Spatial patterns of phytochrome expression in young leaves of the fern Adiantum capillus-veneris

Fern Adiantum capillus-veneris phytochrome 1 comprises two native photochemical types similar to seed plant phytochrome A

Phytochrome (phy) in etiolated seedlings of wild-type (WT) Arabidopsis (Ler) and its transgenic lines (TL) L15 and L20 transformed with Adiantum capillus-veneris PHY1 cDNA (Okamoto et al., 1997) was investigated using low-temperature (85K) fluorescence spectroscopy and photochemistry. It was found that while WT seed germination requires stimulation by light, the TL germinated equally well with or without pre-illumination. Phytochrome content [Ptot] was 2-fold higher in TL whereas the level of Pr→lumi-R phototransformation at 85K (γ1) was similar between WT (0.25) and TL (0.27). When seeds germinated with pre-illumination, the proportion of the photochemical types Pr' active and Pr″ inactive at 85K was 50/50 in WT and 54/46 in TL, respectively. Dark-germinated TL had a γ1 value of 0.16 and the proportion of Pr' and Pr″ was 32/68, respectively, without changes in [Ptot]. Evaluations based on these data revealed that phy1 has Pr' and Pr″, designated phy1' and phy1″, akin to phyA, which comprises both Pr photochemical types (phyA' and phyA″), and in contrast to phyB that possesses only Pr″. The proportion of phy1' and phy1″ depends on pre-illumination for induction of germination. The pigment most likely accumulated in the seeds and was active in promoting Arabidopsis seed germination.

Ginkgo biloba retains functions of both type I and type II flowering plant phytochrome

While the photoreceptor systems of flowering plants have been well studied, the origins of these gene families and their functions are only partially understood. To begin to resolve the evolutionary origins of angiosperm photoreceptor function, we have studied the photomorphogenic responses of the early diverging gymnosperm Ginkgo biloba. Here, we describe the effects of continuous white light, red light, far-red light, and blue light on stem length, chlorophyll accumulation, Lhcb mRNA accumulation, and plastid development. Differences in the efficacy of these light regimes on de-etiolation in Ginkgo suggest separate but complementary roles for red and blue light-sensing systems. Additionally, the unique manner in which developmental regulation occurs in Ginkgo reveals a far-red high irradiance response different from both angiosperm and other gymnosperm species. We conclude from these data that Ginkgo contains a functional complement to both flowering plant type I and type II phytochromes, as well as independent blue light-sensing system(s). The implications of these findings are discussed with respect to the evolution of higher plant photoreceptors.