Methylgyoxal signalling in Phaseolus vulgaris under phosphate deficiency

Gcanga, Esihle

January 2020

Masters of Science / In this study, we observed that phosphate (P) deficiency stunted plant growth and produced plants with poor morphological characteristics (yellow and small leaves). Furthermore, we treated plants with 0.8 mM (control) and 0.02 mM P (deficient) in addition to 6 μM methylglyoxal (MG) and we observed that the plants treated with MG had a higher germination, and better morphological characteristics (the leaves were more dark green and bigger in size) compared to the P deficient plants. However, we also observed that the P deficient plants treated with MG had low levels of both O2- and H2O2 and this could be a possible reason for the improved growth and morphological characteristics. In contrast, the P deficient plants not treated with MG had high levels of O2- and H2O2 which could be the possible reason for the observed cell death. We also performed biochemical assays including superoxide dismutase, ascorbate peroxidase, malondialdehyde content, ascorbic acid content, catalase, and most of the assays showed high levels of reactive oxygen species (ROS) and low levels of antioxidant activities in plants not treated with MG while high levels of antioxidant activities and low levels of ROS were observed in plants treated with exogenous MG. Since nitric oxide (NO) is also known to be a signalling molecule, we did a NO assay and observed that NO content increased under low exogenous doses of MG. From our findings we came to a hypothesis that MG modulates P deficiency stress in P. vulgaris through NO signalling or it might be that NO and MG work in tandem to modulate signalling pathways under P deficiency. Finally, we looked at the nutrient profile and the results showed that while there was a poor nutrient profile generally under P deficiency, there was an improvement in nutrient profile when MG was administered at low doses.

Antioxidant enzymes

Ascorbate peroxidase

Biomass

Cell death

Heavy metal

Hydrogen peroxide

Lipid peroxidation

Methylglyoxal

Nitric oxide

P. vulgaris

Phosphate deficiency

Reactive oxygen species

Superoxide dismutase

Superoxide

Anpassung antioxidativer Systeme an Licht und Temperatur: / holzige und krautige Pflanzen im Vergleich / Acclimation of antioxidative systems to light and temperature: / woody and herbaceous plants in comparison

Peltzer, Detlef

28 March 2001

No description available.

570 Biowissenschaften

Biologie

Economic Sciences

Ascorbat

antioxidative Systeme

Ascorbatperoxidase

Monodehydroascorbatradikalreduktase

Glutathionreduktase

Fagus sylvatica

Coleus blumei

ascorbate

antioxidative systems

ascorbate peroxidase

monodehydroascorbate radical reductase

glutathione reductase

Fagus sylvatica

Coleus blumei

35.74

f kls WI 000

The role of p-coumaric acid on physiological and biochemical response of chia seedling under salt stress

