Responses of normal and dwarf Pharbitis nil to an extended dark period and gibberellic acid

The effects of a 24 hr short day, a 24 hr long day, and a 48hr short day were analyzed with regard to flowering and stemgrowth of normal and dwarf Pharbitis nil, and were comparedto effects of these photoperiodic treatments plus applied GA₃.Both short day treatments produced the same number of flowersper plant after seven cycles. The applied GA₃ was effectivein overcoming the growth deficiency of the dwarf; however, theextended dark period of the 48 hr short day and applied GA₃were both required to enhance a flowering response in the dwarfequal to that of the normal. These results indicate that somefactor is present during the extended dark period which enhancesflowering. ¹ This work was supported by NSF Grant GB-7510 and State supportedresearch TTU-191-4771 to M. W. C. ² Present address: Department of Biology, Union University,Jackson, TN 38301, U.S.A. (Received September 4, 1979; )     

Spectral Dependence of Night-break Effect on Photoperiodic Floral Induction in Lemna paucicostata 441

A single dark period of longer than 8 hr induced flowering inLemna paucicostata 441 cultured in E medium. Monochromatic lightsof 450, 550, 650 and 750 nm with a half-power bandwidth of 9nm given for 10 min at the 8th hour of a 14-hr dark period inhibitedflowering. The fluence rates required for 50% inhibition were10, 0.5, 0.1 and 3 µmol m^–2. sec^–1, respectively.When applied between the 4th and the 10th hour of the dark period,lights of 450, 550 and 650 nm were inhibitory showing a maximumeffect at the 8th hour. But 750-nm light completely inhibitedflowering when applied at any time during the first 8 hr ofthe dark period. The inhibitory effect of 750-nm light givenat the beginning of the dark period was totally reversed bya subsequent exposure to 650-nm light, and the fluence-responsecurves for the effect of 750-nm light given at the 0, 4th and8th hour were essentially the same. This suggests that the presenceof P_FR is crucial for the floral initiation throughout the first8 hr of the inductive dark period. The role of phytochrome inthe photoperiodic flower induction of L. paucicostata is discussed. (Received January 4, 1982; Accepted March 19, 1982)     

RNA metabolism in apices of Pharbitis nil daring floral induction

RNA metabolism was studied in apices of Pharbitis nil duringand after floral induction. In continuous light ³H-uridine accumulatedin RNA at a constant rate over an 18 hr period. In darkness,however, the rate of accumulation of label into RNA was constantuntil the 10th hour at which time a rapid burst of accumulationoccurred, peaking at the 14th hour of darkness and followedby a net loss of label. The RNA involved in this burst is probablymRNA due to its size and poly(A) content. This phenomenon doesnot seem to be associated with floral induction, since the siteof perception is the apex, and it also occurs under conditionswhere floral initiation is inhibited by a brief light interruptionof the dark period. Immediately after floral induction by a16-hr dark period the rate of RNA synthesis was suppressed about14%. This suppression lasts for about 12 hr and was followedby a twofold increase in the rate of RNA synthesis, comparedto non-induced apices, at 64 hr after the beginning of the inductivedark period. These post-induction changes were found to occurin all RNA fractions. ¹Present address: Department of Radiation Biology and Biophysics,University of Rochester School of Medicine and Dentistry, Rochester,N.Y. 14642, U.S.A. (Received March 15, 1976; )     

THE ROLE OF AUXIN IN THE PHOTOPERIODIC TUBERIZATION IN BEGONIA EVANSIANA ANDR.

