Abstract
Summary Stomata are simultaneously tasked with permitting the uptake of carbon dioxide for photosynthesis while limiting water loss from the plant. This process is mainly regulated by guard cell control of the stomatal aperture, but recent advancements have highlighted the importance of several genes that control stomatal development.Using targeted genetic manipulations of the stomatal lineage and a combination of gas exchange and microscopy techniques, we show that changes in stomatal development of the epidermal layer lead to coupled changes in the underlying mesophyll tissues. This coordinated response tends to match leaf photosynthetic potential (V cmax) with gas‐exchange capacity (g smax), and hence the uptake of carbon dioxide for water lost.We found that different genetic regulators systematically altered tissue coordination in separate ways: the transcription factor SPEECHLESS (SPCH) primarily affected leaf size and thickness, whereas peptides in the EPIDERMAL PATTERNING FACTOR (EPF) family altered cell density in the mesophyll. It was also determined that interlayer coordination required the cell‐surface receptor TOO MANY MOUTHS (TMM).These results demonstrate that stomata‐specific regulators can alter mesophyll properties, which provides insight into how molecular pathways can organize leaf tissues to coordinate gas exchange and suggests new strategies for improving plant water‐use efficiency.
Highlights
Recent attention has turned to the contributions of stomatal development in optimizing plant–environment relationships and controlling physiological performance (Chater et al, 2014; Dow & Bergmann, 2014; Lawson & Blatt, 2014)
Gas-exchange experiments in Arabidopsis thaliana identified a connection between gsmax, the anatomical maximum rate of stomatal conductance as defined by stomatal size and density, and photosynthetic rate (Dow et al, 2014a,b)
We investigate the impact of genetic manipulations in the stomatal lineage on the developmental organization and physiological capacity of the mesophyll tissue
Summary
Recent attention has turned to the contributions of stomatal development in optimizing plant–environment relationships and controlling physiological performance (Chater et al, 2014; Dow & Bergmann, 2014; Lawson & Blatt, 2014). Enabling this focus is the availability of genetic resources to modify stomatal numbers and their distribution, or pattern, on the leaf surface (Lau & Bergmann, 2012; Pillitteri & Torii, 2012). The ability to substitute gsmax for A hinted at an underlying link between stomatal development and the photosynthetic potential of the leaf. We investigate the impact of genetic manipulations in the stomatal lineage on the developmental organization and physiological capacity of the mesophyll tissue
Sign-in/Register to view highlights & summary 
Published Version (
Free)
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call