Geert Potters

Ascorbate and glutathione: guardians of the cell cycle, partners in crime?

Abstract Besides the implication of ascorbate and glutathione in the defence against oxidative stress, these two compounds are involved in plant growth and cell cycle control. Ascorbate metabolism is closely linked to the development of embryos and seedlings. Furthermore, ascorbate stimulates cell cycle activity in competent cells, while the oxidised form, dehydroascorbate, blocks normal cell cycle progression. Several possible mechanisms have been proposed to explain the effect of these compounds. The links between glutathione and the cell cycle are less clear. It has long been assumed that both compounds are closely linked by way of the Halliwell–Asada cycle. Any hypothesis concerning the pathways by which ascorbate or glutathione influence cell division, should take this connection into account. However, other mechanisms have been proposed for ascorbate-mediated cell cycle control, e.g. via the thioredoxin pathway.

Different stresses, similar morphogenic responses: integrating a plethora of pathways

Exposure of plants to mild chronic stress can cause induction of specific, stress-induced morphogenic responses (SIMRs). These responses are characterized by a blockage of cell division in the main meristematic tissues, an inhibition of elongation and a redirected outgrowth of lateral organs. Key elements in the ontogenesis of this phenotype appear to be stress-affected gradients of reactive oxygen species (ROS), antioxidants, auxin and ethylene. These gradients are present at the the organismal level, but are integrated on the cellular level, affecting cell division, cell elongation and/or cell differentiation. Our analysis of the literature indicates that stress-induced modulation of plant growth is mediated by a plethora of molecular interactions, whereby different environmental signals can trigger similar morphogenic responses. At least some of the molecular interactions that underlie morphogenic responses appear to be interchangeable. We speculate that this complexity can be viewed in terms of a thermodynamic model, in which not the specific pathway, but the achieved metabolic state is biologically conserved.

Ascorbate function and associated transport systems in plants

Abstract Ascorbate is present in different cell compartments of higher plant cells. At a physiological level, the best-studied phenomena involving ascorbate is its participation in an oxygen scavenging pathway in the chloroplast known as the ascorbate-glutathione cycle. In addition, evidence is emerging that ascorbate fulfils essential roles in growth, development and defence outside the chloroplast. Despite its importance in plant biology, the pathway of ascorbate biosynthesis has only recently been elucidated. From the site of synthesis in the mitochondria, ascorbate must be transported to other cellular compartments where it accumulates to high concentrations. Translocation of ascorbate through the plasmalemma and chloroplast membrane is mediated by specific carriers. Initial observations indicate that carriers for both ascorbate and its oxidised form dehydroascorbate are present in plant membranes. Regulation of ascorbate transport systems may be central in the regulation of different physiological processes including progression through the cell cycle, expansion of the cell wall and defence against abiotic and biotic threats.

The cellular redox state in plant stress biology – A charging concept

Different redox-active compounds, such as ascorbate, glutathione, NAD(P)H and proteins from the thioredoxin superfamily, contribute to the general redox homeostasis in the plant cell. The myriad of interactions between redox-active compounds, and the effect of environmental parameters on them, has been encapsulated in the concept of a cellular redox state. This concept has facilitated progress in understanding stress signalling and defence in plants. However, despite the proven usefulness of the concept of a redox state, there is no single, operational definition that allows for quantitative analysis and hypothesis testing.

