Hongyang Xu scite author profile

Zinc (Zn) is a widespread industrial pollutant that causes detrimental effects to plant growth and development. Photoprotective properties ensure plant survival during stress by protecting the photosynthetic apparatus. This occurs via numerous mechanisms, including non-photochemical quenching (NPQ), cyclic electron flow (CEF), and the water-to-water cycle (WWC). However, whether and how Zn stress affects the photoprotective properties of plants to enhance tolerance of Zn toxicity remains unknown. In this study, we treated Melia azedarach plants with different Zn concentrations ranging from 200 to 1,000 mg Kg−1. We then analyzed the activities of two leaf photosynthetic pigment components—photosystems I and II (PSI and PSII) and the relative expression levels of their subunit genes. As expected, we found that Zn treatment decreases photosynthesis and increases photodamage in M. azedarach leaves. Zn treatments exacerbated a variety of photodamage phenotypes in photosystem activities and altered the expression levels of key photosystem complex genes and proteins. Furthermore, our results demonstrated that PSI was more seriously damaged than PSII under Zn stress. Subsequently, we compared differences in photodamage in the NPQ, CEF, and WWC photoprotection pathways under Zn stress and found that each exerted a protective function again photodamage under 200 mg Kg−1 Zn stress. NPQ and CEF may also play major protective roles to avoid irreversible photodamage and ensure survival under higher (i.e., 500 and 1,000 mg Kg−1) levels of Zn stress. Thus, our study revealed that NPQ- and CEF-based photoprotection mechanisms are more effective than WWC in M. azedarach upon Zn stress.

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Hongyang Xu

Soil microbial communities and their co-occurrence networks in response to long-term Pb–Zn contaminated soil in southern China

Along with cyclic electron flow and non-photochemical quenching, water-to-water cycle is involved uniquely in alleviating Zn stress-caused photodamage in Melia azedarach

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