Nkomo, Mbukeni Andrew

January 2020

Philosophiae Doctor - PhD / The role of phenolic acids in mitigating salt stress tolerance have been well documented. However, there are contradicting reports on the effect of exogenously applied phenolic acids on the growth and development of various plants species. A general trend was observed where phenolic acids were shown to inhibit plant growth and development, with the exception of a few documented cases. One of these such cases is presented in this thesis. This study investigates the role of exogenously applied p-coumaric acid (p-CA) on physio-biochemical and molecular responses of chia seedlings under salt stress. This study is divided into three parts. Part one (Chapter 3) focuses on the impact of exogenous p-coumaric acid on the growth and development of chia seedlings. In this section, chia seedlings were supplemented with exogenous p-CA and the various biochemical and plant growth parameters were measured. The results showed that exogenous p-CA enhanced the growth of chia seedlings. An increase in chlorophyll, proline and superoxide oxide contents were also observed in the p-CA treatment relative to the control. We suggested that the increase in chia seedling growth could possibly be via the activation of reactive oxygen species-signalling pathway involving O2− under the control of proline accumulation (Chapter 3). Given the allopathy, nature of p-coumaric acid it is noteworthy that the response observed in this study may be species dependent, as contrasting responses have been reported in other plant species. Part two (Chapter 4) of this study investigates the influence of piperonylic acid (an inhibitor of endogenous p-coumaric acid) on the growth and development of chia seedlings. In trying to illustrate whether p-CA does play a regulatory role in enhancing pseudocereal plant growth, we treated chia seedlings with the irreversible inhibitor of C4H enzyme, to inhibit the biosynthesis of endogenous p-CA. In this section, chia seedlings were treated with piperonylic acid and changes in plant growth, ROS-induced oxidative damage, p-CA content and antioxidant capacity was monitored. Inhibition of endogenous p-CA restricted chia seedling growth by enhancing ROS-induced oxidative damage as seen for increased levels of superoxide, hydrogen peroxide and the extent of lipid peroxidation. Although an increase in antioxidant activity was observed in response to piperonylic acid, this increase was not sufficient to scavenge the ROS molecules to prevent oxidative damage and ultimate cellular death manifested as reduced plant growth. The results presented in this section support our hypothesis that p-CA play an important regulatory role in enhancing chia seedling growth and development as shown in Chapter 3. Part three (Chapter 5) seeks to identify and functionally characterise p-coumaric acid induced putative protein biomarkers under salt stress conditions in chia seedlings. Previous studies have shown that p-CA reversing the negative effect caused by NaCl-induced salt stress. While these studies were able to demonstrate the involvement of p-CA in promoting plant growth under salt stress conditions, they focussed primarily on the physiological aspect, which lacks in-depth biochemical and molecular analysis (ionomic and proteomic data) which could help in detecting the genes/proteins involved in salt stress tolerance mechanisms. A comparative ionomics and proteomic study was conducted, with the aim of elucidating the pivotal roles of essential macro elements and/or key protein markers involved in p-CA induced salt stress tolerance in chia seedlings. With the exception of Na, all the other macro elements were decreased in the salt treatment. Contrary to what was observed for the salt treatment most of the macro elements were increased in the p-CA treatment. However, the addition of exogenous p-CA to salt stressed seedlings showed an increase in essential macro elements such as Mg and Ca which have been shown to play a key role in plant growth and development. In the proteomic analysis we identified 907 proteins associated with shoots across all treatments. Interestingly, only eight proteins were conserved amongst all treatments. A total of 79 proteins were unique to the p-CA, 26 to the combination treatment (NaCl + p-CA) and only two proteins were unique to the salt stress treatment. The unique proteins identified in each of the treatments were functionally characterised to various subcellular compartments and biological processes. Most of the positively identified proteins were localised to the chloroplast and plays key roles in photosynthesis, transportation, stress responses and signal transduction pathways. Moreover, the protein biomarkers identified in this study (especially in the p-CA treatment) are putative candidates for genetic improvement of salt stress tolerance in plants.

Antioxidant enzymes

Ascorbate peroxidase

Chia

Chlorophyll

Glycine betaine

Lipid peroxidation

p-Coumaric acid

Peroxidase

Photosynthesis

Piperonylic acid

Plant proteomics

Proline

Pseudocereals

Reactive oxygen species

Salt stress

Superoxide radical

Superoxide dismutase

Osmoprotectant

Oxidative stress

Suprimento de enxofre e o alívio do estresse causado pelo bário em capim tanzânia / Sulfur supply and alleviation of the stress caused by barium in Tanzania guineagrass