The formation of aerial tubers in Begonia plants, an SD response,was inhibited by IAA, NAA and IBA applied to their leaves duringthe dark periods. The effectiveness of IAA differed accordingto the time of application during the dark periods, and themost sensitive time varied with daylengths employed. In order to inhibit the tuberization under optimal photoperiods(8-hr SDs), IAA had to be applied during the first 2 days orso of the SDs. Under non-optimal photoperiods, however, IAAwas effective even when applied somewhat later. The auxin activity of leaf extracts from the plants subjectedto 8-hr SDs decreased during the first 2 or 3 days to a minimum,and then increased until finally began to decrease, again; undernon-optimal photoperiods, the minimum of auxin activity wasattained more slowly. The paper-chromatographic study suggestedthat the change in auxin activity was mainly due to the changein IAA content. The number of SDs making the auxin content minimal agreed withthe minimum number of SDs required for tuberization. On the basis of the above results, the part played by endogenousauxin in photoperiodic induction is discussed. ¹Present address: Institute for Agricultural Research, TôhokuUniversity, Sendai. ²Present address: Biological Institute, Yamaguchi University,Yamaguchi.     

Effect of varying lengths of inductive and supplementary non-inductive photoperiods on vegetative growth and flowering of Impatiens balsamina

The photoperiodic requirement for flowering in Impatiens balsaminachanges with the length of the photoperiod. Floral buds wereinitiated with two 8 hr but with four 15 hr photoperiods andflowers opened with four 8 hr but twenty-eight 15 hr photoperiods.A part of the photoperiodic requirement for floral inductionin this plant can be substituted by LDs containing 4 or morehours of darkness (10). It indicates the identical nature ofthe floral stimulus produced during the dark period, whetherit forms a part of the inductive or non-inductive cycles. Theeffect of these supplementary non-inductive photoperiodic cyclesin causing floral bud initiation also depends on the lengthof the first inductive obligatory cycle. More floral buds andflowers were produced on plants exposed to 15 hr than 8 hr photoperiods,probably due to the higher number of leaves that were producedunder the former condition of weaker induction. The shorterthe dark period in the photoperiodic cycle, the weaker the induction,the slower the rate of extension growth but the more differentiationof leaves. ¹ Present address: Department of Biology, Guru Nanak Dev University,Amritsar-143005, India. (Received November 9, 1977; )     

Novel Light-Dark Change of Proline Levels in Halophyte (Mesembryanthemum crystallinum L.) and Glycophytes (Hordeum vulgare L. and Triticum aestivum L.) Leaves and Roots under Salt Stress

Proline accumulation was determined in a facultative halophyte,Mesembryanthemum crystallinum and glycophytes, barley (Hordeumvulgare L.) and wheat (Triticum aestivum L.) Proline accumulationpreceded the shift of CAM in M. crystallinum and did not occurin the continuous darkness. The novel light-dark change of prolinelevel (high in the light and low in the dark) was observed inleaves of all three plants. Proline levels of shoots in barleyand wheat also showed the same light-dark change, suggestingthat proline accumulated in the leaves in the light was nottranslocated to other tissues in the dark period. These resultssuggest that proline has a bifunctional role in the acclimationto high salt stress; an osmoregulant role in the light, anda substrate for dark respiration to supply energy to compartmentationof ions into vacuole in the dark. ¹Present address: Kyoto Biological Res. Lab., Bio-Chiba Inc.Watsuka,Soraku, Kyoto, 619-12 Japan ²Present address: Kobayashi Pharmaceutical Co., Ltd. Doshomachi,Chuo-ku, Osaka, 541 Japan     

Regulation of Protochlorophyll(ide) Levels in Dark-Grown Non-Dividing Euglena 3. Proplastid Structure during Loss and Regeneration of Protochlorophyll(ide)

Cells of Euglena gracilis Klebs var. bacillaris Cori growingin darkness on a complete medium have small undifferentiatedproplastids. On transfer to an incomplete (resting) medium indarkness, the cells cease division within 72 h. During thistime the proplastid expands and several prothylakoids and prolamellarbodies develop even though phototransformable protochlorophyll(ide)[PT-Pchl(ide)] is decreasing. As PT-Pchl(ide) decreases furtherand reaches a stable plateau after 4–5 more days in darkness,the proplastid structure becomes highly reduced. Forty minutesof light plus a one h dark period, or addition of glutamateor malate for 7 h does not change the proplastid structure significantlyeven though PT-Pchl(ide) returns to the level found in growingcells. Upon prolonged incubation in darkness after light treatment(72 h) an expanded proplastid containing prothylakoids, prolamellarbodies and membrane whorls with mitochondria in close associationis seen; most of the cellular paramylum is lost during thisperiod leaving cavities in the cytoplasm. Without light, prolongedincubation in darkness (72 h) with malate leads to accumulationof cellular paramylum but no change in proplastid structurewhile prolonged treatment with glutamate (72 h) allows the formationof a few prothylakoids but no prolamellar bodies. ¹Supported by Grants GM 14595 from the National Institutes ofHealth. ²Permanent address: Department of Microbiology, Tokyo MedicalCollege, 6-1-1 Shinjuku, Tokyo 160, Japan. ³Abraham and Etta Goodman Professor of Biology. (Received July 23, 1983; Accepted September 22, 1983)     

