Kapuganti Jagadis Gupta scite author profile

SummaryQuantitative data on nitric oxide (NO) production by plants, and knowledge of participating reactions and rate limiting factors are still rare. We quantified NO emission from tobacco (Nicotiana tabacum) wild-type leaves, from nitrate reductase (NR)-or nitrite reductase (NiR)-deficient leaves, from WT-or from NR-deficient cell suspensions and from mitochondria purified from leaves or cells, by following NO emission through chemiluminescence detection. In all systems, NO emission was exclusively due to the reduction of nitrite to NO, and the nitrite concentration was an important rate limiting factor. Using inhibitors and purified mitochondria, mitochondrial electron transport was identified as a major source for reduction of nitrite to NO, in addition to NR. NiR and xanthine dehydrogenase appeared to be not involved. At equal respiratory activity, mitochondria from suspension cells had a much higher capacity to produce NO than leaf mitochondria. NO emission in vivo by NiR-mutant leaves (which was not nitrite limited) was proportional to photosynthesis (high in light þCO 2 , low in light )CO 2 , or in the dark). With most systems including mitochondrial preparations, NO emission was low in air (and darkness for leaves), but high under anoxia (nitrogen). In contrast, NO emission by purified NR was not much different in air and nitrogen. The low aerobic NO emission of darkened leaves and cell suspensions was not due to low cytosolic NADH, and appeared only partly affected by oxygendependent NO scavenging. The relative contribution of NR and mitochondria to nitrite-dependent NO production is estimated.

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On the origins of nitric oxide

Gupta

Fernie

Kaiser

et al. 2011

Trends in Plant Science

509

328

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Regulation of Respiration and Fermentation to Control the Plant Internal Oxygen Concentration

Zabalza

Dongen

Froehlich³

et al. 2008

Plant Physiol.

240

263

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Plant internal oxygen concentrations can drop well below ambient even when the plant grows under optimal conditions. Using pea (Pisum sativum) roots, we show how amenable respiration adapts to hypoxia to save oxygen when the oxygen availability decreases. The data cannot simply be explained by oxygen being limiting as substrate but indicate the existence of a regulatory mechanism, because the oxygen concentration at which the adaptive response is initiated is independent of the actual respiratory rate. Two phases can be discerned during the adaptive reaction: an initial linear decline of respiration is followed by a nonlinear inhibition in which the respiratory rate decreased progressively faster upon decreasing oxygen availability. In contrast to the cytochrome c pathway, the inhibition of the alternative oxidase pathway shows only the linear component of the adaptive response. Feeding pyruvate to the roots led to an increase of the oxygen consumption rate, which ultimately led to anoxia. The importance of balancing the in vivo pyruvate availability in the tissue was further investigated. Using various alcohol dehydrogenase knockout lines of Arabidopsis (Arabidopsis thaliana), it was shown that even under aerobic conditions, alcohol fermentation plays an important role in the control of the level of pyruvate in the tissue. Interestingly, alcohol fermentation appeared to be primarily induced by a drop in the energy status of the tissue rather than by a low oxygen concentration, indicating that sensing the energy status is an important component of optimizing plant metabolism to changes in the oxygen availability.

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Nitric oxide in plants: an assessment of the current state of knowledge

et al. 2012

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Moving nitrogen to the centre of plant defence against pathogens

Mur

Simpson

Kumari

et al. 2016

Ann Bot

136

181

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Nitrite-driven anaerobic ATP synthesis in barley and rice root mitochondria

Stoimenova

Igamberdiev

Gupta³

et al. 2007

Planta

200

165

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Mitochondria isolated from the roots of barley (Hordeum vulgare L.) and rice (Oryza sativa L.) seedlings were capable of oxidizing external NADH and NADPH anaerobically in the presence of nitrite. The reaction was linked to ATP synthesis and nitric oxide (NO) was a measurable product. The rates of NADH and NADPH oxidation were in the range of 12-16 nmol min(-1) mg(-1) protein for both species. The anaerobic ATP synthesis rate was 7-9 nmol min(-1) mg(-1) protein for barley and 15-17 nmol min(-1) mg(-1) protein for rice. The rates are of the same order of magnitude as glycolytic ATP production during anoxia and about 3-5% of the aerobic mitochondrial ATP synthesis rate. NADH/NADPH oxidation and ATP synthesis were sensitive to the mitochondrial inhibitors myxothiazol, oligomycin, diphenyleneiodonium and insensitive to rotenone and antimycin A. The uncoupler FCCP completely eliminated ATP production. Succinate was also capable of driving ATP synthesis. We conclude that plant mitochondria, under anaerobic conditions, have a capacity to use nitrite as an electron acceptor to oxidize cytosolic NADH/NADPH and generate ATP.

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In higher plants, only root mitochondria, but not leaf mitochondria reduce nitrite to NO, in vitro and in situ

Gupta

Stoimenova²,

Kaiser³

2005

268

165

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At oxygen concentrations of < or =1%, even completely nitrate reductase (NR)-free root tissues reduced added nitrite to NO, indicating that, in roots, NR was not the only source for nitrite-dependent NO formation. By contrast, NR-free leaf slices were not able to reduce nitrite to NO. Root NO formation was blocked by inhibitors of mitochondrial electron transport (Myxothiazol and SHAM), whereas NO formation by NR-containing leaf slices was insensitive to the inhibitors. Consistent with that, mitochondria purified from roots, but not those from leaves, reduced nitrite to NO at the expense of NADH. The inhibitor studies suggest that, in root mitochondria, both terminal oxidases participate in NO formation, and they also suggest that even in NR-containing roots, a large part of the reduction of nitrite to NO was catalysed by mitochondria, and less by NR. The differential capacity of root and leaf mitochondria to reduce nitrite to NO appears to be common among higher plants, since it has been observed with Arabidopsis, barley, pea, and tobacco. A specific role for nitrite to NO reduction in roots under anoxia is discussed.

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Regulation of respiration when the oxygen availability changes

Gupta

Zabalza

Dongen

2009

Physiologia Plantarum

157

158

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Oxygen is a vital substrate for plant energy metabolism. Since plants do not have a sophisticated mechanism to deliver oxygen to those sites where it is actually needed, a plant cell has to continuously cope with changes of the oxygen tension within the tissue. The actual internal oxygen concentration will depend on the resistance for oxygen diffusion through the tissue, as well as on the actual respiratory activity. This paper discusses the current state of knowledge on the regulation of respiration by the oxygen availability. Contradicting opinions from the literature on plant respiration are reviewed and commented upon. Also, knowledge about the regulation of respiration in animal mitochondria is included. Apart from changes in glycolytic flux, the role of both the cytochrome-c oxidase (COX) and the alternative oxidase (AOX) in the adaptive response of respiration to changes in the oxygen availability are discussed. One hypothesis is formulated which describes an alternative or additional role for AOX. It is suggested that AOX could play a role in maintaining oxygen homeostasis within the mitochondrion. Because of the relative low affinity for oxygen of AOX as compared to COX, the alternative oxidase will not interfere with COX activity, but AOX activity will reduce the free oxygen concentration, thereby decreasing the production of reactive oxygen species (ROS) inside the mitochondrion.

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