Protoplasts from Phaseolus coccineus L. Pulvinar Motor Cells Show Circadian Volume Oscillations

The circadian movement of the lamina of the primary leaf of Phaseolus coccineus is mediated by circadian volume changes of the extensor and flexor cells in the upper and lower half of the laminar pulvinus. Isolated protoplasts from the extensor, flexor, and flank cells of the pulvinus showed a circadian volume rhythm with a period longer than 24 h. In the case of the flexor protoplasts, we found a period length of 28 h, which is similar to that of the pulvinar cells in situ. In the extensor protoplasts, the volume rhythm was synchronized with 14-h light/10-h dark cycles. The larger volume was correlated with the early hours in the light period and the smaller volume with the dark period, as would be expected from the behavior of the extensor cells in situ.     

Extensor and flexor protoplasts from samanea pulvini : I. Isolation and initial characterization

Protoplasts were isolated from extensor and flexor regions of open pulvini of the nyctinastic tree Samanea saman. Both types of protoplasts undergo many changes during isolation. Extensor protoplasts are univacuolate in vivo, but some become multivacuolate. All flexor protoplasts are univacuolate. In an open pulvinus, extensor cells have a higher osmotic pressure than flexor cells. However, both types of protoplasts can be isolated with optimal yield using the same osmoticum (0.5 molar sorbitol) in the digestion medium. This suggests that some leakage of osmoticum occurs during harvest or digestion, especially from extensor tissue. Despite these changes, both types of protoplasts extrude protons in response to 10 micromolar fusicoccin (1.6-1.8 nanoequivalent/10⁶ protoplasts/minute), demonstrating that the protoplasts are metabolically active and that proton transport mechanisms must be at least partially functional. The changes in vacuolar structure and osmotic pressure are what one might expect if the protoplasts, which are isolated from open pulvini, take on characteristics of cells in a closed pulvinus.     

Potassium Flux and Leaf Movement in Samanea saman : I. Rhythmic Movement

Samanea leaflets usually open in white light and fold together when darkened, but also open and dose with a circadian rhythm during prolonged darkness. Leaflet movement results from differential changes in the turgor and shape of motor cells on opposite sides of the pulvinus; extensor cells expand during opening and shrink during closure, while flexor cells shrink during opening and expand during closure but change shape more than size. Potassium in both open and closed pulvini is about 0.4 N. Flame photometric and electron microprobe analyses reveal that rhythmic and light-regulated postassium flux is the basis for pulvinar turgor movements. Rhythmic potassium flux during darkness in motor cells in the extensor region involves alternating predominance of inwardly directed ion pumps and leakage outward through diffusion channels, each lasting ca 12 h. White light affects the system by activating outwardly directed K⁺ pumps in motor cells in the flexor region.     

Effects of Light on the Membrane Potential of Protoplasts from Samanea saman Pulvini : Involvement of K Channels and the H -ATPase

Rhythmic light-sensitive movements of the leaflets of Samanea saman depend upon ion fluxes across the plasma membrane of extensor and flexor cells in opposing regions of the leaf-movement organ (pulvinus). We have isolated protoplasts from the extensor and flexor regions of S. saman pulvini and have examined the effects of brief 30-second exposures to white, blue, or red light on the relative membrane potential using the fluorescent dye, 3,3′-dipropylthiadicarbocyanine iodide. White and blue light induced transient membrane hyperpolarization of both extensor and flexor protoplasts; red light had no effect. Following white or blue light-induced hyperpolarization, the addition of 200 millimolar K⁺ resulted in a rapid depolarization of extensor, but not of flexor protoplasts. In contrast, addition of K⁺ following red light or in darkness resulted in a rapid depolarization of flexor, but not of extensor protoplasts. In both flexor and extensor protoplasts, depolarization was completely inhibited by tetraethylammonium, implicating channel-mediated movement of K⁺ ions. These results suggest that K⁺ channels are closed in extensor plasma membranes and open in flexor plasma membranes in darkness and that white and blue light, but not red light, close the channels in flexor plasma membranes and open them in extensor plasma membranes. Vanadate treatment inhibited hyperpolarization in response to blue or white light, but did not affect K⁺ -induced depolarization. This suggests that white or blue light-induced hyperpolarization results from activation of the H⁺ -ATPase, but this hyperpolarization is not the sole factor controlling the opening of K⁺ channels.     

