Abstract: By DNA recombination technology in vitro, ORF469- mutant of cynobacterium Synechocystis sp. PCC 6803 was constructed, in which the ORF469 fragment relative to the light-inde-pendent protochlorophyllide (Pchlide) reduction was deleted. In BG-11 medium with 5 mmol/L glucose, the mutant was grown in darkness with a brief period (10 min) of illumination everyday (light-activated heterotrophic growth, LAHG) for 2 weeks to delete chlorophyll (Chl). The 665 mn Chl peak was replaced by the 629 nm Pchlide peak in the absorption spectra of the methanol extracts. The absorption spectra of the intact cells showed only shoulder peak at 620 nm (representing phyco- biliprotein). The thylakoid membrane disappeared, but the amount of phycobilisome did not decrease. When the mutant was transferred from LAHG condition to continuous light illumination for 3 h, the absorbance at 665 nm became higher than that at 629 nm and two peaks at 620 nm and 440 nm,representing phycobiliprotein and Chi-protein complex respectively, appeared in the absorption spectra of the intact cells. Mter exposure to the light for 8 h, the thylakoid membrane was visible in the cells. And for 24 h, a shoulder peak was present at 680 nm in the absorption spectra of the intact cells. Meanwhile the absorption spectra of the methanol extracts had no difference from that of cells grown in the light. Mter 48 h, the shape of the absorption spectra of the intact cells became the same as that of cells grown in the light. The layers of thylakoid membranes were as clear as those of the cells grown in the light. The results indicated that the biosynthesis of chlorophyll regulates the reconstmction of thylakoid membrane rendering the Chl protein complex to play its functional role in photosystems.

Key words: DNA recombination, Reconstruction of thylakoid membrane, Light-independent synthesis of chlorophyll