On the origin of respiration: electron transport proteins from archaea to man.

All aerobic organisms use the exergonic reduction of molecular oxygen to water as primary source of metabolic energy. This reaction is catalyzed by membrane residing terminal heme/Cu-oxidases which belong to a superfamily of widely varying structural complexity between mitochondrial and bacterial members of this family. Over the last few years, considerable information from this and other laboratories accumulated also on archaeal respiratory chains and their terminal oxidases. In the following, the molecular and catalytic properties of the latter are discussed and compared to those from bacteria and eucarya under the aspect of their energy conserving capabilities and their phylogenetic relations. The Rieske iron-sulfur proteins being important functional constituents of energy transducing respiratory complexes are included in this study. A number of essential conclusions can be drawn. (1) Like bacteria, archaea can also contain split respiratory chains with parallel expression of separate terminal oxidases. (2) The functional core of all oxidases is the highly conserved topological motif of subunit I consisting of at least 12 membrane spanning helices with the 6 histidine residues of the heme/Cu-binding centers in identical locations. (3) Some archaeal oxidases are organized in unusual supercomplexes with other cytochromes and Rieske [2Fe2S] proteins. These complexes are likely to function as proton pumps, whereas on a structural basis several subunit I equivalents alone are postulated to be unable to pump protons. (4) The genes of two archaeal Rieske proteins have been cloned from Sulfolobus; phylogenetically they are forming a separate archaeal branch and suggest the existence of an evolutionary ancestor preceding the split into the three urkingdoms. (5) Archaeal oxidase complexes may combine features of electron transport systems occurring exclusively as separate respiratory complexes in bacteria and eucarya. (6) As far back as the deepest branches of the phylogentic tree, terminal oxidases reveal a degree of complexity comparable to that found in higher organisms. (7) Sequence analysis suggests a monophyletic origin of terminal oxidases with an early split into two types found in archaea as well as bacteria. This view implies an origin of terminal oxidases prior to oxygenic photosynthesis in contrast to the widely accepted inverse hypothesis.

Unusual cytochrome a592 with low PO2 affinity correlates as putative oxygen sensor with rat carotid body chemoreceptor discharge.

Light-absorption spectra and afferent chemoreceptor discharge were simultaneously recorded on superfused rat carotid bodies (CBs) under the influence of cytochrome a3-CuB ligands (O2, CN-, CO) in order to identify the primary mitochondrial cytochrome c oxidase (CCO) oxygen sensor. Spectra could be described on the basis of weighted light-absorption spectra of cytochrome b558 of the NAD(P)H oxidase and mitochondrial cytochromes b and c, CCO, cytochrome a3, and an unusual cytochrome a peaking at 592 nm. Discharge signals were deconvoluted into phasic and tonic activity for comparing different CB responses. The spectral weight of cytochrome a592 decreased significantly starting at high PO2 (100 mm Hg) and low sodium cyanide (CN-, 10 mM) accompanied by increasing phasic peak discharge. Combined CO-hypoxia or CO-CN- application inhibited photolysis of CO-stimulated chemoreceptor discharge, revealing photometrically cytochrome a592 as central in oxygen sensing. Control spectra in tissue from sympathetic and nodose ganglia did not show any cytochrome a592 contribution. According to these results, cytochrome a592 is assumed as a unique component of CB CCO, revealing in contrast to other cytochromes an apparent low PO2 and high CN- affinity, probably due to a shortcut of electron flow within CCO between CuA and cytochrome a3-CuB.

Reciprocal photolabile O2 consumption and chemoreceptor excitation by carbon monoxide in the cat carotid body: evidence for cytochrome a3 as the primary O2 sensor.

High carbon monoxide (CO) gas tensions (> 500 Torr) at normoxic PO2 (125-140 Torr) stimulates carotid chemosensory discharge in the perfused carotid body (CB) in the absence but not in the presence of light. According to a metabolic hypothesis of O2 chemoreception, the increased chemosensory discharge should correspond to a photoreversible decrease of O2 consumption, unlike a non-respiratory hypothesis. We tested the respiratory vs. non-respiratory hypotheses of O2 chemoreception in the cat CB by measuring the effect of high CO. Experiments were conducted using CBs perfused and superfused in vitro with high CO in normoxic, normocapnic cell-free CO2-HCO3- buffer solution at 37 degrees C. Simultaneous measurements of the rate of O2 disappearance with recessed PO2 microelectrodes and chemosensory discharge were made after flow interruption with and without CO in the perfusate. The control O2 disappearance rate without CO was -3.66 +/- 0.43 (S.E.) Torr/s (100 measurements in 12 cat CBs). In the dark, high CO reduced the O2 disappearance rate to -2.35 +/- 0.33 Torr/s, or 64.2 +/- 9.0% of control (P < 0.005, 34 measurements). High CO was excitatory in the dark, with an increase in baseline neural discharge from 129.2 +/- 47.0 to 399.3 +/- 49.1 impulses per s (P < 0.0001), and maximum discharge rate of 659 +/- 76 impulses/s (N.S. compared to control) during flow interruption. During perfusion with high CO in the light, there were no significant differences in baseline neural discharge or in the maximum neural discharge after flow interruption, and little effect on O2 metabolism (88.8 +/- 11.5% of control, N.S., 29 measurements).(ABSTRACT TRUNCATED AT 250 WORDS)