The Chemical Interplay between Nitric Oxide and Mitochondrial CytochromecOxidase: Reactions, Effectors and Pathophysiology

Nitric oxide (NO) reacts with Complex I and cytochromecoxidase (CcOX, Complex IV), inducing detrimental or cytoprotective effects. Two alternative reaction pathways (PWs) have been described whereby NO reacts with CcOX, producing either a relatively labile nitrite-bound derivative (CcOX-NO2 −, PW1) or a more stable nitrosyl-derivative (CcOX-NO, PW2). The two derivatives are both inhibited, displaying different persistency and O2competitiveness. In the mitochondrion, during turnover with O2, one pathway prevails over the other one depending on NO, cytochromec2+and O2concentration. High cytochromec2+, and low O2proved to be crucial in favoring CcOX nitrosylation, whereas under-standardcell-culture conditions formation of the nitrite derivative prevails. All together, these findings suggest that NO can modulate physiologically the mitochondrial respiratory/OXPHOS efficiency, eventually being converted to nitrite by CcOX, without cell detrimental effects. It is worthy to point out that nitrite, far from being a simple oxidation byproduct, represents a source of NO particularly important in view of the NO cell homeostasis, the NO production depends on the NO synthases whose activity is controlled by different stimuli/effectors; relevant to its bioavailability, NO is also produced by recycling cell/body nitrite. Bioenergetic parameters, such as mitochondrialΔΨ, lactate, and ATP production, have been assayed in several cell lines, in the presence of endogenous or exogenous NO and the evidence collected suggests a crucial interplay between CcOX and NO with important energetic implications.

Electron paramagnetic resonance studies of heme c and its nitrosyl derivative in Vibrio (Achromobacter) fischeri nitrite reductase

Interactions of Vibrio (formerly Achromobacter) fischeri nitrite reductase were studied by electron paramagnetic resonance spectroscopy. The spectrum of the oxidized enzyme showed a number of features which were attributed to two low-spin ferric hemes. These comprised an unusual derivative peak at g = 3.7 and a spectrum at g = 2.88, 2.26, and 1.51. Neither heme was reactive in the oxidized state with the substrate nitrite and with cyanide and azide. When frozen under turnover conditions (i.e., reduction in the presence of excess nitrite), the enzyme showed the spectrum of a nitrosyl heme derivative. The g = 2.88, 2.26, and 1.51 signals reappeared partially on reoxidation by nitrite, indicating that the nitrosyl species which remained arose from the g = 3.7 heme. The nitrosyl derivative showed a 14N nuclear hyperfine splitting, Az = 1.65 mT. The nitrosyl derivative was produced by treatment of the oxidized nitrite reductase with nitric oxide or hydroxylamine. Exchange of nitric oxide between the nitrosyl derivative and NO gas in solution was observed by using the [15N]nitrosyl compound. A possible reaction cycle for the enzyme is discussed, which involves reduction of the enzyme followed by binding of nitrite to one heme and formation of the nitrosyl intermediate.

Electron-spin-resonance studies of the NADH-dependent nitrite reductase from Escherichia coli K12

The NADH-dependent nitrite reductase of Escherichia coli, which contains sirohaem, flavin, non-haem iron and labile sulphide, was examined by low-temperature e.s.r. spectroscopy. The enzyme, stored in the presence of nitrite and ascorbate, gave the spectrum of a nitrosyl derivative, with hyperfine splitting due to the nitrosyl nitrogen. On removal of these reagents, a series of signals centred around g = 6 was observed, typical of high-spin ferric haem. Cyanide converted this into a low-spin form. On reduction of the enzyme with NADH, an axial spectrum at g = 1.92, 2.01 was observed. The temperature-dependence of this signal is indicative of a [2Fe-2S] iron-sulphur cluster. The midpoint potential of this cluster was estimated to be −230 +/- 15 mV by two independent methods. Reduction of the enzyme with dithionite yielded further signals, which are at present unidentified, at g = 2.1-2.28. No signals were observed that could be assigned to a [4Fe-4S] cluster, such as is found in other sulphite reductases and nitrite reductases that contain sirohaem.

Electron-paramagnetic-resonance studies of leghaemoglobins from soya-bean and cowpea root nodules. Identification of nitrosyl-leghaemoglobin in crude leghaemoglobin preparations

1. Leghaemoglobins from soya-bean (Glycine max) and cowpea (Vigna unguiculata) root nodules were purified by chromatography on DEAE-cellulose phosphate columns at pH8.0 and pH5.8, to avoid the relatively low pH (5.2) commonly used to purify these proteins. 2. E.p.r. (electron-paramagnetic-resonance) spectra of the fluoride, azide, hydroxide and cyanide complexes of these ferric leghaemoglobins were very similar to the spectra of the corresponding myoglobin derivatives, indicating that the immediate environment of the iron in leghaemoglobin and myoglobin is similar, an imidazole moiety of histidine being the proximal ligand to the haem iron [cf. Appleby, Blumberg, Peisach, Wittenberg & Wittenberg (1976) J. Biol. Chem.251, 6090–6096]. 3. E.p.r. spectra of the acid-metleghaemoglobins showed prominent high-spin features very near g=6 and g=2 and, unlike myoglobin, small low-spin absorptions near g=2.26, 2.72 and 3.14. The width of the g=6 absorption derivative at 10–20K was about 4–4.5mT, similar to the value for acid-methaemoglobin. In contrast, a recently published (Appleby et al., 1976) spectrum of acid-metleghaemoglobin a had less high-spin character and a much broader absorption derivative around g=6. 4. E.p.r. spectra of ferric leghaemoglobin nicotinate and imidazole complexes suggest that the low-spin absorption near g=3.14 can be attributed to a trace of ferric leghaemoglobin nicotinate, and those near g=2.26 and 2.72 are from an endogenous dihistidyl haemichrome. 5. A large e.p.r. signal at g=2 in all samples of crude leghaemoglobin was shown to be from nitrosyl-leghaemoglobin. A soya-bean sample contained 27±3% of the latter. A previously unidentified form of soya-bean ferrous leghaemoglobin a was shown to be its nitrosyl derivative. If this is not an artifact, and occurs in the root nodule, the nitrosyl radical may interfere with the function of leghaemoglobin.

A ruthenium chloro nitrosyl derivative of dithioacetylacetone

The novel dithioacetylacetonato complex [Ru(C5H7S2)2(NO)Cl] has been characterized by analytical and spectral methods. A trans configuration is suggested. The electronic spectrum is consistent with the oxidation state II for the coordinated metal ion.