Response to chilling stress in plant cells II. Redistribution of intracellular calcium

Summary We have investigated the possibility that the rapid low temperature effects upon cyclosis and subcelluar structure might be due to a breakdown in compartmentation of intracellular calcium, leading to an increase in cytoplasmic Ca²⁺. Changes in fluorescence of chlortetracycline (CTC), a probe for membrane-bound Ca²⁺ were monitored in the corners of individual trichome cells (effective spot size ca. 800 square microns) with the aid of a Zeiss epifluorescence microscope linked to a Zeiss Zonax analyzing system. A consistent decrease in signal was observed as cells of chilling-sensitiveLycopersicon esculentum Mill. (cv.Ace) were cooled below their threshold temperature for chilling sensitivity. On rewarming, as the temperature rose above the chilling threshold, there was an increase in fluorescent signal. In contrast, trichomes ofDigitalis purpurea (chilling-resistant) showed no such changes. The uncoupling agent, CCCP, and the Ca²⁺-chelator, EGTA, induced marked decreases in the fluorescent signal in cells from both species. A more direct approach to testing the hypothesis was to examine the effect of modulating cytoplasmic Ca²⁺ with the aid of the Ca²⁺ -ionophore A 23187 and a Ca²⁺ concentration series in EGTA buffer. Above 10^–8 M external free Ca²⁺, streaming began to be inhibited, full inhibition occurring at 5 x 10^–6M Ca²⁺. The strand structure started to disappear when the Ca²⁺ rose above 10^–7M. Disappearance of strands was accompanied by an increase in the number of cells with vesiculated cytoplasm, an effect analogous to that of chilling temperatures on these cells. The phenothiazines, trifluoperazine and chlorpromazine (10^–5M) had similar effects. However but such effects were not seen with R 24571 or N(6-aminohexyl)5-chloro-1-napthalenesulfonamide (W 7) until concentrations were reached that orders of magnitude above their IC₅₀ for calmodulin.     

Possible involvement of protein phosphorylation in the regulation of cytoplasmic organization and streaming in root hair cells as revealed by a protein phosphatase inhibitor, calyculin A

Summary The effects of a protein phosphatase inhibitor, calyculin A (CA), on cytoplasmic streaming and cytoplasmic organization were examined in root hair cells ofLimnobium stoloniferum. CA at concentrations higher than 50 nM inhibited cytoplasmic streaming and also induced remarkable morphological changes in the cytoplasm. The transvacuolar strands, in which actin filament bundles were oriented parallel to the long axis, disappeared and spherical cytoplasmic bodies emerged in the CA-treated cells. In these spherical bodies, actin filaments were present and the spherical bodies were connected to each other by thin strands of actin filaments. Upon CA removal, transvacuolar strands, in which actin filament bundles were aligned, and cytoplasmic streaming reappeared. A nonselective inhibitor for protein kinases, K-252a, delayed the inhibitory effect of CA on cytoplasmic streaming and suppressed the CA-induced formation of the spherical bodies. From these results, it is suggested that phosphatases sensitive to CA regulate cytoplasmic streaming and are involved in the organization of the cytoplasm in root hair cells.Abbreviations APW artificial pond water - CA calyculin A     

The effect of temperature of the rate of photosynthetic electron transfer in chloroplasts of chilling-sensitive and chilling-resistant plants