Dehydroascorbate Influences the Plant Cell Cycle through a Glutathione-Independent Reduction Mechanism

Glutathione is generally accepted as the principal electron donor for dehydroascorbate (DHA) reduction. Moreover, both glutathione and DHA affect cell cycle progression in plant cells. But other mechanisms for DHA reduction have been proposed. To investigate the connection between DHA and glutathione, we have evaluated cellular ascorbate and glutathione concentrations and their redox status after addition of dehydroascorbate to medium of tobacco (Nicotiana tabacum) L. cv Bright Yellow-2 (BY-2) cells. Addition of 1 mm DHA did not change the endogenous glutathione concentration. Total glutathione depletion of BY-2 cells was achieved after 24-h incubation with 1 mm of the glutathione biosynthesis inhibitor l-buthionine sulfoximine. Even in these cells devoid of glutathione, complete uptake and internal reduction of 1 mm DHA was observed within 6 h, although the initial reduction rate was slower. Addition of DHA to a synchronized BY-2 culture, or depleting its glutathione content, had a synergistic effect on cell cycle progression. Moreover, increased intracellular glutathione concentrations did not prevent exogenous DHA from inducing a cell cycle shift. It is therefore concluded that, together with a glutathione-driven DHA reduction, a glutathione-independent pathway for DHA reduction exists in vivo, and that both compounds act independently in growth control.

Copper-mediated oxidative burst in **Nicotiana tabacum** L. cv. Bright Yellow 2 cell suspension cultures

Summary. In cell suspension cultures of Nicotiana tabacum L. cv. Bright Yellow 2 (BY-2) a rapid and concentration-dependent accumulation of H2O2 is induced by excess concentrations of copper (up to 100 μM). This specific and early response towards copper stress was shown to be extracellular. Addition of 300 U of catalase per ml decreased the level of H2O2. Superoxide dismutase (5 U/ml) induced an increase in H2O2 production by 22.2%. This indicates that at least part of the H2O2 is produced by dismutation of superoxide. Pretreatment of the cell cultures with the NAD(P)H oxidase inhibitors diphenylene iodonium (2 and 10 μM) and quinacrine (1 and 5 mM) prevented the generation of H2O2 under copper stress for 90%. The influence of the pH on the H2O2 production revealed the possible involvement of cell-wall-dependent peroxidases in the generation of reactive oxygen species after copper stress.

Dehydroascorbate Uptake Activity Correlates with Cell Growth and Cell Division of Tobacco Bright Yellow-2 Cell Cultures

Recently, ascorbate (ASC) concentration and the activity of a number of enzymes from the ASC metabolism have been proven to correlate with differences in growth or cell cycle progression. Here, a possible correlation between growth and the activity of a plasma membrane dehydroascorbate (DHA) transporter was investigated. Protoplasts were isolated from a tobacco (Nicotiana tabacum) Bright Yellow-2 cell culture at different intervals after inoculation and the activity of DHA transport was tested with 14C-labeled ASC. Ferricyanide (1 mm) or dithiothreitol (1 mm) was included in the test to keep the external 14C-ASC in its oxidized respectively reduced form. Differential uptake activity was observed, correlating with growth phases of the cell culture. Uptake of DHA in cells showed a peak in exponential growth phase, whereas uptake in the presence of dithiothreitol did not. The enhanced DHA uptake was not due to higher endogenous ASC levels that are normally present in exponential phase because preloading of protoplasts of different ages did not affect DHA uptake. Preloading was achieved by incubating cells before protoplastation for 4 h in a medium supplemented with 1 mm DHA. In addition to testing cells at different growth phases, uptake of DHA into the cells was also followed during the cell cycle. An increase in uptake activity was observed during M phase and the M/G1 transition. These experiments are the first to show that DHA transport activity into plant cells differs with cell growth. The relevance of the data to the action of DHA and ASC in cell growth will be discussed.