Acid-Induced Stomatal Opening in Commelina communis and Vicia faba

The effects of H^$ and fusicoccin (FC) on stomatal opening inthe dark were investigated using epidermal strips of Commelinacommunis and Vicia faba cv. Ryosai Issun. Citrate-phosphatebuffer induced maximal opening of stomata at pH 3.0 when testedover the range of 2.7 to 5.0. HCl at 1 mM also induced stomatalopening without appreciable accumulation of K^$ in the guardcells. After 4 hr treatment with 10 µM FC, stomata openedwith concomitant accumulation of K^$ in the guard cells, although1–2 hr treatment caused opening without concomitant K^$increase. These results suggest that stomatal opening can be caused bysalt accumulation and/or changes of the physicochemical conditionsin the cell wall of the guard cells due to high acidity. ¹ Present address: Biological Laboratory, Faculty of Education,Nagasaki University, Nagasski 852, Japan. (Received April 30, 1982; Accepted July 17, 1982)     

Studies on chilling injury in plant cells II. Ultrastructural changes in cells rewarmed at 26?C after chilling treatment

Both the restoration and deterioration of ultrastructures wereobserved during therewarming of cultured cells of Cornus stoloniferain which chilling at 0?C had caused an apparent change in themorphology of the organelles. Complete restoration of the ultrastructures,moderately altered by the 12-hr chilling, took place within12 hr of wanning at 26?C. Even in cells chilled for 24 hr, severelyaltered ultrastructures were partially or completely repairedin more than fifty percent of the treated cells. Some cellschilled for 24 hr, however, displayed further deteriorationof their ultrastructures during rewarming. Restoration of therough endoplasmic reticulum and the development of polysomesin recovering cells were characteristic of the early stage ofrewarming. Rupture of the tonoplast was sometimes observed duringrewarming of cells chilled for 24 hr. A possible role for therough endoplasmic reticulum and for the integrity of the tonoplastin cell recovery during the chill-warm sequence is discussed. ¹Contribution No. 2026 from the Institute of Low TemperatureScience, Hokkaido University. ²This work was supported in part by Grant 248004 from the Ministryof Education. (Received November 6, 1978; )     

Effects of Light on Degradation of Chlorophyll and Proteins during Senescence of Detached Rice Leaves

