EFEITO DO TRATAMENTO TÉRMICO SOBRE A ATIVIDADE DE PEROXIDASE (POD) E POLIFENOLOXIDASE (PPO) EM MAÇÃ (Mallus comunis)

O extrato enzimático foi preparado a partir da polpa e casca da maçã de cultivares Fuji e Gala utilizando tampão fosfato de sódio 100mM, pH 5,0 como solução extratora. Dentre as análises determinou-se a concentração de proteína nos extratos enzimáticos concentrados de polpa e casca, sendo que o cultivar Fuji apresentou teores mais elevados em comparação ao cultivar Gala. Os tratamentos térmicos foram realizados nas temperaturas de 60, 65, 70 e 75°C por períodos que variaram de 1 a 10 minutos, sendo observado diminuição da atividade de POD e PPO com o aumento da temperatura e tempo; no entanto a POD não chegou a ser inativada em nenhum dos tratamentos realizados. A PPO foi inativada totalmente após 10 minutos de tratamento a 75°C. A eletroforese mostrou uma composição diferente de isoenzimas aniônicas e catiônicas da peroxidase.

Características da atividade da peroxidase de abacaxis (Ananas comosus (L.) Merrill) da cultivar IAC Gomo-de-mel e do clone IAC-1

No presente trabalho foram estudadas as características bioquímicas das peroxidases de novos abacaxis, cultivar IAC Gomo-demel e clone IAC-1. As peroxidases dos sucos destes abacaxis apresentaram atividade ótima entre 45ºC e 50°C e entre 50°C e 55°C, respectivamente. Estas peroxidases apresentaram atividade ótima em pH 4,5 e mostraram-se estáveis na faixa de pH 4,0 a 9,0, retendo, após 24 horas de incubação a 50ºC, mais de 80% da atividade inicial. Foi observada regeneração parcial da atividade da peroxidase, após tratamento a 75ºC por 10 minutos. As peroxidases dos sucos dos abacaxis estudados foram inativadas, após tratamento a 90ºC por 2 minutos.

Peroxidase (POD) e polifenoloxidase (PPO) em polpa de goiaba (Psidium guajava R.)

A peroxidase E.C. 1.11.1.7 (POD) e a polifenoloxidase E.C. 1.10.3.1 (PPO) foram extraídas da polpa de goiaba. Os extratos foram preparados utilizando-se a polpa da goiaba e solução tampão fosfato de sódio 100mM com pH variando de 6,0 a 7,0 em intervalos de 0,1. Foi determinada a atividade enzimática da peroxidase e da polifenoloxidase desses extratos, a fim de se observar o melhor pH para a extração de cada enzima. O pH 6,3 foi considerado o melhor para a extração da POD da polpa de goiaba, enquanto que para PPO, o pH foi 6,8. Os extratos brutos de POD e PPO foram submetidos a temperaturas de 60 °C, 65 °C, 70 °C, 75 °C e 80 °C por um período de 0 a 10 min. Os resultados demonstraram um decréscimo da atividade enzimática nos extratos com o aumento da temperatura e do tempo. No entanto, a total inativação não foi atingida o que sugere a presença de isoenzimas termoresistentes.

Obtenção de nova fonte de peroxidase de folha de Copaifera langsdorffii Desf. com alta atividade

Objetivou-se neste trabalho extrair peroxidase de folha de Copaifera langsdorffii (COP), medir sua atividade, compará-la com a peroxidase de raiz forte (Horseradish peroxidase - HRP) e determinar o pH ótimo, a melhor solução extratora e o efeito de aditivos sobre a atividade da COP. Os resultados mostraram que a COP atingiu 81,6% da atividade de HRP e a faixa de pH ótimo foi de 5,5 a 6,0. A melhor solução extratora da enzima foi o tampão fosfato de sódio 50 mM, pH 6,0 e o melhor aditivo foi o PVPP. Concluindo, a COP apresenta atividade mais alta que outras peroxidases de diferentes fontes citadas na literatura.

Extração e caracterização parcial de peroxidase de folhas de Copaifera langsdorffii Desf.

