It is common, textbook knowledge that plants use light to grow. The process of photosynthesis relies on capturing light by pigment-binding proteins located in the chloroplast. Then, a series of electron transfer reactions follows, allowing photosynthetic organisms to reduce atmospheric carbon in CO2. However, sunlight is also constantly damaging plants’ photosynthetic apparatus. In particular, Photosystem II (PSII), the multimeric light-driven enzyme capable of water oxidation in the first step of photosynthetic electron transfer, very often becomes damaged and requires disassembly and repair. The impairment of PSII due to light is called photoinhibition. During the course of this Marie Skłodowska-Curie fellowship, we investigated first steps of photodamage process to better understand the Janus-faced relationship between plants and light. Comprehension of the initial stages of photoinhibition is crucial because it is one of the main processes that limits the growth of plants in the natural conditions and as such, possesses a large energetic cost for these organisms.
In particular, presence of light prompts plants to develop or trigger mechanisms allowing them to dissipate some of the excess absorbed energy, termed non-photochemical quenching (NPQ). We aimed at describing the location of this quenching after photoinhibition was triggered in living organisms, and then providing full characteristics of this process.