Stefan Rümer scite author profile

Plants are known to produce NO via the reduction of nitrite. Oxidative NO production in plants has been considered only with respect to a nitric oxide synthase (NOS). Here it is shown that tobacco cell suspensions emitted NO when hydroxylamine (HA) or salicylhydroxamate (SHAM), a frequently used AOX inhibitor, was added. NG-hydroxy-L-arginine, a putative intermediate in the NOS-reaction, gave no NO emission. Only a minor fraction (≤1%) of the added HA or SHAM was emitted as NO. Production of NO was decreased by anoxia or by the addition of catalase, but was increased by conditions inducing reactive oxygen (ROS) or by the addition of hydrogen peroxide. Cell-free enzyme solutions generating superoxide or hydrogen peroxide also led to the formation of NO from HA or (with lower rates) from SHAM, and nitrite was also an oxidation product. Unexpectedly, the addition of superoxide dismutase (SOD) to cell suspensions stimulated NO formation from hydroxylamines, and SOD alone (without cells) also catalysed the production of NO from HA or SHAM. NO production by SOD plus HA was higher in nitrogen than in air, but from SOD plus SHAM it was lower in nitrogen. Thus, SOD-catalysed NO formation from SHAM and from HA may involve different mechanisms. While our data open a new possibility for oxidative NO formation in plants, the existence and role of these reactions under physiological conditions is not yet clear.

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DAF-fluorescence without NO: Elicitor treated tobacco cells produce fluorescing DAF-derivatives not related to DAF-2 triazol

Rümer¹,

Krischke²,

Fekete³

et al. 2012

Nitric Oxide

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Oxidation of hydroxylamines to NO by plant cells

Rümer¹,

Gupta²,

Kaiser³

2009

Plant Signaling & Behavior

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A t least theoretically, plants maysynthesize nitric oxide (NO) either by reduction of N in higher oxidations states, or by oxidation of more reduced N-compounds. The well established reductive pathway uses nitrite as a substrate, produced by cytosolic nitrate reductase. The only oxidative pathway described so far comprises nitric oxide synthase (NOS)-like activity, where guanidino-N from L-arginine is oxidized to NO. In our previous paper we have demonstrated yet another form of oxidative NO formation, whereby hydroxylamine (HA), but also the AOX-inhibitor salicylhydroxamate (SHAM) is oxidized to NO by tobacco suspension cells. Oxidation of HA to NO was also demonstrated in vitro by using ROS producing enzymes. Apparently superoxide radicals and/or hydrogen peroxide served as oxidants. Another unexpected observation pointed to a special role for superoxide dismutase in oxidative NO formation.

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Nitrate Reductase and Nitric Oxide

Kaiser¹,

Planchet

Rümer³

2010

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Stefan Rümer

An anatomical study of the haustoria of Rhinanthus minor attached to roots of different hosts

Plant cells oxidize hydroxylamines to NO

DAF-fluorescence without NO: Elicitor treated tobacco cells produce fluorescing DAF-derivatives not related to DAF-2 triazol

Oxidation of hydroxylamines to NO by plant cells

Nitrate Reductase and Nitric Oxide

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