Adenine-nucleotide levels and metabolism-dependent membrane potential in cells of Nitellopsis obtusa Groves

The relationship between adenine-nucleotide levels and metabolism-dependent membrane potential was studied in cells of Nitellopsis obtusa. Effects of ADP and AMP in the presence of ATP on electrogenic pump activity were measured in the dark, using the continuous perfusion method. Both ADP and AMP acte as competitive inhibitors for ATP, the K_i value for either compound being about 0.4 mM. The role of ADP and AMP as regulating factors for the electrogenic pump was investigated under various metabolic conditions. Application of N₂ gas in the dark caused a significant membrane depolarization amounting to 90 mV, but cytoplasmic streaming and membrane excitability were not affected. Under anoxia, the ATP level decreased from 1.6 to 0.5 mM; ADP increased but only slightly, and AMP increased greatly. However, the time course of changes in the adenine nucleotides was not concurrent with that of the membrane-potential changes, thus, the adenine-nucleotide level changes cannot fully account for the N₂-elicited depolarization. Under light, although the membrane hyperpolarized, no significant changes in the adenine-nucleotide levels were observed. Therefore, the light-induced membrane hyperpolarization cannot be explained solely by changes in adenine-nucleotide levels.Abbreviations APW artificial pond water - E_m membrane potential - R_m membrane resistance     

Relationship between light conditions and behavior of the freshwater snail Biomphalaria glabrata (Say)

The influence of light upon behavior of Biomphalaria glabrata was investigated in snails submitted for 48 h to one of the following regimes: normal light cycle, continuous darkness, continuous light. Time-lapse cinematography was used to provide data about snail locomotor activity in response to (a) continuous light or darkness; (b) light or dark phases; (c) light transitions. Snails were significantly less active under continuous light than under continuous or intermittent darkness. Under the normal light cycle, the activity rate was significantly higher in the dark than in the light. Changes from light to dark corresponded to increases in the activity rate which persisted long afterwards. No significant variation in activity occurred upon changes from dark to light.     

Diminution and enlargement of the mosquito rhabdom in light and darkness

The rhabdoms of the larval ocelli of the mosquito Aedes aegypti undergo morphological light and dark adaptation over periods of hours. The rhabdom enlarges during dark adaptation and grows smaller during light adaptation. Diminution is exponential, enlargement linear, and rates of change are proportional to log light intensity. Rhabdoms maintained at a constant intensity level off at a constant volume proportional to log intensity. We argue that changes in rhabdom volume after changes in light intensity reflect an influence of light on the turnover of photoreceptro membrane, and that the volumes at which rhabdoms level off represent equilibria between opposed processes of membrane loss and renewal.     

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     

Adaptation in the Ventral Eye of Limulus is Functionally Independent of the Photochemical Cycle, Membrane Potential, and Membrane Resistance

The early receptor potential (ERP), membrane potential, membrane resistance, and sensitivity were measured during light and/or dark adaptation in the ventral eye of Limulus. After a bright flash, the ERP amplitude recovered with a time constant of 100 ms, whereas the sensitivity recovered with an initial time constant of 20 s. When a strong adapting light was turned off, the recovery of membrane potential and of membrane resistance had time-courses similar to each other, and both recovered more rapidly than the sensitivity. The receptor depolarization was compared during dark adaptation after strong illumination and during light adaptation with weaker illumination; at equal sensitivities the cell was more depolarized during light adaptation than during dark adaptation. Finally, the waveforms of responses to flashes were compared during dark adaptation after strong illumination and during light adaptation with weaker illumination. At equal sensitivities (equal amplitude responses for identical flashes), the responses during light adaptation had faster time-courses than the responses during dark adaptation. Thus neither the photochemical cycle nor the membrane potential nor the membrane resistance is related to sensitivity changes during dark adaptation in the photoreceptors of the ventral eye. By elimination, these results imply that there are (unknown) intermediate process(es) responsible for adaptation interposed between the photochemical cycle and the electrical properties of the photoreceptor.     

