Increased CO2 exacerbates the stress of ultraviolet radiation on photosystem II function in the diatom Thalassiosira weissflogii.

Highlights • Increased CO 2 and UVR synergistically reduce photosystem II activity. • Increased CO 2 increases PsbA removal rate but reduces PsbD's. • Both increased CO 2 and UVR enhance nonphotochemical quenching. • Increased CO 2 decreases the ratio of Rubisco large subunit (RbcL) to PsbA. Abstract Diatoms usually dominate phytoplankton community in coastal waters and experience rapid changes of underwater light. However, little is known regarding how increased CO 2 would affect diatoms' capacity in dealing with changing photosynthetically active radiation (PAR) and ultraviolet radiation (UVR). Here, we cultured a globally abundant diatom Thalassiosira weissflogii under two levels of CO 2 (400, 1000 ppmv), and then analysed its PSII function during an increase in PAR and UVR to mimic an upward mixing event. UVR noticeably reduced photosystem II (PSII) activity (F V /F M) during the high light exposure, which was more significant for cells grown at the higher CO 2 condition. The PsbA removal rate (K PsbA) was synergistically increased by high CO 2 and UVR, while the PsbD removal rate (K PsbD) was decreased under higher CO 2. Both CO 2 and UVR had an inducible effect on sustained phase of nonphotochemical quenching (NPQs). The higher CO 2 decreased the ratio of Rubisco large subunit (RbcL) to PsbA regardless of the radiation treatments. It seems that the increased NPQs and turnover of PsbA induced by higher CO 2 were not enough to offset the stressful effect it brought about, particularly when higher CO 2 was combined with UVR. These findings indicate that increased CO 2 may exacerbate the harmful effect of UVR on PSII function in the T. weissflogii through reducing PsbD removal rate and the ratio of RbcL to PsbA during UVR exposure, and thus would affect its abundance and distribution in future ocean environment. [ABSTRACT FROM AUTHOR]