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41	Impact of vanadium stress on physiological and biochemical characteristics in heavy metal susceptible and tolerant Brassicaceae Gokul, Arun January 2013 (has links) >Magister Scientiae - MSc / There is an influx in heavy metals into soils and ground water due to activities such as increased mineral mining, improper watering and the use of heavy metal contaminated fertilizers. These heavy metals are able to increase the ROS species within plants which may result in plant metabolism deterioration and tissue damage. Heavy metals may also directly damage plants by rendering important enzymes non-functional through binding in metal binding sites of enzymes. The heavy metal focused on in this study was vanadium due to South Africa being one of the primary produces of this metal. Two related Brassica napus L cultivars namely Agamax and Garnet which are economically and environmentally important to South Africa were exposed to vanadium. Physiological experiments such as cell death, chlorophyll and biomass determination were conducted to understand how these cultivars were affected by vanadium toxicity. A low cost, sensitive and robust vanadium assay was developed to estimate the amount of vanadium in samples such as water, soils and plant material. The oxidative state as well as the antioxidant profile of the two cultivars were also observed under vanadium stress. A chlorophyll assay which was conducted on the two cultivars exposed to vanadium showed a marked decrease in chlorophyll A in the suspected sensitive cultivar which was Garnet. However, the suspected tolerant cultivar Agamax fared better and the decrease in chlorophyll A was much less. A similar trend was observed for the two cultivars when the cell death assay was conducted. The vanadium assay showed that Garnet had higher concentrations of vanadium within its leaves and lower concentrations in its roots when compared to Agamax. This observation displayed that Agamax had inherent mechanisms which it used to localize vanadium in its roots and which assisted in its tolerance to the vanadium stress. The oxidative state was determined by doing assays for the specific reactive oxygen species namely hydrogen peroxide and superoxide. It was observed that vanadium treated Garnet leaves had higher reactive oxygen species (ROS) production when compared to the Agamax treated leaves. In-gel native PAGE activity gels were conducted to determine the antioxidant profile for the two cultivars which were exposed to vanadium. The antioxidant enzymes which were under investigation were ascorbate peroxide (APX), superoxide dismutase (SOD) and glutathione-dependent peroxidases (GPX-like) as these enzymes are known to be responsible for controlling the ROS produced in the plants. The GPX-like profile consisted of three isoforms. No isoforms were inhibited by vanadium treatments but one isoform had increased activity in both the Garnet and Agamax treated samples. The SOD profile for Garnet consisted of six isoforms and Agamax had seven isoforms. One isoform which was visualized in both Agamax as well as Garnet was inhibited by vanadium treatments. Agamax also had two isoforms which were up-regulated however the corresponding isoforms in Garnet showed no change. The Ascorbate peroxidase profile consisted of seven isoforms for both Garnet and Agamax. No isoforms were inhibited by vanadium treatment. Three isoforms were up-regulated in Garnet and Agamax under vanadium treatments. Here, it is illustrated that Garnet lacked certain mechanisms found in Agamax (and thus experienced more cell death, yield and chlorophyll loss) and performed worst under high vanadium concentrations. Although Garnet increased the activity of some of its antioxidant isoforms in response to increasing ROS levels it was not adequate to maintain a normal oxidative homeostasis. This disruption in oxidative homeostasis lead to plant damage. Agamax was observed to produce less ROS than Garnet and was able to control the ROS produced more effectively than Garnet and thus less damage was observed in Agamax. Ascorbate peroxidase Biomass Cell death Hydrogen peroxide Hypertolerant Lipid peroxidation Superoxide