1. Photochemical activities as a function of temperature have been compared in chloroplasts isolated from chilling-sensitive (below approximately 12 °C) and chilling-resistant plants.2. An Arrhenius plot of the photoreduction of NADP⁺ from water by chloroplasts isolated from tomato (Lycopersicon esculentum var. Gross Lisse), a chilling-sensitive plant, shows a change in slope at about 12 °C. Between 25 and 14 °C the activation energy for this reaction is 8.3 kcal·mole^?1. Between 11 and 3 °C the activation energy increases to 22 kcal·mole^?1. Photoreduction of NADP⁺ by chloroplasts from another chilling-sensitive plant, bean (Phaseolus vulgaris var. brown beauty), shows an increase in activation energy from 5.9 to 17.5 kcal·mole^?1 below about 12 °C.3. The photoreduction of NADP⁺ by chloroplasts isolated from two chilling-resistant plants, lettuce (Lactuca sativa var. winter lake) and pea (Pisum sativum var. greenfeast), shows constant activation energies of 5.4 and 8.0 kcal·mole^?1, respectively, over the temperature range 3–25 °C.4. The effect of temperature on photosynthetic electron transfer in the chloroplasts of chilling-sensitive plants is localized in Photosystem I region of photosynthesis. Both the photoreduction of NADP⁺ from reduced 2,6-dichlorophenol-indophenol and the ferredoxin-NADP⁺ reductase (EC 1.6.99.4) activity of choroplasts of chilling-sensitive plants show increases in activation energies at approximately 12 °C whereas Photosystem II activity of chloroplasts of chilling-sensitive plants shows a constant activation energy over the temperature range 3–25 °C. The photoreduction of Diquat (1,1′-ethylene-2,2′-dipyridylium dibromide) from water by bean chloroplasts, however, does not show a change in activation energy over the same temperature range. The activation energies of each of these reactions in chilling-resistant plants is constant between 3 and 25 °C.5. The effect of temperature on the activation energy of these reactions in chloroplasts from chilling-sensitive plants is reversible.6. In chilling-sensitive plants, the increased activation energies below approximately 12 °C, with consequent decreased rates of reaction for the photoreduction of NADP⁺, would result in impaired photosynthetic activity at chilling temperatures. This could explain the changes in chloroplast structure and function when chilling-sensitive plants are exposed to chilling temperatures.     

Temperature-induced Changes in Hill Activity of Chloroplasts Isolated from Chilling-sensitive and Chilling-resistant Plants

The effect of temperature on Hill activity has been compared in chilling-sensitive and chilling-resistant plants. The Arrhenius activation energy (Ea) for the photoreduction of 2,6-dichlorophenolindophenol by chloroplasts isolated from two chilling-sensitive plants, mung bean (Vigna radiata L. var. Mungo) and maize (Zea mays L. cv. PX 616), increased at low temperatures, below 17 C for mung bean and below 11 C for maize. However, the Ea for this reaction in pea (Pisum sativum L. cv. Massay Gem), a chilling-resistant plant, likewise increased at temperatures below 14 C. A second change in Ea occurred at higher temperatures. The Ea decreased above about 28 C for mung bean, 30 C for maize, and 25 C for pea. At temperatures approaching 40 C, thermal inactivation of Hill activity occurred. These results, when taken together with previous results obtained with the chilling-resistant plant barley, indicate that chloroplasts from both chilling-sensitive and chilling-resistant plants can undergo a change in chloroplast membrane activity at low temperatures above freezing and that the presence of such a change in chloroplast membranes is not necessarily correlated with chilling sensitivity.     

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     

Roles of the plasma membrane and the cell wall in the responses of plant cells to freezing

In an effort to clarify the responses of a wide range of plant cells to freezing, we examined the responses to freezing of the cells of chilling-sensitive and chilling-resistant tropical and subtropical plants. Among the cells of the plants that we examined, those of African violet ( Saintpaulia grotei Engl.) leaves were most chilling-sensitive, those of hypocotyls in mungbean [ Vigna radiata (L.) R. Wilcz.] seedlings were moderately chilling-sensitive, and those of orchid [ Paphiopedilum insigne (Wallich ex Lindl.) Pfitz.] leaves were chilling-resistant, when all were chilled at -2 degrees C. By contrast, all these plant cells were freezing-sensitive and suffered extensive damage when they were frozen at -2 degrees C. Cryo-scanning electron microscopy (Cryo-SEM) confirmed that, upon chilling at -2 degrees C, both chilling-sensitive and chilling-resistant plant cells were supercooled. Upon freezing at -2 degrees C, by contrast, intracellular freezing occurred in Saintpaulia leaf cells, frost plasmolysis followed by intracellular freezing occurred in mungbean seedling cells, and extracellular freezing (cytorrhysis) occurred in orchid leaf cells. We postulate that chilling-related destabilization of membranes might result in the loss of the ability of the plasma membrane to act as a barrier against the propagation of extracellular ice in chilling-sensitive plant cells. We also examined the role of cell walls in the response to freezing using cells in which the plasma membrane had been disrupted by repeated freezing and thawing. In chilling-sensitive Saintpaulia and mungbean cells, the cells with a disrupted plasma membrane responded to freezing at -2 degrees C by intracellular freezing. By contrast, in chilling-resistant orchid cells, as well as in other cells of chilling-resistant and freezing-resistant plant tissues, including leaves of orchard grass ( Dactylis glomerata L.), leaves of Arabidopsis thaliana (L.) Heynh. and cortical tissues of mulberry ( Morus bombycis Koids.), cells with a disrupted plasma membrane responded to freezing by extracellular freezing. Our results indicate that, in the chilling-sensitive plants cells that we examined, not only the plasma membrane but also the cell wall lacked the ability to serve as a barrier against the propagation of extracellular ice, whereas in the chilling-resistant plant cells that we examined, not only the plasma membrane but also the cell wall acted as a barrier against the propagation of extracellular ice. It appears, therefore, that not only the plasma membrane but also the cell wall greatly influences the freezing behavior of plant cells.     

