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Galactosyl-transfer Reactions from UDP-[ 14 C] Galactose, Catalysed by Enzyme from Pea Epicotyl Membranes in the Presence of XyloglucanChileshe, Chinga January 1995 (has links)
Note:
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Studies on the specificity of Pisum glycosyltransferases towards polyprenyl acceptorsTorossian, Krikor. January 1985 (has links)
No description available.
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The membrane envelopes in soybean root nodules /Zogbi, Victor. January 1981 (has links)
No description available.
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Studies on the specificity of Pisum glycosyltransferases towards polyprenyl acceptorsTorossian, Krikor. January 1985 (has links)
Total polyprenols prepared from Pisum stem and analyzed by HPLC, possessed chain-lengths equivalent to 15-17 isoprene units and were (alpha)-saturated. Pea membranes were supplied with GDP- ('14)C mannose, UDP- ('14)C GlcNAc and UDP- ('14)C glucose as substrates for glycosyltransfer in the presence or absence of added polyprenyl phosphates. Mono- and pyro-phosphorylated fractions were characterized using chromatographic and hydrolytic criteria. Glucosyl and mannosyl transfer took place to form endogenous polyprenyl-P-saccharide. Dolichyl-P was the only added polyprenyl phosphate which acted as an acceptor for these transferases. In contrast, incorporation of all the supplied sugars into polyprenyl-PP-saccharide was stimulated greatly in the presence of relatively short (alpha)-saturated polyprenyl phosphates, e.g., dihydro-heptaprenyl phosphate (7HP). A major product was 7H-PP-monosaccharide. / Oligosaccharide-lipids were also synthesized, all of which could be digested by treatment with endo H, indicating the presence of chitobiose. When UDP- ('14)C GlcNAc was used as substrate in the presence of dolP, labelled dol-PP-chitobiose was formed and then lengthened in the presence of unlabelled GDP-mannose. The same oligosaccharides were formed in experiments where the label was present in mannose. Evidence is presented for the further addition of terminal glucose to form "G" oligosaccharide. Endogenous levels of polyprenyl phosphates clearly limited the activities of pea transglycosylases, which were capable of recognizing isoprenoids of particular chain lengths and saturation patterns.
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The membrane envelopes in soybean root nodules /Zogbi, Victor. January 1981 (has links)
No description available.
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Early effects of boron deficiency on membrane function in higher plantsHeyes, J. A. January 1984 (has links)
The transfer of plants to boron-free solutions induces rapid responses in membrane functions without necessarily affecting root growth and anatomy. In sunflowers (Helianthus annuus), root growth slows within 3-6 h. However in maize (Zea mays), no growth effects are apparent after more than 30 h without boron (-B). In both species early disturbances in ion uptake and cell wall deposition are seen. Ultrastructural studies on sunflower root tips after 5.5 h or 3 d -B are reported. Detailed studies on the absorption of P<sub>j</sub> and K<sup>+</sup> by root tips were complemented by studies on protoplasts isolated from the root tips of +B and -B plants. There were no significant differences in the protoplast yield or viability according to their B status. Ion absorption by protoplasts isolated from roots of +B and -B plants generally resembled that by intact roots of the corresponding B status. Altering the B status of the protoplasts was expected to initiate earlier responses than in the roots where cell wall binding and diffusion times buffer the system against change; but the greater variability inherent in measuring the protoplast responses prevented the detection of subtle changes. The activities of two+ membrane bound arjzymes were investigated; β-glucan synthetase and a K<sup>+</sup>-stimulated, Mg<sup>2+</sup> -dependent ATPase. UDPG incorporation by protoplasts continued for over 18 h and was consistently higher in +B protoplasts and root membranes than -B. However SEM revealed no significant differences in fibre deposition around sunflower and maize protoplasts according to their boron status. (K<sup>+</sup>+Mg<sup>2+</sup>)-ATPase from sunflower roots was found to be reversibly impaired by the loss of B; and preliminary investigations implied that restoration of activity when B was resupplied to the intact roots was correlated with the B content of the membrane fraction, as determined by the (n,α) method.
