LONG-TERM RELATIONSHIPS AMONG ATMOSPHERIC CO2, STOMATA, AND INTRINSIC WATER USE EFFICIENCY IN INDIVIDUAL TREES

Leaf-level responses to increases in atmospheric carbon dioxide (CO2) concentrations could have large implications for water and carbon cycles. We investigated whether stomatal density, guard cell length, and intrinsic water use efficiency (iWUE) of 27 individual trees growing at the Arnold Arboretum in Boston. Massachusetts have responded to changing environmental conditions over the last 100 years. We examined leaves from 74 herbarium specimens collected from three genera-Acer (maples), Quercus (oaks), and Carpinus (hornbeams)-from 1893 to 2006. During this period, global average atmospheric CO2 concentrations increased by approximately 29% (86 ppm), and temperatures in Boston increased by 1.8 degrees C. Stomatal density and guard cell length were negatively correlated in oaks and hombeams. Although stomatal density declined and guard cell length increased over time, the changes were not dependent on the magnitude of changes in CO2 concentrations. Intrinsic WUE did not change significantly over time. Our findings suggest that iWUE may not respond to changes in CO2 concentrations over the lifetimes of individual trees, possibly because of compensating changes in stomatal density and guard cell size. We provide an example of a method that can enable researchers to differentiate between genetic and plastic responses to global change in long-lived trees.