Occurrence of cytochrome c-554 in a facultative methylotroph,Protaminobacter ruber strain NR-1, during bacteriochlorophyll formation

A facultative methylotroph, Protaminobacter ruber was grown under two different conditions (aerobically grown under light, and aerobically in the dark after a light period). Bacteriochlorophyll was synthesized inducibly in the cells which were initially grown in the ligt and then grown in the dark, while bacteriochlorophyll was not found in the cells cultured under continuous light. Cytochrome c-554 was solely synthesized parallel to bacteriochlorophyll after switching from light to dark conditions. Both cytochrome c-554 and bacteriochlorophyll levels in the membrane preparation reached to a plateau in 24 h after switching from light and dark conditions. This cytochrome was membrane-bound and its M _r was 45,000 by sodium dodecylsulfate polyacrylamide gel electrophoresis. The midpoint potential was 358 mV at pH 7. Other major membrane-bound cytochromes and two soluble cytochromes were present in both types of cells and their content did not change irrespective of growth conditions.Abbreviations SDS-PAGE sodium dodecylsulfate polyacrylamide gel electrophoresis - Bchl bacteriochlorophyll     

Effect of high pH on the plasma membrane potential and conductance in Elodea densa

In leaves of Elodea densa the membrane potential measured in light equals the equilibrium potential of H+ on the morphological upper plasma membrane. The apoplastic pH on the upper side of the leaf is as high as 10.5-11.0, which indicates that alkaline pH induces an increased H+ permeability of the plasmalemma. To study this hypothesis in more detail we investigated the changes in membrane potential and conductance in response to alterations in the external pH from 7 (= control) to 9 or 11 under both light and dark conditions. Departing from the control pH 7 condition, in light and in dark the application of pH 9 resulted in a depolarization of the membrane potential to the Nernst potential of H+. In the light but not in the dark, this depolarization was followed by a repolarization to about -160 mV. The change to pH 9 induced, in light as well as in dark, an increase in membrane conductance. The application of pH 11, which caused a momentary hyper- or depolarization depending on the value at the time pH 11 was applied, brought the membrane potential to around -160 mV. The membrane conductance also increased, in comparison to its value at pH 7, as a result of the application of pH 11, irrespective of the light conditions.     

Chloroplast envelopes as affected by light or dark pretreatment of pea plants

Glutaraldehyde fixation in 0.33 M sorbitol without any buffer reveals changes in the staining properties of the envelopes of chloroplasts of pea plants kept in the light or in the dark prior to fixation. After dark pretreatment the outer double membrane of the chloroplast does not adsorb heavy metals, resulting in a white unstained rim instead of the usual membrane. All other membranes of the cell, including chloroplast grana, are not affected and stain normally. Light pretreatment of the plants allows the usual staining of the outer membrane of the chloroplats. Fixation carried out in the medium usually used to isolate intact CO₂ fixing chloroplasts (sorbitol+buffer+ions) reverses the above process and results in unstained envelopes of chloroplasts from preilluminated leaves, while the envelopes of chloroplasts from leaves kept in the dark stain normally. Glutaraldehyde-fixed chloroplats isolated from preilluminated leaves show a very basic isoelectric point during electrofocusing, while fixed chloroplasts from predarkened tissue exhibit an isoelectric point at about pH 7.     

Effects of spermidine on chlorophyll content,photosynthetic activity and chloroplast ultrastructure in the dark and under light

Spermidine prevented the loss of chlorophyll from detached komatsuna (Brassica campestris cv. komatsuna) leaves in the dark but caused a striking reduction in light. It also inhibited photochemical activity in leaves incubated in the dark and light. Striking changes were seen in the chloroplast ultrastructure in light; the envelope was lacking, grana were dilated and thylakoids were distributed throughout the cytoplasm.     

Photoregulation of the incorporation of guaiacyl units into lignins

When fed with [¹⁴C] phenylalanine in the light, xylem tissues isolated from poplar stems were able to incorporate part of the radioactivity into both the guaiacyl and the syringyl residues of lignins. In the dark, only syringyl units were integrated into the polymer whereas the guaiacyl residues remained unlabeled.When a membrane perturber (isopropanol) was added to the incubation mixture, the label was incorporated into the guaiacyl units either in the light or in the dark. Conversely, a membrane stabilizer (CaCl₂) prevented the labeling of the guaiacyl units even when the tissues were illuminated. These results suggest that light acts through the modification of membrane permeabilities, altering specifically the synthesis and the transport or the polymerization of guaiacyl-type units during the process of lignification.Abbreviations S syringyl residue - G guaiacyl residue This is paper No. 4 in a series. For paper No. 3 see Grand and Ranjeva, in press     

