A phytochrome-phototropin light signaling complex at the plasma membrane.

Phytochromes are red/far-red photochromic photoreceptors central to regulating plant development. Although they are known to enter the nucleus upon light activation and, once there, regulate transcription, this is not the complete picture. Various phytochrome effects are manifested much too rapidly to derive from changes in gene expression, whereas others seem to occur without phytochrome entering the nucleus. Phytochromes also guide directional responses to light, excluding a genetic signaling route and implying instead plasma membrane association and a direct cytoplasmic signal. However, to date, no such association has been demonstrated. Here we report that a phytochrome subpopulation indeed associates physically with another photoreceptor, phototropin, at the plasma membrane. Yeast two-hybrid methods using functional photoreceptor molecules showed that the phytochrome steering growth direction in Physcomitrella protonemata binds several phototropins specifically in the photoactivated Pfr state. Split-YFP studies in planta showed that the interaction occurs exclusively at the plasma membrane. Coimmunoprecipitation experiments provided independent confirmation of in vivo phy-phot binding. Consistent with this interaction being associated with a cellular signal, we found that phytochrome-mediated tropic responses are impaired in Physcomitrella phot(-) mutants. Split-YFP revealed a similar interaction between Arabidopsis phytochrome A and phototropin 1 at the plasma membrane. These associations additionally provide a functional explanation for the evolution of neochrome photoreceptors. Our results imply that the elusive phytochrome cytoplasmic signal arises through binding and coaction with phototropin at the plasma membrane.

Bellis perennis: a useful tool for protein localization studies.

Fluorescent fusion proteins together with transient transformation techniques are commonly used to investigate intracellular protein localisation in vivo. Biolistic transfection is reliable, efficient and avoids experimental problems associated with producing and handling fragile protoplasts. Onion epidermis pavement cells are frequently used with this technique, their excellent properties for microscopy resulting from their easy removal from the underlying tissues and large size. They also have advantages over mesophyll cells for fluorescence microscopy, as they are devoid of chloroplasts whose autofluorescence can pose problems. The arrested plastid development is peculiar to epidermal cells, however, and stands in the way of studies on protein targeting to plastids. We have developed a system enabling studies of in vivo protein targeting to organelles including chloroplasts within a photosynthetically active plant cell with excellent optical properties using a transient transformation procedure. We established biolistic transfection in epidermal pavement cells of the lawn daisy (Bellis perennis L., cultivar "Galaxy red") which unusually contain a moderate number of functional chloroplasts. These cells are excellent objects for fluorescence microscopy using current reporters, combining the advantages of the ease of biolistic transfection, the excellent optical properties of a single cell layer and access to chloroplast protein targeting. We demonstrate chloroplast targeting of plastid-localised heme oxygenase, and two further proteins whose localisation was equivocal. We also demonstrate unambiguous targeting to mitochondria, peroxisomes and nuclei. We thus propose that the Bellis system represents a valuable tool for protein localisation studies in living plant cells.

Cytoplasmic phytochrome action.

Phytochrome photoperception is a common mechanism for the detection of red and far-red light in bacteria, cyanobacteria, fungi and plants. However, the responses following phytochrome activation appear to be quite diverse between species. Lower plants, such as mosses, show phytochrome-mediated directional responses, namely phototropism and polarotropism. These cannot be explained by nuclear gene regulation and are thought to be triggered by phytochromes in the cytoplasm or at the plasma membrane. In higher plants, similar directional responses are mediated via phototropin, a blue light receptor, with phytochromes mainly controlling morphogenetic responses through gene regulation. However, cytoplasmic phytochrome responses exist in higher plants too, which appear to be intertwined with directional blue light perception. By summarizing the respective findings, a possible conservation of cytoplasmic phytochrome function in higher and lower plants is addressed here.