Isolation of functional extensor and flexor protoplasts fromPhaseolus coccineus L. pulvini: potassium induced swelling

Methods are described for the isolation of functional protoplasts from secondary pulvinus tissue (flexor and extensor) and from leaf mesophyll tissue of primary leaves ofPhaseolus coccineus L. Integrity of the protoplasts was shown by vital staining and their ability to evolve oxygen in the light. Extensor-cell protoplasts increased their volume for up to 60% upon addition of 10 mM KCl. This K⁺-induced swelling was accompanied by increased rates of proton extrusion.     

Circadian rhythm leaf movement of Phaseolus vulgaris and the role of calcium ions

Legume plants, due to their distinctive botanical characteristics, such as leaf movements, physiological characteristics, such as nitrogen fixation, and their abilities to endure environmental stresses, have important roles in sustainable pastures development. Leaf movement of legume plants is turgor regulated and osmotically active fluxes of ions between extensor and flexor of pulvinus cause this movement. To determine the role of calcium ions in circadian leaf movements of Phaseolus vulgaris L., a radiotracer technique experiment using ⁴⁵Ca ions were employed. Measurements were taken during circadian leaf movements, and samples were taken from different parts of the leaflet. The ⁴⁵Ca β-particle activity reduced from leaflet base pulvinus to leaf tip. The pulvinus had the highest activity, while the leaf tip had the lowest. By increase of the ratio of ⁴⁵Ca β-particle activity within flexor to extensor (Fl/Ex) the midrib-petiole angle, as an indicator of leaf movement, increased linearly during circadian leaf movement (r = 0.86). The ⁴⁵Ca β-particle activity of Flex/Ext ratio reduced linearly (r = −0.88) toward midnight. In conclusion, it was found that calcium ions accumulation is opposite to the fluxes of osmatically active ions and water movement. Calcium ions accumulate at less negative water potential side of the pulivnus.Key words: pulvinus, extensor, flexor, leaf movement, rhythm, circadian, calcium, Phaseolus vulgaris, radioactive     

Mechanics of circadian pulvini movements in Phaseolus coccineus L.

The circadian movement of the lamina of primary leaves of Phaseolus coccineus L. is mediated by antagonistic changes in the length of the extensor and flexor cells of the laminar pulvinus. The cortex of the pulvinus is a concentric structure composed of hexagonal disc-like cells, arranged in longitudinal rows around the central stele. Observations with polarization optics indicate that the cellulose microfibrils are oriented in a hoop-like fashion in the longitudinal walls of the motor cells. This micellation is the structural basis of the anisotropic properties of the cells: tangential sections of the extensor and flexor placed in hypotonic mannitol solutions showed changes only in length. As a consequence a linear correlation between length and volume was found in these sections. Based on the relationship between the water potential (which is changed by different concentrations of mannitol) and the relative volume of the sections and on the osmotic pressure at 50% incipient plasmolysis, osmotic diagrams were constructed for extensor and flexor tissues (cut during night position of the pulvinus). The bulk moduli of extensibility, , were estimated from these diagrams. Under physiological conditions the values were rather low (in extensor tissue below 10 bar, in flexor tissue between 10 to 15 bar), indicating a high extensibility of the longitudinal walls of the motor cells. They are strongly dependent on the turgor pressure at the limits of the physiological pressure range.In well-watered plants, the water potentials of the extensor and flexor tissues were surprisingly low,-12 bar and-8 bar, respectively. This means that the cells in situ are by no means fully turgid. On the contrary, the cell volume in situ is similar to the volume at the point of incipient plasmolysis: the cell volumes of extensor and flexor cells in situ were only 1.01 times and 1.1 times larger, respectively, than at the point of incipient plasmolysis, whereas at full turgidity (cells in water) the corresponding factors were 1.8 and 1.5. It is suggested that the high elasticity of the longitudinal walls, the anisotropy of the cell walls, and the low water potential of the sections which is correlated with slightly stretched cell walls in situ, are favourable and effective for converting osmotic work in changes in length of the pulvinus cells, and thus for the up and down movement of the leaf.Symbols volumetric elastic modulus - _i instantaneous volumetric elastic modulus - _i stationary volumetric elastic modulus - weight-averaged stationary bulk modulus of extensibility - ₀ osmotic pressure of the vacuole of a cell at the point of incipient plasmolysis - weight-averaged osmotic pressure of the vacuoles of the tissue at 50% incipient plasmolysis - water potential     

Blue-light-dependent osmoregulation in protoplasts of Phaseolus vulgaris Pulvini.