42	Elektrodų, modifikuotų laidžiais polimerais, tyrimas ir taikymas elektroanalizės tikslams / Studies of conducting polymer- modified electrodes and their application for electroanalysis Barzdžiuvienė, Kristina 30 December 2010 (has links) Darbo tikslas - ištirti askorbo rūgšties elektrocheminės oksidacijos ant elektrodų, modifikuotų polianilinu ir poli(N-metilanilinu), dėsningumus, siekiant sukurti jautrius askorbatui jutiklius. Ištirta įvairių faktorių įtaka anilino ir N-metilanilino elektrocheminei polimerizacijai bei gautų PANI ir PNMA sluoksnių savybėms. Atlikti palyginamieji modifikuotų elektrodų tyrimai skirtingo pH tirpaluose ir parodyta, kad PNMA lyginant su polianilinu pasižymi geresniu aktyvumu silpnai rūgščiuose ir neutraliuose tirpaluose. Ištirtas modifikuotų elektrodų amperometrinio atsako į askorbatą pobūdis, ir pasiūlytas autokatalizinis askorbato elektrooksidacijos mechanizmas ant PANI modifikuoto elektrodo. Panaudojus PANI ir PNMA modifikuotus elektrodus, sukurti amperometrinių askorbato jutiklių prototipai ir atlikti jų palyginamieji tyrimai. / The main purpose of this work - to investigate patterns of electrochemical oxidation of ascorbic acid on polyaniline and poly(N-methylaniline) modified electrodes, in order to develop ascorbate-sensitive sensors. A detailed study of various factors affecting the aniline and N-methylaniline electrochemical polymerization and the resulting properties of PANI and PNMA layers was carried out for this purpose. Comparative study of modified electrodes in solutions of different acidity was performed and it was shown that PNMA had a better redox activity in slightly acidic and neutral solutions compared to polyaniline. The nature of amperometric response of modified electrodes to ascorbate was investigated and autocatalytic mechanism of ascorbate electrooxidation on PANI modified electrode was suggested. Using PANI and PNMA modified electrodes, prototypes of amperometric ascorbate sensors have been developed and their comparative studies were carried out. Chemistry Askorbato jutiklis Elektrokatalizė Polianilinas Poli(N-metilanilinas) Elektroanalizė Ascorbate sensor Electrocatalysis Polyaniline Poly(N-methylaniline) Electroanalysis
43	Étude de la biosynthèse de l'ascorbate et des métabolismes associés chez la Tomate : rôle de la L-galactono-1,4-lactone déshydrogénase et de la GDP-D-mannose-3',5'-épimérase Gilbert, Louise 09 December 2009 (has links) La réduction de l’expression de deux gènes codant pour la L-galactono-lactone-1,4-déshydrogénase (GalLDH) et de la GDP-D-mannose-3’,5’-épimérase (GME), enzymes de la voie de biosynthèse de l’ascorbate, a permis de mieux comprendre le rôle physiologique de ces enzymes chez la tomate. D’une part, l’étude de la GalLDH a mis en évidence la régulation complexe du métabolisme de l’ascorbate et la fonction essentielle de cette protéine au sein de la chaîne de transport des électrons au niveau mitochondrial. D’autre part, ce travail a révélé le rôle central de la GME à la fois pour la biosynthèse de l’ascorbate et la biosynthèse des polysaccharides pariétaux, notamment les mannanes et le rhamnogalacturonane II. Chez les plantes sous-exprimant la GME, nous avons pu noter l’incidence de perturbations de la structure pariétale sur les propriétés mécaniques des tiges et des fruits ainsi que sur la fécondation. Ces modifications ont notamment engendré une fragilité accrue des tiges et une stérilité partielle. La GME est donc déterminante pour la qualité nutritionnelle et organoleptique du fruit de tomate. Enfin, dans le cadre d’une approche de biologie intégrative, nos résultats associés aux données issues de plantes sous-exprimant des gènes codant pour des enzymes de la voie de recyclage de l’ascorbate chez la tomate ouvrent des perspectives originales pour l’approfondissement des connaissances sur la régulation et sur l’intégration du métabolisme de l’ascorbate dans le fonctionnement de la cellule. / Down-regulation of two genes encoding the L-galactono-1,4-lactone dehydrogenase (GalLDH) and the GDP-D-mannose-3',5'-epimerase (GME), enzymes of ascorbate biosynthesis pathway, led to a better understanding of the physiological role of these enzymes in tomato plants. On one hand, the study of GalLDH highlighted the complex regulation of ascorbate metabolism and the essential function of this