Priority of light/dark entrainment over temperature in setting the circadian rhythms of the prokaryote Synechococcus RF-1

Light/dark (L/D) and temperature are two major factors in the entrainment of circadian rhythms. The input pathways of these two environmental factors for the entrainment of circadian rhythms in Synechococcus RF-1 are different since the overt rhythms in mutant CR-1, one of the circadian-rhythm mutants of Synechococcus RF-1, could be established by temperature cycles but not by L/D. Therefore, it was of interest to investigate the phases of Synechococcus RF-1 cells entrained simultaneously by L/D and temperature. The circadian rhythms of nitrogenase activity and protein synthesis in RF-1 cells entrained by L/D, and by lowered or raised temperatures differed in their peaks of activity. Comparison of the phases of RF-1 cells entrained by L/D and temperature independently, and by L/D and temperature simultaneously indicated that L/D entrainment has priority over the temperature effect. Received: 8 February 1999 / Accepted: 1 April 1999     

Calcium requirement in nitrogen fixation in the cyanobacterium Synechococcus RF-1

Under diurnal 16/8-h light-dark cycles, ethyleneglycol-bis-(-aminoethyl ether)-N,N,N,N-tetraacetic acid (EGTA) at 1 mM completely blocked the appearance of rhythmic N₂-fixing activity in Synechococcus RF-1. Ca²⁺ at 2 mM, when supplied either together with or several hours after the EGTA application, restored the nitrogenase activity, whereas, when Ca²⁺ was supplied several hours later, the peak of nitrogenase activity was shifted from the dark to the light period in which the activity is normally suppressed. Sr²⁺ also reversed the inhibition by EGTA, but only partially. When O₂ in the gas phase above the culture was below 1%, the inhibition of nitrogenase activity by EGTA was reduced to less than 20% of the control value without EGTA. Thus Ca²⁺ appears to be required by the cell to protect its nitrogenase from inactivation by O₂. In media without EGTA, a close correlation between nitrogenase activity and concentrations of Ca²⁺ was also observed.Abbreviation EGTA ethyleneglycol-bis-(-aminoethyl ether)-N,N,N,N-tetraacetic acid     

Light- and temperature-entrained circadian regulation of activity and mRNA accumulation of 1-aminocyclopropane-1-carboxylic acid oxidase in Stellaria longipes

Stem and leaf tissues of Stellaria longipes Goldie (prairie ecotype) exhibit circadian rhythmicity in the activity and mRNA abundance for 1-aminocyclopropane-1-carboxylic acid oxidase (EC 1.4.3). The steady-state mRNA levels and enzymatic activity levels fluctuated with a period of approximately 24 h and reached their maxima by the middle of the light phase and minima by the middle of the dark phase. The oscillations showed damping under constant light, constant dark and constant temperature conditions, indicating that the rhythm is entrained by an external signal. The results indicate that light/dark cycles have greater entraining effects than temperature cycles. A 15-min red light pulse, but not a blue light pulse, could reset rhythm in continuous darkness, suggesting the possible role of a red-light signal transduction pathway in the circadian regulation of 1-aminocyclopropane-1-carboxylic acid oxidase.Abbreviations ACC 1-aminocyclopropane-1-carboxylic acid - DD continuous dark - LD light-dark - LL continuous light - ZT Zeitgeber time (start of light period for circadian entrainment) This study was supported by operating grants to C.C.C., and D.M.R. from the Natural Sciences and Engineering Research Council of Canada.The authors gratefully acknowledge the award of a Bettina Bahlsen memorial Graduate Scholarship by University of Calgary to A.K. We are grateful to Dr. M.M. Moloney for allowing the use of his laboratory facilities.     

Energy-dependent phases of the circadian clock and the clock-controlled leaf movement in Phaseolus coccineus L.