Blue light was found to induce shrinkage of the protoplasts isolated from first-leaf lamina pulvini of 18-day-old Phaseolus vulgaris. The response was transient following pulse stimulation, while it was sustainable during continuous stimulation. No apparent difference was found between flexor and extensor protoplasts. Protoplasts of the petiolar segment located close to the pulvinus showed no detectable response. In the plants used, the pulvinus was fully matured and the petiole was ceasing its elongation growth. When younger, 12-day-old, plants were used, however, the petiolar protoplasts did respond to blue light. The pulse-induced response was similar to that in pulvinar protoplasts, although the response to continuous stimulation was transient and differed from that in pulvinar protoplasts. No shrinkage was induced in pulvinar protoplasts when the far-red-light-absorbing form of phytochrome was absent for a period before blue-light stimulation, indicating that the blue-light responsiveness is strictly controlled by phytochrome. Inhibitors of anion channels and H(+)-ATPase abolished the shrinking response, supporting the view that protoplasts shrink by extruding ions. The response of pulvinar protoplasts is probably involved in the blue-light-induced, turgor-based movement of pulvini. The blue-light responding system in pulvini is suggested to have evolved from that functioning in other growing organs.     

Extensor protoplasts of the Phaseolus pulvinus: light-induced swelling may require extracellular Ca2+ influx, dark-induced shrinking inositol 1,4,5-trisphosphate-induced Ca2+ mobilization

The photonastic upward movement and scotonastic downward movementof the primary leaf of Phaseolus coccineus L. depends on ionfluxes across the plasma membrane of extensor and flexor cellsof the laminar pulvinus. Extensor protoplasts cultured in 0.4M mannitol, 10 mM KCl, 1 mM CaCl₂ and 5 mM MES-KOH buffer pH6 were found to swell upon switching on white light at the endof a 15 h dark period and to shrink upon switching off the lightat the end of the following 9 h light period, behaviour consistentwith that expected in the cells of intact plants. Light-inducedswelling requires Ca²⁺ in the surrounding medium. Both the Ca²⁺channel blocker verapamil and La³⁺ inhibited this reaction,whereas TMB-8, an inhibitor of intracellular Ca²⁺ transport,had no effect. When the Ca²⁺ iono phore A 23187, the Ca²⁺ channelagonist Bay K-8644, or thapsigargin, an inhibitor of Ca²⁺ -ATPasesat endo-membranes, was added to the medium, extensor proto-plastsswelled in the dark. These results suggest that in extensorprotoplasts light opens Ca²⁺ channels in the plasma membraneand that the influx of extracellular Ca²⁺ results in an increasedcytoplasmic Ca²⁺ concentration which is sufficient to mimicthe light-on signal in activating or deactivating the ion transportersrequired for swelling. Dark-induced shrinking occurred in Ca²⁺-free medium. It was not inhibited by verapamil, but was byTMB-8. Both neomycin and Li⁺ , substances which are known toinhibit the phosphoinositide path way of transmembrane signalling,inhibited dark induced shrinking. Myo-inositol nullified theLi⁺ inhibition of dark-induced shrinking. Neither A 23187 norBay K-8644 induced shrinking in the light, but were able tonullify the inhibitory effect of TMB-8 on dark-induced shrinking.These results suggest that, in extensor protoplasts, the shrinkingsignal ‘light off’ is transduced through phosphoinositidehydrolysis and Ca²⁺ release from internal stores. In additionto the inositol 1,4,5-trisphosphate (IP₃)-induced increase ofthe cytoplasmic Ca²⁺ concentration, further events dependingon the light-off signal appear to be required for shrinking. Key words: Phaseolus pulvinus, extensor protoplasts, light-induced swelling, dark-induced shrinking, Ca²⁺, phosphoinositide signalling     

Relationships between Motor Cell Ultrastructure and Leaf Movements in Samanea saman