protein in mitochondrial electron transport chain. Moreover, this work revealed the central role of the GME for both the ascorbate biosynthesis and the biosynthesis of cell wall polysaccharides, including mannans and rhamnogalacturonan II. In the GME-silenced plants, we found that modifications of the cell wall structure change the mechanical properties of stems and fruit as well as the fertilization. These changes led to an increase of stem fragility and to an increase of sterility. Therefore, GME plays a crucial role regarding the nutritional and organoleptic quality of tomato fruit. Finally, within the context of a systems biology approach, our results associated to datas obtained with plants silenced for recycling pathway related genes lead to the prospect to unravel the knowledges on the regulation and the integration of ascorbate metabolism in cell functions. Ascorbate Mitochondrie Tomate Paroi Biologie intégrative
44	Koaxiální nanovlákna s inkorporovanými suplementy pro řízenou chondrogenní diferenciaci / Coaxial nanofibers with incorporated suplements for regulated chondrogenic differentiation Korbelová, Gabriela January 2019 (has links) In the field of regenerative medicine, regeneration of cartilage defects (caused either by injury or age-related degeneration) has become a widely discussed topic. Nanofibrous scaffolds provide a suitable environment for cell adhesion, proliferation, differentiation, and also for the local involvement of bioactive substances. Nanofibrous scaffolds mimic the extracellular matrix (ECM) of hyaline cartilage. These scaffolds are seeded with autologous chondrocytes. After having been isolated from the patient, the cells must be cultivated in vitro in order to obtain a sufficient amount of chondrocytes. Scaffolds with cultivated chondrocytes are later implanted back into the pacient. Chondrocytes, however, when grown on a 2D tissue culture plastic rapidly de-differentiate and thus lose the ability to synthesize ECM molecules. The aim of the work was modulation of chondrogenic differentiation medium through finding the ideal concentration of chondrogenic supplements, composed of L-ascorbate-2-phosphate (A2P) and dexamethasone (DEX), in the culture of primary chondrocytes seeded on a nanofibrous polycaprolactone (PCL) scaffold. The effect of different concentrations of the chondrogenic supplements on chondrocyte adhesion to the scaffold and their proliferation and differentiation was studied. The influence...
45	Resposta antioxidante enzimática, respiratória e fisiológica do tomate-cereja (Solanum lycopersicum var. cerasiforme) submetido ao choque térmico / Antioxidant enzyme answer, respiratory and physiological of tomato-cherry (Solanum lycopersicum var. cerasiforme) submitted When thermal shock Paulus, Cristiane 29 January 2016 (has links) Made available in DSpace on 2017-07-10T17:37:12Z (GMT). No. of bitstreams: 1 Cristiane Paulus.pdf: 907945 bytes, checksum: f84d9e19a342d1e11d80efa3864b0389 (MD5) Previous issue date: 2016-01-29 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Post-harvest treatments with thermal shock have been studied as an extension of alternative technical life of fruit. The beneficial effect of this technique has been related to their effects on the induction of physiological responses in protection against oxidative stress and development of pathogens. Enzymes are catalysts of the reactions occurring in biological systems. However, although the mechanisms by which post-harvest treatments induce this type of response are known in the plant organs are not clearly elucidated the mechanisms induced by postharvest heat shock that may affect the antioxidant status of treated fruits. The objective of this study was to evaluate the effect of heat shock on postharvest cherry tomatoes conservation, mediated biochemical and physicochemical answers related to antioxidant enzyme activity, respiratory activity, phenolic compounds, ascorbic, soluble solids acid, titratable acidity , percentage of weight, firmness, skin color and degradation of the fruit. The cherry tomatoes were subjected to heat shock treatments immersed in hot water at 45 ± 2 ° C at times 0, 5, 10, 15, 20 and 25 minutes. After treatments, fruits were divided into two groups. The first group was