| Abstract: | Infected cells of soybean (Glycine max) nodules require NADH,ATP, and 2-oxoglutarate for ammonia assimilation. The role ofmitochondria in nodule metabolism was investigated by determiningtheir respiratory properties and comparing them with cotyledonmitochondria. Nodule mitochondria oxidized malate at a ratetwice that of any other NAD-linked substrate although theirmalic enzyme activity was very low, accounting for only 12%of malate oxidation at pH 6.4 compared to 56% for cotyledonmitochondria. The reduction of NAD+ in mitochondria of noduleson adding malate (determined by fluorescence) was rapid andreached a stable level, whereas in cotyledon mitochondria theNADH level declined rapidly as oxaloacetate accumulated. Anoxaloacetate scavenging system in the mitochondrial reactionmedium increased malate oxidation by cotyledon mitochondria4-fold, but increased that of nodule mitochondria by less than50%. This demonstrates that the efflux of oxaloacetate by theoxaloacetate carrier is highly regulated by the extra-mitochondrialoxaloacetate concentration in cotyledon mitochondria comparedto nodule mitochondria. The activity of TCA cycle enzymes, exceptmalate and succinate dehydrogenases, was low in nodule mitochondria.Their oxaloacetate export during malate oxidation was rapid.The aspartate amino transferase activity associated with nodulemitochondria was sufficient to account for significant formationof 2-oxoglutarate from oxaloacetate and glutamate. These resultssuggest that nodule mitochondria operate a truncated form ofthe TCA cycle and primarily oxidize malate to provide oxaloacetateand ATP for NH3 assimilation. Key words: Glycine max (L.), nitrogen fixation, gluconeogenesis, respiration |
