Phytochrome-Mediated Photoorientation of Chloroplasts in Protonemal Cells of the Fern Adiantum Can be Induced by Brief Irradiation with Red Light

Measuring the ratio of the number of photooriented chloroplaststo the total number of chloroplasts, we found that photoorientationof chloroplasts in protonemata of the fern Adiantum capillus-veneriscould be induced by brief irradiation with polarized red light.After irradiation with red light (R) of 3 or 10 min, orientationalmovement was detected as early as 10 min after the irradiation;it continued during the subsequent dark period for 30–60min, after which chloroplasts gradually dispersed again. WhenR-treated protonemata were irradiated briefly with a second10-min pulse of R, 60 min after the onset of the first irradiation,the orientational response of chloroplasts was again observed.Typical red/far-red photoreversibility was apparent in the response,indicating the involvement of phytochrome. By contrast, irradiationwith polarized blue light for 10 min was ineffective, whileirradiation with blue light (B) at the same fluence for a longerperiod of time clearly induced the photoorientation of chloroplasts.It is likely that longterm irradiation is necessary for theresponse mediated by a blue-light receptor. When protonemata were irradiated with far-red light (FR) immediatelyafter R or after a subsequent dark period of 10 min, the magnitudeof the orientational response was smaller and chloroplasts dispersedmore quickly than those exposed to R alone. When FR was appliedat 50 min, when the response to R had reached the maximum level,chloroplasts again dispersed rapidly to their dark positions.These results indicate that P_FR not only induces the photoorientationmovement of chloroplasts but also fixes the chloroplasts atthe sites to which they have moved as a result of photoorientation. (Received June 2, 1993; Accepted January 11, 1994)     

Effects of Blue Light on Cell Elongation and Microtubule Orientation in Dark-Grown Gametophytes of Ceratopteris richardii

Gametophytes of Ceratopteris richardii developed into strap-shapedprothalli in the dark. The prothalli had an apical meristem,a subapical elongation zone and a basal zone where no growthoccurred. Continuous irradiation of blue light inhibited cellgrowth of the elongation zone, although red or far-red lighthad no effect on elongation. Cortical microtubules (MTs) ofsubapical cells reoriented from transverse to oblique or parallelto the growing axis during blue light inhibition. Each regionof the strap-shaped prothallus was irradiated with a micro-beamof blue light. Cell elongation in the subapical region was notinhibited by irradiation at the apical meristem. Irradiationof the subapical region inhibited cell elongation to a similarextent as the whole irradiation control. When a single elongatingcell at one side of the subapical region was irradiated by ablue microbeam, elongation was inhibited in a cell at the irradiateside only, resulting in a bowing prothallus. Cortical MTs reorientedfrom transverse to longitudinal to the cell axis in irradiatedcells only. The results indicate that each cell in the subapicalregion perceives blue light by itself, reorients only its corticalMTs and ceases only its cell elongation, independent of surroundingcells. (Received October 17, 1996; Accepted December 9, 1996)     

Dichroic Orientation of Phytochrome Intermediates in the Pathway from PR to PFR as Analyzed by Double Laser Flash Irradiations in Polarotropism of Adiantum Protonemata

The polarotropic response in protonemata of the fern Adiantumis regulated by phytochrome (Kadota et al. 1984); P_R and P_FRhave been shown to be dichroically oriented parallel and normalto the cell surface, respectively (Kadota et al. 1982). Thischange in the dichroic orientation of phytochrome during photoconversionwas analyzed by a newly-built, polarization plane-rotatabledouble laser flash irradiator. A polarotropic response was effectivelyinduced with a flash of polarized red (640 nm) light (6xl0^–7s) having the vibration plane of the electrical vector parallelto the protonemal cell axis. When a flash of polarized far-red(710 nm) light (6xl0^–7s) was given 30 sec after the redflash, the red flash-induced response was reversed by a far-redflash vibrating normal to the cell axis but not by one vibratingparallel. However, when given 2 µs or 2 ms after the redflash, the polarotropic response was not reversed by a polarizedfar-red flash vibrating normal to the cell axis but was reversedby a parallel-vibrating flash. These results suggest that theorientation of phototransformation intermediates existing 2µs or 2 ms after a red flash is still parallel to thecell surface, and that the change in the orientation of phytochromemolecules occurs between 2 ms and 30 s after the red flash. (Received February 3, 1986; Accepted April 23, 1986)     