Regulatory effects of light on senescence of rice leaves wereinvestigated by measuring degradation of chlorophyll and proteinsin leaf segments which had been kept in the dark or under illuminationwith light of different intensities and colors. When leaveshad been left in total darkness for three days at 30°C,there was an initial long lag that lasted for one whole dayand then chlorophyll was rapidly degraded in the second andthird days. Breakdown of chlorophyll was strongly retarded bycontinuous illumination with white light of intensity as lowas 0.5 µmol photons m^–2 s^–1 but the effectof light decreased at intensities above 10 µmol photonsm^–2 s^–2. The initial lag and subsequent degradationof chlorophyll in the dark were little affected by illuminationwith red or far red light at the beginning of dark treatment.However, a brief illumination with red light at the end of thefirst and/or second day significantly suppressed degradationof chlorophyll during subsequent dark periods and the effectof red light was nullified by a short irradiation with far redlight. Thus, degradation of chlorophyll is regulated by phytochrome.Thylakoid membrane proteins and soluble proteins were also largelydegraded during three days in the dark. Degradation of membraneproteins such as the apoproteins of light-harvesting chlorophylla/b proteins of photosystem II and chlorophyll a-binding proteinsof reaction center complexes showed a long lag and was stronglysuppressed by illumination with weak white light. Thus, theloss of chlorophyll can be correlated with degradation of chlorophyll-carryingmembrane proteins. By contrast, light had only a weak protectingeffect on soluble proteins and ribulose-1,5-bisphosphate carboxylase/oxygenaserapidly disappeared under illumination with weak white light.Thus, breakdown of thylakoid membrane and soluble proteins aredifferently regulated by light. Artifacts which would be introducedby detachment of leaves were also discussed. ¹ Present address: Department of Applied Biology, Faculty ofScience and Technology, Science University of Tokyo, Yamazaki,Noda-shi, Chiba, 278 Japan. ² Present address: Department of Life Science, Faculty of Science,Himeji Institute of Technology, Harima Science Park City, Hyogo,678-12 Japan.     

Light-Stimultated Aerobic Growth of Erythrobacter Species OCh 114

Bright light almost completely suppressed bacteriochlorophyllsynthesis in Erythrobacter species OCh 114. Consequently, theeffect of continuous illumination on growth was barely observedwhen illumination was started an inoculation and the inoculumsize was small. However, when an aerobic culture of this bacteriumgrown preliminarily in the dark was illuminated after the celldensity became high, light stimulated the growth remarkably,indicating that the utilization of light energy for growth viabacteriochlorophyll which had been formed during the growthin the dark. The maximum cell yield from a culture intenselyilluminated following preliminary growth in the dark was twofoldthat from a culture grown in the dark throughout. A continuousoxygen supply was a prerequisite for the stimulation of growthby light. Microaerobic or anaerobic incubation of a dark-grownculture in the light brought about a decrease in spheroidenonecontent and a formation of an unknown pigment. ¹ Present address: Kawaguchi Factory, Sapporo Breweries Ltd.,Namikimoto-cho, Kawaguchi, Saitama 332, Japan ² Present address: Institute of Applied Microbiology, The Universityof Tokyo, Yayoi 1-1-1, Bunkyo-ku, Tokyo 113, Japan (Received October 6, 1986; Accepted January 9, 1987)     

Identification of Hinesol as a Chlorophyll-Preserving Substance

A chlorophyll-preserving substance was isolated from rhizomesof Atractylodes lancea DC. and identified as (—)-hinesolon the basis of spectroscopic data. Hinesol at more than 0.22DIH was effective for preserving chlorophyll of oat (Avena sativaL. cv Victory) leaves in the dark with 40 to 50% of the initialchlorophyll content being retained at 2.2 mM. However, hinesolstimulated chlorophyll loss with light exposure and at 4.5 mMcaused complete bleaching when measured 4 days after treatment. ¹Dedicated to the memory of the late Professor Joji Ashida. (Received December 9, 1982; Accepted April 22, 1983)     

Perithecial formation in Gelasinospora reticulispora III. Inhibitory effects of near-UV and blue light during the inductive dark period

Growing hyphae of Gelasinospora reticulispora required a continuousdark period prior to photoinduction of perithecia. The inductivedark period was interrupted by brief exposure of the hyphaeto white light so that the formation of perithecia no longertook place. Photosensitivity of the hyphae in terms of the light-breakeffect gradually changed during the inductive dark period. Sensitivityreached its maximum at the 18th hr of the dark period when anirradiation of 1?10⁵ ergs cm^–2 of near-UV light or 4?10⁴ergs cm^–2 of blue-light was sufficient for the light-break.Red and far-red light had no effect at all. The light-breakeffect was limited to the irradiated portion of the hyphae anddid not affect any unirradiated portions. Inhibitory effecton perithecial formation of continuous white light could betotally replaced for several days with intermittent irradiationof near-UV or blue light if given for 5 min every 4 hr. (Received December 18, 1973; )     

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)     

