M Kovacsovics-Bankowski’s research while affiliated with Dana-Farber Cancer Institute and other places

To generate Ab responses to most protein Ags, B cells must first degrade proteins in endocytic compartments and then display antigenic peptides bound to MHC class II molecules. T helper lymphocytes recognize these complexes and stimulate the B cell to synthesize Ab. Although Ab play a key role in host defense against bacteria, it is believed that B cells are incapable of internalizing particulate Ags. However, we find that B lymphoblastoid cell lines and LPS-activated B lymphocytes can present particulate Ag up to 10(5)-fold more efficiently compared with soluble Ag. Moreover, particulate Ags are presented efficiently by unstimulated B cells when they bind to surface Ig. In comparison to B cells, macrophages in general presented particulate Ags 10- to 1000-fold more efficiently and could also present Ag from particles of a much wider range of sizes. We document by ultrastructural and immunofluorescence analysis that B lymphoblastoid cell lines bind and internalize these particles. The internalization and presentation of the particulate Ag is inhibited by cytochalasin B. In contrast, a similar morphologic analysis of normal lymphocytes demonstrated that while Ag beads are bound to the cell surface, they are internalized only rarely. These results suggest there may be both surface and intracellular pathways for the presentation of particulate Ags by B cells. Interestingly, for both macrophages and B cells, the epitopes generated from particulate and soluble Ags were not identical quantitatively or qualitatively, indicating that there are differences in how these forms of Ag are processed and presented.

In most cells, antigens (Ag) in the extracellular fluids do not get access into the MHC class I presentation pathway. However Ag targeted into macrophage's (M0) phagosomes can elicit a CD8+ T cell response. To study this novel Ag presenting pathway, we immortalized BMM0 by overexpressing two oncogenes. These cells present particulate exogenous OVA with MHC class I molecules up to 104 fold more efficiently than soluble OVA. Presentation of exogenous Ag on class I is not affected by weak base chloroquine which elevates the pH in endocytic compartment. In contrast, it is blocked by several tripeptide aldehydes. Their potency in inhibiting presentation correlates with their ability to inhibit proteasomes but not other proteases, suggesting that peptides from exogenous antigens presented on MHC class I molecules are generated in the cytosol- Presentation of exogenous antigens with MHC class I molecules requires a functional TAP1TAP2, the peptide transporter that ferries peptides from the cytosol into the endoplasmic reticulum. This presentation pathway is also sensitive to Brefeldin A, whose major action is to inhibit exocytosis of proteins out of the ER. Moreover, phagocytosis of gelonin, a ribosomal-inactivatirig protein, selectively inhibits M0 protein synthesis. Taken together, these data demonstrate that M0 have a unique capacity to transfer protein from phagosomes into the cytosol and that peptides from exogenous and endogenous Ag follow a final common pathway. Studies are in progress to determine how exogenous proteins are translocated into the cytosol.

Cytotoxic T lymphocytes (CTLs) kill neoplastic or virally infected cells after recognizing on their surface antigenic peptides bound to major histocompatibility complex class I molecules. These peptides are derived from antigens that are degraded in the cytosol of the affected cell. Because exogenous proteins cannot enter the cytosol, immunizations with killed pathogens or their proteins do not generally elicit CTLs. However, antigens that are internalized into phagocytic cells can enter the cytosol and be processed for class I presentation. Here we show that immunization with a purified antigen on an avidly phagocytized particle primes CTLs, which in turn protect animals from subsequent challenge with tumours transfected with the antigen gene. Interestingly, these animals also become immune to other antigens expressed by the tumour. This approach could be exploited to develop tumour and viral vaccines.

Peptides from endogenous proteins are presented by major histocompatibility complex class I molecules, but antigens (Ags) in the extracellular fluids are generally not. However, pathogens or particulate Ags that are internalized into phagosomes of macrophages (M phi s) stimulate CD8 T cells. The presentation of these Ags is resistant to chloroquine but is blocked by inhibitors of the proteasome, a mutation in the TAP1-TAP2 transporter, and brefeldin A. Moreover, phagocytosis of a ribosomal-inactivating protein inhibited M phi protein synthesis. These results demonstrate that M phi s transfer Ags from phagosomes into the cytosol and that endogenous and exogenous Ags use a final common pathway for class I presentation.

There is an antigen presenting cell (APC) in the lymphoid organs capable of presenting exogenous antigen (Ag) with major histocompatibility complex (MHC) class I molecules. This study was initiated to isolate clones of these APC to definitively establish their phenotype and to further study their properties. Murine bone marrow macrophages (BM M psi) were immortalized by overexpression myc and raf oncogenes. Five BM M psi cell lines were generated that are phagocytic and expressed at their surface M psi differentiation Ag. All five cell lines processed and presented exogenous ovalbumin (OVA) with MHC class I molecules. They all presented OVA-linked to a phagocytic substrate 10(2)-10(4)-fold more efficiently than soluble Ag. Clonal isolates of two of the M psi cell lines had an identical phenotype and functional properties as the uncloned lines. These results definitively establish that M psi are APC with the capacity of presenting exogenous Ag with MHC class I molecules. Interferon (IFN)-gamma interleukin-4, granulocyte-macrophage colony stimulating factor and lipopolysaccharide either alone or in combination induced little or no augmentation and in some cases decreased presentation of exogenous OVA with MHC class I. In contrast, all of M psi activating factors increased MHC class I expression. Moreover, IFN-gamma increased the presentation of cytosolic OVA, demonstrating differences between the presentation of cytosolic Ag versus exogenous Ag with MHC class I. Finally, some lines constitutively processed and presented exogenous OVA with MHC class II while others only presented after stimulation with IFN-gamma. These results demonstrate that the pathways involved in the presentation of exogenous Ag with MHC class I and class II are independently regulated and that a cloned cell is capable of presenting exogenous Ag through both pathways.

Antigens in extracellular fluids can be processed and presented with major histocompatibility complex (MHC) class I molecules by a subset of antigen presenting cells (APCs). Chicken egg ovalbumin (Ova) linked to beads was presented with MHC class I molecules by these cells up to 10(4)-fold more efficiently than soluble Ova. This enhanced presentation was observed with covalently or noncovalently linked Ova and with beads of different compositions. A key parameter in the activity of these conjugates was the size of the beads. The APC that is responsible for this form of presentation is a macrophage. These cells internalize the antigen constructs through phagocytosis, since cytochalasin B inhibited presentation. Processing of the antigen and association with MHC class I molecules appears to occur intracellularly as presentation was observed under conditions where there was no detectable release of peptides into the extracellular fluids. When injected in vivo in C57BL/6 mice, Ova-beads, but not soluble Ova, primed CD4- CD8+ cytotoxic T lymphocytes (CTLs). Similar results were obtained in BALB/c mice immunized with beta-galactosidase-beads. The implications of these findings for development of nonliving vaccines that stimulate CTL immunity are discussed.