Effect of far-red light pulse on induction and production of flowers in Lemna paucicostata 6746 in darkness

A short-day duckweed, Lemna paucicostata 6746, was exposed tocontinuous darkness at 26^?C, and the changes in the floral parameters(3) due to far-red and/or red light pulse given at various timesof the dark period were studied. Parameters a (vegetative growth rate) and (flowering ratio)were respectively decreased and increased with a far-red lightpulse given at the outset of the dark period. The decreaseda and the increased remained almost unchanged until the 7thhour, but returned to their initial levels thereafter. The far-redlight actions on a and were reversed by subsequent exposureto red light. Parameter P₁ (pre-flower induction period) wasextended by 1 day when far-red and/or red pulse was given atabout the 7th hour of the dark period. A far-jed pulse givenat the outset of the dark period only affected parameter P₂(flower induction period). Although the sensitivity of P₂ tored light increased with time, its sensitivity to far-red lightremained constant and at about the 7th hour was equally sensitiveto far-red and red lights. Both red and far-red pulses givenlater than the 7th hour were increasingly ineffective on P₂.The red/far-red reversibility occurred only for the action onP₂ of the far-red pulse applied during the early dark period.Parameter P₄ (flower production period) varied rhythmicallyin length with a far-red puke, the maximum shortening and extensionbeing induced by the pulse given at about the 7th and 19th hours,respectively. The sensitivity of P₄ to red light also changedrhythmically with an inverse phase angle to the rhythmic responseto farred light, and the far-red and red light actions werereversed respectively by subsequent red and far-red lights. These findings suggested that multiple timing devices includingan hourglass-type clock and a circadian clock are involved induckweed flowering. (Received October 25, 1978; )     

Returning Dark-Induced Cell Cycle to the Beginning of G1 Phase by Red Light Irradiation in Fern Adiantum Protonemata

In filamentous protonemata of Adiantum capillus-veneris L. preculturedunder continuous red light, the progression of cell cycle whichwas induced by transferring the protonemata to the dark wasinhibited and the phase returned to the beginning of G1 by redlight irradiation unless the cell cycle had progressed to a"point of no return" which coincides with the beginning of Sphase. The effect of red light was reversed by subsequent far-redlight. Typical red far-red reversibility indicates that thephotoreceptive pigment is phytochrome. (Received May 17, 1984; Accepted June 21, 1984)     

Intracellular Photoreceptive Site for Blue Light-Induced Cell Division in Protonemata of the Fern Adiantum--Further Analyses by Polarized Light Irradiation and Cell Centrifugation

The intracellular localization of the photoreceptive site forblue light-induced cell division in single-celled protonemataof Adiantum capillus-veneris L. was investigated using polarizedlight irradiation and protonemal cell centrifugation. The responseto irradiation with polarized blue light showed no dependenceon the direction of light polarization. However, centrifugationof the protonemata followed by microbeam irradiation showedthat the site of blue light perception could be displaced togetherwith the nucleus. Centrifugal treatment changed the distributionof intracellular organelles at the time of light exposure andbasipetally displaced the nucleus about 90µm. This treatmenthad no effect on the induction of cell division with blue lightif the protonemata were centrifuged again acropetally afterthe light treatment. Microbeam (30x30 µm²) irradiationwith blue light of the apical 45–75 ßm region,the receptive site of blue light in non-centrifuged cell, didnot induce cell division. However, cell division was inducedby irradiation of the nucleus-containing region, indicatingthat the photoreceptive site was displaced together with thenucleus by the centrifugation. These results suggest that theblue light receptor regulating cell division in Adiantum protonematais not likely to be located on the plasma membrane. (Received February 20, 1986; Accepted May 27, 1986)     

Intracellular Photoreceptive Site for Polarotropism in Protonema of the Fern Adiantum capillus-veneris L.