stored at 20 ± 2 ° C and at intervals of 1, 3, 6, 9 and 12 days, samples were taken and subjected to color analysis, firmness, weight loss, total phenolics, total flavonoids acid ascorbic acid and total soluble solids. The second group was submitted to respiratory activity assessments, ethylene production and enzymatic activity of superoxide dismutase, catalase and ascorbate peroxidase, at time intervals of 0, 2, 6, 24 and 48 hours of storage at 20 ± 2 ° C. According to the results, the fruits treated with heat shock suffered greater respiratory stress from the sixth day of storage. There was no significant difference between treatments for firmness, maintaining the rigidity of the fruit even after 12 days, and all treatments exhibited fruits with greater weight loss compared to the control. The application of heat treatment did not alter the total soluble solids content to the 6th day, heat exposure times of 15 and 20 min had a greater effect on the content of phenolic compounds during storage. exposed to heat fruits expressed the higher flavonoid content than the control and showed no recovery or increase in the concentration of ascorbic acid of cherry tomatoes in response to heat shock treatments that could indicate suppressive effect to stress. Thus, despite having the ability to prolong the life of cherry tomato, reducing the loss of the fruit after storage was not favorable for their use to reduce costs to prolong their shelf life / Tratamentos pós-colheita com choque térmico têm sido estudado como técnica alternativa de extensão da vida útil de frutos. A ação benéfica dessa técnica tem sido relacionada com seus efeitos na indução de respostas fisiológicas de defesa contra estresses oxidativos e desenvolvimento de patógenos. As enzimas são os catalisadores das reações que ocorrem nos sistemas biológicos. Entretanto, embora sejam conhecidos os mecanismos pelos quais os tratamentos pós-colheita induzem este tipo de resposta nos órgãos vegetais, ainda não estão claramente elucidados os mecanismos induzidos pelo choque térmico pós-colheita que possam afetar o status antioxidante de frutos tratados. O objetivo deste trabalho foi avaliar o efeito do choque térmico na conservação pós-colheita de tomates-cereja, mediada por respostas bioquímicas e físico-químicas relacionadas à atividade enzimática antioxidante, atividade respiratória, compostos fenólicos, ácido ascórbico, sólidos solúveis, acidez total titulável, porcentagem de massa fresca, firmeza, cor da casca e degradação dos frutos. Os tomates-cereja foram submetidos aos tratamentos de choque térmico com imersão em água quente a 45 ± 2 ºC nos tempos de 0, 5, 10, 15, 20 e 25 minutos. Após os tratamentos, os frutos foram divididos em dois grupos. O primeiro grupo foi armazenado a 20 ± 2 ºC e, em intervalos de 1, 3, 6, 9 e 12 dias, amostras foram retiradas e submetidas a análises de cor, firmeza, perda de massa, compostos fenólicos totais, flavonoides totais, ácido ascórbico e sólidos solúveis totais. O segundo grupo foi submetido às avaliações de atividade respiratória, produção de etileno e atividade enzimática de superóxido dismutase, catalase e ascorbato peroxidase, nos intervalos de tempo de 0, 2, 6, 24 e 48 horas de armazenamento à 20 ± 2 ºC. De acordo com os resultados, os frutos tratados com o choque térmico sofreram maior estresse respiratório a partir do sexto dia de armazenamento. Não houve diferença significativa entre os tratamentos para a firmeza, permanecendo a rigidez do fruto mesmo após 12º dias, e todos os tratamentos exibiram frutos com maior perda de massa, quando comparado ao controle. A aplicação dos tratamentos térmicos não alterou o teor de sólidos solúveis totais até o 6º dia, os tempos de exposição ao calor de 15 e 20 min tiveram maior efeito nos conteúdos de compostos fenólicos ao longo do armazenamento. Os frutos expostos ao calor expressaram conteúdos de flavonoides mais elevados do que o controle e não mostraram recuperação ou aumento na concentração de ácido ascórbico dos tomates-cereja em resposta aos tratamentos de choque térmico que pudessem indicar efeito supressor ao estresse. Com isso, apesar de possuir a capacidade de prolongar a vida útil do tomate-cereja, reduzindo a perda do fruto após o armazenamento, não se mostrou favorável para a sua utilização de forma a reduzir gastos para prolongar seu tempo de prateleira Tomate-cereja Calor Superóxido dismutase Catalase Ascorbato peroxidase Cherry tomato Heat Superoxide dismutase Catalase Ascorbate CIÊNCIAS AGRÁRIAS:AGRONOMIA
