Love on wings, a Dof family protein regulates floral vasculature in Vigna radiata

Dof proteins are members of a major family of plant transcription factors. The proteins have similar DNA-binding properties because of the highly conserved DNA-binding domain. However, recent studies are disclosing their diverse roles in gene expression when associated with plant-specific phenomena including light, phytohormone and defense responses, seed development and germination. Based on the structural diversity indicated by the complete catalog of Arabidopsis Dof proteins, Dof genes appear to have evolved multiple times, preceding and paralleling the diversification of angiosperms. Such gene multiplication might have led to the functional diversification of Dof proteins proceeding differently in distinct plant species.

Polar auxin transport controls multiple developmental processes in plants, including the formation of vascular tissue. Mutations affecting the PIN-FORMED (PIN1) gene diminish polar auxin transport in Arabidopsis thaliana inflorescence axes. The AtPIN1gene was found to encode a 67-kilodalton protein with similarity to bacterial and eukaryotic carrier proteins, and the AtPIN1 protein was detected at the basal end of auxin transport-competent cells in vascular tissue. AtPIN1 may act as a transmembrane component of the auxin efflux carrier.

Organ asymmetry is thought to have evolved many times independently in plants. In Antirrhinum, asymmetry of the flower and its component organs requires cyc and dich gene activity. We show that, like cyc, the dich gene encodes a product belonging to the TCP family of DNA-binding proteins that is first expressed in the dorsal domain of early floral meristems. However, whereas cyc continues to be expressed throughout dorsal regions, expression of dich eventually becomes restricted to the most dorsal half of each dorsal petal. This correlates with the effects of dich mutations and ectopic cyc expression on petal shape, providing an indication that plant organ asymmetry can reflect subdomains of gene activity. Taken together, the results indicate that plant organ asymmetry can arise through a series of steps during which early asymmetry in the developing meristem is progressively built upon.