Transport of ascorbate into protoplasts ofNicotiana tabacum Bright Yellow-2 cell line

SummaryThe uptake of ascorbate into protoplasts isolated from aNicotiana tabacum Bright Yellow-2 (BY-2) cell suspension culture was investigated. Addition of14C-labelled ascorbate to freshly isolated protoplasts resulted in a time- and substrate-dependent association of radioactive molecules with the protoplasts. The kinetic characterisation of this presumptive uptake revealed kinetics of Michaelis-Menten type with an apparent maximal uptake activity of 24 pmol/min·106 protoplasts and an apparent affinity constant of 139 μM. The amount of ascorbate molecules transported intoN. tabacum protoplasts decreased when nonlabelled dehydroascorbate or iso-ascorbate were added but was not affected by addition of 5,6-o-cyclohexylidene ascorbate or ascorbate-2-sulfate. These data indicate a carrier-mediated uptake of ascorbate into the protoplasts that shows a high structural specificity. To investigate which redox status of ascorbate is preferentially taken up by theN. tabacum protoplasts, transport was tested in the presence of various compounds that can affect the redox status of ascorbate. Testing uptake in the presence of a reductant, dithiothreitol, resulted in a significant and concentration-dependent inhibition of the amount of ascorbate molecules transported into the protoplasts. On the other hand, ascorbate uptake was significantly stimulated in the presence of the enzyme ascorbate oxidase. Ferricyanide did not affect ascorbate transport. Inhibition studies revealed that ascorbate uptake in the protoplasts is sensitive to addition of sulfhydryl reagents N-ethyl maleimide andp-chloro-mercuribenzenesulfonic acid and to a disruption of the proton gradient by the protonophore carbonylcyanide-3-chlorophenylhydrazone. The uptake of ascorbate was also inhibited by addition of cytochalasin B but not sensitive to addition of phloretin or sulfinpyrazone. Taken together these data indicate the presence of an ascorbate transport system in the plasma membrane ofN. tabacum protoplasts and suggest dehydroascorbate as the preferentially transported redox species. The putative presence of different carriers for reduced and oxidised ascorbate in the plasma membrane is discussed.

The thiol compounds glutathione and homoglutathione differentially affect cell development in alfalfa (Medicago sativa L.)

Glutathione (GSH) is an important scavenger of Reactive Oxygen Species (ROS), precursor of metal chelating phytochelatins, xenobiotic defence compound and regulator of cell proliferation. Homoglutathione (hGSH) is a GSH homologue that is present in several taxa in the family of Fabaceae. It is thought that hGSH performs many of the stress-defence roles typically ascribed to GSH, yet little is known about the potential involvement of hGSH in controlling cell proliferation. Here we show that hGSH/GSH ratios vary across organs and cells and that these changes in hGSH/GSH ratio occur during dedifferentiation and/or cell cycle activation events. The use of a GSH/hGSH biosynthesis inhibitor resulted in impaired cytokinesis in isolated protoplasts, showing the critical importance of these thiol-compounds for cell division. However, exposure of isolated protoplasts to exogenous GSH accelerated cytokinesis, while exogenous hGSH was found to inhibit the same process. We conclude that GSH and hGSH have distinct functional roles in cell cycle regulation in Medicago sativa L. GSH is associated with meristemic cells, and promotes cell cycle activation and induction of somatic embryogenesis, while hGSH is associated with differentiated cells and embryo proliferation.

Seasonal, Diurnal and Vertical Variation of Chlorophyll Fluorescence on Phyllostachys humilis in Ireland

In recent years, temperate bamboo species have been introduced in Europe not only as an ornamental plant, but also as a new biomass crop. To measure adaptation stress of bamboo to the climate of Western Europe, chlorophyll fluorescence was measured on a diurnal and seasonal basis in Ballyboughal, Co. Dublin, Ireland. Measurements were attained on the leaves of each node of Phyllostachys humilis. The most frequently used parameter in chlorophyll fluorescence is the photosynthetic efficiency (Fv/Fm). A seasonal dip - as well as a larger variation - of Fv/Fm in spring compared to the rest of the year was observed. Over the year, the upper leaves of the plant perform better than the bottom leaves. These findings were linked to environmental factors such as light intensity, air temperature and precipitation, as increased light intensities, decreasing air temperatures and their interactions, also with precipitation levels have an effect on the photosynthetic efficiency (Fv/Fm) in these plants.