Chilling-Induced Heat Evolution in Plants

Increases in respiration, particularly via the alternative pathway, are observed in response to chilling. These increases result in increased heat evolution. We have measured increases in heat evolution in response to chilling in a number of plant species using a microcalorimeter. After 8 h of exposure to 8[deg]C, heat evolution in a variety of chilling-sensitive species increased 47 to 98%. No increase in heat evolution was seen with the extremely chilling-sensitive ornamental Episcia cupreata Hook. Heat evolution increased only 7 to 22% in the chilling-resistant species. Increases in heat evolution were observed when plants were chilled in constant light or in the dark, but not when plants were chilled at high humidity. Increased capacity to produce respiratory heat after exposure to chilling temperatures may contribute to the cold-acclimation process.     

The Influence of Dark Adaptation Temperature on the Reappearance of Variable Fluorescence following Illumination

The effect of chilling temperatures (5°C) on chlorophyll fluorescence transients was used to study chilling-induced inhibition of photosynthesis in plant species with differing chilling sensitivities. A Brancker SF-20 fluorometer was used to measure induced fluorescence transients from both attached and detached leaves of chilling-sensitive cucumber (Cucumis sativus L. cv Ashley) and chilling-resistant pea (Pisum sativum L. cv Alaska). The rate of reappearance of the variable component of fluorescence (F_v), following a period of illumination at 25°C, was dependent on the temperature at which the leaf was allowed to dark adapt in chilling-sensitive cucumber, but not in chilling-resistant pea. In cucumber, dark adaptation at 25°C following illumination resulted in a much faster return of F_v than dark adaptation at 5°C following illumination. However, F_v reappearance during the dark adaptation period in chilling-resistant pea was temperature independent. The difference in the temperature response of F_v following illumination correlated with temperature sensitivity of these two species. The process responsible for the difference in F_v may represent a site of chilling sensitivity in the photosynthetic apparatus.     

Effect of cytoplasmic streaming on photosynthetic activity of chloroplasts in internodes of <Emphasis Type="Italic">Chara corallina</Emphasis>

Cytoplasmic streaming plays an important role in cell processes since it promotes solute exchange between the cytoplasm and organelles and enables lateral transport for extensive distances. The role of cyclosis in chloroplast functioning should be most conspicuous under conditions mimicking natural mosaic illumination and consequent alternation of cell regions with dominant dark and photosynthetic metabolism. Based on this assumption, we examined the light response curves and the induction kinetics of fluorescence-based parameters of chloroplast photosynthetic activity on small regions (d ∼ 100 μm) of Chara corallina Klein ex Willd. internodal cells exposed to local and overall illumination under conditions of normal cytoplasmic streaming and after suppression of cyclosis by cytochalasin B, an inhibitor of actin microfilaments. Under control conditions, the whole cell illumination caused non-photochemical quenching (NPQ) of chlorophyll fluorescence, which approached the saturation at a photon flux density of about 40 μmol/(m² s). By contrast, illumination of a small (2 mm wide) cell part did not cause significant NPQ at light intensities up to 100 μmol/(m² s), indicating that the chloroplast photosynthetic activity was substantially higher under conditions of localized illumination. After the inhibition of cyclosis by cytochalasin B, the light response curves were represented by nearly identical sigmoid curves, irrespective of the illumination pattern. When the cyclosis was restored in the cells washed from the inhibitor, the light response curves measured under overall and localized illumination returned to their original divergent shapes. These and other data indicate that different photosynthetic activities of chloroplasts in cells exposed to entire and partial illumination are directly related to the flow of compositionally nonuniform cytoplasm between the cell parts with prevalent photosynthetic and respiratory metabolism.     