Electrophysiological properties of onion guard cells

Intracellular electrical recordings in onion (Allium cepa L.) guard cells show that they maintain a membrane potential difference (MPD), inside negative. The MPD of intact cells averaged -72±29 mV (n=45); MPD of cells partially digested with a cellulolytic enzyme, -39±7 mV (n=65). Evidence indicates that the guard cells have two electrically distinct compartments, presumably delimited by the plasmalemma and tonoplast. Epidermal cells in partially digested preparations also showed MPD that could be either positive (+15±7 mV; n=23) or negative (-15 ±8 mV; n=13). Guard cells exposed to light-dark cycles hyperpolarized in the light and depolarized in the dark. The largest observed voltage changes reached 52 mV during hyperpolarizations and 60 mV during depolarizations. The light responses saturated with roughly exponential kinetics, with the depolarizations exhibiting a slower second phase that might be related to the contracting movements of the guard cells. Initial rates of the responses averaged about 14 mV min^-1 in the dark and about 8 mV min^-1 in the light. The results can be interpreted as electrical correlates of fluctuations in intracellular potassium concentration, as light-induced changes in membrane permeability, or as the photoactivation of an electrogenic proton pump. The last possibility seems to be the simplest interpretation of the data that also provides us with a mechanism driving the ion fluxes associated with stomatal function.     

Effect of Na(3)VO(4) on the P State of Nitella translucens

The capacity of sodium orthovanadate to inhibit the plasmalemma H⁺ ATPase of Nitella translucens internodal cells in vivo was tested. Here we show that 1 millimolar vanadate added externally depolarizes strongly and permanently the membrane potential, both in dark and light, to the Nernst potential for potassium consistent with pump inhibition by vanadate. From the results it is clear that the H⁺ ATPase is always active, under light or dark conditions, in contradiction with the widespread idea of pump inactivation by darkness. The changes in conductance for light, dark, and vanadate-induced conditions are analyzed. The effect of dark on membrane passive permeabilities and on the possibility that some plasmalemma channels could be regulated by a phosphorylation-dephosphorylation process is discussed.     

Synthesis and turnover of the light-harvesting chlorophylla/b-protein inLemna gibba grown with intermittent red light: possible translational control

Lemna gibba L. G-3 plants grown heterotrophically in the dark with intermittent red light (2 min every 8 h) contain a substantial amount of translatable mRNA encoding the light-harvesting chlorophyll (Chl)a/b-protein. However, very little [³⁵S]methionine is incorporated into the apoproteins during a 1-h labeling period in the dark in these plants compared to plants grown in continuous white light. The Chla/b-protein mRNA is found to be associated with functioning polysomes in plants grown in the dark with intermittent red illumination (R plants). The small amounts of the apoproteins which are synthesized by these plants are found in the membrane fraction; neither the mature apoproteins nor their precursor(s) can be detected immunologically in the soluble fraction. The protein does not accumulate in these plants. Pulse-chase experiments with the R plants demonstrate that the newly synthesized apoproteins have a half-life of about 10 h in the dark. This turnover is not sufficient to explain the observed 20-fold difference in [³⁵S]methionine incorporation into the apoprotein between white-light-grown and R plants. We therefore suggest that the synthesis of the Chla/b-apoproteins can be regulated by a light-dependent step at the level of translation, and that this regulation occurs after the initiation of translation.Abbreviations Chl chlorophyll - W Lemna plants grown in continuous white light - R plants grown heterotrophically in the dark with intermittent red light (2 min/8 h)     

PROTONATION AND CHLOROPLAST MEMBRANE STRUCTURE

Light changes the structure of chloroplasts. This effect was investigated by high resolution electron microscopy, photometric methods, and chemical modification. (a) A reversible contraction of chloroplast membrane occurs upon illumination, dark titration with H⁺, or increasing osmolarity. These gross structural changes arise from a flattening of the thylakoids, with a corresponding decrease in the spacing between membranes. Microdensitometry showed that illumination or dark addition of H⁺ resulted in a 13–23% decrease in membrane thickness. Osmotically contracted chloroplasts do not show this effect. (b) Rapid glutaraldehyde fixation during actual experiments revealed that transmission changes are closely correlated with the spacing changes and therefore reflect an osmotic mechanism, whereas the light scattering changes have kinetics most similar to changes in membrane thickness or conformation. (c) Kinetic analysis of light scattering and transmission changes with the changes in fluorescence of anilinonaphthalene sulfonic acid bound to membranes revealed that fluorescence preceded light scattering or transmission changes. (d) It is concluded that the temporal sequence of events following illumination probably are protonation, changes in the environment within the membrane, change in membrane thickness, change in internal osmolarity accompanying ion movements with consequent collapse and flattening of thylakoid, change in the gross morphology of the inner chloroplast membrane system, and change in the gross morphology of whole chloroplasts.     