Growth and flowering of Lemna paucicostata I. General aspects and role of chelating agents in flowering

Lemna paucicostata HEGELM. is normally a short-day plant andflowers only in the presence of a chelating agent (EDTA or EDDHA)in the medium. The plant can be induced to flower even by asingle long night treatment; the flowering percentage, however,increases with further inductive cycles. The length of the criticaldark period depends upon the chelating agent employed in themedium. It is between 10 and 12 hr in the medium containingEDTA and about 8 hr in the EDDHA-supplemented medium. Red lightinterruption in the middle of the dark period—even fora minute—is inhibitory for flowering. Attempts to identify the metal ion(s) chelated reveal that thechelating agents affect flowering by facilitating iron uptake.This is also supported by the fact that the requirement of achelating agent for flowering can be overcome with an excessof iron in the medium. Interestingly, provision of EDDHA andexcess of ferric citrate, together, can bring about floweringeven under long days. ¹Originally HEGELMAIER (1) designated L. paucicostata as a separatespecies; however, THOMPSON (2) and DAUBS (3) have treated itsynonymous to L. perpusilla. More recently, based on physiologicaland chemotaxonomic studies, the distinctiveness of L. paucicostatafrom L. perpusilla has been favoured (4, 5). (Received September 8, 1969; )     

Circadian Rhythms of Potassium and Sodium Contents in the Growing Front of Neurospora crassa

The temporal changes of potassium (K⁺) and sodium (Na⁺) contentsin the growing front of Neurospora crassa (al-2, bd strain)grown on solid medium showed circadian rhythms which persistedfor at least 45 h in the dark. The K⁺ content reached a maximumat about 10 and 30 h after the transfer from light to darkness,while the Na⁺ content was at a minimum at these times. Boththe rhythms were set off by the light to dark transition andwere not observed in constant light. The phase of the circadianrhythm of conidiation of this strain was delayed by 5 h by exposureto 50 min of white light (photon fluence rate 20.7 W/m²) 7 hafter the light to dark transition. The same exposure significantlychanged the ratio of K⁺ to Na⁺ content in the growing frontmeasured 8 h after the exposure. ³ Present address: Pesticides Research Laboratory, TakarazukaResearch Center, Sumitomo Chemical Co., Ltd., 2-1, 4-chome,Takatsukasa Takarazuka, Hyogo 665, Japan. (Received June 26, 1984; Accepted January 11, 1985)     

Effects of continuous illumination on the rhizome of Caulerpa prolifera

Caulerpa plants were grown under a 12-hr light and 12-hr dark(12L-12D) regime for 8 days followed by 8 days of continuouslight (24L-0D). Under both light regimes the elongation of therhizome was by means of "tip growth". However, the rate of rhizomeelongation in 24L-0D regime (10.9 mm/day) was higher than thatof 12L-12D regime (7.9 mm/day). Jn the region of 1.5 mm fromthe tip, the RERE (relative elemental rate of elongation) under24L-0D and 12L-12D regimes were respectively 4% and 3% elongationper hr. Under 12L-12D photoperiod the subapical part of therhizome exhibited distinctive oscillation: bending upward duringthe light period or at the time of rhizoid cluster initiation,and in the dark becoming relatively straight except at the timeof cluster initiation. No such distinctive oscillation was observedin continuous light. ¹ Report of work supported by research grant GB-7885 from theNational Science Foundation, and in part by Research Councilof Rutgers University. (Received June 8, 1971; )     

Metabolism and Translocation of Gibberellins in Seedlings of Pharbitis nil. (I) Effect of Photoperiod on Stem Elongation and Endogenous Gibberellins in Cotyledons and Their Phloem Exudates

