The self-renewing capacity of B1 cells infers homeostatic regulation; however, previous work suggests the low level of N-region addition characterizing B1 cells early in life increases with age, which implies that the B1-cell population is not a closed system. To explore this, we evaluated Nregion addition in CD5 + B1 cells generated from adult BM. Adult BM cells were marked with GFP introduced by mouse stem cell virus transduction, and were then adoptively transferred into lethally irradiated recipients. Within 2-3 months, we found GFP-marked CD5 + B cells in the peritoneal cavities of recipients, which we demonstrate here meet a variety of criteria for B1-cell traits including Mac-1 surface expression; annexin, elfin, and Pax-5 gene expression; mitogenic responsiveness to phorbol ester; and spontaneous immunoglobulin secretion. Notably, we found by single-cell PCR that this population of BM-derived CD5 + B1 cells expressed immunoglobulin with abundant Nregion addition (and little V H 11/V H 12 skewing), unlike CD5 + B1 cells obtained from unmanipulated animals but reminiscent of B2 cells. Further, we confirmed that native CD5 + B1 cells from older mice contain more N-region additions than native CD5 + B1 cells from younger mice. These results suggest that adult BM progenitors contribute to the peritoneal CD5 + B1-cell pool over time.
Upon stimulation of mature B cells, class switch recombination (CSR) can alter the specific immunoglobulin heavy chain constant region that is expressed. In a tissue culture cell line, we previously demonstrated that inhibition of late SV40 factor (LSF) family members enhanced IgM to IgA CSR. Here, isotype specificity of CSR regulation by LSF family members is addressed in primary mouse splenic B cells. First, we demonstrate that LBP-1a is the prevalent family member in B lymphocytes. Second, we demonstrate by ChIP that LBP-1a binds genomic sequences around mouse switch regions (S) in an isotype-specific manner, in accordance with computational predictions: binding is observed to Sμ and Sα, but not to the tested Sγ1, regions. Importantly, binding of LBP-1a is tightly regulated, with occupancy at genomic S regions dramatically decreasing following LPS stimulation. Finally, the consequence of DNA-binding by LBP-1a is determined using bone marrow chimeric mice in which LSF/LBP-1 activity is inhibited in hematopoietic lineages. Upon in vitro stimulation of such primary B-cells, CSR occurs with a higher efficiency to IgA, but not to IgG1. These results are supportive of a model whereby LBP-1a represses CSR in an isotype-specific manner via direct interaction with switch regions involved in the recombination.
Pseudotyped retroviral vectors combine the advantages of broad host range, high expression, stable chromosomal integration, and ease of preparation. These vectors greatly facilitate delivery into mammalian cells of sequences encoding individual peptide inhibitors-including those with therapeutic utility-and inhibitor libraries. However, retroviral vectors vary in behavior, particularly with respect to expression levels in different cell lines. Expression level is especially important in transdominant experiments because the concentration of an inhibitor (for example, an expressed peptide) is one of the key determinants in the degree of complex formation between the inhibitor and its target. Thus, inhibitor concentration should have an impact on the expressivity and/or penetrance of an induced phenotype. Here, we compare several retroviral vectors and human cell lines for relative expression levels using a green fluorescent protein reporter. We show for a subset of these lines that cellular protein concentrations produced by single-copy vectors range up to about 2 microM. We also examine other variables that contribute to expression level, such as the nature of the expressed protein's carboxy terminus. Finally, we test the effect of increased concentration on phenotype with a nine-amino-acid peptide derived from the human papilloma virus protein E7 which overcomes E7-mediated cell growth.
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