Bacillus azotoformans is a Gram-positive denitrifying soil bacterium, which is capable of respiring nitrate, nitrite, nitric oxide, and nitrous oxide under anaerobic conditions. It contains a unique menaquinol-dependent nitric oxide reductase (qCu(A)NOR) with a Cu(A) center in its small subunit. The qCu(A)NOR exhibits menaquinol-dependent NO reductase activity, whereas reduced horse heart cytochrome c was inactive. Here we describe the purification of three membrane-bound c cytochromes from B. azotoformans. Their apparent molecular masses on SDS-PAGE are approximately 11 kDa. At neutral pH, these c cytochromes are negatively charged and the E(m) for all is close to 150 mV. Only one of these c cytochromes, which exhibits an alpha-band maximum at 551 nm, acts as a direct electron donor to qCu(A)NOR. Further investigation demonstrated that this cytochrome c(551) possesses two lipoyl moieties, which presumably function to anchor it to the membrane. Steady-state kinetic studies reveal that cytochrome c(551) is a noncompetitive inhibitor of NO reduction when menaquinol is used as an electron donor. This finding points to the presence of two different electron donation pathways in qCu(A)NOR. The ability of qCu(A)NOR to accept electrons from both menaquinol and cytochrome c(551) might be related to the regulation of the rate of NO reduction especially as a defense mechanism of B. azotoformans against the toxicity of NO. Growth experiments in batch culture indeed show that B. azotoformans is highly NO tolerant, in contrast to, for example, Paracoccus denitrificans that has a monofunctional cytochrome c-dependent NOR. We propose that the menaquinol pathway, which has a 4-fold greater maximal activity than the pathway via cytochrome c(551), is used for NO detoxification, whereas electron donation via the endogenous cytochrome c involves the cytochrome b(6)f complex serving the bioenergetic needs of the organism.