Lhcf9 is a novel negative regulator of non-photochemical quenching in the diatom Chaetoceros gracilis

Photosynthetic organisms in aquatic environments experience rapid fluctuations in light intensity, light quality, and carbon availability, requiring tight regulation of photosynthetic energy conversion. In marine diatoms, non-photochemical quenching (NPQ), particularly energy-dependent quenching (qE), plays a central role in dissipating excess excitation energy as heat. However, excessive NPQ can reduce photosynthetic efficiency under light-limiting or carbon-rich conditions, and how this trade-off is regulated remains poorly understood. Here, we identify CgLhcf9, a previously uncharacterized light-harvesting complex (LHC) protein, as a negative regulator of qE-type NPQ in the centric diatom Chaetoceros gracilis. Expression of CgLhcf9 is induced under low red-light and high CO2 conditions and strongly suppressed by blue light, indicating regulation by both light quality and carbon availability. Functional analyses using CgLhcf9 knockout and overexpression lines reveal that CgLhcf9 suppresses qE: NPQ induction is enhanced in the absence of CgLhcf9, whereas its accumulation downregulates NPQ without affecting other established qE effectors, including Lhcx1 or xanthophyll cycle pigments. Notably, CgLhcf9 accumulation improves cellular growth under light-limiting conditions. These results identify CgLhcf9 as a novel LHC-type regulator that fine-tunes photosynthetic energy dissipation in response to environmental signals. Our findings establish a regulatory mechanism that balances photoprotection, electron transport, and carbon fixation, advancing our understanding of how marine diatoms optimize photosynthesis under fluctuating light and CO2 conditions. Significance statementPhotosynthetic microalgae must balance light-driven electron transport with carbon fixation to maximize growth under fluctuating light and CO2 conditions. While non-photochemical quenching (NPQ) protects photosystems from excess light, excessive NPQ can limit photosynthetic efficiency when light or carbon is limiting. Here, we identify the antenna protein CgLhcf9 as a negative regulator of energy-dependent NPQ in the marine diatom Chaetoceros gracilis. CgLhcf9 integrates light-quality and CO2 signals to suppress NPQ without altering canonical quenching effectors, thereby improving growth under light-limiting conditions. This study reveals a regulatory role for a light-harvesting complex protein in tuning the balance between photoprotection and photosynthetic efficiency, providing insight into how marine diatoms coordinate electron transport and carbon fixation in dynamic environments.