Litcius/Paper detail

Quantifying the effect of shade on cuticle morphology and carbon isotopes of sycamores: present and past

Joseph N. Milligan, Andrew G. Flynn, Jennifer D. Wagner, Lenny L.R. Kouwenberg, Richard S. Barclay, Bruce W. Byars, Regan E. Dunn, Joseph D. White, Bernd Zechmann, Daniel J. Peppe

2021American Journal of Botany14 citationsDOIOpen Access PDF

Abstract

PREMISE: Reconstructing the light environment and architecture of the plant canopy from the fossil record requires the use of proxies, such as those derived from cell wall undulation, cell size, and carbon isotopes. All approaches assume that plant taxa will respond predictably to changes in light environments. However, most species-level studies looking at cell wall undulation only consider "sun" or "shade" leaves; therefore, we need a fully quantitative taxon-specific method. METHODS: We quantified the response of cell wall undulation, cell size, and carbon isotopes of Platanus occidentalis using two experimental setups: (1) two growth chambers at low and high light and (2) a series of outdoor growth experiments using green and black shade cloth at different densities. We then developed and applied a proxy for daily light integral (DLI) to fossil Platanites leaves from two early Paleocene floras from the San Juan Basin in New Mexico. RESULTS: . CONCLUSIONS: Cell wall undulation of P. occidentalis is a robust, quantifiable measurement of light environment that can be used to reconstruct the paleo-light environment from fossil leaves. The distribution of high DLI values from fossil leaves may provide information on canopy architecture; indicating that either (1) most of the canopy mass is within the upper portion of the crown or (2) leaves exposed to more sunlight are preferentially preserved.

Topics & Concepts

CanopyIsotopes of carbonBiologyFossil RecordBotanyTaxonPaleontologyEcologyTotal organic carbonPlant Water Relations and Carbon DynamicsPlant Diversity and EvolutionPlant Surface Properties and Treatments