46	The role of redox-active iron metabolism in the selective toxicity of pharmacological ascorbate in cancer therapy Schoenfeld, Joshua David 01 May 2018 (has links) Pharmacological ascorbate, intravenous administration of high-dose vitamin C aimed at peak plasma concentrations ~ 20 mM, has recently re-emerged, after a controversial history, as a potential anti-cancer agent in combination with standard-of-care radiation and chemotherapy-based regimens. The anti-cancer effects of ascorbate are hypothesized to involve the auto-oxidation or metal-catalyzed oxidation of ascorbate to generate H2O2, and preclinical in vitro and in vivo studies in a variety of disease sites demonstrate the efficacy of adjuvant ascorbate. Furthermore, phase I clinical trials in pancreatic and ovarian cancer have demonstrated safety and tolerability in combination with chemotherapy and preliminary results suggest therapeutic efficacy. Both preclinical in vitro and in vivo studies as well as phase I clinical trials suggest a cell-intrinsic mechanism of selective toxicity of cancer cells as compared to normal cells; however, the mechanism(s) for cancer cell-selective toxicity remain unknown. The current study aims to investigate the preclinical therapeutic efficacy of pharmacological ascorbate in combination with standard cancer therapies in three novel disease sites: non-small cell lung cancer (NSCLC), glioblastoma multiforme (GBM), and some histological subtypes of sarcoma. In vitro experiments demonstrate cancer cell-selective susceptibility to pharmacological ascorbate as compared to normal cells of identical cell lineages. Furthermore, in vivo murine xenograft models of NSCLC, GBM, and fibrosarcoma demonstrate therapeutic efficacy of pharmacological ascorbate in combination with chemotherapy and/or radiation as compared to chemotherapy and/or radiation alone without any additional therapeutic toxicity. Additionally, a phase I clinical trial in GBM subjects demonstrates the safety and tolerability of ascorbate in combination with radiation and temozolomide therapy. Although not powered for efficacy, preliminary results suggest that ascorbate may be efficacious in these subjects (median survival 18.2 months vs. 14.6 months in historical controls), and, importantly, that ascorbate therapy may be independent of MGMT promoter methylation status (median survival 23.0 months vs. 12.7 months in historical controls with absent MGMT promoter methylation). Preliminary results from a phase II clinical trial of ascorbate in combination with carboplatin/paclitaxel chemotherapy in advanced stage NSCLC subjects also demonstrate promising preliminary results related to efficacy (objective response rate (ORR) 29% and disease control rate (DCR) 93% vs. historical control ORR 15-19% and DCR 40%). In addition to demonstrating the potential efficacy of pharmacological ascorbate in combination with standard anti-cancer therapies, this work demonstrates that the selective toxicity of ascorbate may be mediated by perturbations in cancer cell oxidative metabolism. Increased mitochondrial-derived O2- and H2O2 disrupts cellular iron metabolism, resulting in increased iron uptake via Transferrin Receptor and a larger intracellular labile iron pool. The larger pool of labile iron in cancer cells underlies the selective sensitivity of cancer cells to ascorbate toxicity through pro-oxidant chemistry with ascorbate-produced H2O2. This mechanism is further supported by the finding of increased levels of O2- and labile iron in patient lobectomy-derived NSCLC tissue as compared to adjacent normal fresh frozen tissue. Together, these studies demonstrate the feasibility, selective toxicity, tolerability, and potential efficacy of pharmacological ascorbate in NSCLC, GBM, and sarcoma therapy and propose that further investigations of tumor and systemic iron metabolism are required to determine if these alterations can be exploited to enhance therapeutic efficacy or serve as therapeutic biomarkers. cancer free radical biology glioblastoma multiforme iron metabolism non-small cell lung cancer pharmacological ascorbate
