PHYTOCHROME-MEDIATED PHOTOTROPISM AND DIFFERENT DICHROIC ORIENTATION OF Pr AND Pfr IN PROTONEMATA OF THE FERN ADIANTUM CAPILLUS-VENERIS L.

Abstract— Single-celled protonemata of Adiantum capillus-veneris were cultured under continuous red light for 6 days and then in the dark for 15 h. Brief local exposure of a flank (5 times 20 /mi) of the subapical region of a protonema to a microbeam of red light effectively induced a phototropic response toward the irradiated side. The degree of the response was dependent upon the fluence of the red light. Red/far-red reversibility was typically observed in this photoreaction, showing that phytochrome was the photo-receptive pigment. When the flank was irradiated with a microbeam of linearly polarized red and far-red light, red light with an electrical vector parallel to the cell surface was most effective. However, the far-red light effect was most prominent when its electrical vector was normal to the cell surface. These polarized light effects indicate the different dichroic orientation of P_r (red-light-absorbing form of phytochrome) and P_r (far-red-light-absorbing form of phytochrome) at the cell flank.     

A Study of Electromagnetic Cascade Showers with the LPM Effect in Water for the Detection of Extremely High Energy Neutrinos An application of the matrix method to LPM showers

The matrix method given by Fujimaki and Misaki is proved to be a powerful means for the calculations of electromagnetic cascade showers at extremely high energies. The method is essentially simple and has wide applications for the calculation of cascade showers. This method is used for the calculation of the cascade showers with the LPM effect in water, for the detection of extremely high energy neutrinos. The characteristics of LPM showers in water are extracted referring to cascade showers in the absence of the LPM effect.     

INTRACELLULAR DICHROIC ORIENTATION OF THE BLUE LIGHT-ABSORBING PIGMENT AND THE BLUE-ABSORPTION BAND OF THE RED-ABSORBING FORM OF PHYTOCHROME RESPONSIBLE FOR PHOTOTROPISM OF THE FERN Adiantum PROTONEMATA

The intracellular localization and orientation of the receptors for the blue light-induced phototropism in the fern Adianrum protonemata, phytochrome and the blue light-absorbing pigment, were investigated by combining the techniques of cell centrifugation and of microbeam irradiation with linearly polarized light. The phototropic response was induced in the cells even after they had been centrifuged basipetally to spin down the endoplasm from the apical region. When a polarized blue microbeam was given to a flank of the apical region of the protonema, the phototropic response after compensation of phytochrome effect by far-red light was most effectively induced when the polarization plane was parallel to the long axis of the cell. If protonemata were pre-irradiated with blue and far-red light, the phototropic response was mediated through phytochrome alone. If such pre-irradiated protonemata were similarly irradiated with a polarized blue microbeam, polarized light vibrating parallel to the cell axis was again most effective in inducing the response. These results indicate that both the blue light-absorbing pigment and the phytochrome responsible for the blue light-induced phototropism in Adiantum are confined to the plasma membrane and/or the ectoplasm and that the transition moments of their blue-absorption bands are nearly parallel to the cell surface.     

PHYTOCHROME-MEDIATED PHOTOTROPISM IN Adiantum PROTONEMATA-I. PHOTOTROPISM AS A FUNCTION OF THE LATERAL Pfr GRADIENT*

Abstract— Phytochrome-mediated phototropism of the protonema of the fern Adiantum capillus-veneris was studied in view of the hypothesis that phototropism is controlled by the gradient of Pfr (phytochrome in the far-red-absorbing form) across the short axis of the protonema. Fluence-response relationships were investigated using a microbeam irradiation technique that allowed simultaneous stimulation of the two sides of the subapical portion of the protonema with different fluences of red light. Mathematical models describing the tropic response as a function of fluence were derived from the hypothesis in consideration of the minimal phototransformation kinetics of phytochrome. and the fitness of the functions to the experimental data was examined. The analytical results were then evaluated in view of the photochemical properties of phytochrome known from the literature. It is concluded that the extent of the tropic response is determined by the difference in the Pfr concentrations between the two sides of the protonemal cell. It is further suggested that, even if phytochrome exists as a dimer in vivo, the physiological unit of phytochrome is the monomer.