Light/dark labeling differences in chloroplast membrane polypeptides associated with chloroplast coupling factor o.

The fluorogenic reagent fluorescamine has been used to determine the labeling patterns of Type C spinach chloroplast membrane polypeptides. Membrane polypeptides labeled with fluorescamine were detected by scanning high resolution sodium dodecyl sulfate polyacrylamide gradient slab gels for fluorescence emission. Three membrane polypeptides show a decrease in the extent of labeling when chloroplast membranes are labeled in the light compared to when they are labeled in the dark. These polypeptides have apparent molecular weights 0f 32 000, 23 000 and 15 000. The decrease in labeling observed in the light is abolished or reduced by treatments which inactivate the light-generated transmembrane pH gradient. CF1-depleted chloroplasts show neither a light-activated pH gradient nor a light/dark difference in labeling of these three polypeptides. Both a light-activated pH gradient and light/dark difference in labeling are observed in CF1-depleted chloroplasts which have been treated with N,N'-dicyclohexylcarbodiimide. The same ammonium sulfate fractions of a 2% sodium cholate extract, which are believed to be enriched in the membrane-bound sector of the chloroplast ATPase (CFo) are also found to be enriched in the 32 000, 23 000 and 15 000 molecular weight polypeptides. The three polypeptides are believed to be components of CFo, and the light/dark labeling differences may indicate conformational changes within CFo. Such conformational changes may reflect a mechanism which couples light-generated proton gradients to ATP synthesis.     

Light-induced decreases in cGMP concentration precede changes in membrane permeability in frog rod photoreceptors

This study examines whether changes in cGMP concentration initiated by illumination of frog rod photoreceptors occur rapidly enough to implicate cGMP as an intermediate between rhodopsin activation in the disc membrane and permeability changes in the plasma membrane. Previous studies using whole retinas or isolated outer segments have provided conflicting evidence on the role of cGMP in the initial events of phototransduction. The rod photoreceptor preparation employed in this work consists of purified suspensions of outer segments still attached to the mitochondria-rich ellipsoid portion of the inner segment. These photoreceptors are known to retain normal electrophysiological responses to illumination and have cGMP levels comparable to those measured in the intact retina. When examined under several different conditions, changes in cGMP concentrations were found to occur as rapidly or more rapidly than the suppression of the membrane dark current. Subsecond changes in cGMP concentration were analyzed with a rapid quench apparatus and confirmed by comparison with a rapid freezing technique. In a 1 mM Ca2+ Ringer's solution, cGMP levels decrease to 65% of their final extent within 200 ms after bright illumination; changes in membrane dark current follow a similar time course. When the light intensity is decreased to 8000 rhodopsins bleached per rod per s, the light-induced cGMP decrease is completed within 50 ms, with 7 X 10(5) cGMP molecules hydrolyzed per rhodopsin bleached. During this time the dark current has not yet begun to change. Thus, under physiological conditions it is clear that changes in cGMP concentration precede permeability changes at the plasma membrane. The correlation of rapid changes in cGMP levels with changes in membrane current leave open the possibility that changes in cGMP concentration may be an obligatory step in the reaction sequence linking rhodopsin activation by light and the resultant decrease in sodium permeability of the plasma membrane.     

Hydrolytic enzyme activities in germinating spores ofAdiantum capillus-veneris L.

