缺磷羽扇豆根和根瘤中丙酮酸的合成途径。

Routes of pyruvate synthesis in phosphorus-deficient lupin roots and nodules.

作者信息

Le Roux M R, Ward C L, Botha F C, Valentine A J

机构信息

Department of Environmental Sciences, Applied Sciences Faculty, Cape Peninsula University of Technology, PO Box 652, Cape Town SA-8000, South Africa.

出版信息

New Phytol. 2006;169(2):399-408. doi: 10.1111/j.1469-8137.2005.01594.x.

DOI:10.1111/j.1469-8137.2005.01594.x

PMID:16411942

Abstract

Here, nodulated lupins (Lupinus angustifolius (cv Wonga)) were hydroponically grown at low phosphate (LP) or adequate phosphate (HP). Routes of pyruvate synthesis were assessed in phosphorus (P)-starved roots and nodules, because P-starvation can enhance metabolism of phosphoenolpyruvate (PEP) via the nonadenylate-requiring PEP carboxylase (PEPc) route. Since nodules and roots may not experience the same degree of P stress, it was postulated that decreases in metabolic inorganic phosphorus (Pi) of either organ, should favour more pyruvate being synthesized from PEPc-derived malate. Compared with HP roots, the LP roots had a 50% decline in Pi concentrations and 55% higher ADP : ATP ratios. However, LP nodules maintained constant Pi levels and unchanged ADP : ATP ratios, relative to HP nodules. The LP roots had greater PEP metabolism via PEPc and synthesized more pyruvate from PEPc-derived malate. In nodules, P supply did not influence PEPc activities or levels of malate-derived pyruvate. These results indicate that nodules were more efficient than roots in maintaining optimal metabolic Pi and adenylate levels during LP supply. This caused an increase in PEPc-derived pyruvate synthesis in LP roots, but not in LP nodules.

摘要

在此，将结瘤羽扇豆（羽扇豆（品种Wonga））在低磷（LP）或充足磷（HP）条件下进行水培种植。对缺磷的根和根瘤中丙酮酸的合成途径进行了评估，因为缺磷可通过不需要腺苷酸的磷酸烯醇丙酮酸羧化酶（PEPc）途径增强磷酸烯醇丙酮酸（PEP）的代谢。由于根瘤和根可能不会经历相同程度的磷胁迫，因此推测任何一个器官中代谢无机磷（Pi）的降低，都应有利于从PEPc衍生的苹果酸合成更多的丙酮酸。与HP根相比，LP根的Pi浓度下降了50%，ADP:ATP比率高出55%。然而，相对于HP根瘤，LP根瘤的Pi水平保持恒定，ADP:ATP比率没有变化。LP根通过PEPc进行的PEP代谢更强，并且从PEPc衍生的苹果酸合成了更多的丙酮酸。在根瘤中，磷供应不影响PEPc活性或苹果酸衍生的丙酮酸水平。这些结果表明，在LP供应期间，根瘤在维持最佳代谢Pi和腺苷酸水平方面比根更有效。这导致LP根中PEPc衍生的丙酮酸合成增加，但LP根瘤中没有增加。

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缺磷羽扇豆根和根瘤中丙酮酸的合成途径。

Routes of pyruvate synthesis in phosphorus-deficient lupin roots and nodules.

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