In the heterocystous cyanobacterium Anabaena variabilis, a change in nitrogenase activity and concomitant modification of dinitrogenase reductase (the Fe protein of nitrogenase) was induced either by NH4Cl at pH 10 (S. Reich and P. Boger, FEMS Microbiol. Lett. 58:81-86, 1989) or by cessation of C supply resulting from darkness, CO2 limitation, or inhibition of photosystem II activity. Modification induced by both C limitation and NH4Cl was efficiently prevented by anaerobic conditions. Under air, endogenously stored glycogen and added fructose protected against modification triggered by C limitation but not by NH4Cl. With stored glycogen present, dark modification took place after inhibition of respiration by KCN. Reactivation of inactivated nitrogenase and concomitant demodification of dinitrogenase reductase occurred after restoration of diazotrophic growth conditions. In previously C-limited cultures, reactivation was also observed in the dark after addition of fructose (heterotrophic growth) and under anaerobiosis upon reillumination in the presence of a photosynthesis inhibitor. The results indicate that modification of dinitrogenase reductase develops as a result of decreased carbohydrate-supported reductant supply of the heterocysts caused by C limitation or by increased diversion of carbohydrates towards ammonia assimilation. Apparently, a product of N assimilation such as glutamine is not necessary for modification. The increase of oxygen concentration in the heterocysts is a plausible consequence of all treatments causing Fe protein modification.In the cyanobacterium Anabaena variabilis, aerobic nitrogen fixation by the enzyme complex nitrogenase (EC 1.18.6.1) is located in the heterocysts (12,13). Heterocysts are devoid of an oxygenic photosystem II and ribulose-1,5-bisphosphate carboxylase, which are operative in vegetative cells. Thus, N2 fixation is spatially separated from water photolysis and coupled ATP formation. The necessary ATP is generated in the heterocysts by photosystem Imediated photophosphorylation and by oxidative phosphorylation. Reductants are produced by dissimilation of fixed carbon imported from vegetative cells into heterocysts (for a review, see reference 41).It is accepted that cyanobacterial nitrogenase activity is controlled at the level of gene expression (13) and by the ability of cells to modulate the supply of reductants and ATP (7,8). Under air, nitrogenase activity in vivo is known to be inhibited by dark treatment (9, 33) and by photosynthesis inhibitors such as 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU), which is considered to be due to reductant limitation of heterocysts and concurrent oxygen inactivation of the heterocystous nitrogenase enzyme complex (24, 25). The repressing effect of excess ammonia and other nitrogenous compounds was attributed to enzyme turnover and regulation of enzyme biosynthesis (see, for example, references 4, 13, and 33). Some authors interpreted these effects in terms of inhibition of nitrogenase activity, possibly exerted by glutami...