Em recentes publicações têm sido descritos vários processos para obtenção de peroxidases. O propósito deste trabalho foi extrair peroxidase de folhas de Copaifera langsdorffii e caracterizar parcialmente a enzima usando planejamento experimental e teste univariado, para confirmação dos resultados obtidos por planejamento experimental. A atividade da peroxidase foi medida usando sistema guaiacol: peróxido de hidrogênio. A peroxidase isolada apresentou 81,6% da atividade da horseradish peroxidase e é de fácil obtenção, a partir de folhas de uma árvore abundante em todo o país. A peroxidase semi-purificada (COP) foi obtida pela precipitação do extrato bruto com acetona 65% (v.v-1), produzindo o pó cetônico. A COP apresentou atividade ótima na faixa de pH 5,0 a 7,0 e temperatura de 5 a 45 °C, com atividade máxima em pH 6,0 e 35 °C. A enzima mostrou-se estável em temperaturas inferiores a 50 °C e pH entre 4,5 e 9,0, por até 24 horas. A peroxidase foi inativada após 4 horas a 80 °C e após 3 minutos a 96 °C. Esta enzima demonstra possibilidade para ser usada como reagente para diagnósticos, construção de biossensores e outros métodos analíticos em vários campos da ciência.

Atividades das enzimas peroxidase (POD) e polifenoloxidase (PPO) nas uvas das cultivares benitaka e rubi e em seus sucos e geléias

A peroxidase e a polifenoloxidase estão relacionadas com o escurecimento de frutas, por isso o controle das atividades destas enzimas é de grande importância para a tecnologia de alimentos. Neste trabalho estudaram-se as atividades dessas enzimas nas uvas frescas das cultivares Benitaka e Rubi, bem como as suas termoestabilidades e as suas atividades enzimáticas residuais no suco e nas geléias (extra e light). Foi também avaliada a qualidade microbiológica dos produtos elaborados. As atividades da enzima POD, tanto da fração solúvel quanto da ionicamente ligada, foram semelhantes nas uvas das duas variedades, Benitaka e Rubi. A atividade da enzima polifenoloxidase foi maior na variedade Rubi. As operações de cocção e pasteurização foram mais eficientes para baixar as atividades enzimáticas residuais da POD e PPO quando aplicadas às geléias de uva, em comparação com o suco. Embora não foram suficientes para a total inativação enzimática, essas operações reduziram-nas consideravelmente, e foram eficientes para garantir seguridade microbiológica dos produtos, geléias e suco.

Polyphenoloxidase and peroxidase in avocado pulp (Persea americana Mill.)

The aim of the present investigation was to evaluate the enzymatic activity of polyphenoloxidase and peroxidase in avocado pulps, from the Northwest area of Paraná-Brazil, in order to compare the varieties on their enzymatic activity for both, minimum and industrial processing. Enzymatic extracts were prepared from avocado pulp of Choquete, Fortuna and Quintal varieties, in green and ripe maturation stage. Thermal treatment was applied with temperatures 60, 65, 70, 75 and 80 °C. The enzymatic activities were determined by using spectrophotometer. A decline of polyphenoloxidase activity was observed in all of the varieties when both, temperature and time increased. Total inactivation of enzymes was not observed in the largest temperature. Fortuna and Choquete variety showed the lowest polyphenoloxidase activity in the ripe stage. Soluble peroxidase showed activity in the green stage, whereas, ionically bound peroxidase activity increased with the change from green to ripe maturation stage in Choquete variety.

Deoxynivalenol (DON) degradation and peroxidase enzyme activity in submerged fermentation

This work aims to evaluate deoxynivalenol degradation by Aspergillus oryzae and Rhizopus oryzae in a submerged fermentation system and to correlate it to the activity of oxydo-reductase enzymes. The submerged medium consisted of sterile distilled water contaminated with 50 μg of DON and 4 × 10(6) spore.mL-1 inoculum of Aspergillus oryzae and Rhizopus oryzae species, respectively in each experiment. Sampling was performed every 24 hours for monitoring the peroxidase specific activity, and every 48 hours for determining mycotoxin levels. Results showed that the fungi species were able to decrease DON levels as the peroxidase activity increased. The 48 hours fermentation interval presented the highest peroxidase specific activity (ΔABS/minute.μg.protein-1), 800 and 198, while the highest DON degradation velocity was 10.8 and 12.4 ppb/hour, respectively in both cases for Rhizopus oryzae and Aspergillus oryzae.

