Altered translatability of messenger RNA from suspended anchorage-dependent fibroblasts: reversal upon cell attachment to a surface.

Anchorage-dependent cells, when forced into suspension culture, display a repertoire of dramatic, coordinated regulatory phenomena. Message production promptly decreases 5 gold but the cells maintain a constant amount of poly(A)+ by means of a concomitant stabilization of mRNA against decay. Protein synthesis shuts down much later and the mRNA is stored in a nonfunctioning state. In this study, the inactive mRNA is extracted from suspended cells and shown to have aberrant translation properties. Well defined polypeptides are apparently no longer synthesized when this mRNA directs protein formation in either reticulocyte or wheat germ-derived heterologous translation systems. Rather, shortened peptides are formed by this mRNA and these become smaller as mRNA is used from cells suspended for longer periods of time. Very few focused spots are formed when the aberrant polypeptides are analyzed in two-dimensional electrophoresis. The sedimentation properties of suspended cell mRNA and the size of poly(A) are unchanged from control monolayer cells. Cross-hybridization of cDNA transcribed from a control cell message population with suspended cell mRNA shows that all sequences are present in normal concentrations. While most identifiable spots disappear from the two-dimensional gel electropherograms of the protein products produced by suspended cell mRNA, a few polypeptides are still synthesized in relatively normal amounts. Conserved polypeptides are found in products of both the reticulocyte and wheat germ systems, but they are different products in each case. The lesion in the suspended cell mRNA does not seem to be at the 5' termini, since synthesis of the shortened peptides is fully sensitive to inhibition of pm7G. Cells that contain extensively modified message can resume protein synthesis when allowed to reattach to a solid substrate. There is an apparent remodification of mRNA to normal translatability within a few hours of cell reattachment, since mRNA from recovering cells quickly resumes directing relatively normal patterns of polypeptide synthesis in vitro. The restoration of normal message function occurs even when new message formation is blocked with actinomycin. Cells recovering after reattachment synthesize supranormal amounts of a few major proteins involved with cell structure, as shown in these studies by an increased amount of translatable sequences which encode these proteins. The most apparent enhanced message is that coding for actin. mRNA from recovering cells produces in vitro several times more actin relative to other proteins than does control cell mRNA. The enhancement of actin mRNA is not seen in the message population of cells that reattach in the presence of actinomycin. The results suggest a morphologically related induction of gene expression.