PT - JOURNAL ARTICLE AU - Daniel H. Chitwood AU - Ravi Kumar AU - Aashish Ranjan AU - Julie M. Pelletier AU - Brad T. Townsley AU - Yasunori Ichihashi AU - Ciera C. Martinez AU - Kristina Zumstein AU - John J. Harada AU - Julin N. Maloof AU - Neelima R. Sinha TI - Light-induced indeterminacy alters shade avoiding tomato leaf morphology AID - 10.1101/024018 DP - 2015 Jan 01 TA - bioRxiv PG - 024018 4099 - http://biorxiv.org/content/early/2015/08/05/024018.short 4100 - http://biorxiv.org/content/early/2015/08/05/024018.full AB - Plants sense foliar shade of competitors and alter their developmental programs through the shade avoidance response. Internode and petiole elongation, and changes in overall leaf area and leaf mass per area, are the stereotypical architectural responses to foliar shade in the shoot. However, changes in leaf shape and complexity in response to shade remain incompletely, and qualitatively, described. Using a meta-analysis of >18,000 previously published leaflet outlines, we demonstrate that shade avoidance alters leaf shape in domesticated tomato and wild relatives. The effects of shade avoidance on leaf shape are subtle with respect to individual traits, but are combinatorially strong. We then seek to describe the developmental origins of shade-induced changes in leaf shape by swapping plants between light treatments. Leaf size is light-responsive late into development, but patterning events, such as stomatal index, are irrevocably specified earlier.Observing that shade induces increases in shoot apical meristem size, we then describe gene expression changes in early leaf primordia and the meristem using laser microdissection. We find that in leaf primordia shade avoidance is not mediated through canonical pathways described in mature organs, but rather the expression of KNOX and other indeterminacy genes, altering known developmental pathways responsible for patterning leaf shape. We also demonstrate that shade-induced changes in leaf primordium gene expression largely do not overlap with those found in successively initiated leaf primordia, providing evidence against classic hypotheses that shaded leaf morphology results from prolonged production of juvenile leaf types.