Stems of dicotyledonous plants consist of an outer epidermis, a cortex, a ring of secondarily thickened vascular bundles and interfascicular cells, and inner pith parenchyma cells with thin primary walls. It is unclear how the different cell layers attain and retain their identities. Here, we show that WRKY transcription factors are in part responsible for the parenchymatous nature of the pith cells in dicotyledonous plants. We isolated mutants of Medicago truncatula and Arabidopsis thaliana with secondary cell wall thickening in pith cells associated with ectopic deposition of lignin, xylan, and cellulose, leading to an ∼50% increase in biomass density in stem tissue of the Arabidopsis mutants. The mutations are caused by disruption of stem-expressed WRKY transcription factor (TF) genes, which consequently up-regulate downstream genes encoding the NAM, ATAF1/2, and CUC2 (NAC) and CCCH type (C3H) zinc finger TFs that activate secondary wall synthesis. Direct binding of WRKY to the NAC gene promoter and repression of three downstream TFs were confirmed by in vitro assays and in planta transgenic experiments. Secondary wall-bearing cells form lignocellulosic biomass that is the source for second generation biofuel production. The discovery of negative regulators of secondary wall formation in pith opens up the possibility of significantly increasing the mass of fermentable cell wall components in bioenergy crops.lignocellulosic bioenergy crops | transcriptional regulation | lignin modification | biomass yield I n dicotyledonous plants, the stem structure in cross-section is organized into (from outer to inner) the epidermis, the cortex, a ring of vascular bundle cells and interfascicular tissues characterized by secondary wall thickening, and the parenchymatous pith cells with thin primary cell walls. The different cell layers are well-defined and manifest distinct functions. How these cells attain and retain their identities is still unclear.The secondary cell walls of mature plants comprise a large proportion of the lignocellulosic biomass used as starting material for second generation biofuel production (1, 2). The synthesis of secondary cell wall components is highly coordinated and regulated by ordered transcriptional switches (3, 4). Several closely related NAC transcription factors (TFs) act as master regulators (5-9). MYB domain TFs, either upstream (10) or downstream (11) of NAC TFs, may also function as master switches, and farther downstream, TFs directly interact with cellulose, lignin, and xylan biosynthesis genes (12, 13).Forward genetic mutant screening is a powerful tool to identify players in a given biological process. Screening for ectopic lignification mutants in Arabidopsis has identified two mutants that show lignified pith cells (14, 15), but neither mutation defines a negative transcriptional regulator of lignin synthesis as originally proposed (16,17). In this study, we report the identification and characterization of Medicago and Arabidopsis mutants showing ectopic secondary cell wall f...
