Pronounced up-regulation of the PA28alpha/beta proteasome regulator but little increase in the steady-state content of immunoproteasome during dendritic cell maturation.

Dendritic cells (DC) are professional antigen-presenting cells that activate CTL by presenting MHC class I-restricted peptides that are processed through the proteasome pathway. Previously, we reported that upon DC maturation the synthesis is switched towards the exclusive production of immunoproteasomes containing the active site subunits LMP2, LMP7 and MECL-1. In this study we investigated the mechanism by which proteasome assembly is regulated in mature DC. Quantitative analysis of mRNA expression showed very limited transcriptional induction of LMP7, MECL-1 and UMP1 in mature DC and a moderate mRNA increment for LMP2 and PA28alpha and beta. We investigated a role of PA28alpha/beta in regulating proteasome assembly in DC. PA28alpha/beta coprecipitated with 13S/16S proteasome precursor complexes but associated with mature constitutive and immunoproteasomes to the same extent. Furthermore, we determined the steady-state proteasome subunit composition in DC. Replacement of constitutive proteasomes by immunoproteasomes in maturing DC was very slow and occurred only to a minor extent. Our data suggest that the limited turnover of 20S proteasomes in mature DC probably contributes little to recently reported marked differences in antigen presentation between immature and mature DC and that alternative mechanisms may be responsible for this phenomenon.

Structural plasticity of the proteasome and its function in antigen processing.

The proteasome is the main provider of peptide ligands for major histocompatibility complex class I molecules. During an immune response to pathogens, the proinflammatory cytokine interferon (IFN)-gamma and tumor necrosis factor (TNF)-alpha are released, which induce the proteasome subunits LMP2, LMP7, and MECL-1. These replace the constitutively expressed active site subunits of the proteasome (delta, MB1, and Z) leading to a marked change in the cleavage preference of the proteasome and the production of T-cell epitopes. Proteasome activity is further changed by the IFN-gamma-mediated induction of the proteasome regulator PA28alpha/beta and the downregulation of PA28gamma. Why such an extensive exchange of proteasome active site subunits and regulators occurs is still poorly understood. In this article we discuss recent insights in the structural consequences of proteasome reorganization and their effects on epitope generation and shaping of the cytotoxic immune response. Moreover, we review the latest data on how the ubiquitin pathway targets protein antigens for peptide processing and discuss the potential of proteasome inhibitors for the modulation of antigen presentation.

Dendritic cells up-regulate immunoproteasomes and the proteasome regulator PA28 during maturation.

Dendritic cells (DC) are highly specialized professional antigen presenting cells which are pivotal for the initiation and control of the cytotoxic T cell response. Upon stimulation by cytokines, bacteria, or CD40L DC undergo a maturation process from an antigen-receptive state to a state of optimal stimulation of T cells. We investigated the composition of proteasomes of DC derived from human peripheral blood monocytes before and after stimulation by CD40L, LPS, or proinflammatory cytokines (TNF-alpha + IL-6 + IL-1beta). Immunoprecipitation of proteasomes and analysis on two-dimensional gels revealed that during maturation the inducible proteasome subunits LMP2, LMP7, and MECL-1 are up-regulated and that the neosynthesis of proteasomes is switched exclusively to the production of immunoproteasomes containing these subunits. The proteasome regulator PA28 is markedly up-regulated in mature DC and in addition a so - far unidentified 21-kDa protein co-precipitates with the proteasome in LPS - stimulated DC. These changes in proteasome composition may be functionally linked to special properties of DC like MHC class I up-regulation or cross-priming. Our findings imply that the spectrum of class I-bound peptides may change after DC maturation which could be relevant for the design of DC - based vaccines.

Specific sequence-directed anti-bilitranslocase antibodies as a tool to detect potentially bilirubin-binding proteins in different tissues of the rat.

The hypothesis that the uneven distribution of bilirubin in the organism, which occurs in hyperbilirubinemia, could reflect an uneven distribution of bilirubin-binding proteins was tested by searching for peptides containing the bilirubin-binding motif identified in bilitranslocase (Battiston et al., 1998). In the rat, positive proteins bands were found to be present only in the liver, gastric mucosa and central nervous system. The electrophoretic mobilities of the positive compounds in the liver and stomach were identical to that of purified bilitranslocase (38 kDa). In the brain, on the contrary, two peptides were found with molecular masses of 79 and 34 kDa, respectively. Their distribution pattern in the central nervous system was different for each of them.

The bilirubin-binding motif of bilitranslocase and its relation to conserved motifs in ancient biliproteins.

In the primary structure of bilitranslocase, currently under study in our laboratory, an aminoacid motif was identified and found to be conserved in a number of alpha-phycocyanines, ancient biliproteins present in cyanobacteria. To test the possibility that such a motif could be at least part of the binding site for bilirubin, epitope-specific antibodies were raised. The target corresponds to the sequence 65-75 of bilitranslocase and covers the central portion of the motif identified. The antibodies were shown: 1) to inhibit the electrogenic BSP transport by plasmamembrane vesicles; 2) to react with purified bilitranslocase; and 3) to identify only one protein band with electrophoretic mobility identical to bilitranslocase in Western blots of solubilised plasmamembrane vesicles. The presence of either bilirubin or nicotinate during pre-incubation with the antibodies decreases concentration-wise the inhibition kinetics. From these experiments a dissociation constant of 2.2 +/- 0.3 and 11.3 +/- 1.3 nM for bilirubin-bilitranslocase and nicotinate-bilitranslocase complexes were calculated.