Thermal inactivation of polyphenoloxidase and peroxidase in Jubileu clingstone peach and yeast isolated from its spoiled puree

The thermal inactivation of yeast isolated from spoiled Jubileu peach puree and that of polyphenoloxidase (PPO) and peroxidase (POD) in cv. Jubileu, which is widely cultivated in southern Rio Grande do Sul state, Brazil, were studied. PPO and POD were extracted using the protein powder method and submitted to partial purification by precipitation followed by dialysis. The enzymatic activity was determined measuring the increase in absorbance at 420 nm for PPO and 470 nm for POD. The yeast used in this investigation was isolated from spoiled Jubileu peach puree at 22 °Brix, with total initial microbial count of 22 × 10² UFCmL- 1. Stock cultures were maintained on potato dextrose agar (PDA) slants at 4 °C and pH 5 for later use for microbial growth. In all cases, kinetic analysis of the results suggests that the thermal inactivation was well described by a first-order kinetic model, and the temperature dependence was significantly represented by the Arrhenius law. Both enzymes were affected by heat denaturation, and PPO was more thermostable. PPO was also more thermosTable than the yeast isolated from peach puree. The D60-values were 1.53 and 1.87 min for PPO and yeast isolated from spoiled Jubileu peach puree, respectively.

Peroxidase activity and sensory quality of ready to cook mixed vegetables for soup: combined effect of biopreservatives and refrigerated storage

Enzymatic senescence processes and browning of fresh cut vegetables negatively affect their sensory properties and nutritional value and finally result in the rejection of affected products by consumers. In order to prevent quality decay, the combined effects of natural antioxidants and storage temperature on peroxidase activity and sensory attributes (overall visual quality, browning and odor) of individual and mixed vegetables for soup (butternut squash, leek and celery) were evaluated. Fresh cut vegetables were treated with antioxidant solutions as tea tree essential oil (15 μl/mL), propolis extract (15 μl/mL) and gallic acid (2 mg/mL) and stored at optimal (5 °C) and abusive (15 °C) temperature for a maximum of 14 days. The application of natural preservatives, plus optimal storage conditions, exerted significant inhibitory effects in peroxidase activity of squash, celery and mixed vegetables throughout the storage. Furthermore, propolis treatment applied on mixed vegetables retarded browning appearance and preserved the visual quality for a longer period when compared to untreated product.

Cytosolic calcium levels and stress induced y-amino butyrate synthesis in asparagus mesophyll cells

Numerous investigations have demonstrated large increases in y-amino butyrate (GABA) levels in response to a variety of stresses such as touch or cold shock (Wallace et ale 1984) Circumstantial evidence indicating a role of Ca2 + in these increases includes elevated Ca2+ levels in response to touch and cold shock (Knight et ale 1991), and the demonstration of a calmodulin binding domain on glutamate decarboxylase (GAD), the enzyme responsible for GABA synthesis (Baum et al 1993) In the present study the possible role of Ca2+ and calmodulin in stimulation of GAD and subsequent GABA accumulation was examined using asparagus mesophyll cells. Images of cells loaded with the Ca2+ indicator Fluo-3 revealed a rapid and transient increase in cytosolic Ca2+ in response to cold shock. GABA levels increased by 106% within 15 min. of cold shock. This increase was inhibited 70% by the calmodulin antagonist W7, and 42% by the Ca2+ channel blocker La3+.. Artificial elevation of intracellular Ca2+ by the Ca2+ionophore A23187 resulted in an 61% increase in GABA levels. Stimulation of GABA synthesis by ABA resulted in an 83% increase in GABA levels which was inhibited 55% by W7. These results support the hypothesis that cold shock stimulates Ca2+ entry into the cytosol of the cells which results in Ca2+/calmodulin mediated activation of GAD and consequent GABA synthesis.