Arnon Afonso de Souza Cardoso

24 August 2016

Elevada disponibilidade de bário (Ba) no meio de cultivo pode resultar em severa toxidez nas plantas. A toxidez causada pelo metal pesado nas plantas pode ser amenizada pelo fornecimento de nutrientes, particularmente o enxofre (S). Objetivou-se avaliar os parâmetros produtivos, sintomas visuais, estado nutricional, índice SPAD, indicadores de estresse (malondialdeído, peróxido de hidrogênio e prolina) e a atividade de enzimas do sistema antioxidante (glutationa redutase, superóxido dismutase, catalase, ascorbato peroxidase e guaiacol peroxidase) do capim tanzânia (Panicum maximum Jacq. cv. Tanzânia) cultivado com combinações de doses de S e de Ba na solução nutritiva, em casa de vegetação, em dois ciclos de crescimento das plantas. As plantas foram submetidas às combinações de cinco doses de S (0,1; 1,0; 1,9; 2,8 e 3,7 mmol L-1) com cinco doses de Ba (0,0; 2,5; 5,0; 10,0 e 20,0 mmol L-1), utilizando esquema fatorial fracionado (52), em blocos ao acaso, com seis repetições e seis plantas por unidade experimental. Os parâmetros produtivos e o estado nutricional das plantas foram severamente afetados pelas combinações de S e Ba em ambos os ciclos de crescimento. O aumento na dose de Ba na solução nutritiva prejudicou acentuadamente o crescimento e o estado nutricional das plantas, principalmente na área foliar, e nos nutrientes potássio e magnésio, enquanto o aumento da dose de S amenizou o efeito tóxico do metal. Maiores concentrações de malondialdeído foram observadas nas plantas que apresentaram maior acúmulo do metal pesado. As atividades das enzimas glutationa redutase, catalase e ascorbato peroxidase foram mais altas nas plantas cultivadas com baixo fornecimento de S, enquanto a atividade da guaiacol peroxidase foi aumentada com incremento das doses de Ba e de S. / High barium (Ba) availability in growth medium can cause severe toxicity in plants. Nutrient supply may mitigate heavy metal phytotoxicity, especially the sulphur (S) supply. The study was carried out to evaluate the plant growth, visual symptoms, nutritional status, indicators of stress (malondialdehyde, hydrogen peroxide and proline) and activities of the antioxidant enzymes (glutathione reductase, superoxide dismutase, catalase, ascorbate peroxidase and guaiacol peroxidase) in Tanzania guineagrass (Panicum maximum Jacq. cv. Tanzania) grown with combinations of S rates and Ba rates in nutrient solution, in a greenhouse, for two growth periods. Plants received nutrient solutions where combinations of five S rates (0.1, 1.0, 1.9, 2.8 and 3.7 mmol L-1) with five Ba rates (0.0, 2.5, 5.0, 10.0 and 20.0 mmol L-1) were used in a fractionated factorial (52), in randomized block design, with six replications and six plants per experimental unit. Plant production and nutritional status were highly affected by combinations of S and Ba rates, in both growth periods. Increase on Ba rates impaired growth, mainly on leaf area production. Barium rates impaired nutritional status, mainly on potassium and calcium, while increasing on S rates alleviated Ba toxic effects. High concentrations of malondialdehyde was observed in plants with increase of Ba application. The activities of catalase and ascorbate peroxidase were high in plants grown with low S availability, while guaiacol peroxidase activity was enhanced by increasing Ba and S rates in the nutrient solution.

Panicum maximum

Ascorbato peroxidase

Catalase

Crescimento

Estado nutricional

Estresse oxidativo

Glutationa redutase

Guaiacol peroxidase

Índice SPAD

Malondialdeído

Peróxido de hidrogênio

Prolina

Sintomas de toxidez

Superóxido dismutase

Panicum maximum

Ascorbate peroxidase

Catalase

Glutathione reductase

Guaiacol peroxidase

Hydrogen peroxide

Malondialdehyde

Nutritional status

Oxidative stress

Plant growth

Proline

SPAD value

Superoxide dismutase

Toxicity symptoms

Suprimento de enxofre e o alívio do estresse causado pelo bário em capim tanzânia / Sulfur supply and alleviation of the stress caused by barium in Tanzania guineagrass