We examined the fine structure of motor cells in the secondary pulvinus of Samanea saman (Jacq.) Merrill, to aid in analyzing the cellular basis for K⁺ and Cl^? driven, turgor regulated circadian leaflet movements. Pulvini that were (a) open (horizontal) in the light, (b) closed (vertical) in the dark, or (c) at an intermediate angle after 96-h incubation in H₂O in darkness, were cut into cross sections, sub-divided into quadrants, and prepared for electron microscopy by standard methods. The walls of many cells are ridged, appearing scalloped in cross section, the plasmalemma following the wall contours. Plasmodesmata localized in pit fields are most numerous in the inner cortex of the extensor (abaxial), and least numerous in the outer cortex of the flexor (adaxial) (3.9 and 0.7, respectively, per μm² wall area). Vacuole size, number of vacuoles per cell, and the condition of the electron dense precipitate within the vacuole also vary with cell location, multivacuolation being most pronounced in the outer cortex of the extensor. Chloroplasts are dimorphic: those in cells close to the vascular tissue are very large, circular in cross section, and contain huge starch deposits at all times, while those in the remainder of the cortex are smaller, usually oblong, and contain large starch deposits at the beginning of the dark period, but are devoid of starch at the beginning of the light period. However, both types of chloroplasts in excised pulvini incubated in H²O in darkness for 96 h still contain starch deposits, indicating that (1) light may promote starch degradation, or (2) starch degradation and resynthesis may be rhythmic.     

Experimental evidence for a non-clock role of the circadian system in spider mite photoperiodism

In the spider mite Tetranychus urticae photoperiodic time measurement proceeds accurately in orange-red light of 580 nm and above in light/dark cycles with a period length of 20 h but not in 'natural' cycles with a period length of 24 h. To explain these results it is hypothesized that the photoperiodic clock in the spider mite is sensitive to orange-red light, but the Nanda-Hamner rhythm (a circadian rhythm with a free-running period tau of 20 h involved in the photoperiodic response) is not and consequently free runs in orange-red light. To test this hypothesis a zeitgeber was sought that could entrain the Nanda-Hamner rhythm to a 24-h cycle without inducing diapause itself, in order to manipulate the rhythm independently from the orange-red sensitive photoperiodic clock. A suitable zeitgeber was found to be a thermoperiod with a 12-h warm phase and a 12-h cold phase. Combining the thermoperiod with the long-night orange-red light/dark regime, both with a cycle length of 24 h, resulted in a high diapause incidence, although neither regime was capable of inducing diapause on its own. The conclusion is that the Nanda-Hamner rhythm is necessary for the realization of the photoperiodic response, but is not part of the photoperiodic clock, because photoperiodic time measurement takes place in orange-red light whereas the rhythm is not able to 'see' the orange-red light. It is speculated that the Nanda-Hamner rhythm is involved in the timely synthesis of a substrate for the photoperiodic clock in the spider mite.     

Exotic photoperiods induce and entrain split circadian activity rhythms in hamsters

The split circadian activity rhythm that emerges in hamsters after prolonged exposure to constant light has been a theoretical cornerstone of a multioscillator view of the mammalian circadian pacemaker. The present study demonstrates a novel method for splitting hamster circadian rhythms and entraining them to exotic light:dark cycles. Male Syrian hamsters previously maintained on a 14-h day and 10-h night were exposed to a second 5-h dark phase in the afternoon. The 10-h night was progressively shortened until animals experienced two 5-h dark phases beginning 10 h apart. Most hamsters responded by splitting their activity rhythms into two components associated with the afternoon and nighttime dark phases, respectively. Each activity component was entrained to this light:dark:light:dark cycle. Transfer of split hamsters to constant darkness resulted in rapid joining of the two activity components with the afternoon component associated with onset of the fused rhythm. In constant light, the nighttime component corresponded to activity onset of the fused rhythm, but splitting emerged again at an interval characteristic for this species. The results place constraints on multi-oscillator models of circadian rhythms and offer opportunities to characterize the properties of constituent circadian oscillators and their interactions.     

