Anti-CD3-stimulated T cells induce the production of multiple Ig H chain isotypes by individual human peripheral B lymphocytes.

Polyclonal activation of human B cells is achieved by coculture with T cells stimulated by mAb to the CD3 molecular complex. By formal limiting dilution analysis, approximately 60% of human peripheral blood B cells were found to produce Ig in this system. When individual B cells were cultured in microtiter wells with anti-CD3-activated T cells, more than one-third of cultures producing Ig contained multiple Ig H chain isotypes. Similar results were observed when individual IgM-expressing B cells, selected and dispersed by FACS were cultured with anti-CD3-activated T cells. The clonality of the B cells producing multiple Ig isotypes was supported by L chain analysis of the secreted Ig. Of the wells containing more than one H chain isotype, nearly 85% contained only a single L chain type. Clonality was further examined by polymerase chain reaction amplification of cDNA harvested from cultures originally seeded with individual B cells. In general, only a single VH gene family could be amplified from cultures producing more than one Ig isotype. Three separate VH regions were cloned and sequenced. One, a VHIV-mu was nearly identical to a previously described VH gene VH71.4; as second, a VHIV-gamma was very similar to a previously described VH gene segment V-79, whereas a third, a VHIII-gamma differed by 14% in nucleotide sequence from its closest germline counterpart VH3005. These results indicate that anti-CD3-activated T cells not only stimulate the majority of B cells to secrete Ig, but also induce individual B cells to produce multiple Ig H chain isotypes. Additionally, the procedure described provides a reliable method to sample a large proportion of the human peripheral B cell repertoire.     

DNase I sensitivity of immunoglobulin light chain genes in Abelson murine leukemia virus transformed pre-B cell lines.

We have used Abelson murine leukemia virus (A-MuLV) transformed pre-B cell lines to test the hypothesis that the rearrangement potential of a developing B-lymphocyte is dependent on an "opening" of the chromatin structure surrounding immunoglobulin (Ig) genes, thus allowing accessibility to an Ig gene recombinase. The chromatin structures surrounding heavy (H), kappa (kappa), and lambda (lambda) chain constant-region genes were assessed by DNase I sensitivity in A-MuLV transformed cell lines capable of H, kappa or lambda gene rearrangement. Our results indicate that DNase I-sensitive chromatin structures of these Ig constant-region genes correlate closely with the ability of the genes to undergo recombination. We also find that the chromatin structure of an Ig constant-region locus becomes DNase I sensitive before any DNA rearrangement events occur.     

B cell abnormalities induced by a mu Ig transgene extend to L chain isotype usage

We have analyzed the phenotype of B cell populations from mice transgenic for a rearranged Ig mu H chain gene. We find a decrease in the number of B cells in the spleens of these mice. Transgenic B cells have decreased surface levels of both IgM and IgD. The circulating IgM in these mice is 3- to 10-fold enriched in lambda L chains, compared with that in non-transgenic mice. Analysis of IgM-producing hybridomas, from transgenic mice that express the transgene at high levels, demonstrates that this higher lambda frequency is observed in transgene-nonexpressing as well as transgene-expressing hybridomas. A partial loss of L chain isotype exclusion is also noted in these hybridomas, and a significant proportion of primary B cells expressing both kappa and lambda L chains on their surface can be demonstrated. These findings suggest an ability of the transgenic Ig H chain to affect events in B cell ontogeny beyond the H chain locus. Our results support a quantitative model of exclusion for both the H chain alleles and the L chain isotypes.     

Chromatin remodeling at the Ig loci prior to V(D)J recombination.

Rearrangement of Ig H and L chain genes is highly regulated and takes place sequentially during B cell development. Several lines of evidence indicate that chromatin may modulate accessibility of the Ig loci for V(D)J recombination. In this study, we show that remodeling of V and J segment chromatin occurs before V(D)J recombination at the endogenous H and kappa L chain loci. In recombination-activating gene-deficient pro-B cells, there is a reorganization of nucleosomal structure over the H chain J(H) cluster and increased DNase I sensitivity of V(H) and J(H) segments. The pro-B/pre-B cell transition is marked by a decrease in the DNase I sensitivity of V(H) segments and a reciprocal increase in the nuclease sensitivity of Vkappa and Jkappa segments. In contrast, J(H) segments remain DNase I sensitive, and their nucleosomal organization is maintained in mu(+) recombination-activating gene-deficient pre-B cells. These results indicate that initiation of rearrangement is associated with changes in the chromatin structure of both V and J segments, whereas stopping recombination involves changes in only V segment chromatin. We further find an increase in histone H4 acetylation at both the H and kappa L chain loci at the pro-B cell stage. Although histone H4 acetylation appears to be an early change associated with B cell commitment, acetylation alone is not sufficient to promote subsequent modifications in Ig chromatin.