Gibberellin A₁, (GA₁), GA₁₉, and GA₂₀ in phloem exudates andcotyledons of seedlings of Pharbitis nil cv. Violet, grown underdifferent photoperiodic conditions, were qualitatively and semi-quantitativelyanalyzed by a combination of high performance-liquid chromatography(HPLC) and radioimmunoassays (RIA). The levels of GA₁₉ and GA₂₀were higher in cotyledons from plants grown under dark treatment(DT) conditons of 16 h-light/8 h-dark for 6 days followed by8 h-light/16 h-dark for 3 days than in those grown under continuouslight (CL) for 9 days. This relationship was also observed forthe GAs in phloem exudates, although the levels were much lowerthan in the cotyledons. When GAs were applied to the cotyledons,elongation of the epicotyl was promoted more by GA₂₀ than byGA₁ or GA₁₉, especially under the CL treatment. The relativeeffect of GA₁ and GA₂₀ on the epicotyl elongation was reversedwhen these GAs were applied to epicotyls pre-treated with prohexadione,an inhibitor of 2-oxoglutarate-dependent dioxygenases. ³Present address: Frontier Research Program, The Institute ofPhysical and Chemical Research (RIKEN), 2-1 Hirosawa, Wakoshi,Saitama, 351-01 Japan ⁴Present address: Laboratory of Horticulture, Faculty of Agriculture,Nagoya University, Nagoya, 464-01 Japan     

Studies on chloroplast development in Chlamydomonas reinhardtii I. Effect of brief illumination on chlorophyll synthesis

When dark grown cells of Chlamydomonas reinhardtii y-1 mutantwere exposed to continuous light, an immediate transformationof small amounts of protochlorophyll(ide), which had been presentin the dark grown cells, to chlorophyll was observed. Afterthis, there was a slow accumulation of chlorophyll lasting for2.5-3 hr before the start of exponential synthesis. Initialaccumulation of chlorophyll was distinctly slower at a highlight intensity (13,000 lux) than it was at moderate intensitiesof light (2,000–5,000 lux). However, the exponential synthesisof chlorophyll started after the same 2.5–3 hr of illumination. A brief pre-illumination of cells followed by incubation indarkness was effective in promoting chlorophyll synthesis undersubsequent continuous illumination at high, as well as moderatelight intensities. Pretreatment alleviated retardation of theinitial chlorophyll accumulation by light of high intensity.The promoting effect of preillumination on chlorophyll synthesiswas sufficient, even when a light impulse as short as 10 secwas given. However, the effect was dependent on length of thedark period after the short pre-illumination. The full extentof this effect was observed when the dark period was about 2.5–3hr long. Further dark incubation gradually decreased the effect. On the basis of these findings, it is assumed that a factor(s)responsible for promotion of chlorophyll (or chloroplast) synthesisin the process of greening of dark grown cells is produced duringthe dark period after a brief pre-illumination, and that thefactor is turned over at a relatively fast rate. The possiblenature of the presumed factor is discussed in relation to chloroplastdevelopment. ¹Present address: Department of Biology, Faculty of Science,Kobe University, Nada-ku, Kobe, Japan. (Received August 18, 1970; )     

Tentoxin Inhibits Both Photophosphorylation in Thylakoids and the ATPase Activity of Isolated Coupling Factor F1 from the Cyanobacterium Anacystis nidulans

Tentoxin strongly inhibited the ATPase activity of isolatedcoupling factor 1 (AF₁) from the cyanobacterium Anacystis nidulans,with 50% inhibition occurring at 0.3 µM. When thylakoidsfrom A. nidulans were preincubated with 0.3 µM tentoxinfor 30 min, photophosphorylation was inhibited by 50%. Measurementsof fluorescence from 9-aminoacridine indicated that tentoxininhibited the utilization of the proton gradient by ATP formationin thylakoids. These results indicate that tentoxin is a strongenergy-transfer inhibitor of photophosphorylation in A. nidulans.Tentoxin decreased the level of ATP in intact cells both inthe light and in darkness, its effects being much stronger inthe dark. Tentoxin at 50 µM strongly inhibited the growthof the cells. ³Present address: Corporate Research and Development Laboratory,Tonen Co. 1-3-1 Nishi-tsurugaoka, Ohi-machi, Saitama, 354 Japan ⁴Present address: Technology and Engineering Laboratories, AjinomotoCo., Inc. Suzuki-cho 1, Kawasaki, 210 Japan