Sam J. P. Gobin

REGULATION OF MHC CLASS I AND II GENE TRANSCRIPTION : DIFFERENCES AND SIMILARITIES

Major histocompatibility complex (MHC) molecules serve as peptide receptors. These peptides are derived from processed cellular or extra-cellular antigens. The MHC gene complex encodes two major classes of molecules, MHC class I and class II, whose function is to present peptides to CD8+ (cytotoxic) and CD4+ (helper) T cells, respectively. The genes encoding both classes of MHC molecules seem to originate from a common ancestral gene. One of the hallmarks of the MHC is its extensive polymorphism which displays locus and allele-specific characteristics among the various MHC class I and class II genes. Because of its central role in immunosurveillance and in various disease states, the MHC is one of the best studied genetic systems. This review addresses several aspects of MHC class I and class II gene regulation in human and in particular, the contribution to the constitutive and cytokine-induced expression of MHC class I and II genes of MHC class-specific regulatory elements and regulatory elements which apparently are shared by the promoters of MHC class I and class II genes.

The RFX Complex Is Crucial for the Constitutive and CIITA-Mediated Transactivation of MHC Class I and β2-Microglobulin Genes

In type III bare lymphocyte syndrome (BLS) patients, defects in the RFX protein complex result in a lack of MHC class II and reduced MHC class I cell surface expression. Using type III BLS cell lines, we demonstrate that the RFX subunits RFX5 and RFXAP are crucial for constitutive and CIITA-induced MHC class I and beta2m transactivation. Similar to MHC class II, the promoters of MHC class I and beta2m contain an S-X-Y region of which the X1 box is crucial for constitutive and CIITA-induced MHC class I and beta2m transactivation. Thus, the RFX complex is part of a regulatory pathway linking the transactivation of MHC class I and II and their accessory genes.

SHARED REGULATORY ELEMENTS IN THE PROMOTERS OF MHC CLASS I AND CLASS II GENES

Abstract The finding that the major histocompatibility complex (MHC) class II trans-activator (CIITA) gene product plays a role in the regulation of transcription of MHC class I genes suggests a common regulation of transcription of class I and class II genes. Here, Peter van den Elsen and colleagues argue that the RFX complex also plays a role in the regulation of transcription of class I genes.

Transcriptional regulation of the MHC class Ib genes HLA-E, HLA-F, and HLA-G

The restricted tissue expression of the MHC class Ib molecules HLA-E, HLA-F, and HLA-G has suggested specialized functions and tight transcriptional control of their genes. Transactivation of classical MHC class I genes is mediated by two groups of juxtaposed cis-acting elements, which can be viewed as regulatory modules. The most upstream module consists of the enhancer A and ISRE, and mediates constitutive and cytokine induced expression, whereas the SXY module is important for the constitutive and CIITA-mediated transactivation of MHC class I genes. Nucleotide sequence divergence in these regulatory elements in the promoters of HLA-E, HLA-F, or HLA-G determines their differential responsiveness to NF-kappaB, IRF1, and CIITA-mediated induction. HLA-E is not inducible by NF-kappaB or IRF1, but is responsive to IFN-gamma through an upstream STAT1 binding site. Furthermore, HLA-E is inducible by CIITA through the SXY regulatory module. HLA-F is inducible by NF-kappaB through the kappaB1 site of enhancer A, is responsive to IFN-gamma through the ISRE, and is inducible by CIITA. Both regulatory modules are divergent in HLA-G rendering this gene unresponsive to NF-kappaB, IRF1, and CIITA-mediated induction. This implies a unique regulation of HLA-G transcription amongst the MHC class Ib genes.

