Changes in the spacing patterns of Ca-oxalate crystals during enlargement ofCarya ovata Mill. leaves were quantified by computerized image-analysis. Single Ca-oxalate crystals form in the vacuoles of young mesophyll cells transformed into crystal cells Crystals are very small in newly induced crystal cells and increase in size throughout leaf development. Crystal patterns thus reflect both induction and relative age of crystal cells. Shortly after the emergence of young leaves from the bud, very small crystals are formed in the mesophyll at high density. As leaves expand, these crystals grow larger and become separated by increasing distances. New small crystals appear in the gaps between the older, larger crystals. Later crystal patterns consist of widely spaced, larger crystals only. Finally, clusters of small crystals are formed again in the gaps between large crystals. No crystals were observed in young leaves expanding in a moist chamber, but large numbers of crystal cells were induced experimentally in sections of immature leaves floating on 4 mM Ca-acetate. The observations support the following mechanism of crystal-pattern formation: Ca(2+) carried into leaves with the transpiration stream acts as the developmental signal inducing transdifferentiation of a few mesophyll cells into crystal cells when apoplastic [Ca(2+)] rises. Crystal cells precipitate absorbed Ca(2+) as oxalate and, acting as Ca(2+) sinks, inhibit crystal-cell induction in their vicinity by depleting apoplastic Ca(2+). This prevents close spacing of crystal cells. New crystal cells form in the gaps between the depletion zones of older crystal cells when these move apart during leaf expansion. Later changes in crystal patterns result from increasing sink strength of crystal cells, lowered inducibility of mesophyll cells, and increased Ca(2+) influx into leaves during intensive transpiration. Throughout leaf development, spacing of crystal cells permits rapid secretion of apoplastic Ca(2+) as Ca-oxalate.