Cine-photomicrography of low temperature effects on cytoplasmic streaming, nucleoar activity and mitosis in single tobacco cells in microculture

Living, unstained, single tobacco (Nicoliana tabacum × N. glutinosa) cells (clone H-196) were grown in microcultures in liquid medium containing sucrose, mineral salts, coconut milk and 2,4-dichlorophenoxyaeetic acid. Time-lapse motion pictures were taken through interference and phase microscopes. The movement of cytoplasm and cell organelles gradually slowed and ultimately completely ceased as the cell was cooled by dry ice. The cessation of the movement of cell organelles took place between 5 and –7C. The typical cytoplasmic morphology was lost as the movement slowed. The cytoplasmic strands thinned out and numerous small vacuoles formed. During rewarming of the cell to room temperature, the vacuoles were replaced by numerous small globular masses of cytoplasm which reorganized into cytoplasmic strands. The normal movement of cytoplasmic strands and cell organelles was resumed. A number of small nucleolar vacuoles at room temperature gradually expanded and coaleseed to form a large central vacuole which underwent further expansion and then contracted rapidly. Four different concentric zones were visible across the nucleolar region. A white, highly reflecting, glossy substance appeared on the surface of the expanding vacuole. The position of the nucleus during contraction and expansion was never stationary. Some nucleolar vacuoles remained open for an indefinite period of time when the cell was cooled to 5C. No change was noticed during cooling, but during rewarming to room temperature, the nucleolar vacuole was partially closed. The pumping action of the nucleolar vacuole suggested important exchanges of metabolites between the nucleolus and the cytoplasm. A single cell of tobacco did not divide at –10C, but mitosis proceeded upon cooling the cell to – 12–15C for a brief period. Different phases of mitosis, specifically formation of the cell plate, cell wall, and separation of nuclei, were delayed by low temperature treatment.     

Phospholipid Biosynthesis and Fatty Acid Content in Relation to Chilling Injury during Germination of Seeds

The proportion of labeled ¹⁴C-glycerol incorporated into phospholipids and the fatty acid composition of three phospholipids in germinating seeds and seedlings of chilling-sensitive lima beans (Phaseolus lunatus L.) and chilling-resistant broad beans (Vicia faba L.) and peas (Pisum sativum L.) at 10 and 25 C were determined. During the imbibition of seeds (first 24 hours), lima beans were sensitive to chilling injury at 10 C and a higher proportion of label was incorporated into phosphatidylethanolamine and phosphatidylglycerol than in broad beans and peas. Broad beans and peas incorporated a higher proportion of label into phosphatidylcholine. The oleic acid content of phosphatidylcholine was higher and linolenic acid content was lower in peas and broad beans than in lima beans at 10 and 25 C. The unsaturated to saturated fatty acid ratio was much higher for the chilling-resistant seeds than for the chilling-sensitive ones. In the seedling stage, the proportion of label incorporated into the four major phospholipids was similar in the three species regardless of temperature treatment. The fatty acid content of the phospholipids examined was not different in the three species in the seedling stage.     