Polarotropic response was induced by short-term irradiationwith polarized red light in single-celled protonemata of thefern Adiantum capillus-veneris L. that had been grown apicallyunder red light for 6 days then for 15 hr in the dark. Sequentialobservation of the apical growth with a time-lapse video systemshowed that the direction of apical growth changed within 30min after the brief irradiation. Microbeam irradiation withpolarized red light of the subapical, dark-grown flank of theapical, 5–15 µm region of the protonema inducedthe polarotropic response most effectively. When both sidesof the flank were irradiated simultaneously with different fluencesof polarized red light with the same vibrating plane of 45°with protonemal axis, polarotropism took place normally, ifthe fluence ratio, B/A (B: fluence given to the side towardwhich the protonema should bend in polarotropism, A: fluencegiven to the other side) was not less than one-half. But, ifthe ratio became less than that, the protonemata no longer showedpolarotropism, they grew toward the side of higher fluence dependingon the difference in fluences between both sides. (Received August 1, 1981; Accepted September 29, 1981)     

Studies on the Photoreceptors for the Promotion and Inhibition of Flowering in Dark-Grown Seedlings of Pharbitis nil Choisy

Three-day-old etiolated seedlings of Pharbitis nil were exposedto red light for 10 min and sprayed with N⁶-benzyladenine beforetransfer to a 48-h inductive dark period, after which they weregrown under continuous white light. A second red irradiationpromoted flowering when given at the 5 and 24th hour of theinductive dark period but inhibited flowering at the 10 and15th hour. Far-red light inhibited flowering when given at anytime during the first 24 h of the dark period. Red/far-red reversibilitywas clearly observed at the 0, 5, 10 and 24th hour, but notat the 15th hour when both red and far-red lights completelyinhibited flowering. The action spectrum for the inhibition of flowering at the 15thhour of the inductive dark period had a sharply defined peakat 660 nm and closely resembled the absorption spectrum of theP_R form of phytochrome. The photoreceptors involved in thesephotoreactions are discussed. (Received June 10, 1983; Accepted July 6, 1983)     

Apical Growth of Protonemata in Adiantum capillus-veneris IV. Phytochrome-Mediated Induction in Non-Growing Cells

In non-growing two-celled protonemata of Adiantum capillus-veneris,apical growth was induced most effectively by red light irradiation;half of the samples were induced to grow by 660 nm light ofca. 1.5 J m^–2 and the maximum number by ca. 70 J m^–2.The reciprocity law was valid in this photoinduction. The growthresumption became detectable 6 hr after the light irradiationand reached a plateau within 24 hr irrespective of given fluences.When non-growing samples were irradiated with red light of 4.6W m^–2 for 4 sec or shorter, the effect was fully reversedby a subsequent irradiation with far-red light to the far-redlight control level. But, when the red light was given for 16sec or longer, photoreversibility became partial. An interveningdark period of 2 min between red and far-red light did not significantlyinfluence the photoreversibility so that the escape reactionin the dark may not be attributed to the above-mentioned lossof photoreversibility. By means of a local irradiation with a narrow red light beam(10 µm in width), the apical cell was found to be photosensitivefor the growth induction, but basal cell was not. Photoreceptivesite was not localized in any particular region of the apicalcell, but was rather dispersed in the entire apical cell. (Received January 26, 1981; Accepted March 10, 1981)     

Changes in microtubule and microfibril arrangement during polarotropism inAdiantum protonemata

