Role of nitric oxide and mitochondria in control of firefly flash

In light-producing cells (photocytes) of the firefly light organ,mitochondria are clustered in the cell periphery, positionedbetween the tracheolar air supply and the oxygen-requiring bioluminescentreactants which are sequestered in more centrally-localizedperoxisomes. This relative positioning suggests that mitochondriacould control oxygen availability for the light reaction. Wehypothesized that active cellular respiration would make theinterior regions of the photocytes relatively hypoxic, and thatthe "on" signal for production of bioluminescence might dependon inhibition of mitochondrial oxygen consumption, which wouldallow delivered oxygen to pass through the peripheral mitochondrialzone to reach peroxisomes deep in the cell interior. We publishedrecently that exogenous NO induces bioluminescence in the intactfirefly; that NO mediates octopamine-induced bioluminescencein the dissected lantern, and that nitric oxide synthase isabundant in cells of the tracheolar system of the light organ.Additional experiments showed that nitric oxide gas (NO) inhibitsrespiration in isolated lantern mitochondria. Inhibition isreversed by bright light, and this inhibition is relieved whenthe light is turned off. Altogether, the results support theidea that NO triggers light production by reversible inhibitionof mitochondrial respiration in lantern cells, and probablyin tracheolar cells as well. The data also suggest that thelight of bioluminescence itself relieves NO inhibition thuscontributing to rapid on/off switching. While other mechanismsmay be in play, NO production that is directly related to neuralinput appears to have a key role in the oxygen gating that controlsflash communication signals.