Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
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Target Concepts:
Gene/Protein
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Query: EC:1.7.1.2 (
nitrate reductase
)
3,861
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
During oxidation of nitrite, cells of Nitrobacter winogradskyi are shown to catalyze the active exchange of oxygen atoms between exogenous nitrate molecules (production of 15N16/18O3- during incubation of 14N16/18O3-, 15N16O3-, and 15N16O2- in H216O). Little, if any, exchange of oxygens between nitrate and water also occurs (production of 15N16/18O3- during incubation of 15N16O3- and 14N16O2- in H218O). 15N species of nitrate were assayed by 18O-isotope shift in 15N NMR. Taking into account the O-exchange reactions which occur during nitrite oxidation, H2O is seen to be the source of O in nitrate produced by oxidation of nitrite by N. winogradskyi. The data do not establish whether the nitrate-nitrate O exchange is catalyzed by nitrite oxidase (H2O + HNO2----
HNO3
+ 2H+ + 2e-) or
nitrate reductase
(
HNO3
+ 2H+ + 2e-----HNO2 + H2O) or both enzymes in consort. The nitrate-nitrate exchange reaction suggests the existence of an oxygen derivative of a H2O-utilizing oxidoreductase.
...
PMID:Oxygen exchange between nitrate molecules during nitrite oxidation by Nitrobacter. 373 17
The nitrate-nitrite-NO pathway is emerging as an alternative to the l-arginine/NO-synthase pathway for the generation of NO in mammals. Bioactivation of the stable nitrate anion involves initial reduction to nitrite by commensal bacteria in the gastrointestinal tract. Nitrite is then further metabolized in blood and tissues to form nitric oxide (NO) and other bioactive nitrogen oxides. In addition to nitrate reduction by bacteria, a functional mammalian
nitrate reductase
activity was recently explored. It was demonstrated that xanthine oxidoreductase (XOR) and possibly other enzymes can catalyze nitrate reduction under normoxic conditions in vivo. In the present study, we compared nitrate reduction in germ free (GF) and conventional mice. One aim was to see if the complete lack of bacterial nitrate reduction in the GF mice would be associated with an upregulation of mammalian
nitrate reductase
activity.
Sodium nitrate
(NaNO(3)) or placebo (NaCl) was injected intraperitoneally and blood and tissues were collected 1.5-2h later for measurements of nitrate and nitrite and in some cases analyses of protein expression. Tissue and plasma levels of nitrate increased to a similar extent in conventional and GF animals after nitrate administration. Plasma nitrite was 3-fold higher in GF mice receiving nitrate compared to placebo while this effect of nitrate was absent in the conventional mice. In GF mice pretreated with the xanthine oxidase inhibitor allopurinol the increase in nitrite was attenuated. The levels of nitrite in the liver and small intestine increased after the nitrate load in GF mice but not in the conventional mice. Anaerobic nitrate reduction to nitrite in intestinal tissue homogenates was also accelerated in GF mice. Studies of tissue protein levels revealed increased expression of XOR in the livers of GF animals. We conclude that XOR expression in tissues is enhanced in germ free mice and this may explain the apparently greater tissue
nitrate reductase
activity observed in these animals. Future studies will reveal if this represents a compensatory functional response to uphold nitrite homeostasis in the absence of commensal bacteria.
...
PMID:Enhanced xanthine oxidoreductase expression and tissue nitrate reduction in germ free mice. 2014 47
Numerous studies have shown beneficial cardiovascular and metabolic effects of dietary nitrate but the release or uptake of these anions on an organ level is still poorly elucidated. Here we administered sodium nitrate in the pig and measured acute changes in release/uptake of nitrate and nitrite across several organs as well as cardiovascular and metabolic functions. In 17 anesthetized pigs multiple venous catheters and arterial ultrasonic blood flow probes were positioned. After pretreatment with the NO synthase (NOS) inhibitor l-NAME to minimize involvement of NOS-dependent nitrate/nitrite generation, the animals received bolus injections of either sodium nitrate or sodium chloride. Organ blood flows and release/uptake of nitrate and nitrite were measured in the pulmonary, splanchnic, hepatic and renal circulations for up to two hours. In addition, small intestinal luminal NO, gut secretion of nitrate, as well as hepatic and renal NADPH oxidase activity were measured. At baseline there was a significant uptake of nitrite in the liver and kidneys together with a release of nitrite from the lungs. In the control pigs, arterial plasma nitrite progressively declined during the observation period (-54%) but was stable in the nitrate group, indicating conversion of nitrate to nitrite.
Sodium nitrate
led to a marked accumulation of nitrate in the small intestinal lumen with a parallel increase in luminal nitrite. This was coupled with release of nitrite in the portal vein and a concomitant uptake of this anion in the liver. There was a trend towards reduced NADPH oxidase-dependent superoxide generation in the liver but an increase in the kidney. Nitrate had no acute effects on cardiovascular parameters or regional and systemic oxygen consumption. In conclusion, we found a notable difference in release and uptake of nitrate and nitrite between the organs investigated. Our findings indicate an acute conversion of nitrate to nitrite, most likely independent of oral bacteria but by a mammalian
nitrate reductase
and/or gut bacteria.
...
PMID:Organ uptake and release of inorganic nitrate and nitrite in the pig. 2942 40