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Identification and quantification of lipid metabolites in cotton fibers: Reconciliation with metabolic pathway predictions from DNA databases.Wanjie, Sylvia W. 05 1900 (has links)
The lipid composition of cotton (Gossypium hirsutum, L) fibers was determined. Fatty acid profiles revealed that linolenate and palmitate were the most abundant fatty acids present in fiber cells. Phosphatidylcholine was the predominant lipid class in fiber cells, while phosphatidylethanolamine, phosphatidylinositol and digalactosyldiacylglycerol were also prevalent. An unusually high amount of phosphatidic acid was observed in frozen cotton fibers. Phospholipase D activity assays revealed that this enzyme readily hydrolyzed radioactive phosphatidylcholine into phosphatidic acid. A profile of expressed sequence tags (ESTs) for genes involved in lipid metabolism in cotton fibers was also obtained. This EST profile along with our lipid metabolite data was used to predict lipid metabolic pathways in cotton fiber cells.
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Estudo do direcionamento das proteases FtsH plastidiais às membranas dos tilacóides / Study of plastidial FtsH proteases targeting to thylakoid membranesRodrigues, Ricardo Augusto de Oliveira 15 June 2011 (has links)
O complexo FtsH em Arabidopsis, presente nos tilacóides, é formado pelas subunidades FtsH1/FtsH5 (tipo A) e FtsH2/FtsH8 (tipo B). Os tipos A e B apresentam grande identidade em seus domínios maduros, porém nenhuma similaridade é observada na região amino-terminal do peptídeo de trânsito. Em um experimento de importação em cloroplastos isolados, FtsH2 e FtsH5 foram importadas e subsequentemente integradas aos tilacóides através de um mecanismo de processamento em duas etapas que resultou em um domínio lumenal amino-proximal, uma única âncora transmembrânica e um domínio carboxi-proximal estromal. A integração da FtsH2 em tilacóides isolados foi totalmente dependente do gradiente de prótons, enquanto que a integração da FtsH5 foi dependente de NTPs, sugerindo que a inserção na membrana ocorre pelas vias TAT e Sec, respectivamente. Tal observação foi corroborada por experimentos de competição in-organello e inibição por anticorpos específicos. Os domínios amino-proximais até as âncoras transmembrânicas foram suficientes para a correta integração aos tilacóides. A região madura da FtsH2 apresentou incompatibilidade com a maquinaria Sec, como demonstrado pela troca de peptídeos de trânsito. A incompatibilidade não parece ser determinada por qualquer elemento específico da FtsH2, uma vez que nenhum domínio isolado apresentou incompatibilidade com a via Sec de transporte. Tal fato sugere uma incompatibilidade estrutural que requer a FtsH2 intacta. A descoberta que as subunidades FtsH do tipo A e B, que apresentam grande identidade e usam diferentes vias de integração para formar o mesmo complexo multimérico é uma observação nova e interessante para o estudo da biogênese de proteínas de membranas. O mecanismo de regulação que governa a atividade do complexo FtsH em Arabidopsis é ainda desconhecido, entretanto é proposta a existência de fatores adicionais. Dessa forma, a proteína plastidial FtsH de Arabidopsis foi usada como isca em um rastreamento por duplohíbrido de levedura. O rastreamento resultou em 48 colônias que ativaram os genes repórteres histidina e adenina. Entre todos os cDNAs sequenciados, foi encontrado um candidato em potencial denominado FIP (FtsH5 Interacting Protein). Experimentos GST Pull-Down também indicam uma interação entre FtsH5 e FIP. O precursor FIP radioativo foi incubado com cloroplastos de ervilha. Após a incubação, os cloroplastos foram lisados e separados em estroma e tilacóides. FIP permaneceu associada exclusivamente à fração membranosa dos tilacóides. A inserção na membrana foi verificada através da resistência ao tratamento com álcali e o tratamento dos tilacóides com protease resultou em um fragmento protegido, característico de proteínas inseridas na membrana. A construção FtsH5::GFP transformada em Nicotiana tabacum resultou no direcionamento do gene quimérico aos cloroplastos. Dessa forma, assim como FtsH5, FIP é uma proteína plastidial que está localizada na membrana dos tilacóides. Géis nativos utilizando FIP radioativa mostram que ela está associada a um complexo de aproximadamente 450 kDa, que é o tamanho esperado para o complexo tilacoidal FtsH em Arabidopsis. Como as proteínas FtsH apresentam tanto o domínio ATPase quanto protease, acreditamos que FIP pode de alguma forma modular a atividade do complexo FtsH nos tilacóides. / The Arabidopsis thylakoid FtsH protease complex is composed of FtsH1/FtsH5 (type A) and FtsH2/FtsH8 (type B) subunits. Type A and type B subunits display a high degree of sequence