The production of 4-adminobutyrate in response to treatments reducing cytosolic pH and the regulation of intracellular pH

GABA (4-aminobutyrate) is synthesized through the decarboxylation of LGlu- (L-Glu-+ H+ ---> GABA + C02), and compared to many free amino acids is present in high concentrations in plant cells. GABA levels rise rapidly and dramatically in response to varied stress conditions including anaerobiosis. Recent papers suggest that GABA production and associated H+ consumption are parts of a metabolic pH-stat mechanism which ameliorates the intracellular pH decline associated with anaerobiosis or other treatments. To test this hypothesis GABA production and efflux have been measured in isolated Asparagus sprengeri cells in response to three treatments which potentially cause intracellular acidification. Acid loads were imposed using 60 min of (i) anaerobiosis, (ii) H+/LGlu- cotransport, and (iii) treatment with permeant weak acids (butyric, acetic and propionic). Both intra- and extracellular GABA concentrations increased more than 100% after anaerobiosis, almost 1000% after H+/L-Glu- cotransport (light or dark) and almost 5000/0 after addition of 5 mM butyric acid at pH 5.0. HPLC analysis of amino acids indicates that as GABA concentrations increased in response to butyric acid addition, glutamate concentrations decreased. Time-course studies demonstrated that added butyric acid stimulates GABA production by 2800/0 within 15 seconds. A fluorescent determination of cytosolic pH indicates that addition of butyric or other weak acids resulted in a rapid reduction in cytosolic pH of 0.6 pH units. The half time for the response to butyric acid addition is 2.1 seconds, indicating that the decline in cytosolic pH is rapid enough to account for the rapid stimulation of GABA production. The acid load in response to butyric acid addition was assayed by measurements of 14C-butyric acid uptake. Calculations indicate that GABA production accounted for 45% of the imposed acid load. The biological significance of GABA efflux is not yet understood. The results support the original hypothesis suggesting a role for GABA production in cellular pH regulation.

The regulation of oat coleoptile phosphoenolpyruvate carboxylase and malic enzyme by Hâ ½ and metabolites : kinetic evidence for and against a cytosolic pH-stat

Phosphoenolpyruvate carboxylase (PEPC) and malic enzyme activities in soluble protein extracts of Avena coleoptiles were investigated to determine whether their kinetics were consistent with a role in cytosol pH regulation. Malic enzyme activity was specific for NADP+ and Mn2+. Maximal labelled product formation from [14C]-substrates required the presence of all coenzymes, cofactors and substrates. Plots of rate versus malate concentration, and linear transformations there- 2 of, indicated typical Michaelis-Menten kinetics at non-saturating malate levels and substrate inhibition at higher malate levels. pH increases between 6.5 and 7.25 increased near-optimal activity, decreased the degree of substrate inhibition and the Kmapp(Mn2+) but did not affect the Vmax or Kmapp(malate). Transformed data of PEPC activity demonstrated non-linear plots indicative of non-Michaelian kinetics. pH increases between 7.0 and 7.6 increased the Vmax and decreased the Km app (Mg2+) but did not affect the Kmapp(PEP). Various carboxylic acids and phosphorylated sugars inhibited PEPC and malic enzyme activities, and these effects decreased with pH increases. Metabolite inhibited malic enzyme activity was non-competitive and resulted mainly from Mn2+ chelation. In contrast, metabolite inhibited PEPC activity was unique for each compound tested, being variously dependent on the PEP concentration and the pH employed. These results indicate that fluctuations in pH and metabolite levels affect PEPC and malic enzyme activities similarly and that 3 the in vitro properties of PEPC are consistent with its proposed role in a pH-stat, whereas the in vitro properties of the malic enzyme cannot be interpreted in terms of a role in pH regulation.

