Ligand-independent signaling functions for the B lymphocyte antigen receptor and their role in positive selection during B lymphopoiesis.

Signal transduction through the B cell antigen receptor (BCR) is determined by a balance of positive and negative regulators. This balance is shifted by aggregation that results from binding to extracellular ligand. Aggregation of the BCR is necessary for eliciting negative selection or activation by BCR-expressing B cells. However, ligand-independent signaling through intermediate and mature forms of the BCR has been postulated to regulate B cell development and peripheral homeostasis. To address the importance of ligand-independent BCR signaling functions and their regulation during B cell development, we have designed a model that allows us to isolate the basal signaling functions of immunoglobulin (Ig)alpha/Igbeta-containing BCR complexes from those that are dependent upon ligand-mediated aggregation. In vivo, we find that basal signaling is sufficient to facilitate pro-B --> pre-B cell transition and to generate immature/mature peripheral B cells. The ability to generate basal signals and to drive developmental progression were both dependent on plasma membrane association of Igalpha/Igbeta complexes and intact immunoregulatory tyrosine activation motifs (ITAM), thereby establishing a correlation between these processes. We believe that these studies are the first to directly demonstrate biologically relevant basal signaling through the BCR where the ability to interact with both conventional as well as nonconventional extracellular ligands is eliminated.

Coordinate regulation of HLA class II genes: a novel DNA binding complex.

We have characterized a nuclear protein complex from B lymphoblastoid cell lines that binds to HLA class II promoters as detected by electrophoretic gel mobility shift assays (EMSA). This complex (C1) binds to three independent sites in the proximal DRA promoter which have not been identified previously as cis-acting elements. C1 is very abundant in Burkitt's lymphoma cell lines, but less abundant in "normal" B lymphoblastoid cell lines. The binding specificity of the C1 complex was analysed using competition experiments and chemical footprinting methods. Complexes with specificity similar to C1 also bind the DPA and DQA promoters. Though mutation of the sequences in the DRA promoter that severely reduced binding of the C1 complex had no effect on the ability of the DRA fragment to drive transcription of the reporter gene in transient expression or in vitro transcription assays, this conservation of binding sites among all class II promoters tested suggests functional relevance in transcription. In addition, complexes similar to C1 were observed in nuclear extracts from all cell lines examined, but minor differences in mobility appeared to correlate with class II expression. Thus, the C1 complex may act as a trans-acting factor in MHC class II expression.

The role of the cytoskeleton and intercellular junctions in the transcellular membrane protein polarity of bovine aortic endothelial cells in vitro.

This project examines the transcellular membrane protein polarity of bovine aortic endothelial cell (BAEC) monolayers in vitro with respect to the roles that intercellular junctions (as defined by comparing confluent and subconfluent monolayers) and the submembranous cytoskeleton play in controlling this phenomenon. Plasma membrane (PM) proteins obtained from apical (AP) and basolateral (BL) PM domains of confluent BAEC monolayers were isolated using the cationic colloidal silica technique and resolved by two-dimensional gel electrophoresis (2-D PAGE). To facilitate the identification of domain-specific PM proteins, an isoelectric point/molecular weight database of the proteins from AP and BL PM domains was constructed. Domain-specific PM proteins were assessed for their interaction with the cytoskeleton by determining whether they co-isolated with a Triton X-100 detergent-resistant cytoskeletal/extracellular matrix fraction. The maintenance of polarized PM protein segregation by intercellular junctional complexes was determined by comparing AP and BL protein patterns of confluent monolayers with patterns generated by subconfluent monolayers, which lack such junctional structures. Proteins isolated from AP and BL PM domains from both confluent states were immunoblotted with antibodies to angiotensin-converting enzyme (ACE) and collagen receptors (CR). ACE was restricted exclusively to the AP PM domain in the subconfluent condition, even though no apparent cytoskeletal interaction was observed. CRs, found to interact with the cytoskeleton in either confluence state, were predominantly segregated to the BL PM domain regardless of the presence or absence of cell-cell contact. Membrane proteins found by 2-D PAGE to be asymmetrically distributed in the absence of intercellular junctions were assessed for cytoskeletal interaction by their inability to be extracted by Triton X-100 from monolayers in the subconfluent state. Computer cross-referencing of 2-D PAGE peak lists and immunodetection generated from the above fractionation protocols identifies a set of four proteins associated with the cytoskeleton that remain segregated in the proper domain, and five proteins associated with the cytoskeleton that become equally distributed between AP and BL PM domains in the absence of intercellular junctions. Additionally, six proteins not associated with the cytoskeleton remain asymmetrically distributed to the AP domain in the subconfluent state. The data suggest that BAEC monolayers have unknown mechanisms, apart from intercellular junctions expressed at confluency or cytoskeletal binding, for maintaining transcellular PM protein polarity.