The energy requirements of the various phases of the circadian clock in the laminar pulvini cells of primary leaves of Phaseolus coccineus L. were investigated using 4-h pulses of NaCN (5 mM) and NaN₃ (1 mM). The induced phase shifts were calculated from the timing of the subjective night position during the third cycle after the treatment. Both inhibitors produce advances during phases which are correlated with the upward movement of the leaf (ca. 0–12 h after the maximum of the subjective night position) and during phases which are correlated with the downward movement of the leaf (ca. 20–28 h after the maximum of the subjective night position). Maximal advances are induced during the phase which is correlated with the maximum of the subjective night position (hour 0), whereas during phases which are correlated with the subjective day position (ca. 12–20 h after the maximum of the subjective night position) the inhibitors have no effect or induce only small advances. These results demonstrate that the part of the circadian cycle which, according to Bünning's tension-relaxation model of the circadian clock, is characterized by features of relaxation, represents a sequence of phases with decreasing energy requirement, whereas the tension part of the circadian cycle represents a sequence of phases with increasing energy requirement. The energy requirement for changing and maintaining the leaf positions was investigated by continuously offering NaCN, NaN₃, and dinitrophenol (DNP) to leaves with intact and half (flexor cut away) pulvini. The substances inhibit in both pulvini the upward movement or induce a downward movement, depending on the leaf position, when the transfer to the inhibitor solution takes place. These results give evidence that the movement of intact pulvini reflects the turgor (volume) state of the extensor cells and that the increase of turgor (volume) and high turgor (volume) state requires more energy than the decrease of turgor (volume) or low turgor (small volume) state. Therefore, the time course of the energy requirements of the circadian clock and the clock-controlled turgor (volume states or leaf movement) is out of phase during a circadian cycle. Consequently the reaction of the clock-controlled leaf movement to the reduced energy supply can mask the clock behavior in pulse and step experiments. The phase response curves towards CN^- and N ₃ ^- reflect the time course of the CN^--induced membrane depolarizations (the energy requirement of the electrogenic pump) in extensor cells of the pulvinus (Freudling et al. (1980), Plant Physiol. 65, 966–968), and both are out of phase with the time course of the energy requirement of the turgor. Consequently it is hypothesized that in Phaseolus advances are due to membrane depolarization and that at least in this organism electric properties of the plasmalemma are essentially involved in the mechanism of the circadian clock.Abbreviations LD light-dark cycle - LL continuous light - DNP dinitrophenol This paper is dedicated to Professor Erwin Bünning on the occasion of his 75th birthdayIn this paper zero corresponds to the second maximum of the subjective night position of the leaves after transfer to constant conditions. Zero to twelve hours corresponds approximately to the upward movement of the leaves, 12–20 h to the elevated (subjective day) position, and 20–28 h to the downward movement of the leaves. In other circadian systems Pittendrigh's CT (circadian time) convention is used. CT 00 is the time of dawn after a 12-h light/12-h dark cycle. Since in Phaseolus the plants are raised in a LD cycle different from 12:12 and since the phases at dawn differ considerably from leaf to leaf and are furthermore not precisely determinable (whereas the subjective night position of the leaves is a well-defined and recognizable phase) this convention is not followed in Phaseolus. Phase zero in Phaseolus corresponds to approximately CT 18 in other systems     

Circadian changes in protein-synthesis rate and protein phosphorylation in cell-free extracts of Gonyaulax polyedra

The polysomal pattern of the dinoflagellate Gonyaulax polyedra, cultured under constant conditions, demonstrates a circadian rhythm. The relative amount of polysomes increases during the phase corresponding to the previous night period (=subjective night phase) when the rate of protein synthesis reaches its maximum (Cornelius et al., 1985, Planta 160, 365–370). Cell-free extracts were isolated at different circadian phase. The rate of protein synthesis in the extracts changed rhythmically in the same manner as the rate of protein synthesis in vivo. Substances in the postribosomal supernatants influenced the protein-synthesis rate of the cell-free system, depending on the phase when they were isolated: night factors stimulated protein synthesis in day extracts whereas day factors inhibited protein synthesis in night extracts. These effects were abolished by heating the postribosomal supernatant. In-vitro phosphorylation in parallel probes showed changes in the pattern of phosphorylated proteins. Phosphorylation of one of the proteins (95 kDa) was decreased after addition of night factor(s) and increased after addition of day factor(s). Cyclic-AMP enhanced the rates of protein synthesis and phosphorylation in the day extracts.Abbreviations cAMP cyclic-AMP - CT circadian time - D (N) subjective day (night)phase     

Regulation of D1-protein degradation during photoinhibition of photosystem II in vivo: Phosphorylation of the D1 protein in various plant groups

