Int. J. Dev. Biol. 39: 383 - 393 (1995)
Polyamine depletion-mediated effects on murine odontogenesis are dependent on tooth developmental stage and culture conditions
Published: 1 April 1995
Abstract
Polyamines are known to play a central role in processes such as growth and development. Virtually nothing is known about their importance in tooth development, an attractive and frequently used experimental model for studies of developmental processes. A polyamine-depleted state was created in tooth cells in an organ culture system. First lower molar germs from 16-and 17.5-day old mouse fetuses were used. alpha-difluoromethylornithine (DFMO) and methylglyoxal bis-(guanylhydrazone) (MGBG) were used to deplete the cells from their polyamine content. Polyamine interconversion and catabolism were prevented by aminoguanidine sulfate (AG). In day-16 germs cultured in serum-containing medium, DFMO reduced the frequency of cycling cells as shown by [3H]thymidine incorporation, and induced a delay of odontoblast differentiation of about 24 h. Under the same conditions, MGBG induced an arrest of histo-morphogenesis, correlated to a significant decrease in the rate of cell proliferation. Addition of polyamines prevented DFMO- and MGBG-induced delay of tooth differentiation. Interestingly, MGBG did not delay the terminal differentiation of odontoblasts and ameloblasts in cultured day-17.5 molars; in these, cells at the tip of the cusps are only a few hours before their withdrawal from the cell cycle. In serum-deprived medium, dental cytodifferentiations did not occur. Addition of putrescine or spermidine to serum-free media, however, allowed for tooth morphogenesis and cytodifferentiation. Tooth explants in a serum-deprived medium reacted to DFMO in a cytocidal fashion, whereas MGBG showed only a mild toxicity in some cell types. Addition of putrescine to DFMO-containing medium prevented its cytotoxic effect. Addition of spermidine to MGBG-containing medium not only prevented its mild toxicity but also allowed for predentin secretion by differentiated odontoblasts. The results are discussed with regard to the well-established developmental events of tooth germs cultured in vitro and with respect to present knowledge of polyamine metabolism and their involvement in cellular processes.