Molecular diversity in the adenylylcyclase family. Evidence for eight forms of the enzyme and cloning of type VI.

The conservation of amino acid sequence among types I-IV adenylylcyclase has made it possible to apply the polymerase chain reaction to examine the extent of the molecular diversity within this family of enzymes. cDNA templates from rat heart, liver, kidney, guinea pig brain and testes, and mouse skeletal muscle were amplified with primers specific to adenylylcyclase sequences. Evidence was obtained for a total of eight distinct gene products divisible into five subfamilies. Five of the products correspond to regions from cloned forms of adenylylcyclase, while three are previously unidentified. As many as seven different adenylylcyclases are expressed in rat heart, liver, and kidney based on this analysis. Two newly identified polymerase chain reaction (PCR) products were utilized to screen a rat cDNA library from H35 Reuber hepatoma cells. A 6080-nucleotide cDNA contains an open reading frame encoding the 1166-amino acid type VI protein which has a predicted topography similar to that of other adenylylcyclases. The type VI message is abundantly expressed in rat heart, kidney, and brain. Human embryonal kidney cells stably expressing the cDNA showed an enhanced response to isoproterenol that could be inhibited by carbachol in intact cells. Increases in intracellular Ca2+ contribute to the inhibitory effect of carbachol.

A new form of mammalian electron-transferring flavoprotein.

Mammalian electron-transferring flavoproteins have previously been reported to form the red anionic semiquinone on 1-electron reduction. This work describes a new form of electron-transferring flavoprotein (ETFB) from pig kidney which yields the blue neutral semiquinone upon photochemical, dithionite, or enzymatic reduction. ETFB appears in varying amounts as part of an established purification scheme for ETF. Both the normal form of ETF (ETFR) and ETFB show small differences in the spectra of their oxidized flavins, but no detectable differences in molecular weight or subunit composition. The catalytic activities of ETFR and ETFB are comparable when they mediate the transfer of reducing equivalents between medium chain acyl-CoA dehydrogenase and 2,6-dichlorophenolindophenol. ETFB can be converted into a form showing the characteristic red semiquinone of ETFR by full reduction at pH 6.5 or by preparation of the apoprotein and reconstitution with FAD. In contrast, no conditions for the conversion of red to blue forms of ETF have been found. ETFB contains substoichiometric levels of an unusual FAD analogue which yields a pink flavin species on photochemical or dithionite reduction. The evidence presented suggests that ETFB contains a labile factor or protein modification which is irreversibly lost on conversion to ETFR. The possible physiological significance of these data is discussed.

Alternate electron acceptors for medium-chain acyl-CoA dehydrogenase: use of ferricenium salts.

Medium-chain acyl-CoA dehydrogenase reduced with octanoyl-CoA is reoxidized in two one-electron steps by two molecules of the physiological oxidant, electron transferring flavoprotein (ETF). The organometallic oxidant ferricenium hexafluorophosphate (Fc+PF6-) is an excellent alternative oxidant of the dehydrogenase and mimics a number of the features shown by ETF. Reoxidation of octanoyl-CoA-reduced enzyme (200 microM Fc+PF6- in 100 mM Hepes buffer, pH 7.6, 1 degree C) occurs in two one-electron steps with pseudo-first-order rate constants of 40 s-1 and about 200 s-1 for k1 and k2, respectively. The reaction is comparatively insensitive to ionic strength, and evidence of rate saturation is encountered at high ferricenium ion concentration. As observed with ETF, the free two-electron-reduced dehydrogenase is a much poorer kinetic reductant of Fc+PF6-, with rate constants of 3 s-1 and 0.3 s-1 (for k1 and k2, respectively) using 200 microM Fc+PF6-. In addition to the enoyl-CoA product formed during the dehydrogenation of octanoyl-CoA, binding a number of redox-inert acyl-CoA analogues (notably 3-thia- and 3-oxaoctanoyl-CoA) significantly accelerates electron transfer from the dehydrogenase to Fc+PF6-. Those ligands most effective at accelerating electron transfer favor deprotonation of reduced flavin species in the acyl-CoA dehydrogenase. Thus this rate enhancement may reflect the anticipated kinetic superiority of anionic flavin forms as reductants in outer-sphere electron-transfer processes. Evidence consistent with the presence of two distinct loci for redox communication with the bound flavin in the acyl-CoA dehydrogenase is presented.

An acyl-coenzyme A dehydrogenase assay utilizing the ferricenium ion.

A sensitive assay for medium chain acyl-CoA dehydrogenase has been developed by substituting ferricenium hexafluorophosphate for the physiological acceptor, electron transferring flavoprotein. The ferricenium ion is a facile oxidant of the octanoyl-CoA-reduced enzyme with a Vmax of 1400 min-1 and a KM of 55 microM at pH 7.6. The ferricenium assay does not require additional mediator dyes, exhibits low background rates, and avoids the necessity of purifying substantial amounts of electron transferring flavoprotein. Unlike the fluorescence-based electron transferring flavoprotein assay, this new procedure can be performed aerobically. Both assays give comparable results when tested with crude fibroblast homogenates from normal and medium chain acyl-CoA dehydrogenase deficient patients. The convenience of the ferricenium method suggests it may be generally useful as a screening assay for a number of acyl-CoA dehydrogenases.