To evaluate the physiological significance of cyclic electron f low around photosystem (PS) I, we used a reverse genetic approach to focus on 11 chloroplast genes that encode homologs of mitochondrial complex I subunits (ndhA-K). Since their discovery, the exact function of the respiratory components in plant chloroplasts has been a matter of discussion. We disrupted one of these genes (ndhB) in tobacco by chloroplast transformation. Analysis of the transient increase in chlorophyll f luorescence after actinic light illumination and the redox kinetics of P700 (reaction center chlorophylls of PS I) suggest that the cyclic electron f low around PS I is impaired in the ndhB-deficient transformants. Transformants grew normally in a greenhouse, suggesting that the cyclic electron f low around PS I mediated by ndh gene products is dispensable in tobacco under mild environmental conditions.Photosynthetic electron flow provides the first stable products of photosynthesis: NADPH and ATP. Despite the importance of this electron flow, a fundamental problem remains unsolved; that is, how an appropriate balance between the production of NADPH and ATP is maintained. To answer this question, the contributions of the Q cycle, cyclic electron flow around photosystem (PS) I, and pseudocyclic electron flow (water-water cycle) in chloroplast energetics must be evaluated quantitatively (1). There is little doubt that cyclic electron flow around PS I provides extra ATP in some cellular processes, such as N 2 fixation in cyanobacterial heterocysts (2) and CO 2 concentration in cyanobacterial and C4 photosynthesis (3-8). However, it is unclear whether this cyclic electron flow contributes to the supply of ATP during steady-state photosynthesis in nonspecialized photosynthetic cells of higher plants (1, 9, 10).Although molecular biological dissection using a reverse genetic approach is an effective means to evaluate the physiological significance of cyclic electron flow around PS I, it has not been attempted because of a lack of information about the genes responsible for the electron flow. However, the discovery of an ndhB-deficient mutant of Synechocystis PCC6803 that lacked cyclic electron flow around PS I led to the idea that electron f low is mediated by the respiratory complex, NAD(P)H dehydrogenase, in cyanobacteria (4-8).Eleven ndh genes encoding homologs of mitochondrial complex I subunits are also present in the chloroplast genome of higher plants (11,12). Although respiratory function is limited to the mitochondria, a respiratory complex, NAD(P)H dehydrogenase, may catalyze cyclic electron flow around PS I in chloroplasts, as in cyanobacteria. However, the existence of NAD(P)H dehydrogenase-mediated electron flow in higher plants is still a matter of controversy (1, 13), because genes for the crucial flavoprotein subunits have not yet been identified (14). Moreover, physiological evidence alone has been insufficient to show an NAD(P)H dehydrogenase-mediated pathway for cyclic electron flow around PS I in higher plants...
