Transcriptional control of mu- and kappa-gene expression in resting and bacterial lipopolysaccharide-activated normal B cells.

When murine resting B cells are polyclonally stimulated by bacterial lipopolysaccharide (LPS) in vitro for a short period of 4 days, they are activated to DNA synthesis and cell division, and they also differentiate to immunoglobulin (Ig)-secreting plasma cells. These two events are accompanied with several qualitative changes at the Ig mRNA level: the disappearance of delta mRNA after stimulation, the switch from membrane to secretory form of mu-mRNA, and the late appearance of IgM joining chain (J-chain) mRNA. There is also a quantitative increase of Ig-gene expression at the level of: Ig gene transcription, mu-, kappa- and J-chain mRNA accumulation, and Ig translation and secretion. A comparison of Ig transcription rates before and in the course of LPS stimulation, as determined by in vitro transcriptional run-on assays, has shown that there is a large increase of the RNA polymerase density on both mu- and kappa-loci (30-60-fold), which is quantitatively comparable with the accumulation of both mu- and kappa-mRNAs at the steady state mRNA level. These data therefore suggest that former results obtained with tumor cells regarding post-transcriptional control of Ig gene expression do not reflect the physiological behavior of normal B cells with respect to the molecular events of B cell triggering. We also propose that additional molecular events such as RNA processing and the transcriptional activation of J-chain gene might be essential for controlling the maximal transcriptional rate across the Ig loci.

IgM RNA switch from membrane to secretory form is prevented by adding antireceptor antibody to bacterial lipopolysaccharide-stimulated murine primary B-cell cultures.

Bacterial lipopolysaccharide (LPS) induces proliferation of resting primary murine B lymphocytes and their differentiation into Ig-secreting cells. This is accompanied by an increase in the rate of Ig gene transcription and the accumulation of mu heavy chain secretory mRNA. Specific antiantigen receptor antibody (anti-mu) induces resting B cells to proliferation but not differentiation. Upon addition of both LPS and anti-mu to cultures, resting B cells again proliferate but do not differentiate. RNA transfer blots of the Ig mRNA 2 days after induction with LPS/anti-mu show a specific deficiency of the 2.4-kilobase (kb) mu secretory mRNA, whereas the levels of the 2.7-kb mu membrane and 1.2-kb kappa light chain mRNAs are as high as in cells treated with LPS alone. Between days 3 and 4 after treatment with both reagents, reductions of mu membrane and, to a smaller extent, kappa mRNA become apparent. As measured by nuclear run-on transcription experiments at day 2, the transcription rates of Ig mu and the Ig kappa transcription units are equal in both induction experiments. Only at later stages do the LPS/anti-mu-treated cells transcribe Ig genes at a lower rate. Thus, the anti-mu treatment, drastically reducing the mu secretory mRNA production at early stages, represents a negative regulation occurring primarily at the posttranscriptional level.