Molecular and phenotypic specificity of an antisense PHYB gene in Arabidopsis.

The family of phytochrome photoreceptors plays an essential role in regulating plant growth and development in response to the light environment. An antisense PHYB transgene has been introduced into wild-type Arabidopsis and shown to inhibit expression of the PHYB sense mRNA and the phyB phytochrome protein 4- to 5-fold. This inhibition is specific to phyB in that the levels of the four other phytochromes, notably the closely related phyD and phyE phytochromes, are unaffected in the antisense lines. Antisense-induced reduction in phyB causes alterations of red light effects on seedling hypocotyl elongation, rosette leaf morphology, and chlorophyll content, similar to the phenotypic changes caused by phyB null mutations. However, unlike the phyB mutants, the antisense lines do not flower early compared to the wild type. Furthermore, unlike the phyB mutants, the antisense lines do not show a reduction in phyC level compared to the wild type, making it possible to unequivocally associate several of the photomorphogenic effects seen in phyB mutants with phytochrome B alone. These results indicate that an antisense transgene approach can be used to specifically inhibit the expression and activity of a single member of the phytochrome family and to alter aspects of shade avoidance responses in a targeted manner.

Differential patterns of expression of the Arabidopsis PHYB, PHYD, and PHYE phytochrome genes.

The Arabidopsis thaliana phyB, phyD, and phyE phytochrome apoproteins show higher amino acid sequence similarity to each other than to phyA or phyC, they are the most recently evolved members of this photoreceptor family, and they may interact in regulating photomorphogenesis. The expression patterns of translational fusions of the 5' upstream regions of the PHYB, PHYD, and PHYE genes to the beta-glucuronidase (GUS) coding sequence were compared. PD-GUS and PE-GUS fusions were 5- to 10-fold less active than a PB-GUS fusion, but all three promoter regions drove expression of the reporter gene in all stages of the plant's life cycle. Over the first 10 d of seedling growth, the PHYB and PHYD promoters were more active in the dark than in the light, whereas the opposite was true of the PHYE promoter. Unlike the PB-GUS construct, which was expressed in most parts of seedlings and mature plants, the PD-GUS and PE-GUS transgenes showed differential expression, notably in leaves, flower organs, and root tips. Tissue sections showed that the three promoters are coexpressed in at least some leaf cells. Hence, the PHYB, PHYD, and PHYE genes differ in expression pattern but these patterns overlap and interaction of these receptor forms within individual cells is possible.