The isocyclic ring (E-ring) is a common structural feature of chlorophylls. The E-ring is formed by two structurally unrelated Mg-protoporphyrin IX monomethylester (MPE) cyclase systems, oxygen-dependent (AcsF), and oxygen-independent (BchE) systems, which involve incorporation of an oxygen atom from molecular oxygen and water into the C-13(1) position of MPE, respectively. Which system operates in cyanobacteria that can thrive in a variety of anaerobic environments remains an open question. The cyanobacterium Synechocystis sp. PCC 6803 has two acsF-like genes, sll1214 (chlA(I)) and sll1874 (chlA(II)), and three bchE-like genes, slr0905, sll1242, and slr0309. Five mutants lacking one of these genes were isolated. The DeltachlA(I) mutant failed to grow under aerobic conditions with anomalous accumulation of a pigment with fluorescence emission peak at 595 nm, which was identified 3,8-divinyl MPE by high-performance liquid chromatography-mass spectrometry analysis. The growth defect of DeltachlA(I) was restored by the cultivation under oxygen-limited (micro-oxic) conditions. MPE accumulation was also detected in DeltachlA(II) grown under microoxic conditions, but not in any of the bchE mutants. The phenotype was consistent with the expression pattern of two chlA genes: chlA(II) was induced under micro-oxic conditions in contrast to the constitutive expression of chlA(I). These findings suggested that ChlA(I) is the sole MPE cyclase system under aerobic conditions and that the induced ChlA(II) operates together with ChlA(I) under micro-oxic conditions. In addition, the accumulation of 3,8-divinyl MPE in the DeltachlA mutants suggested that the reduction of 8-vinyl group occurs after the formation of E-ring in Synechocystis sp. PCC 6803.