Photoinhibition of PSII and turnover of the D1 reaction-centre protein in vivo were studied in pumpkin leaves (Cucurbita pepo L.) acclimated to different growth irradiances and in low-light-grown moss, (Ceratodon purpureus) (Hedw.) Brid. The low-light-acclimated pumpkins were most susceptible to photoinhibition. The production rate of photoinhibited PSII centres (k_PI), determined in the presence of a chloroplast-encoded protein-synthesis inhibitor, showed no marked difference between the high- and low-light-grown pumpkin leaves. On the other hand, the rate constant for the repair cycle (k_REC) of PSII was nearly three times higher in the high-light-grown pumpkin when compared to low-light-grown pumpkin. The slower degradation rate of the damaged D1 protein in the low-light-acclimated leaves, determined by pulsechase experiments with [³⁵S]methionine suggested that the degradation of the Dl protein retards the repair cycle of PSII under photoinhibitory light. Slow degradation of the D1 protein in low-light-grown pumpkin was accompanied by accumulation of a phosphorylated form of the D1 protein, which we postulate as being involved in the regulation of D1-protein degradation and therefore the whole PSII repair cycle. In spite of low growth irradiance the repair cycle of PSII in the moss Ceratodon was rapid under high irradiance. When compared to the high- or low-light-acclimated pumpkin leaves, Ceratodon had the highest rate of D1-protein degradation at 1000 mol photons m^–2 s^–1. In contrast to the higher plants, the D1 protein of Ceratodon was not phosphorylated either under high irradiance in vivo or under in-vitro conditions, which readily phosphorylate the D1 protein of higher plants. This is consistent with the rapid degradation of the D1 protein in Ceratodon. Screening experiments indicated that D1 protein can be phosphorylated in the thylakoid membranes of angiosperms and conifers but not in lower plants. The postulated regulation mechanism of D1-protein degradation involving phosphorylation and the role of thylakoid organization in the function of PSII repair cycle are discussed.Abbreviations Chl Chlorophyll - D1^* phosphorylated form of D1 protein - F_max and F_v maximal and variable fluorescence respectively - k_PJ and k_REC rate constants of photoinhibition and concurrent recovery respectively - LHCII lightharvesting chlorophyll a/bprotein of PSII - PFD photon flux density Dr. R. Barbato (Dipartimento di Biologia, Universita di Padova, Padova, Italy), Prof. P. Böger (Lehrstuhl fur Physiologie und Biochemie der Pflanzen, Universität Konstanz, Konstanz, Germany), Prof. A. Melis (Department of Plant Biology, University of California, Berkeley, USA), Prof. I. Ohad (Department of Biological Chemistry, Hebrew University, Jerusalem, Israel) and Mr. A. Soitamo (Department of Biology, University of Turku, Turku, Finland) are gratefully acknowledged for the D1-protein-specific antibodies. The authors thank Ms. Virpi Paakkarinen for excellent technical assistance. This work was supported by the Academy of Finland and the Foundation of the University of Turku.     

A rapid circadian rhythm of carbon-dioxide metabolism in Bryophyllum fedtschenkoi

Leaves of Bryophyllum fedtschenkoi Hamet et Perrier maintained in a stream of normal air and at 15° C exhibit a circadian rhythm of CO₂ uptake in continuous light but not in continuous darkness. The rhythm is unusual in that it persists for at least 10 d, and has a short period of approximately 18 h. The mechanism by which this rhythm is generated is discussed.Abbreviation PEPCase phosphoenolpyruvate carboxylase     

High-frequency oscillations and circadian rhythm of the membrane potential in Spinach leaves

The microelectrode technique was used to follow oscillations in membrane potential in mesophyll cells of spinach (Spinacia oleracea L.) during exposure do different photoperiodic conditions. Both high-frequency oscillations and circadian variations were observed. The circadian rhythm was imposed on the period of high-frequency oscillation during short days as well as in continuous light: The free-running period was 25.2 h. The average period of high-frequency oscillation increased from 7.64 min in the dark to 19.95 min in the light within several minutes after dark to light transition. This period length coincides with the established period length for oscillations in the redox potential in the chloroplast suspensions of spinach.Abbreviations CL continuous light - SD short day - MP membrane potential     

The coupling effects of some thiol and other sulfur-containing compounds on the circadian rhythm of cell division in photosynthetic mutants of Euglena

Previous work has demonstrated a persisting, free-running, circadian rhythm of cell division in the P₄ZUL photosynthetic mutant of the alga Euglena gracilis Klebs (Strain Z) Pringsheim grown organotrophically in continuous light or darkness at 19° C following prior synchronization by a repetitive LD: 10,14 light cycle. A similar circadian rhythmicity has been recently discovered in the W₆ZHL heat-bleached and the Y₉ZNalL naladixic acid-induced mutants of Euglena grown under comparable conditions. Over extended timespans, however, these mutants appear to gradually lose first their ability to display persisting overt rhythms, and then even their capability of being entrained by imposed LD cycles. These properties can be restored by the addition of certain sulfur-containing compounds to the medium including cysteine, methionine, dithiothreital, sodium monosulfide, sodium sulfite, and sodium thiosulfate, as well as thioglycolic [mercaptoacetic] acid. The implications of these findings toward biological clock mechanisms are discussed: It appears that some sort of coupling process is operating as opposed to the initiation of an underlying oscillation.Non-Standard Abbreviations LL continuous illumination - DD continuous darkness - LD repetitive light-dark cycle - SS stepsize - period of biological rhythm Supported by research grants (GB-36287, GB-43543) from the National Science Foundation.Reports on portions of this work were presented at the 19th Annual Meeting of the Biophysical Society, Philadelphia, Pennsylvania, February 19–21, 1975; at the XII International Botanical Congress, Leningrad, U.S.S.R., July 3–10, 1975; and at the XII International Conference of the International Society for Chronobiology, Washington, D.C., August 10–13, 1975.     