Cardoso, Arnon Afonso de Souza

24 August 2016

Elevada disponibilidade de bário (Ba) no meio de cultivo pode resultar em severa toxidez nas plantas. A toxidez causada pelo metal pesado nas plantas pode ser amenizada pelo fornecimento de nutrientes, particularmente o enxofre (S). Objetivou-se avaliar os parâmetros produtivos, sintomas visuais, estado nutricional, índice SPAD, indicadores de estresse (malondialdeído, peróxido de hidrogênio e prolina) e a atividade de enzimas do sistema antioxidante (glutationa redutase, superóxido dismutase, catalase, ascorbato peroxidase e guaiacol peroxidase) do capim tanzânia (Panicum maximum Jacq. cv. Tanzânia) cultivado com combinações de doses de S e de Ba na solução nutritiva, em casa de vegetação, em dois ciclos de crescimento das plantas. As plantas foram submetidas às combinações de cinco doses de S (0,1; 1,0; 1,9; 2,8 e 3,7 mmol L-1) com cinco doses de Ba (0,0; 2,5; 5,0; 10,0 e 20,0 mmol L-1), utilizando esquema fatorial fracionado (52), em blocos ao acaso, com seis repetições e seis plantas por unidade experimental. Os parâmetros produtivos e o estado nutricional das plantas foram severamente afetados pelas combinações de S e Ba em ambos os ciclos de crescimento. O aumento na dose de Ba na solução nutritiva prejudicou acentuadamente o crescimento e o estado nutricional das plantas, principalmente na área foliar, e nos nutrientes potássio e magnésio, enquanto o aumento da dose de S amenizou o efeito tóxico do metal. Maiores concentrações de malondialdeído foram observadas nas plantas que apresentaram maior acúmulo do metal pesado. As atividades das enzimas glutationa redutase, catalase e ascorbato peroxidase foram mais altas nas plantas cultivadas com baixo fornecimento de S, enquanto a atividade da guaiacol peroxidase foi aumentada com incremento das doses de Ba e de S. / High barium (Ba) availability in growth medium can cause severe toxicity in plants. Nutrient supply may mitigate heavy metal phytotoxicity, especially the sulphur (S) supply. The study was carried out to evaluate the plant growth, visual symptoms, nutritional status, indicators of stress (malondialdehyde, hydrogen peroxide and proline) and activities of the antioxidant enzymes (glutathione reductase, superoxide dismutase, catalase, ascorbate peroxidase and guaiacol peroxidase) in Tanzania guineagrass (Panicum maximum Jacq. cv. Tanzania) grown with combinations of S rates and Ba rates in nutrient solution, in a greenhouse, for two growth periods. Plants received nutrient solutions where combinations of five S rates (0.1, 1.0, 1.9, 2.8 and 3.7 mmol L-1) with five Ba rates (0.0, 2.5, 5.0, 10.0 and 20.0 mmol L-1) were used in a fractionated factorial (52), in randomized block design, with six replications and six plants per experimental unit. Plant production and nutritional status were highly affected by combinations of S and Ba rates, in both growth periods. Increase on Ba rates impaired growth, mainly on leaf area production. Barium rates impaired nutritional status, mainly on potassium and calcium, while increasing on S rates alleviated Ba toxic effects. High concentrations of malondialdehyde was observed in plants with increase of Ba application. The activities of catalase and ascorbate peroxidase were high in plants grown with low S availability, while guaiacol peroxidase activity was enhanced by increasing Ba and S rates in the nutrient solution.

Panicum maximum

Panicum maximum

Ascorbate peroxidase

Ascorbato peroxidase

Catalase

Catalase

Crescimento

Estado nutricional

Estresse oxidativo

Glutathione reductase

Glutationa redutase

Guaiacol peroxidase

Guaiacol peroxidase

Hydrogen peroxide

Índice SPAD

Malondialdehyde

Malondialdeído

Nutritional status

Oxidative stress

Peróxido de hidrogênio

Plant growth

Prolina

Proline

Sintomas de toxidez

SPAD value

Superoxide dismutase

Superóxido dismutase

Toxicity symptoms