Plant physiology

About: Plant physiology is a research topic. Over the lifetime, 1537 publications have been published within this topic receiving 72038 citations.

Chloroplast ultrastructure, photosynthesis and accumulation of secondary metabolites in Glechoma longituba in response to irradiance

Abstract: Glechoma longituba (Nakai) Kupr is a perennial shade plant with pharmaceutical importance The aim of this study was to investigate the effects of light intensity on the growth, photosynthesis, and accumulation of secondary metabolites in G longituba grown under six different light environments The high light intensity decreased the leaf size, specific leaf area, and aboveground dry mass, the number of grana per chloroplast, the number of lamella per granum, the thickness of the grana, the apparent quantum efficiency, the chlorophyll (Chl) content, the concentrations of ursolic and oleanolic acid The high light increased the stomatal density, the stoma size, the number of chloroplast per a cell, the chloroplast size, the dark respiration rate, the light saturation point, the light compensation point, and the Chl a/b ratio With the reduction in the light intensity, the light-saturated net photosynthetic rate, the aerial dry mass per plant, and the yields of ursolic and oleanolic acid decreased after an initial increase, peaking at 16 and 33% of sunlight levels Overall, the 16 and 33% irradiance levels were the most efficient in improving the yields and qualities of the medicinal plant The lower light demand and growth characteristics suggest that G longituba is an extremely shade-tolerant plant and that appropriate light intensity management might be feasible to obtain higher yields of secondary metabolites in agricultural management

Insertion of cyanobacterial desA gene coding for Δ12-acyl-lipid desaturase increases potato plant resistance to oxidative stress induced by hypothermia

Abstract: The role of Δ12-acyl-lipid desaturase in plant resistance to hypothermia-induced oxidative stress was investigated. This study focused on modulation of free-radical processes occurring at low temperature in leaf cells of potato plants (Solanum tuberosum L., cv. Desnitsa) transformed with the gene for Δ12-acyl-lipid desaturase from the cyanobacterium Synechocystis sp. PCC 6803. Nontransformed plants of the same cultivar were used as a control material. The plants were grown in vitro on Murashige and Skoog agarized medium containing 2% sucrose. During hypothermia the rate of superoxide anion generation and hydrogen peroxide concentration decreased significantly. In addition, the content of both primary products (conjugated dienes and trienes) and secondary products (malonic dialdehyde) of lipid peroxidation was lower in the transformed plant leaves than in leaves of wild-type plants. It is supposed that the insertion into the plant genome of Δ12-acyl-lipid desaturase stabilizes the composition and physical properties of biomembranes by promoting polyunsaturation of fatty acids, which averts the accelerated generation of O 2 ·− , — and suppresses lipid peroxidation during hypothermia. These changes improved cold resistance of potato plants, which was evident from the less severe injury of leaf blades in cold-treated transgenic plants, as compared to that in the wild-type line. The activity of superoxide dismutase, a key enzyme of the antioxidant defense system was lower in leaves of transformed plants than in leaves of wild-type plants. A comparatively low activity of superoxide dismutase in transgenic plants implies that these plants experience less severe thermal and oxidative stress upon cooling and can cope with the cold without considerable increase in the enzyme activity. It is concluded that the insertion of the desA gene encoding Δ12-acyl-lipid desaturase into cold-resistant potato plants improves plant resistance to cold-induced oxidative stress by decreasing the rate of intracellular free-radical processes.

Spatio-temporal Responses of Arabidopsis Leaves in Photosynthetic Performance and Metabolite Contents to Burkholderia phytofirmans PsJN.