47	Sodium Ascorabe as a Potent Stimulator of Elastic Fiber Production Hyunjun, Kim 30 November 2011 (has links) The complicated problem of efficient stimulation of elastic fiber production in already developed human tissues has not yet been solved. The present study introduces sodium ascorbate (SA) as a stimulator of elastogenesis in cultures of different cell types including fibroblasts isolated from patients with elastopathy genetic diseases. We then elucidated mechanisms of elastogenic action of SA. SA exercises its net elastogenic effect only after being actively transported into the cell interior through two separate mechanisms. These are the “fast effect,” which reflects the greater stability of intracellular tropoelastin, and the “late effect,” which reflects the true enhancement of the elastin gene expression occurring after SA-induced activation of c-src tyrosine kinase and the consecutive phosphorylation of IGF-1 receptor, which triggers the downstream signals leading to activation of the elastin gene expression. In conclusion, for the first time we have established that SA is a potent stimulator of elastic fiber production. Elastic Fiber Production Sodium Ascorbate IGF-1 Receptor Loeys-Dietz Syndrome Williams-Beuren Syndrome 0307 0369 0571
48	Sodium Ascorabe as a Potent Stimulator of Elastic Fiber Production Hyunjun, Kim 30 November 2011 (has links) The complicated problem of efficient stimulation of elastic fiber production in already developed human tissues has not yet been solved. The present study introduces sodium ascorbate (SA) as a stimulator of elastogenesis in cultures of different cell types including fibroblasts isolated from patients with elastopathy genetic diseases. We then elucidated mechanisms of elastogenic action of SA. SA exercises its net elastogenic effect only after being actively transported into the cell interior through two separate mechanisms. These are the “fast effect,” which reflects the greater stability of intracellular tropoelastin, and the “late effect,” which reflects the true enhancement of the elastin gene expression occurring after SA-induced activation of c-src tyrosine kinase and the consecutive phosphorylation of IGF-1 receptor, which triggers the downstream signals leading to activation of the elastin gene expression. In conclusion, for the first time we have established that SA is a potent stimulator of elastic fiber production. Elastic Fiber Production Sodium Ascorbate IGF-1 Receptor Loeys-Dietz Syndrome Williams-Beuren Syndrome 0307 0369 0571
49	Studies of conducting polymer- modified electrodes and their application for electroanalysis / Elektrodų, modifikuotų laidžiais polimerais, tyrimas ir taikymas elektroanalizės tikslams Barzdžiuvienė, Kristina 30 December 2010 (has links) The main purpose of this work - to investigate patterns of electrochemical oxidation of ascorbic acid on polyaniline and poly(N-methylaniline) modified electrodes, in order to develop ascorbate-sensitive sensors. A detailed study of various factors affecting the aniline and N-methylaniline electrochemical polymerization and the resulting properties of PANI and PNMA layers was carried out for this purpose. Comparative study of modified electrodes in solutions of different acidity was performed and it was shown that PNMA had a better redox activity in slightly acidic and neutral solutions compared to polyaniline. The nature of amperometric response of modified electrodes to ascorbate was investigated and autocatalytic mechanism of ascorbate electrooxidation on PANI modified electrode was suggested. Using PANI and PNMA modified electrodes, prototypes of amperometric ascorbate sensors have been developed and their comparative studies were carried out. / Darbo tikslas - ištirti askorbo rūgšties elektrocheminės oksidacijos ant elektrodų, modifikuotų polianilinu ir poli(N-metilanilinu), dėsningumus, siekiant sukurti jautrius askorbatui jutiklius. Ištirta įvairių faktorių įtaka anilino ir N-metilanilino elektrocheminei polimerizacijai bei gautų PANI ir PNMA sluoksnių savybėms. Atlikti palyginamieji modifikuotų elektrodų tyrimai skirtingo pH tirpaluose ir parodyta, kad PNMA lyginant su polianilinu pasižymi geresniu aktyvumu silpnai rūgščiuose ir neutraliuose tirpaluose. Ištirtas modifikuotų elektrodų amperometrinio atsako į askorbatą pobūdis, ir pasiūlytas autokatalizinis askorbato elektrooksidacijos mechanizmas ant PANI modifikuoto elektrodo. Panaudojus PANI ir PNMA modifikuotus elektrodus, sukurti amperometrinių askorbato jutiklių prototipai ir atlikti jų palyginamieji tyrimai. Chemistry Ascorbate sensor Polyaniline Poly(N-methylaniline) Electrocatalysis Electroanalysis Askorbato jutiklis Polianilinas Poli(N-metilanilinas) Elektrokatalizė Elektroanalizė
