogeneity in induction of class II MHC proteins observed in splenic B cells, three mouse B cell lines were treated with IL-4, and the response of MHC class II A alpha mRNA was analyzed. Each of the three cell lines responded with a distinctive profile. In one line, 70Z/3, A alpha mRNA was induced greater than 10 fold by 65 hr of IL-4 stimulation. Additional studies showed that A alpha mRNA was stabilized by IL-4 treatment of 70Z/3 cells, and that changes in gene transcription accounted for little of the increase in mRNA levels. A second line, WEHI.231, was shown to increase A alpha mRNA levels 4 fold after 48 hr of IL-4 treatment. In contrast to 70Z/3, when A alpha mRNA stability in the IL-4 treated WEHI.231 cells was compared to untreated cells, no difference was observed, IL-4 treatment induced A alpha transcription. The third cell line, M12.4.1, expressed high basal levels of A alpha, and these levels increased only slightly following IL-4 stimulation. The small increase correlated with a comparable transcriptional response. These data shown that the nature of the A alpha gene response to IL-4 differs among B cell lines. This heterogeneity of response is consistent with responses in total splenic B cells, and with the existence of functionally distinct subpopulations of B cells.

Human chromosome 16 encodes a factor involved in induction of class II major histocompatibility antigens by interferon gamma

Interferon gamma (IFN-gamma) induces expression of class II major histocompatibility complex (MHC)-encoded antigens in immunocompetent cells. To gain further insight into the mechanism of this induction, we prepared somatic cell hybrids between different human cell lines and a murine cell line, RAG, that does not express murine class II MHC antigens before or after treatment with murine IFN-gamma. Some of the resulting cell hybrids express murine class II MHC antigens when treated with murine IFN-gamma. This inducible phenotype is correlated with the presence of human chromosome 16. It has been shown previously that the induction of class I MHC antigens by human IFN-gamma in human-rodent hybrids requires the presence of species-specific factors encoded by chromosome 6, which bears the gene for the human IFN-gamma receptor, and chromosome 21, whose product(s) is necessary for the transduction of human IFN-gamma signals. In this report, we show that the induction of murine class II MHC antigens by human IFN-gamma in the human-RAG cell hybrids requires, likewise, the presence of human chromosomes 6 and 21, in addition to chromosome 16. In some of these hybrids, when all three of these human chromosomes were present, induction of cell-surface HLA-DR antigens was also observed. Our results demonstrate that human chromosome 16 encodes a non-species-specific factor involved in the induction of class II MHC antigens by IFN-gamma.

The same CCAAT box-binding factor binds to the promoter of two coordinately regulated major histocompatibility complex class II genes

Using competition mobility shift, methylation interference, and proteolytic clipping DNA binding assays, we demonstrate that the protein binding the major histocompatibility complex A beta CCAAT box is indistinguishable from the protein previously named NF-Y, which binds the major histocompatibility complex E alpha CCAAT box. Although the two CCAAT boxes share the same 10-base core sequence, termed the Y box, their flanking sequences, known to be important for binding, are very different.