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  • Ескіз
    Документ
    Образование экзополисахарида этаполана при выращивании Аcinetobacter sp. ИМВ В-7005 на смеси фумарата и глюкозы
    (2007) Пирог, Татьяна Павловна; Высятецкая, Надежда Владимировна; Корж, Юлия Николаевна
    Установлена возможность интенсификации синтеза микробного экзополисахарида (ЭПС) этаполана (продуцент - Acinetobacter sp. ИМВ В-7005) на смеси фумарата (энергетически избыточный субстрат) и глюкозы (энергетически дефицитный субстрат). Введение фумарата натрия (калия) в среду с глюкозой в молярном соотношении 4:1 дало возможность увеличить количество синтезированных ЭПС в 1.3-2.2 раза, их выход по отношению к биомассе – в 1.3-2 раза по сравнению с выращиванием на моносубстратах. Максимальная трансформация углерода обоих субстратов в ЭПС (до 53 %) наблюдалась при соотношении углерод/азот в среде культивирования, равном 70.5, и использовании посевного материала, выращенного на моносубстрате глюкозе. Our studies enabled us to intensify the synthesis of the microbial exopolysaccharide (EPS) ethapolan produced by Acinetobacter sp. IMV B-7005 grown on a mixture of fumarate (an energy-excessive substrate) and glucose (an energy-deficient substrate). Supplementing glucose-containing medium with sodium (potassium) fumarate at a molar ratio of 4 : 1 resulted in a 1.3–2.2-fold increase of the EPS amount synthesized and in a 1.3–2-fold increase of the EPS yield relative to the biomass compared to cultivation on monosubstrates. The conversion of the carbon of both substrates to EPS was the highest if the carbon/nitrogen ratio in the cultivation medium was 70.5 and inoculum grown on glucose monosubstrate was used.
  • Ескіз
    Документ
    Особенности синтеза экзополисахарида этаполана на смеси энергетически дефицитных ростовых субстратов
    (2007) Пирог, Татьяна Павловна; Высятецкая, Надежда Владимировна; Корж, Юлия Николаевна
    Показана возможность интенсификации синтеза микробного экзополи-сахарида этаполана (продуцент - Acinetobacter sp. В-7005) на смеси энергетически дефицитных ростовых субстратов (ацетат+глюкоза). При росте бактерий на смешанном субстрате оба субстрата потребляются одновременно, причем ацетат поглощается путем активного транспорта с использованием энергии протондвижущей силы. При наличии ацетата натрия в смешанном субстрате активность ацетил-КоА-синтетазы и ключевого фермента глюконеогенеза фосфоенолпируватсинтетазы были более, чем в 10 раз, а показатели синтеза этаполана почти в 2 раза выше по сравнению с ацетатом калия. Эти результаты могут свидетельствовать об участии Na+ в создании ионных градиентов на мембране, необходимых для генерации энергии протондвижущей силы. Одновременное функционирование глиоксилатного цикла и пируваткарбоксилазной реакции, повышение активности изоцитратлиазы, малатсинтазы и фосфоенолпируватсинтетазы свидетельствуют об усилении глюконеогенеза и изменении направленности процессов биосинтеза на смеси ацетата и глюкозы в сторону образования углеводов по сравнению с выращиванием Acinetobacter sp. В-7005 на соответствующих моносубстратах. Intensification of the synthesis of the microbial exopolysaccharide ethapolan by Acinetobacter sp. B-7005 was shown to occur on a mixture of energy-deficient growth substrates (acetate + glucose). When the bacterium grew on the substrate mixture, both substrates were utilized simultaneously; acetate was taken up by means of active transport at the expense of the energy of the proton-motive force. When acetate was present in the form of a sodium salt, the activities of acetyl-CoA synthetase and phosphoenolpyruvate synthetase (the key enzyme of gluconeogenesis) were tenfold higher than in the presence of potassium acetate, and the indexes of ethapolan synthesis were two times higher. The positive effect of Na+ on ethapolan synthesis is supposed to consist in the creation of ion gradients on the membrane, necessary for the generation of the proton-motive force. Simultaneous functioning of the glyoxylate cycle and pyruvate carboxylase reaction, as well as an increase in the activity of isocitrate lyase, malate synthase, and phosphoenolpyruvate synthetase, provide evidence of increased gluconeogenesis in the presence of the acetate + glucose mixture (as compared to gluconeogenesis on the corresponding monosubstrates).
  • Ескіз
    Документ
    Formation of the Exopolysaccharide ethapolan by acinetobacter sp. IMV B-7005 on a fumarate–glucose mixture
    (2007) Pirog, Tatiana; Vysyatetska, Nadezhda; Korzh, Yuliya
    Our studies enabled us to intensify the synthesis of the microbial exopolysaccharide (EPS) ethapolan produced by Acinetobacter sp. IMV B-7005 grown on a mixture of fumarate (an energy-excessive substrate) and glucose (an energy-deficient substrate). Supplementing glucose-containing medium with sodium (potassium) fumarate at a molar ratio of 4 : 1 resulted in a 1.3–2.2-fold increase of the EPS amount synthesized and in a 1.3–2-fold increase of the EPS yield relative to the biomass compared to cultivation on monosubstrates. The conversion of the carbon of both substrates to EPS was the highest if the carbon/nitrogen ratio in the cultivation medium was 70.5 and inoculum grown on glucose monosubstrate was used.
  • Ескіз
    Документ
    Specific features of the synthesis of the exopolysaccharide ethapolan on a mixture of energy-deficient growth substrates
    (2007) Pirog, Tatiana; Vysyatetska, Nadezhda; Korzh, Yuliya
    Intensification of the synthesis of the microbial exopolysaccharide ethapolan by Acinetobacter sp. B-7005 was shown to occur on a mixture of energy-deficient growth substrates (acetate + glucose). When the bacterium grew on the substrate mixture, both substrates were utilized simultaneously; acetate was taken up by means of active transport at the expense of the energy of the proton-motive force. When acetate was present in the form of a sodium salt, the activities of acetyl-CoA synthetase and phosphoenolpyruvate synthetase (the key enzyme of gluconeogenesis) were tenfold higher than in the presence of potassium acetate, and the indexes of ethapolan synthesis were two times higher. The positive effect of Na+ on ethapolan synthesis is supposed to consist in the creation of ion gradients on the membrane, necessary for the generation of the proton-motive force. Simultaneous functioning of the glyoxylate cycle and pyruvate carboxylase reaction, as well as an increase in the activity of isocitrate lyase, malate synthase, and phosphoenolpyruvate synthetase, provide evidence of increased gluconeogenesis in the presence of the acetate + glucose mixture (as compared to gluconeogenesis on the corresponding monosubstrates).