Abstract: A valuable strategy to improve crop yield consists in the use of plant growth-promoting rhizobacteria (PGPRs). However, the influence of PGPR colonization on plant physiology is largely unknown. PGPR Burkholderia phytofirmans strain PsJN (Bp PsJN) colonized only Arabidopsis thaliana roots after seed or soil inoculation. Foliar bacteria were detected only after leaf infiltration. Since different bacterial times of presence and/or locations in host plant could lead to different plant physiological responses, photosynthesis and metabolite profiles in A. thaliana leaves were thus investigated following leaf, root or seed inoculation with Bp PsJN. Only Bp PsJN leaf colonization transiently decreased cyclic electron transport and effective quantum yield of photosystem I (PSI), and prevented a decrease in net photosynthesis and stomatal opening compared to the corresponding control. Metabolomic analysis revealed that soluble sugars, amino acids or their derivatives accumulated differently in all Bp PsJN-inoculated plants. Octanoic acid accumulated only in case of inoculated plants. Modifications in vitamin, organic acid such as tricarboxylic acid intermediates, and hormone amounts were dependent on bacterial time of presence and location. Additionally, a larger array of amino acids and hormones (auxin, cytokinin, abscisic acid) were modified by seed inoculation with Bp PsJN. Our work thereby provides evidence that relative short-term inoculation with Bp PsJN altered physiological status of A.thaliana leaves, whereas long-term bacterization triggered modifications on a larger set of metabolites. Our data highlighted the changes displayed during this plant-microbe interaction to trigger physiological and metabolic responses that could explain the increase in plant growth or stress tolerance conferred by the presence of Bp PsJN.

Transgenic Turfgrasses Expressing Hyperactive Ser599Ala Phytochrome A Mutant Exhibit Abiotic Stress Tolerance

Abstract: Turfgrasses are environmentally and recreationally valuable plants that are constantly subjected to various forms of stress in their artificial and natural habitats. Previously, it was shown that the transformation of a hyperactive mutant (Serine 599 Alanine, S599A) of oat phytochrome A in zoysia grass (Zoysia japonica) and creeping bentgrass (Agrostis stolonifera L.) resulted in superior quality turfgrass with improved shade tolerance response. We now examined the abiotic stress response of the transgenic turfgrasses expressing the hyperactive mutant S599A-PhyA. The transgenic S599A-PhyA plants subjected to high salinity and heavy metal toxicity stress exhibited higher chlorophyll content, lower hydrogen peroxide level, and higher proline accumulation than the controls. Furthermore, the anti-oxidative activities of four reactive oxygen species scavenging enzymes and the total biomass (above and below-ground) were higher in S599A-PhyA plants than in the controls under both the stress conditions. Moreover, higher photosynthetic efficiency (F v/F m) of S599A-PhyA plants indicated healthier growth than the controls under stress conditions. Results suggest that the hyperactive mutant of oat phytochrome A confers abiotic stress tolerance in plants, and can be used to efficiently develop abiotic stress tolerant crops in future.

Environmental impacts on carotenoid metabolism in leaves

Abstract: Leaves are primary plant organs harbouring chloroplasts that enable the sensing of changes in environmental conditions and contribute to maintaining cellular homeostasis. Carotenoids, carotenoid-derived phytohormones and apocarotenoid metabolites facilitate photosynthesis, photoprotection and stress acclimation in leaves. The thylakoids in the chloroplasts from the photosynthetically functional leaves accumulate a specific composition of lutein, β-carotene, violaxanthin, and neoxanthin that act as accessory pigments to chlorophyll and maintain optimal photosynthetic performance. The developmental state of leaves and environmental conditions can affect carotenoid metabolism and, hence, chloroplast functions in leaves. The etioplasts in the cotyledons from the germinating seedlings abundantly accumulate lutein. The light exposure of cotyledons triggers ultrastructural development of chloroplast accumulating all primary foliar carotenoids and chlorophylls. The accumulation of zeaxanthin and antheraxanthin during intense light and high temperature maintains the functional integrity of thylakoid membranes and chloroplasts. Carotenoids are continuously synthesised and degraded in leaves, yet their composition remains tightly maintained. The disintegration of chloroplast, such as during the leaf senescence, ceases the carotenoid biosynthesis and triggers carotenoid degradation. This review sheds light on the fundamental aspects of carotenoid metabolism. The effects of altered light regimes, carbon dioxide (CO2), temperature, drought, and soil nutrient levels are discussed in the context of carotenoid metabolism in leaves. The outstanding questions on how environmental perturbations can alter carotenoid metabolism and chloroplast development in leaves are highlighted. This review provides further insights on how carotenoid regulatory networks could be engineered to enrich carotenoids in the leaves of food and horticultural crops.