Lack of CIITA expression is central to the absence of antigen presentation functions of trophoblast cells and is caused by methylation of the IFN-γ inducible promoter (PIV) of CIITA

Lack of MHC-mediated antigen presenting functions of fetal trophoblast cells is an important mechanism to evade maternal immune recognition. In this study we demonstrated that the deficiency in MHC expression and antigen presentation in the trophoblast cell lines JEG-3 and JAR is caused by lack of class II transactivator (CIITA) expression due to hypermethylation of its interferon-gamma (IFN-gamma)-responsive promoter (PIV). Circumvention of this lack of CIITA expression by introduction of exogenous CIITA induced cell surface expression of HLA-DR, -DP, and -DQ, leading to an acquired capacity to present antigen to antigen-specific T cells. Transfection of CIITA in JEG-3 cells also upregulated functional HLA-B and HLA-C expression. Noteworthy, this lack of IFN-gamma-mediated induction of CIITA was also found to exist in normal trophoblast cells expanded from chorionic villus biopsies. Together, these observations demonstrate that lack of CIITA expression is central to the absence of antigen presentation functions of trophoblast cells.

Upregulation of transcription factors controlling MHC expression in multiple sclerosis lesions.

The expression of major histocompatibility complex (MHC) class I and class II in the CNS has received considerable interest because of its importance in neurodegenerative or inflammatory diseases, such as multiple sclerosis (MS). However, at the moment nothing is known about the expression patterns of transcription factors controlling MHC expression in MS lesions. Here, we performed an extensive immunohistochemical analysis on MS affected postmortem brain tissue to determine the cellular localization and distribution of different MHC‐controlling transcription factors. We show that phagocytic macrophages in active demyelinating MS lesions displayed a moderate to strong immunostaining of the MHC‐specific transcription factors RFX and CIITA, as well as the general transcription factors NF‐κB, IRF1, STAT1, USF, and CREB, which was congruent with a strongly enhanced expression of HLA‐DR, HLA‐DQ, HLA‐DP, and HLA class I. In the normal‐appearing white matter (NAWM), clusters of activated microglial cells forming preactive lesions displayed an overall stronger expression level of these transcription factors, combined with a strong to intense level of MHC class I and class II immunostaining. In general, astrocytes and oligodendrocytes either did not express, or weakly expressed, these transcription factors, correlating with a lack of MHC class II and weak MHC class I expression. Together, the elevated expression level of transcription factors governing expression of MHC class I and class II molecules in activated microglial cells and phagocytic macrophages strongly suggests a general state of microglial cell activation in MS lesions. GLIA 36:68–77, 2001.

The MHC-Specific Enhanceosome and Its Role in MHC Class I and β2-Microglobulin Gene Transactivation

The promoter regions of MHC class I and β2-microglobulin (β2m) genes posses a regulatory module consisting of S, X, and Y boxes, which is shared by MHC class II and its accessory genes. In this study we show that, similar to MHC class II, the SXY module in MHC class I and β2m promoters is cooperatively bound by a multiprotein complex containing regulatory factor X, CREB/activating transcription factor, and nuclear factor Y. Together with the coactivator class II transactivator this multiprotein complex drives transactivation of these genes. In contrast to MHC class II, the multiprotein complex has an additional function in the constitutive transactivation of MHC class I and β2m genes. The requirement for all transcription factors in the complex and correct spacing of the binding sites within the SXY regulatory module for complex formation and functioning of this multiprotein complex strongly suggests that this complex can be regarded as a bona fide enhanceosome. The general coactivators CREB binding protein, p300, general control nonderepressible-5, and p300/CREB binding protein-associated factor exert an ancillary function in MHC class I and β2m transactivation, but exclusively through the class II transactivator component of this enhanceosome. Thus, the SXY module is the basis for a specific enhanceosome important for the constitutive and inducible transactivation of MHC class I and β2m genes.