Circadian Rhythms in Stomatal Responsiveness to Red and Blue Light

Stomata of many plants have circadian rhythms in responsiveness to environmental cues as well as circadian rhythms in aperture. Stomatal responses to red light and blue light are mediated by photosynthetic photoreceptors; responses to blue light are additionally controlled by a specific blue-light photoreceptor. This paper describes circadian rhythmic aspects of stomatal responsiveness to red and blue light in Vicia faba. Plants were exposed to a repeated light:dark regime of 1.5:2.5 h for a total of 48 h, and because the plants could not entrain to this short light:dark cycle, circadian rhythms were able to "free run" as if in continuous light. The rhythm in the stomatal conductance established during the 1.5-h light periods was caused both by a rhythm in sensitivity to light and by a rhythm in the stomatal conductance established during the preceding 2.5-h dark periods. Both rhythms peaked during the middle of the subjective day. Although the stomatal response to blue light is greater than the response to red light at all times of day, there was no discernible difference in period, phase, or amplitude of the rhythm in sensitivity to the two light qualities. We observed no circadian rhythmicity in net carbon assimilation with the 1.5:2.5 h light regime for either red or blue light. In continuous white light, small rhythmic changes in photosynthetic assimilation were observed, but at relatively high light levels, and these appeared to be attributable largely to changes in internal CO2 availability governed by stomatal conductance.     

Vasopressin deficiency provides evidence for separate circadian oscillators of activity and temperature

Vasopressin-containing Long-Evans and vasopressin-deficient Brattleboro rats were maintained in individual cages while telemetered activity (AC) and body temperature (BT) data were collected. Rats were initially exposed to a 12 h/12-h light/dark cycle (photic zeitgeber) and were allowed ad-libitum access to food and water. Daily feeding, care, and handling (nonphotic zeitgebers) occurred at the beginning of the second hour of the dark cycle. After a 14-day habituation period, rats were subjected to continuous light (LL) or dark (DD) and nonphotic cues were presented irregularly. During the habituation period, both strains exhibited clear 24-h circadian rhythms of AC and BT. In LL or DD, photic cues were removed and nonphotic cues were presented irregularly. There was a shift in the rhythm for Long-Evans animals to 26 h for both AC and BT in LL and 24.6 h in DD. Feeding, care, and handling were seen as minor artifact. In Brattleboro rats, although there were robust 26-h and 24.6-h circadian rhythms of AC in the LL and DD, respectively, BT data were inconsistent and showed sporadic fluctuations. In the BT rhythm of Brattleboro animals, strong peaks were associated with feeding, care, and handling times and trough periods were characterized by a dramatic drop in temperature. This experiment demonstrates that AC and BT are controlled by separate oscillators. In addition, the importance of vasopressinergic fibers in the control of circadian rhythms of BT is evidenced by the loss of circadian rhythms in animals lacking these functional fibers when exposed to free-running paradigms where there is no entrainment of photic or nonphotic oscillators.     

Phaseshifting of the photoperiodic flowering response rhythm in Pharbitis nil by red-light pulses

The control by light of the flowering response rhythm in the short-day plant Pharbitis nil Choisy cv. Violet was examined by giving a single pulse of light at various times between 1 and 6 h after a 24-h light period. When the first circadian cycle of the rhythm was monitored, it was found that a pulse of red light given at 1, 2 or 3 h into a 72-dark period caused a 1-h delay of the phase of the response rhythm, while a pulse at 6 h caused a 2-h delay. These results support the hypothesis that, when red-light pulses are given at hourly intervals, they are as effective as continuous light in preventing the onset of dark timing because they repeatedly return the rhythm to the circadian time at which it is apparently suspended in continuous light. The perception of and response to continuous light and red-light pulses are also briefly discussed.     

Inositol 1,4,5-trisphosphate may mediate closure of K+ channels by light and darkness in Samanea saman motor cells