Mechanism of inhibition of translocation by localized chilling

Arrhenius plots of translocation velocity as a function of petiole temperature show a marked increase in temperature dependence below 10 C in bean (a chilling-sensitive species) but not in sugar beet (chilling-resistant). The increased temperature dependence below 10 C was not observed for cytoplasmic streaming or oxygen uptake in bean. Bean petioles were served to release pressure in order to determine whether sieve tubes are obstructed in cold-treated petioles. The resulting pressure release caused serious displacement of the crystalline protein bodies in the sieve tubes of petioles at 25 C, but in those locally cooled to 0 C for 30 minutes little displacement occurred, indicating obstruction in the latter. An ultrastructural study of sieve tubes in tissue frozen rapidly in situ and dehydrated by freeze substitution revealed that treatment at 0 C for 30 minutes caused structural alteration and displacement of the cytoplasmic material lining the sieve tube wall resulting in occlusion of sieve plates. The sieve plates of the control petioles at 25 C were generally clear of obstructions. The results indicate that inhibition of translocation by chilling in chilling-sensitive plants results from physical blockage of sieve plates rather than from direct inhibition of a metabolic process which drives translocation.     

Comparison of Membrane Pluidity of Seedling Mitochondria of Chilling Sensitive and Chilling Tolerant Rice

The membrane fluidity of seedling mitochondria of chilling-sensitive rice and that of chilling-tolerant rice were compared by using spin labeled stearic acid: 5, 12 16-NS and fluorescent probe DPH. From the ESR spectra using 5-NS as a spin labeled probe it clearly showed that the calculated order parameter (S) of seedling mitochondria of chilling-sensitive rice Qiu Guang was obviously higher than that of chilling-resistant rice Ji Geng 44. Similar results were obtained when seedling'mitochondria of another species of chilling sensitive Zao Jin were compared with those of chilling tolerant rice Ji Geng 60. Moreover, the difference of order parameters between Ji Geng 44 and Ji Geng 60 was quite small, but both of them are obviously lower than those of chilling-sensitive rice Qiu Guang or Zao Jin. The results using spin labeled probe 12-NS, 16-NS clearly showed that the relative correlation times (τc) of seedling mitochondria of chilling-sensitive rice Qiu Guang or Zao Jin was markedly higher than that of the chilling tolerant rice Ji Geng 44 or Ji Geng 60. A comparison of membrane fluidity of seedling mitochondria of chilling-sensitive and chilling-resistant rice using fluorescent probe DPH was also carried out. Similar results were obtained and showed that the fluidity of mitochondrial membrane of chilling resistant rice seedling was obviously higher than that of the chilling-sensitive ones. Thus, it seemed that the fluidity of mitochondrial membrane might be used as a biophysical test for screening chilling tolerance of rice at seedling stage.     

Dynamic changes in the actin cytoskeleton during the high-fluence rate response of theMougeotia chloroplast

Summary Since photo-induced orientation movement of a single, ribbon-shaped chloroplast in each cell of the filamentous green algaMougeotia is inhibited in the presence of cytochalasin B, actin is thought to be involved in the process of chloroplast movements. However, this possibility remains to be proved. A specific class of cytoplasmic filaments, which emerge from the advancing front of the moving chloroplast, can be seen by differential interference contrast (DIC) microscopy. However, no one has yet succeeded in defining the nature of these filaments. We have been able to stain the actin filaments (AFs) associated with the moving chloroplast with fluorescein-conjugated phalloidin (FP) after pre-treatment withm-maleimidobenzoyl N-hydroxysuccinimide ester (MBS). No filamentous structures were observed in cells that had been pre-irradiated with low-fluence rate red light. However, transversely oriented fluorescent filaments appeared at the front edge of the moving chloroplast when it began to rotate under irradiation with high-fluence rate white light. These filaments disappeared after completion of the orientation movement, suggesting the simultaneous appearance of AFs and the orientation movement of the chloroplast. Thick cytoplasmic strands connecting the edge of the chloroplast with the parietal cytoplasm were often seen by DIC microscopy before and after completion of the high-fluence rate orientation movement. These thick cytoplasmic strands could not be stained by FP, but were often stained by 3,3-dihexyloxacarbocyanine iodide (DiOC₆(3)), suggesting that they are transvacuolar strands that include endoplasmic reticulum.     

