Extinction of immunoglobulin gene expression in B cells upon fusion with HeLa cells is preceded by rapid nuclear depletion of essential transcription factors and is accompanied by widespread inactivation of genes expressed in a B cell-specific manner. When immunoglobulin (Ig) expressing B cells are fused with non-B cells, Ig expression is rapidly suppressed at the level of transcription, a phenomenon termed extinction. Here we demonstrate that fusion of HeLa cells with either diploid or tetraploid B cells (Daudi) results in widespread extinction of several other B cell-encoded genes that are expressed in a B cell-specific manner. In contrast, expression of B cell-expressed genes that are not dependent on cell-specific controls is unaffected. We show that the molecular mechanism(s) underlying Ig gene extinction can be explained, at least in part, by a lack of transcription factors that are essential for Ig gene transcription. These transcription factors are either not produced due to block of transcription of their respective genes (Oct-2, OBF-1, PU.1), or are rendered inactive posttranslationally (NF-kappa B, E47). By isolating Daudi x HeLa heterokaryons a few hours after fusion, we have studied the initial fate of two B cell-specific transcription factors involved in Ig gene transcription, Oct-2 and NF-kappa B. This report provides the first demonstration that upon fusion with HeLa cells, the nuclear contents of B cell-expressed transcription factors are depleted within a few hours with kinetics that are as fast or faster than that of Ig gene extinction. Thus, the extinguishing mechanism is effective very early after fusion. We suggest that extinction of Ig genes is part of a global mechanism that suppresses the differentiation program foreign to the HeLa phenotype.