Novel glutathione disulfide transferase function of CC-glutaredoxins involved in disease resistance and flower development

Glutaredoxins are oxidoreductases capable of reducing protein disulfide bridges and glutathione mixed disulfides through the process of deglutathionylation and glutathionylation. Lately, redox-mediated modifications of functional cysteine residues of TGA1 and TGA8 transcription factors have been postulated. Namely, GRX480 and ROXY1 glutaredoxins have been previously shown to interact with TGA proteins and have been suggested to regulate redox state of these proteins. TGA1, together with TGA2, is involved in systemic acquired resistance (SAR) establishment in the plant Arabidopsis thaliana through PR1 (Pathogenesis related 1) gene activation. They both form an enhanceosome complex with the NPR1 protein (non-expressor of pathogenesis related gene 1) which leads to PR1 transcription. Although TGA1 is capable of activating PR1 transcription, the ability of the TGA1 NPR1 enhanceosome complex to assembly is based on the redox status of TGA1. We identified GRX480 as a glutathionylating enzyme that catalyzes the TGA1 glutathione disulfide transferase reaction with a Km of around 20μM GSSG (oxidized glutathione). Out of four cysteine residues found within TGA1, C172 and C266 were found to be glutathionylated by this enzyme. We also confirmed TGA1 glutathionylation in vivo and showed that this modification takes place while TGA1 is associated with the PR1 promoter enzymatically via GRX480. Furthermore, we show that glutathionylation via GRX480 abolishes TGA1's interaction with NPR1 and consequently prevents the TGA1-NPR1 transcription activation of PR1. When glutathionylated, TGA1 is recruited to the PR1 promoter and acts as a repressor. Therefore, glutathionylation is a mechanism that prevents TGA1 NPR1 interaction, allowing TGA1 to function as a repressor of PR1 transcription. Surprisingly, GRX480 was not able to deglutathionylate proteins demonstrating the irreversible nature of the reaction. Moreover, we demonstrate that other members of CC-class glutaredoxins, namely ROXY1 and ROXY2, can also catalyze protein glutathionylation. The TGA8 protein was previously shown to interact with NPR1 analogs, BOP1 and BOP2 proteins. However, unlike the case of TGA1 NPR1 interaction, here we demonstrate that TGA8-BOP1 interaction is not redox regulated and that TGA8 glutathionylation by ROXY1 and ROXY2 enzymes does not abolish this interaction in vitro. However, TGA8 glutathionylation results in TGA8 oligomer disassembly into smaller complexes and monomers. Our results suggest that CC-Grxs are unable to reduce mixed disulfides, instead they efficiently catalyze the opposite reaction which distinguishes them from traditional glutaredoxins. Therefore, they should not be classified as glutaredoxins but as protein glutathione disulfide transferases.

Caractérisation et étude de la régulation d’une isoforme cytosolique de peroxyrédoxine chez les solanacées

Les peroxyrédoxines (PRXs) forment une famille de peroxydases communes à tous les organismes vivants et ubiquitaires dans la cellule. Leur particularité provient d’un ou deux résidus cystéines accomplissant un cycle d’oxydo-réduction à l’aide d’un donneur d’électron. Ces protéines thiols sensibles au potentiel redox sont impliquées dans le mécanisme de détoxification du H2O2, une molécule oxydante induite lors de situations de stress. Les PRXs pourraient être induites par le stress et régulées par phosphorylation. En effet, des expérimentations in vitro ont démontré que la nucléoside diphosphate kinase 1 (NDPK1) a la capacité de phosphoryler une PRX cytosolique de pomme de terre. Ce mémoire décrit les travaux expérimentaux effectués pour caractériser la fonction de la PRX. Pour cela, le clonage d’une isoforme a été effectué, suivi d’une caractérisation biochimique et d’une étude d’expression de la protéine. Les données de séquençage révèlent qu’il s’agit d’une PRX de type II phylogénétiquement liée aux PRXs cytosoliques. L’ADNc codant pour cette peroxyrédoxine (PRX1) a été cloné chez Solanum chacoense. Une protéine recombinante portant une étiquette (6xHis) en N-terminale a été produite. Des essais enzymatiques ont confirmé la fonction antioxydante de la protéine recombinante et un anticorps polyclonal a été généré chez le lapin puis utilisé en conjonction avec un anticorps anti-NDPK1 pour déterminer les patrons d’expression généraux de ces protéines chez Solanum lycopersicum et Solanum tuberosum lors de situations de stress. Les données démontrent que les deux protéines sont généralement co-exprimées mais pas co-régulées et que la PRX1 est induite en certaines situations de stress.