Abstract
An understanding of what changes occur in the control of gene expression when mammalian cells "spontaneously" immortalize is important to our knowledge of how cancer develops. We describe here an alteration in regulation that occurs when primary mouse embryo fibroblasts (MEFs) are immortalized according to a 3T3 regimen. Mitogen-regulated protein/proliferin mRNA is undetectable in northern blots of RNA from (mortal) MEFs, whereas it is readily detected in immortal 3T3 cell lines derived from the MEFs. Incompletely processed nuclear transcripts of the mitogen-regulated protein/proliferin gene can be detected in MEF RNA preparations by northern blotting and reverse transcriptase polymerase chain reaction analyses, although at roughly half the abundance observed in 3T3 cells. We hypothesize that some attribute of the primary unprocessed transcript determines its assignment to this unique degradative pathway. These results reveal that during passage of MEFs according to a 3T3 regimen the ability of the primary cells to suppress the expression of certain genes by degrading the nuclear transcript is lost concomitantly with immortalization.
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