Temperature-induced phase shifting of circadian rhythms in cotton seedlings as related to variations in chilling resistance

The relationship between the degree of chilling resistance and phase shifting caused by low-temperature pulses was examined in two circadian rhythms in cotton (Gossypium hirsutum L. cv. Deltapine 50) seedlings grown under light-dark cycles of 1212 h at 33° C. The seedlings showed a circadian rhythm of chilling resistance and of cotyledon movement. A pulse of 19° C for 12 h during the chilling-sensitive phase (light period) caused a phase delay of 6 h, while a similar temperature pulse during the chilling-resistant phase (dark period) did not cause any phase shift. Exposure to 19° C, 85% RH (relative humidity) for 12 h during the dark period induced chilling resistance in the following otherwise chilling-sensitive light period. In this light period a 12-h 19° C pulse did not cause a phase shift of chilling resistance. Pulses of low temperatures (5–19° C) were more effective in causing phase delays in the rhythm of cotyledon movement when given during the chilling-sensitive phase than when given during the chilling-resistant phase. A 12-h pulse of 5° C, 100% RH during the light period caused a phase delay of cotyledon movement of 12 h. However, when that pulse had been preceded by a chill-acclimating exposure to 19° C, 85% RH for 12 h during the dark period the phase delay was shortened to 6 h. The correlation between higher degree of chilling resistance and the prevention or shortening of the phase delay caused by low temperatures indicates that the mechanism that increases chilling resistance directly or indirectly confers greater ability for prevention of phase shifting by low temperatures in circadian rhythms.Abbreviations CT circadian time - LDC light-dark cycle of 24 h - RH relative humidity     

Nitrate-reductase expression is under the control of a circadian rhythm and is light inducible in Nicotiana tabacum leaves

Over a 24-h light-dark cycle, the level of mRNA coding for nitrate reductase (NR; EC 1.6.6.1) in the leaves of nitrate-fed Nicotiana tabacum L. plants increased throughout the night and then decreased until it was undetectable during the day. The amount of NR protein and NR activity were two-fold higher during the day than at night. When plants were transferred to continuous light conditions for 32 h, similar variations in NR gene expression, as judged by the above three parameters, still took place in leaf tissues. On the other hand, when plants were transferred to continuous dark conditions for 32 h, the NR-mRNA level continued to display the rhythmic fluctuations, while the amount of NR protein and NR activity decreased constantly, becoming very low, and showed no rhythmic variations. After 56 h of continuous darkness, the levels of NR mRNA, protein and activity in leaves all became negligible, and light reinduced them rapidly. These results indicate the circadian rhythmicity and light dependence of NR expression.     

Control of ribonucleotide reductase in Synechococcus Sp., a unicellular cyanobacterium

Cells of Synechococcus sp., a rod-shaped, unicellular cyanobacterium (blue-green alga) can be readily snychronized by depriving the cells of carbon dioxide and light for a 12 h period. On resumption of growth, a portion of the population undergoes two sharply synchronized divisions. Ribonucleotide reductase activity was found to be maximal during the time of DNA synthesis in these cells. The peak of reductase activity could be abolished by adding inhibitors such a chloramphenicol to the culture, suggesting that the enzyme is induced at the gene level in the cyanobacteria. Additional properties of ribonucleotide reductase were investigated in Synechococcus cells made permeable by treatment with ether. Cytidine triphosphate reduction is absolutely dependent on adenosylcobalamin (coenzyme B₁₂) and is subject to allosteric stimulation by deoxyadenosine triphosphate.Abbreviations ECTA ethylene glycol-cis-(-amino ethyl ether)N,N-tetra acetic acid - HEPES N-2-hydroxy ethyl piperazine-N-2-ethane sulfonic acid - EDTA ethylene diamine tetra acetate - DDT dithiothreitol