Leaflet movements of Samanea saman (Jacq.) Merr. depend in part upon circadian-rhythmic, light-regulated K⁺ fluxes across the plasma membranes of extensor and flexor cells in opposing regions of the leaf-moving organ, the pulvinus. We previously showed that blue light appears to close open K⁺ channels in flexor protoplasts during the dark period (subjective night) (Kim et al., 1992, Plant Physiol 99: 1532–1539). In contrast, transfer to darkness apparently closes open K⁺ channels in extensor protoplasts during the light period (subjective day) (Kim et al., 1993, Science 260: 960–962). We now report that both these channel-closing stimuli increase inositol 1,4,5-trisphosphate [Ins(1,4,5)P₃] levels in the appropriate protoplasts. If extensor cells are given a pulse of red light followed by transfer to darkness, channels still apparently close (Kim et al. 1993) but changes in Ins(1,4,5)P₃ levels are complex with an initial decrease under red light followed by accumulation. Neomycin, an inhibitor of polyphosphoinositide hydrolysis, inhibits both blue-light-induced Ins(1,4,5)P₃ production and K⁺-channel closure in flexor protoplasts and both dark-induced Ins(1,4,5)P₃ production and K⁺ channel closure in extensor protoplasts. The G-protein activator, mastoparan, mimics blue light and darkness in that it both increases Ins(1,4,5)P₃ levels and closes K⁺ channels in the appropriate cell type at the appropriate time. These results indicate that phospholipase C-catalyzed hydrolysis of phosphoinositides, possibly activated by a G protein, is an early step in the signal-transduction pathway by which blue light and darkness close K⁺ channels in S. saman pulvinar cells.Abbreviations DiS-C₃-(5) 3,3-dipropylthiadicarbocyanine iodide - F measure change in Dis-C₃-(5) fluorescence - F_o initial Dis-C₃-(5) fluorescence - Ins(1,4,5)P₃ inositol 1,4,5-trisphosphate - PtdIns(4,5)P₂ phosphatidylinositol 4,5-bisphosphate - rbc red blood cell Supported by grants from NSF (IBN 9206179 and MCB 9305154) and U.S.-Israel Binational Agricultural Research and Development Fund (IS-1670-90RC) to R.C.C. We thank the University of Connecticut Biotechnology Center for the use of a fluorescent spectrophotometer.     

Diurnal Changes in the Malic Acid Concentration in Phaseolus coccineus L. Pulvini

Concentration of malic acid was determined in pulvini and petiolesand in isolated parts of the pulvinus, i.e. extensor and flexorregions, in Phaseolus coccineus. In the light period of thecircadian cycle, the concentration of malic acid in whole pulvinireached the highest value of 35.1 mmole CW while in the darkphase the respective value was 21.0 mmole CW. In the petiole,the highest concentration of malic acid was only 15.3% of themaximum concentration in the whole pulvinus. In isolated regions of motor cells, a cyclic alternation inthe concentration of malic acid was observed. In the light phase,the maximum acid concentration of 43.7 mmole CW in the extensorzone corresponds with the lowest concentration of 15.5 mmoleCW in the flexor region. The lowest value of acid concentrationof 30.8 mmole CW in the extensor part corresponds with the highestacid concentration of 31.1 mmole CW in the flexor part in thedark phase. About 22% of the total concentration of malic acid was transportedbetween the two opposite parts of the pulvinus as dependingupon the phases of leaf movement. (Received February 28, 1986; Accepted May 23, 1986)     

Light-promoted changes in apoplastic K+ activity in the Samanea saman pulvinus,monitored with liquid membrane microelectrodes

The movement of Samanea saman (Jacq.) Merrill leaflets is a consequence of the re-distribution of K⁺ and anions between motor cells on opposite sides of the pulvinus. We used a K⁺-sensitive microelectrode to study dynamic changes in K⁺ transport through motor-cell membranes during and immediately after change in illumination. Potassium-ion-sensitive and reference microelectrodes were inserted into extensor or flexor tissue of a whole pulvinus in white light (WL). A brief pulse of red light (RL) followed by darkness (D) (a) increased K⁺ activity in the extensor apoplast, indicating K⁺ release by the protoplast; and (b) decreased K⁺ activity in the flexor apoplast, indicating K⁺ uptake by the protoplast. White light after 35–40 min D reversed K⁺ activity in the extensor apoplast to approximately its original value. Blue light substituted partially for WL in this regard. Potassium-ion activity in the flexor apoplast reverted to approximately its original value after 2 h, with or without white illumination. Our data support the hypothesis that K⁺ efflux from extensor cells and K⁺ uptake by flexor cells following a WLRLD transition occurs by way of K⁺ channels.Abbreviations L light - WL white light - RL red light - BL blue light - D darkness