Changes in hydrolytic enzyme activities were investigated during spore germination ofAdiantum capillus-veneris L. The spores were incubated for 3 days in the dark at 25 C for imbibition, and then germination of the spores was induced by continuous irradiation with red light. At day 2 after onset of the red light irradiation, rhizoids appeared out of spore coats and protonemal cells became visible on the following day. Lipase occurred in dry spores and its activity decreased during 3 days of dark incubation. The activity started to increase when the spore germination was induced by red light irradiation. On the other hand, amylolytic and aminopeptidase activities which were also detected in dry spores decreased continuously during the dark incubation and following the germination process. RNase activity also decreased during 3 days of dark incubation but the activity was retained thereafter at a constant level with or without red light irradiation. Developmental patterns of these hydrolytic enzymes were classified into two groups: One decreased during imbibition and dark incubation but increased after red light irradiation and the other continuously decreased during dark incubation and germination. These results are discussed in relation to compositional changes of cell constitutions such as lipid, sugars, proteins and amino acids during spore germination.     

Cycloheximide induces synchronous swelling of perialgal vacuoles enclosing symbiotic Chlorella vulgaris and digestion of the algae in the ciliate Paramecium bursaria

Cycloheximide is known to inhibit preferentially protein synthesis of symbiotic Chlorella of the ciliate Paramecium bursaria, but to hardly host protein synthesis. Treatment of algae-bearing Paramecium cells with cycloheximide induces synchronous swelling of all perialgal vacuoles that are localized immediately beneath the host's cell membrane. In this study, the space between the symbiotic algal cell wall and the perialgal vacuole membrane widened to about 25 times its normal width 24 h after treatment with cycloheximide. Then, the vacuoles detached from beneath the host's cell membrane, were condensed and stained with Gomori's solution, and the algae in the vacuoles were digested. Although this phenomenon is induced only under a fluorescent light condition, and not under a constant dark condition, this phenomenon was not induced in paramecia treated with cycloheximide in the light in the presence of the photosynthesis inhibitor 3-(3,4-dichlorophenyl)-1,1-dimethylurea. These results indicate that algal proteins synthesized in the presence of algal photosynthesis serve some important function to prevent expansion of the perialgal vacuole and to maintain the ability of the perialgal vacuole membrane to protect itself from host lysosomal fusion.     

Phytochrome control of rapid nyctinastic movements and membrane permeability in Albizzia julibrissin

Summary The rapid nyctinastic movements of Albizzia julibrissin pinnules are under the control of phytochrome. When given prior to a dark period, red light facilitates and far-red light inhibits pinnule closure in the dark. These light effects are mutually photoreversible. The opening reaction of the pinnules following a dark period is mediated mainly by blue light. The nyctinastic closure response is accompanied by an increased rate of electrolyte efflux from the cut pinna base. This observation, coupled with the fact that the rapid nyctinastic movement is not affected by actinomycin D, supports the view that phytochrome control of the sleep movement is not mediated through effects on RNA metabolism, but rather through changes in membrane permeability.     

On the relationship between the non-photochemical quenching of the chlorophyll fluorescence and the Photosystem II light harvesting efficiency. A repetitive flash fluorescence induction study

Plants respond to excess light by a photoprotective reduction of the light harvesting efficiency. The notion that the non-photochemical quenching of chlorophyll fluorescence can be reliably used as an indicator of the photoprotection is put to a test here. The technique of the repetitive flash fluorescence induction is employed to measure in parallel the non-photochemical quenching of the maximum fluorescence and the functional cross-section (sigma(PS II)) which is a product of the photosystem II optical cross-section a(PS II) and of its photochemical yield Phi(PS II) (sigma (PS II) = a(PS II) Phi(PS II)). The quenching is measured for both, the maximum fluorescence found in a single-turnover flash (F(M) (ST)) and in a multiple turnover light pulse (F(M) (MT)). The experiment with the diatom Phaeodactylum tricornutum confirmed that, in line with the prevalent model, the PS II functional cross-section sigma (PS II) is reduced in high light and restored in the dark with kinetics and amplitude that are closely matching the changes of the F(M) (ST) and F(M) (MT) quenching. In contrast, a poor correlation between the light-induced changes in the PS II functional cross-section sigma (PS II) and the quenching of the multiple-turnover F(M) (MT) fluorescence was found in the green alga Scenedesmus quadricauda. The non-photochemical quenching in Scenedesmus quadricauda was further investigated using series of single-turnover flashes given with different frequencies. Several mechanisms that modulate the fluorescence emission in parallel to the Q(A) redox state and to the membrane energization were resolved and classified in relation to the light harvesting capacity of Photosystem II.