Polarotropism was induced inAdiantum (fern) protonemata grown under polarized red light by turning the electrical vector 45 or 70 degrees. One hour after the light treatment, tropic responses became apparent in many cells as a slight distortion of the apical dome. Changes in the position of the circumferentially-arranged cortical microtubule band (Mt-band) (Murataet al., 1987) and the arrangement of microfibrils around the subapical part of protonemata were investigated in relation to the polarotropic responses. Twenty minutes after turning the electrical vector, preceding the morphological change of cell shape, the Mt-band began to change its orientation from perpendicular to oblique to the initial growing axis. After 30 min, the Mt-band changed its orientation further under 45 degrees polarized light, but under light rotated 70 degrees, it began to disappear. In phototropic responses induced by local irradiation of a side of the subapical part of a protonema with a non-polarized red microbeam, the Mt-band on the irradiated side disappeared or became faint within 20 min, but neither disappearance nor a change of orientation of Mts occurred on the non-irradiated side. One hour after turning the electrical vector 45 degrees, in half of the cells tested, the innermost layer of microfibrils in the subapical part of the protonema changed its orientation from perpendicular to oblique to the growing axis, corresponding to the changes in the orientation of the Mt-band. After 2 hr, those changes were obvious in all cells examined. The same basic results on the orientation of microfibrils were obtained with protonemata cultured for 2 hr under 70 degrees polarized light. The role of the Mt-band in tropic responses is discussed.     

The junction between the plasma membrane and the cell wall in fern protonemal cells,as visualized after plasmolysis,and its dependence on arrays of cortical microtubules

Summary The junction between the plasma membrane and the cell wall in the subapical region of tip-growing protonemata of the fernAdiantum capillus-veneris was visualized by plasmolyzing the cells with a 1 M solution of NaCl. When the protonemata were treated with this solution, cells were rapidly plasmolyzed and the plasma membrane became detached from the cell wall around the entire periphery of the cell, with the exception of the subapex. In the subapical region, the connection between the cell wall and the plasma membrane remained undisturbed, whereas the membrane in other regions, as well as at the apex, was detached from the cell wall. As a result, the protoplasm appeared to adhere to the wall by a ringlike band of plasma membrane at the subapex. The location of the junction coincided with that of a circular array of microtubules (MTs) and microfilaments (MFs) at the cell cortex. The subapical junction disappeared when protonemata were treated with colchicine, cytochalasin B (CB), and blue-light irradiation, all of which are known to disrupt circular arrays of MTs. CB and blue light also disrupt the array of MFs but colchicine does not. Thus, the junction depends on the cortical MTs and not on the MFs. This finding indicates that the junction between the plasma membrane and the cell wall is sustained by a cortical array of MTs and suggests the presence of a specific and localized transmembrane structure.Abbreviations CB cytochalasin B - MF microfilament - MT microtubule     

Flowering of the long-day plant, Lemna gibba, under short-day schedules composed of red and far-red light

Flowering in Lemna gibba, a long-day duckweed, can be inducedunder a short-day condition when the photoperiodic regimes areR₇FR₃ (7 hr red followed by 3 hr far-red), R₅FR₅ and R₃FR₇.This indicates the necessity of a proper balance between redand far-red effects for flowering. The flowering induced bythese regimes is inhibited by a brief exposure to red givenat the start of darkness and this inhibition is reversed bysubsequent exposure to far-red. Thus, the red/far-red reversibleeffect is found only at the beginning of darkness for floweringof L. gibba. However, flowering of L. gibba is promoted by a red light breakgiven near the middle of a 14 hr dark period. The promotiveeffect is not reversed by subsequent exposure to far-red, i.e.,the effect of the red break converts from inhibition to promotionas when given later in the dark period, which suggests the involvementof a timing mechanism. (Received July 21, 1973; )     

Action spectra for polarotropism and phototropism in protonemata of the fern Adiantum capillus-veneris

The action spectrum for polarotropism was determined, using the Okazaki large spectrograph, by brief irradiation with light between 260 nm and 850 nm in single-celled protonemata of the fern Adiantum capillus-veneris L., which had been cultured for 6 days in red light and then in the dark for 15 h. The action spectrum had a peak at around 680 nm. This effect was nullified by subsequent irradiaton with far-red light, and typical red/far-red reversibility was observed, indicating the involvement of phytochrome. Polarized ultraviolet or blue light had no effect on the direction of apical growth. The action spectrum for phototropism was also determined in the red light region by means of brief microbeam irradiation of a flank of the subapical region of the protonema. This spectrum showed a peak at 662 nm which was consistent with the absorption peak of phytochrome, but not with the peak of the action spectrum for polarotropism.     

