Phycocyanin， which covalently binds phycocyanobilin chromophores， is not only a candidate fluorescent probe for biological imaging， but also a potential antioxidative agent for healthcare. Herein， a plasmid harboring two cassettes was constructed， with from in one cassette and the fusion gene in the other， and then expressed in . PCB-CpcB(C-82)， a fluorescent phycocyanin β subunit， was biosynthesized in ， exhibiting an absorption maximum at 620 nm and fluorescence emission maximum at 640 nm. When was replaced by ， PCB-CpcB(C-153)， another fluorescent phycocyanin β subunit， was produced， exhibiting an absorption maximum at 590 nm and fluorescence emission maximum at 620 nm. These two fluorescent biliproteins showed stronger scavenging activity toward hydroxyl and DPPH free radicals than apo-CpcB. The IC values for hydroxyl radical scavenging by PCB-CpcB(C-82)， PCB-CpcB(C-153)， and apo-CpcB were 38.72 ± 2.48 µg/mL， 51.06 ± 6.74 µg/mL， and 81.82 ± 0.67 µg/mL， respectively， and the values for DPPH radical scavenging were 201.00 ± 5.86 µg/mL， 240.34 ± 4.03 µg/mL， and 352.93 ± 26.30 µg/mL， respectively. The comparative antioxidant capacities of the proteins were PCB-CpcB(C-82) > PCB-CpcB(C-153) > apo-CpcB， due to bilin binding. The two fluorescent biliproteins exhibited a significant effect on relieving the growth of cells injured by H₂O₂. The results of this study suggest that the fluorescent phycocyanin β subunits of were reconstructed by one expression vector in ， and could be developed as potential antioxidants.