50	Investigations into senescence and oxidative metabolism in gentian and petunia flowers Zhang, Shugai January 2008 (has links) Using gentian and petunia as the experimental systems, potential alternative post-harvest treatments for cut flowers were explored in this project. Pulsing with GA₃ (1 to 100 µM) or sucrose (3%, w/v) solutions delayed the rate of senescence of flowers on cut gentian stems. The retardation of flower senescence by GA₃ in both single flower and half petal systems was accompanied by a delay in petal discoloration. The delay in ion leakage increase or fresh weight loss was observed following treatment with 5 or 10 µM GA₃ of the flowers at the unopen bud stage. Ultrastructural analysis showed that in the cells of the lower part of a petal around the vein region, appearance of senescence-associated features such as degradation of cell membranes, cytoplasm and organelles was faster in water control than in GA₃ treatment. In particular, degeneration of chloroplasts including thylakoids and chloroplast envelope was retarded in response to GA₃ treatment. In the cells of the top part of a petal, more carotenoids-containing chromoplasts were found after GA₃ application than in water control. In petunia, treatment with 6% of ethanol or 0.3 mM of STS during the flower opening stage was effective to delay senescence of detached flowers. The longevity of isolated petunia petals treated with 6% ethanol was nearly twice as long as when they were held in water. Senescence-associated petal membrane damage, weight decline, ovary growth and decrease in protein and total RNA levels were counteracted in ethanol-treated petals. The accumulation of ROS, particularly superoxide and hydrogen peroxide, was also inhibited or delayed by ethanol application. Anti-senescence mechanisms, particularly the changes of oxidative / antioxidant metabolism involved in petal senescence, were investigated. In gentian, activities of AP and SOD but not POD in the GA₃-treated petals were significantly higher than those of the control. In isolated petunia petals, the decreased trends of antioxidative SOD and AP activities during senescence were apparently prevented in response to ethanol treatment although the levels of ascorbate and photo-protective carotenoids were not affected. Furthermore, by optimizing a range of critical PCR parameters such as primer combinations, cDNA concentrations and annealing temperatures, a reliable protocol has been established for quantifying the expression level of Cu-Zn SOD gene in petunia petals using SYBR Green I based real-time RT-PCR. A 228 bp gene fragment of Cu-Zn SOD was isolated from petunia (var. 'hurrah') using RT-PCR. It was found that the mRNA level (relative to 18S rRNA level) of Cu-Zn SOD decreased significantly after 6 days in water. However, there was about a 55-fold increase in Cu-Zn mRNA level after 6 days of ethanol treatment when compared to water-treated petals. Similarly, down-regulation of the mRNA level of glyceraldehyde-3-phosphate dehydrogenase (GAPDH) was also observed during senescence of petunia petals. Increased vase life of petunia petals by ethanol treatment was correlated with promotion of GAPDH expression by a factor of about 16 on day 6. Taking together, the anti-senescence effects of GA₃ and ethanol are at least partially associated with an increased efficiency of petal system utilizing ROS since the selected antioxidants were significantly maintained when compared to the corresponding values for the control. Petunia Gentian Senescence Flower Ethanol Gibberellic acid Reactive oxygen species Superoxide Hydrogen peroxide Antioxidant Superoxide dismutase Ascorbate peroxidase.

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