identity throughout their mature domains, but no similarity in their amino-terminal targeting peptide regions. In chloroplast import assays, FtsH2 and FtsH5 were imported and subsequently integrated into thylakoids by a two-step processing mechanism that resulted in an amino-proximal lumenal domain, a single transmembrane anchor, and a carboxyl proximal stromal domain. FtsH2 integration into washed thylakoids was entirely dependent on the proton gradient, whereas FtsH5 integration was dependent on NTPs, suggesting their integration by Tat and Sec pathways, respectively. This finding was corroborated by in organello competition and by antibody inhibition experiments. The amino proximal domains through the transmembrane anchors were sufficient for proper integration. The mature FtsH2 protein was found to be incompatible with the Sec machinery as determined with targeting peptide-swapping experiments. Incompatibility does not appear to be determined by any specific element in the FtsH2 domain as no single domain was incompatible with Sec transport. This suggests an incompatible structure that requires the intact FtsH2. That the highly homologous type A and type B subunits of the same multimeric complex use different integration pathways is a striking example of the notion that membrane insertion pathways have evolved to accommodate structural features of their respective substrates. The regulation mechanism which governs the Arabidopsis FtsH complexs activity is still unknown, but it is proposed the presence of additional factors. For this reason, the plastidial Arabidopsis FtsH5 was used as bait in a yeast two hybrid screening. The screening resulted in 48 colonies that activated the histidine and adenine reporter genes. Among all the sequenced cDNAs we have found a potential candidate named FIP (FtsH5 Interacting Protein). GST Pull-Down experiments also indicate an interaction between FtsH5 and FIP. Radiolabeled FIP was incubated with intact isolated chloroplasts. After incubation, intact chloroplasts were lysated and separated into stroma and thylakoids. FIP remained associated exclusively with the thylakoid membrane fraction. The insertion into membrane was verified throughout resistance to alkali treatment and the thylakoid protease treated fraction resulted in a protected fragment, characteristic of membrane-inserted proteins. Agroinfiltrated Nicotiana tabacum leaves with a FtsH5::GFP construct resulted that the chimeric gene was targeted to chloroplasts. Thus, as FtsH5, FIP is a plastidial protein which is located into thylakoid membrane. Blue native gels using radiolabeled FIP protein show that it runs associated with a complex around 450 kDa, which is the expected size for the Arabidopsis FtsH thylakoidal complex. As FtsH proteins present both ATPase and protease domains, we believe that FIP can somehow modulates the activity of the thylakoidal FtsH complex.
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Estudo do direcionamento das proteases FtsH plastidiais às membranas dos tilacóides / Study of plastidial FtsH proteases targeting to thylakoid membranesRicardo Augusto de Oliveira Rodrigues 15 June 2011 (has links)
O complexo FtsH em Arabidopsis, presente nos tilacóides, é formado pelas subunidades FtsH1/FtsH5 (tipo A) e FtsH2/FtsH8 (tipo B). Os tipos A e B apresentam grande identidade em seus domínios maduros, porém nenhuma similaridade é observada na região amino-terminal do peptídeo de trânsito. Em um experimento de importação em cloroplastos isolados, FtsH2 e FtsH5 foram importadas e subsequentemente integradas aos tilacóides através de um mecanismo de processamento em duas etapas que resultou em um domínio lumenal amino-proximal, uma única âncora transmembrânica e um domínio carboxi-proximal estromal. A integração da FtsH2 em tilacóides isolados foi totalmente dependente do gradiente de prótons, enquanto que a integração da FtsH5 foi dependente de NTPs, sugerindo que a inserção na membrana ocorre pelas vias TAT e Sec, respectivamente. Tal observação foi corroborada por experimentos de competição in-organello e inibição por anticorpos específicos. Os domínios amino-proximais até as âncoras transmembrânicas foram suficientes para a correta integração aos tilacóides. A região madura da FtsH2 apresentou incompatibilidade com a maquinaria Sec, como demonstrado pela troca de peptídeos de trânsito. A incompatibilidade não parece ser determinada por qualquer elemento específico da FtsH2, uma vez que nenhum domínio isolado apresentou incompatibilidade com a via Sec de transporte. Tal fato sugere uma incompatibilidade estrutural que requer a FtsH2 intacta. A descoberta que as subunidades FtsH do tipo A e B, que apresentam grande identidade e usam diferentes vias de integração para formar o mesmo complexo multimérico é uma observação