Phytochrome in the Fern, Adiantum capillus-veneris L.: Spectrophotometric Detection in Vivo and Partial Purification

Spectrophotometric studies of fern phytochrome were performedusing dark-grown leaves of Adiantum. The absorbance differencespectrum between the red- and far-red-light irradiated sampleshowed a photoreversible absorbance change in the far-red region,with a maximum located at 728–730 nm. The concentrationof phytochrome was highest at the leaf tips and decreased graduallyalong the leaf axis. As in the case of angiosperm phytochrome,the level of fern phytochrome decreased under continuous whitelight, and the level increased again when deetiolated tissuewas transferred back to the dark. When the fern tissue was exposedto a pulse of red light, the dark reversion of P_FR to P_R tookplace with almost no destruction of P_FR. Phytochrome could beextracted from light-grown young leaves of the fern with a slightlyalkaline, aqueous buffer that contained 1 M NaCl. The differencespectrum of the partially purified phytochrome from fern wassimilar to that of partially degraded phytochrome from angio-sperms.A polyclonal antibody raised against phytochrome from etiolatedrye seedlings immuno-stained (albeit weakly) a 110-kDa polypeptideafter fractionation by SDS-polyacrylamide gel electrophoresisof the preparation of fern phytochrome. The band was very probablyfern phytochrome since it emitted zinc-induced fluorescence. (Received July 12, 1990; Accepted October 5, 1990)     

Rhizoid differentiation in Spirogyra II. Photoreversibility of rhizoid induction by red and far-red light

The optimum light conditions for rhizoid formation in Spirogyrawere determined. Red light was significantly effective on rhizoidformation while green, blue and violet lights had less effect.The dose-effect curve of red light was investigated and theminimum energy needed to saturate the effect was 8.1 Kergs.cm_–2.The effect of red light was completely reversed by subsequentirradiation with far-red light. The doseeffect curve of far-redlight was also obtained. The repeatedly reversible photoresponseswith red and far-red light strongly suggest that the photoreceptorof the rhizoid formation system is phytochrome. The existenceof phytochrome in the Spirogyra cell was also demonstrated spectrophotometrically.The half time for the escape reaction from the reversal effectof far-red light was 2hr. There may be no pigment other thanphytochrome mediating the photoreaction. (Received December 14, 1972; )     

Phytochrome Control of Turion Formation in Spirodela polyrhiza L. Schleiden

Turion yield in Spirodela polyrhiza, strain SJ, is increasedby increasing the daily light period. This effect is more pronouncedin autotrophic than in mixotrophic conditions. Night-break irradiation(15 mins) increased turion yield by 150 % under the conditionsof an 8-h daily light period. Besides the effect of night-breakirradiation, end-of-day far-red irradiation decreased turionyield with increasing photoperiod, whereas end-of-day red irradiationwas without any effect. This demonstrates the promoting effectof the P_fr form of phytochrome on formation of light-grown turions. Formation of dark-grown turions was increased by about 240%by a single red light pulse and was reversed by an immediatelyapplied far-red light pulse. Consequently, under heterotrophicconditions phytochrome modulates the turion formation process. Spirodela polyrhiza L. Schleiden, duckweed, Lemnaceae, photomorphogenesis, phytochrome, turion     

Changes in Organelle Movement in the Nuclear Region during the Cell Cycle of Adiantum Protonema

Movements of organelles in the nuclear region as the cell cycleprogresses in single-celled protonemata of Adiantum capillus-veneriswere examined by digital image processing techniques and microscopyof particle movement. Organelles in the nuclear region werenot very crowded and moving directionally along the longitudinalaxis of the filamentous cell in the G₁ and S phases. They beganto gather and accumulate in the nuclear region in early G₂ phase,after which directional movement changed to undirectional Brownianmotion-like movement in late G₂ phase. Movement of organelleslocated on the lateral surface of the nucleus slowed after premitoticpositioning of nucleus and lasted until the nucleolus disappeared.Movement of organelles in the cytoplasm surrounding the nucleoplasmresumed just after the nucleolus disappeared, whereas organelleslocated in the outer regions of the apical and basal surfacesof the nucleus moved rapidly during prophase but did not moveduring metaphase, movement being resumed after chromosome separation.Thus, organelle movement in the nuclear region showed temporaland spatial change during the cell cycle. (Received August 24, 1983; Accepted December 28, 1983)     

