The reverse transcription-polymerase chain reaction was used to examine alternative splicing at each of the three fibronectin exons known to undergo alternative splicing, i.e. extra domain A (ED-A), extra domain B (ED-B), and type III connecting sequence (IIICS). Ratios of fibronectin mRNAs with or without a given exon were determined in several rat tissues and human cell lines during aging in vivo and cellular senescence in vitro. We demonstrate that statistically significant shifts in the alternative splicing of fibronectin occur during aging in vivo and in vitro. Since all three alternatively spliced exons are spliced out at a higher frequency in aging tissues and cells, the fibronectin protein produced by old cells should be slightly smaller than that obtained from young cells. The reverse transcription-polymerase chain reaction demonstrates tissue-specific patterns of alternative splicing in several tissues. Whereas fibronectin mRNAs from adult rat tissues were found to range from 0 to 25% ED-A+ and from 0 to 10% ED-B+, fibronectin mRNAs from cultured cell lines were found to be approximately 50-60% ED-A+ and 15-25% ED-B+. We observed similarity in splicing of fibronectin RNA by the different cultured cell lines obtained from many tissues and attribute this observation to the effect of growth factors. We demonstrate that serum deprivation; placement of cells into primary culture; and growth factors such as transforming growth factor beta 1, retinoic acid, and 1,25-dihydroxyvitamin D3 can all change the alternative splicing of fibronectin pre-mRNA in the ED-A, ED-B, and type III connecting sequence exons. Possible mechanisms for the regulation of the alternative splicing of fibronectin RNA by growth factors are discussed.