Nucleus-associated actin in Amoeba proteus

The presence, spatial distribution and forms of intranuclear and nucleus-associated cytoplasmic actin were studied in Amoeba proteus with immunocytochemical approaches. Labeling with different anti-actin antibodies and staining with TRITC-phalloidin and fluorescent deoxyribonuclease I were used. We showed that actin is abundant within the nucleus as well as in the cytoplasm of A. proteus cells. According to DNase I experiments, the predominant form of intranuclear actin is G-actin which is associated with chromatin strands. Besides, unpolymerized actin was shown to participate in organization of a prominent actin layer adjacent to the outer surface of nuclear envelope. No significant amount of F-actin was found in the nucleus. At the same time, the amoeba nucleus is enclosed in a basket-like structure formed by circumnuclear actin filaments and bundles connected with global cytoplasmic actin cytoskeleton. A supposed architectural function of actin filaments was studied by treatment with actin-depolymerizing agent latrunculin A. It disassembled the circumnuclear actin system, but did not affect the intranuclear chromatin structure. The results obtained for amoeba cells support the modern concept that actin is involved in fundamental nuclear processes that have evolved in the cells of multicellular organisms.     

Photoinhibition at low temperature in chilling-sensitive and -resistant plants

Photoinhibition resulting from exposure at 7°C to a moderate photon flux density (300 micromoles per square meter per second, 400-700 nanometers) for 20 hours was measured in leaves of annual crops differing widely in chilling tolerance. The incidence of photoinhibition, determined as the decrease in the ratio of induced to total chlorophyll fluorescence emission at 693 nanometers (F_v/F_max) measured at 77 Kelvin, was not confined to chilling-sensitive species. The extent of photoinhibition in leaves of all chilling-resistant plants tested (barley [Hordeum vulgare L.], broad bean [Vicia faba L.], pea [Pisum sativum L.], and wheat [Triticum aestivum L.]) was about half of that measured in chilling-sensitive plants (bean [Phaseolus vulgaris L.], cucumber [Cucumis sativus L.], lablab [Lablab purpureus L.], maize [Zea mays L.], pearl millet [Pennisetum typhoides (Burm. f.) Stapf & Hubbard], pigeon pea [Cajanus cajun (L.) Millsp.], sesame [Sesamum indicum L.], sorghum [Sorghum bicolor L. Moench], and tomato [Lycopersicon esculentum Mill.]). Rice (Oryza sativa L.) leaves of the indica type were more susceptible to photoinhibition at 7°C than leaves of the japonica type. Photoinhibition was dependent both on temperature and light, increasing nonlinearly with decreasing temperature and linearly with increasing light intensity. In contrast to photoinhibition during chilling, large differences, up to 166-fold, were found in the relative susceptibility of the different species to chilling injury in the dark. It was concluded that chilling temperatures increased the likelihood of photoinhibition in leaves of both chilling-sensitive and -resistant plants. Further, while the photoinhibition during chilling generally occurred more rapidly in chilling-sensitive plants, this was not related directly to chilling sensitivity.     

A Comparison of the Effects of Chilling on Thylakoid Electron Transfer in Pea (Pisum sativum L.) and Cucumber (Cucumis sativus L.)

Experiments comparing the photosynthetic responses of a chilling-resistant species (Pisum sativum L. cv Alaska) and a chilling-sensitive species (Cucumis sativus L. cv Ashley) have shown that cucumber photosynthesis is adversely affected by chilling temperatures in the light, while pea photosynthesis is not inhibited by chilling in the light. To further investigate the site of the differential response of these two species to chilling stress, thylakoid membranes were isolated under various conditions and rates of photosynthetic electron transfer were determined. Preliminary experiments revealed that the integrity of cucumber thylakoids from 25°C-grown plants was affected by the isolation temperature; cucumber thylakoids isolated at 5°C in 400 millimolar NaCl were uncoupled, while thylakoids isolated at room temperature in 400 millimolar NaCl were coupled, as determined by addition of gramicidin. The concentration of NaCl in the homogenization buffer was found to be a critical factor in the uncoupling of cucumber thylakoids at 5°C. In contrast, pea thylakoid membranes were not influenced by isolation temperatures or NaCl concentrations. In a second set of experiments, thylakoid membranes were isolated from pea and cucumber plants at successive intervals during a whole-plant light period chilling stress (5°C). During wholeplant chilling, thylakoids isolated from cucumber plants chilled in the light were uncoupled even when the membranes were isolated at warm temperatures. Pea thylakoids were not uncoupled by the whole-plant chilling treatment. The difference in integrity of thylakoid membrane coupling following chilling in the light demonstrates a fundamental difference in photosynthetic function between these two species that may have some bearing on why pea is a chilling-resistant plant and cucumber is a chilling-sensitive plant.     