Action Spectra Confirm Two Separate Actions of Phytochrome in the Induction of Flowering in Lemna paucicostata 441

Action spectra studies have shown that in the short day plant(SDP) Lemna paucicostat441 there are at least two actions ofphytochrome in the induction of flowering. At the beginningof the dark period far-red light inhibited flowering, and theaction spectrum corresponded to the absorption spectrum of P_FR,while at the middle of the inductive dark period both red andfar-red light were inhibitory. The action spectrum for the redlight corresponded to that of PR absorption, but there was activityin the region beyond 720 nm which exactly coincided with theabsorption by P_FR observed at the beginning of the dark period,indicating that at the middle of the dark period there was absorptionby both P_R and P_FR. The difference in quantum efficiency betweenthe red and far-red light effects was about 60-fold. These resultsare consistent with there being a stable pool of P_FR necessaryfor the induction of flowering and another pool of phytochromein a different cellular environment which participates in thenight-break reaction as P_R. ¹ Present address: School of Applied Biology, Faculty of Science,Lancashire Polytechnic, Preston PR1 2TQ, U.K. ² 2 Present address: Division of Environmental Biology, NationalInstitute for Environmental Studies, Yatabemachi, Tsukuba, Ibaraki305, Japan. ³ Present address: Division of Plant Biological Regulation,The Riken Institute for Frontier Research Program, Hirosawa,Wako-shi, 351-01, Japan. (Received December 13, 1986; Accepted July 17, 1987)     

APICAL GROWTH OF PROTONEMATA IN ADIANTUM CAPILLUSVENERIS. I. RED FAR-RED REVERSIBLE EFFECT ON GROWTH CESSATION IN THE DARK

Apical growth of individual protonemata in Adiantum capillus-veneris was microphotographically observed before, during and after light treatment. When single-celled protonemata precultured under continuous red light were transferred to darkness, the apical growth continued for the next 24 hr at a rate somewhat slower than that under continuous red light, but the rate significantly decreased thereafter and growth ceased within 72 hr in the dark. The growth in the dark was strongly inhibited by a brief irradiation with far-red light given immediately before the dark period, and the effect of far-red light was fully reversed by subsequent red light. This reversibility was repeatedly observed, suggesting the involvement of a phytochrome system.
The intracellular localization of the phytochrome system in the protonemata was studied, using a narrow-beam irradiator. The results showed that the photoreceptive sites of far-red light are not localized in any particular region of the cell.     

Blue Light-Induced Phototropic Response and the Intracellular Photoreceptive Site in Adiantum Protonemata

Blue light-induced phototropism in Adiantum protonemata wasinvestigated with microbeam irradiation. Brief irradiation withblue light effectively induced a phototropic response when itwas applied to a half-side of the apical 200d µm regionof a protonema. The phototropic response was partly reversedby the subsequent far-red light irradiation but the full reversalof the response was not observed even when the fluence of far-redlight was increased. In the far-red reversible part of the response,blue/far-red photoreversibility was repeatedly observed. Thus,both phytochrome and a blue light-absorbing pigment (other thanphytochrome) seem to be involved in the blue light-induced phototropicresponse in Adiantum protonemata. Furthermore, detailed studiesof the far-red light effect on the fluence-response curve forblue lightinduced phototropism revealed that the concomitantmediation by the two receptors was limited to the response inthe relatively higher fluence range of blue light and that theblue light-absorbing pigment alone was responsible in the lowerfluence range. In the higher fluence range, the response mediatedby the blue light-absorbing pigment became saturated and thephytochrome response became evident, indicating a differencein the sensitivities of the two receptor pigments to blue light. When various regions of half-sides of protonemata were irradiatedwith a blue microbeam of 10 µm width, irradiation at theapical 5–25 µm region was most effective both forphytochrome- and blue light-absorbing pigment-mediated response,indicating that the site of blue light perception is almostidentical for each response. (Received July 14, 1986; Accepted September 26, 1986)