Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: EC:1.7.1.2 (
nitrate reductase
)
3,861
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
We have assayed absorbance changes generated by blue light in plasma membranes,
endoplasmic reticulum
, and mitochondrial membranes from Neurospora crassa. Light minus dark difference spectra, obtained anaerobically in the presence of ethylenediaminetetraacetate, indicated that b-type cytochromes could be photoreduced in all three membranes. In plasma membranes, a b-type cytochrome with a distinct difference spectrum was photoreducible without addition of exogenous flavin. Addition of riboflavin greatly stimulated the photoreduction of cytochromes in
endoplasmic reticulum
and mitochondrial membranes. In its spectral characteristics the cytochrome on the
endoplasmic reticulum
resembled cytochrome b(5) or
nitrate reductase
, while the cytochrome in mitochondrial membranes had the same spectrum as cytochrome b of the mitochondrial respiratory chain.Cytochromes in the three membrane fractions reacted differently to blue light in the presence of various inhibitors. Potassium azide inhibited reduction of plasma membrane cytochrome b, with 50% inhibition at 1.0 millimolar. The same concentration of azide stimulated photoreduction of cytochromes in both
endoplasmic reticulum
and mitochondria. Although photoreduction of cytochromes in all three membranes was inhibited by salicylhydroxamic acid, cytochromes in plasma membranes were more sensitive to this inhibitor than those in
endoplasmic reticulum
and mitochondria. Cells grown to induce
nitrate reductase
activity showed an elevated amount of blue light-reducible cytochrome b in the
endoplasmic reticulum
.
...
PMID:Blue Light-Reducible Cytochromes in Membrane Fractions from Neurospora crassa. 1666 61
At sufficiently low oxygen concentrations, hemeproteins are deoxygenated and become capable of reducing nitrite to nitric oxide (NO), in a reversal of the reaction in which NO is converted to nitrate or nitrite by oxygenated hemeproteins. The maximum rates of NO production depend on the oxygen avidity. The hemeproteins with the highest avidity, such as hexacoordinate hemoglobins, retain oxygen even under anoxic conditions resulting in their being extremely effective NO scavengers but essentially incapable of producing NO. Deoxyhemeprotein-related NO production can be observed in mitochondria (at the levels of cytochrome c oxidase, cytochrome c, complex III and possibly other sites), in plasma membrane, cytosol,
endoplasmic reticulum
and peroxisomes. In mitochondria, the use of nitrite as an alternative electron acceptor can contribute to a limited rate of ATP synthesis. Non-heme metal-containing proteins such as
nitrate reductase
and xanthine oxidase can also be involved in NO production. This will result in a strong anoxic redox flux of nitrogen through the hemoglobin-NO cycle involving
nitrate reductase
, nitrite: NO reductase, and NO dioxygenase. In normoxic conditions, NO is produced in very low quantities, mainly for signaling purposes and this nitrogen cycling is inoperative.
...
PMID:Anoxic nitric oxide cycling in plants: participating reactions and possible mechanisms. 1992 98