ULTRASTRUCTURE,DEVELOPMENT AND CYTOPLASMIC ROTATION OF SETA-BEARING CELLS OF COLEOCHAETE SCUTATA (CHLOROPHYCEAE)1

Part of the cytoplasm, which always contains the plastid, of seta-bearing cells of Coleochaete scutata Bréb. rotates clockwise about the base of the seta. Many golgi bodies, vesicles and much endoplasmic reticulum occupy the bridges between the rotating central core of cytoplasm and the stationary peripheral layer of these cells. The setae, which grow from their base, are devoid of organelles other than vesicles and elongate mitochondria. At irregular intervals along the thin seta wall are annular thickenings containing callose. Microtubules which encircle the base of the seta disappear on treatment with colchicine. This drug had no effect on the speed of rotational streaming or the growth rate of existing hairs but did inhibit the development of new setae. Cytochalasin B slowed, but did not stop, streaming after 3 h exposure. However caffeine, but not EDTA, EGTA or the Ca ionophore A23187, reversibly inhibited cyclosis. The mechanism of cytoplasmic rotation is discussed in the light of these drug treatments and the presence of actin in the alga.     

Differential cytoplasm-plasma membrane-cell wall adhesion patterns and their relationships to hyphal tip growth and organelle motility

Summary Plasmolysis of hyphae of the oomycetesSaprolegnia ferax andAchlya ambisexualis and the ascomyceteNeurospora crassa produced abundant cytoplasmic strands between the retracted cytoplasm and punctate adhesions of the plasma membrane to the cell wall. These strands formed throughout the length of mature hyphae and are the first demonstration of Hechtian strands in hyphae. In contrast to similar strands in various plant cells, the strands inSaprolegnia lacked endoplasmic reticulum but contained F-actin, suggesting similarity between their adhesion sites and focal contacts in animal cells. However, strand adhesion to the wall was insensitive to RGD-containing peptides, suggesting that the trans-membrane adhesion molecules differ from animal integrins. The pattern of plasma membrane-cell wall adhesion varied in different zones along hyphae, with broad, irregular connections in the extreme apex, uniform and continuous connection in a transition zone, and small, punctate adhesions in the mature subapical zone, suggesting differential functions in these different regions. The apical adhesions are important in tip growth, as diverse inhibitors induced concomitant changes in hyphal growth and the adhesions in the apical and transition zones. Plasmolysis also induced cytoplasmic migrations throughout hyphae. Such migrations were dominated by the central cytoplasm, and produced distorted organelles which spanned central and peripheral cytoplasm, thus supporting the idea that the adhesions in mature zones of hyphae anchor the peripheral cytoplasm and facilitate cytoplasmic and organelle migrations.Abbreviations OM organic medium - RP rhodamine phalloidin - DIC differential interference contrast - PIPES piperazine-N,N-bis-2-ethanosulphonic acid     

Molecular Species Composition of Phosphatidylglycerols from Chilling-Sensitive and Chilling-Resistant Plants

The molecular species of phosphatidylglycerols from leaves of9 species of chilling-sensitive plants and 12 species of chilling-resistantplants were analyzed by gas-liquid chromatography and gas chromatography-massspectrometry. The sum of the contents of the dipalmitoyl plusthe 1-palmitoyl-2-(trans-3-hexadecenoyl) species of phosphatidylglycerolranged from 3 to 19% of the total of this lipid in the chilling-resistantplants, and from 26 to 65% in the chilling-sensitive plants.These findings suggest that these two molecular species of phosphatidylglycerolsare closely associated with the chilling sensitivity of theplants. The biochemical difference between the chilling-sensitiveand the chilling-resistant plants is discussed in terms of theactivities of enzymes involved in phosphatidylglycerol biosynthesisin the chloroplasts. (Received August 19, 1982; Accepted November 19, 1982)