nova e interessante para o estudo da biogênese de proteínas de membranas. O mecanismo de regulação que governa a atividade do complexo FtsH em Arabidopsis é ainda desconhecido, entretanto é proposta a existência de fatores adicionais. Dessa forma, a proteína plastidial FtsH de Arabidopsis foi usada como isca em um rastreamento por duplohíbrido de levedura. O rastreamento resultou em 48 colônias que ativaram os genes repórteres histidina e adenina. Entre todos os cDNAs sequenciados, foi encontrado um candidato em potencial denominado FIP (FtsH5 Interacting Protein). Experimentos GST Pull-Down também indicam uma interação entre FtsH5 e FIP. O precursor FIP radioativo foi incubado com cloroplastos de ervilha. Após a incubação, os cloroplastos foram lisados e separados em estroma e tilacóides. FIP permaneceu associada exclusivamente à fração membranosa dos tilacóides. A inserção na membrana foi verificada através da resistência ao tratamento com álcali e o tratamento dos tilacóides com protease resultou em um fragmento protegido, característico de proteínas inseridas na membrana. A construção FtsH5::GFP transformada em Nicotiana tabacum resultou no direcionamento do gene quimérico aos cloroplastos. Dessa forma, assim como FtsH5, FIP é uma proteína plastidial que está localizada na membrana dos tilacóides. Géis nativos utilizando FIP radioativa mostram que ela está associada a um complexo de aproximadamente 450 kDa, que é o tamanho esperado para o complexo tilacoidal FtsH em Arabidopsis. Como as proteínas FtsH apresentam tanto o domínio ATPase quanto protease, acreditamos que FIP pode de alguma forma modular a atividade do complexo FtsH nos tilacóides. / The Arabidopsis thylakoid FtsH protease complex is composed of FtsH1/FtsH5 (type A) and FtsH2/FtsH8 (type B) subunits. Type A and type B subunits display a high degree of sequence identity throughout their mature domains, but no similarity in their amino-terminal targeting peptide regions. In chloroplast import assays, FtsH2 and FtsH5 were imported and subsequently integrated into thylakoids by a two-step processing mechanism that resulted in an amino-proximal lumenal domain, a single transmembrane anchor, and a carboxyl proximal stromal domain. FtsH2 integration into washed thylakoids was entirely dependent on the proton gradient, whereas FtsH5 integration was dependent on NTPs, suggesting their integration by Tat and Sec pathways, respectively. This finding was corroborated by in organello competition and by antibody inhibition experiments. The amino proximal domains through the transmembrane anchors were sufficient for proper integration. The mature FtsH2 protein was found to be incompatible with the Sec machinery as determined with targeting peptide-swapping experiments. Incompatibility does not appear to be determined by any specific element in the FtsH2 domain as no single domain was incompatible with Sec transport. This suggests an incompatible structure that requires the intact FtsH2. That the highly homologous type A and type B subunits of the same multimeric complex use different integration pathways is a striking example of the notion that membrane insertion pathways have evolved to accommodate structural features of their respective substrates. The regulation mechanism which governs the Arabidopsis FtsH complexs activity is still unknown, but it is proposed the presence of additional factors. For this reason, the plastidial Arabidopsis FtsH5 was used as bait in a yeast two hybrid screening. The screening resulted in 48 colonies that activated the histidine and adenine reporter genes. Among all the sequenced cDNAs we have found a potential candidate named FIP (FtsH5 Interacting Protein). GST Pull-Down experiments also indicate an interaction between FtsH5 and FIP. Radiolabeled FIP was incubated with intact isolated chloroplasts. After incubation, intact chloroplasts were lysated and separated into stroma and thylakoids. FIP remained associated exclusively with the thylakoid membrane fraction. The insertion into membrane was verified throughout resistance to alkali treatment and the thylakoid protease treated fraction resulted in a protected fragment, characteristic of membrane-inserted proteins. Agroinfiltrated Nicotiana tabacum leaves with a FtsH5::GFP construct resulted that the chimeric gene was targeted to chloroplasts. Thus, as FtsH5, FIP is a plastidial protein which is located into thylakoid membrane. Blue native gels using radiolabeled FIP protein show that it runs associated with a complex around 450 kDa, which is the expected size for the Arabidopsis FtsH thylakoidal complex. As FtsH proteins present both ATPase and protease domains, we believe that FIP can somehow modulates the activity of the thylakoidal FtsH complex.
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