A Novel Autocrine Pathway of Tumor Escape from Immune Recognition: Melanoma Cell Lines Produce a Soluble Protein That Diminishes Expression of the Gene Encoding the Melanocyte Lineage Melan-A/MART-1 Antigen Through Down-Modulation of Its Promoter

We have observed that malignant melanoma cells produce a soluble protein factor(s), which down-regulates melanocyte lineage Melan-A/MART-1 Ag expression by melanoma cells with concomitant loss of recognition by Melan-A/MART-1-specific T cells. This down-modulation of Melan-A/MART-1 expression, which we refer to as “Ag silencing,” is mediated via its minimal promoter, whereas the promoter for the restricting Ag-presenting HLA-A2 molecule is not affected. Significantly, this Ag silencing is reversible, as removal of factor-containing supernatants from Melan-A/MART-1-expressing cells results in up-regulation of the promoter for the gene encoding this Ag, and renewed expression of the protein. We have evaluated over 20 known factors, none of which accounts for the Ag-silencing activity of the melanoma cell culture supernatants. The existence of this autocrine pathway provides an additional novel explanation for melanoma tumor progression in vivo in the presence of CTL specific for this melanocyte lineage Ag. These observations may have important implications for Melan-A/MART-1-specific CTL-mediated immunotherapy of melanoma tumors.

Differential expression regulation of the alpha and beta subunits of the PA28 proteasome activator in mature dendritic cells.

Activation of dendritic cells (DC) by Th-dependent (CD40) or -independent (LPS, CpG, or immune complexes) agonistic stimuli strongly enhances the expression of the proteasome activator PA28αβ complex. Upon activation of DC, increased MHC class I presentation occurred of the melanocyte-associated epitope tyrosinase-related protein 2180-188 in a PA28αβ-dependent manner. In contrast to other cell types, regulation of PA28αβ expression in DC after maturation was found to be IFN-γ independent. In the present study, we show that expression of PA28α and β subunits was differentially regulated. Firstly, PA28α expression is high in both immature and mature DC. In contrast, PA28β expression is low in immature DC and strongly increased in mature DC. Secondly, we show the presence of a functional NF-κB site in the PA28β promoter, which is absent in the PA28α promoter, indicating regulation of PA28β expression by transcription factors of the NF-κB family. In addition, glycerol gradient analysis of DC lysates revealed elevated PA28αβ complex formation upon maturation. Thus, induction of PA28β expression allows proper PA28αβ complex formation, thereby enhancing proteasome activity in activated DC. Therefore, maturation of DC not only improves costimulation but also MHC class I processing. This mechanism enhances the CD8+ CTL (cross)-priming capacity of mature DC.

HLA-G transactivation by cAMP-response element-binding protein (CREB). An alternative transactivation pathway to the conserved major histocompatibility complex (MHC) class I regulatory routes.

The expression of HLA-G in extravillous cytotrophoblast cells coincides with a general lack of classical major histocompatibility complex (MHC) class I expression in this tissue. This differential expression of HLA-G and classical HLA class I molecules in trophoblasts suggests a tight transcriptional control of MHC class I genes. Transactivation of the classical MHC class I genes is mediated by two groups of juxtaposed cis-acting elements that can be viewed as regulatory modules. Both modules are divergent in HLA-G, rendering this gene unresponsive to NF-κB, IRF1, and class II transactivator (CIITA)-mediated induction pathways. In this study, we searched for alternative regulatory elements in the 1438-bp HLA-G promoter region.HLA-G was not responsive to interferon-α (IFNα), IFNβ, or IFNγ, despite the presence of an upstream ISRE binding IRF1 in vitro. However, the HLA-G promoter contains three CRE/TRE elements with binding affinity for CREB/ATF and Fos/Jun proteins both in vitro and in vivo. In transient transfection assays, it was shown that HLA-Gtransactivation is regulated by CREB, CREB-binding protein (CBP), and p300. Moreover, immunohistochemical analysis demonstrated that HLA-G is co-expressed with CREB and CBP in extravillous cytotrophoblasts, revealing the in vivo relevance of this transactivation pathway. This implies a unique regulation of HLA-Gtranscription among the MHC class I genes.