The immediate early protein ICP47 of herpes simplex virus (HSV) inhibits the transporter for antigen processing (TAP)‐mediated translocation of antigen‐derived peptides across the endoplasmic reticulum (ER) membrane. This interference prevents assembly of peptides with class I MHC molecules in the ER and ultimately recognition of HSV‐infected cells by cytotoxic T‐lymphocytes, potentially leading to immune evasion of the virus. Here, we demonstrate that recombinant, purified ICP47 containing a hexahistidine tag inhibits peptide import into microsomes of insect cells expressing human TAP, whereas inhibition of peptide transport by murine TAP was much less effective. This finding indicates an intrinsic species‐specificity of ICP47 and suggests that no additional proteins interacting specifically with either ICP47 or TAP are required for inhibition of peptide transport. Since neither purified nor induced ICP47 inhibited photocrosslinking of 8‐azido‐ATP to TAP1 and TAP2 it seems that ICP47 does not prevent ATP from binding to TAP. By contrast, peptide binding was completely blocked by ICP47 as shown both by photoaffinity crosslinking of peptides to TAP and peptide binding to microsomes from TAP‐transfected insect cells. Competition experiments indicated that ICP47 binds to human TAP with a higher affinity (50 nM) than peptides whereas the affinity to murine TAP was 100‐fold lower. Our data suggest that ICP47 prevents peptides from being translocated by blocking their binding to the substrate‐binding site of TAP.
Using the baculovirus expression system the gene products of human tapl and tap2 were over-expressed as wild-type as well as oligohistidine fusion proteins in Spodopterafrugiperda (Sf9) insect cells, Both gene products were co-expressed within the same cells and were found enriched in microsomal membranes. Immunoprecipitation and immobilized metal affinity chromatography revealed complex formation between TAP1 and TAP2. The expressed TAP complex was shown to be functional by peptide translocation into microsomes of Sf9 cells. Peptide transport strictly requires TAP1 and TAP2 as well as ATE For the first time the functional expression ofthe human TAP complex in insect cells has been demonstrated, indicating that additional cofactors of a highly developed immune system are not essential for peptide transport across microsomal membranes.
Biocompatible inorganic matrices have been used to enhance bone repair by integrating with endogenous bone architecture. Hypothesizing that a three-dimensional framework might support reconstruction of other tissues as well, we assessed the capacity of a tantalum-coated carbon matrix to support reconstitution of functioning thymic tissue. We engineered a thymic organoid by seeding matrices with murine thymic stroma. Co-culture of human bone marrow-derived hematopoietic progenitor cells within this xenogeneic environment generated mature functional T cells within 14 days. The proportionate T-cell yield from this system was highly reproducible, generating over 70% CD3+ T cells from either AC133+ or CD34+ progenitor cells. Cultured T cells expressed a high level of T-cell receptor excision circles (TREC), demonstrating de novo T lymphopoiesis, and function of fully mature T cells. This system not only facilitates analysis of the T-lymphopoietic potential of progenitor cell populations; it also permits ex vivo genesis of T cells for possible applications in treatment of immunodeficiency.
Antigenic peptides are translocated into the lumen of the endoplasmic reticulum by the action of the transporter associated with antigen processing (TAP), where they are subsequently needed for the correct assembly of major histocompatibility complex molecules. The transport function was reconstituted in insect cells by expression of both TAP genes. On the basis of this over-expression system, substrate selection was analyzed in detail by a direct biomolecular peptide binding assay. Competition assays with peptide variants, including substitutions of residues with alanine or structurally related amino acids, underline the broad peptide specificity of the human TAP complex. Steric requirements of the substrate-binding pocket were mapped using elongated peptides and scans with bulky, hydrophobic amino acids. Complex nonapeptide libraries were used to determine the contribution of each residue to stabilize peptide-TAP complexes. For the first time, this approach lets us directly evaluate the importance of peptide selection for the overall process of antigen presentation on the level of the peptide transporter.
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