A study of dark luminescence in Chlorella. Background luminescence, 3-(3,4-dichlorophenyl)-1,1-dimethylurea-triggered luminescence and hydrogen peroxide chemiluminescence

Dark luminescence, defined as the ability of completely relaxed (darkadapted) photosynthetic systems to emit light, has been studied in Chlorella. Three main effects have been demonstrated. 3-(3,4-Dichlorophenyl)-1,1-dimethylurea elicits a weak emission L_D of very long lifetime (several minutes); it is believed to result from a negative shift of redox potential of the secondary System II electron acceptor B producing in some centers a state Q^? (reduced primary acceptor), as postulated by Velthuys and Amesz ((1974) Biochim. Biophys. Acta 333, 85–94), which can recombine with an oxidizing equivalent in a state S₂ present in very small amount. As in photoinduced luminescence, this recombination excites chlorophyll which then emits light. A much stronger emission L_H is observed after injection of H₂O₂. Both signals are modified or suppressed by treatments specific of the oxygen emission system, such as: thermal denaturation at 50°C, NH₂OH, etc. In addition, a weak, permanent background luminescence L₀ has been observed; like L_D and L_H, it is a System II property and requires the integrity of the oxygen-evolving system. It is believed to reflect a very slow back flow of electrons from an endogeneous reductant pool to oxygen through part of the photosynthetic chain. Using flash preillumination, it is demonstrated that H₂O₂ is able to oxidize S₀ into S₂, the latter giving rise to L_H; H₂O₂ does not act on S₁ (or much less). The reactive site of H₂O₂ seems to be the same as the binding site of NH₂OH. Evidence is given that the strong L_H signal in particular reveals a stable, low pH of the intrathylakoid phase in Chlorella.