Temporal heterogeneity in photosystem II photochemistry in Artemisia ordosica under a fluctuating desert environment

Chuan Jin; Tianshan Zha; Charles P-A Bourque; Xin Jia; Yun Tian; Peng Liu; Xinhao Li; Xinyue Liu; Xiaonan Guo; Mingze Xu; Xiaoyu Kang; Zifan Guo; Ning Wang

doi:10.3389/fpls.2022.1057943

Temporal heterogeneity in photosystem II photochemistry in Artemisia ordosica under a fluctuating desert environment

Front Plant Sci. 2022 Nov 3:13:1057943. doi: 10.3389/fpls.2022.1057943. eCollection 2022.

Authors

Chuan Jin¹, Tianshan Zha^{1

2}, Charles P-A Bourque^{1

3}, Xin Jia^{1

2}, Yun Tian^{1

2}, Peng Liu¹, Xinhao Li¹, Xinyue Liu¹, Xiaonan Guo⁴, Mingze Xu¹, Xiaoyu Kang³, Zifan Guo¹, Ning Wang¹

Affiliations

¹ Yanchi Research Station, School of Soil and Water Conservation, Beijing Forestry University, Beijing, China.
² Key Laboratory for Soil and Water Conservation, State Forestry and Grassland Administration, Beijing Forestry University, Beijing, China.
³ Faculty of Forestry and Environmental Management, University of New Brunswick, Fredericton, NB, Canada.
⁴ School of Land Science and Space Planning, Hebei GEO University, Shijiazhuang, China.

Abstract

Acclimation strategies in xerophytic plants to stressed environmental conditions vary with temporal scales. Our understanding of environmentally-induced variation in photosystem II (PSII) processes as a function of temporal scales is limited, as most studies have thus far been based on short-term, laboratory-controlled experiments. In a study of PSII processes, we acquired near-continuous, field-based measurements of PSII-energy partitioning in a dominant desert-shrub species, namely Artemisia ordosica, over a six-year period from 2012-2017. Continuous-wavelet transformation (CWT) and wavelet coherence analyses (WTC) were employed to examine the role of environmental variables in controlling the variation in the three main PSII-energy allocation pathways, i.e., photochemical efficiency and regulated and non-regulated thermal dissipation, i.e., Φ _PSII, Φ _NPQ, and Φ _NO, respectively, across a time-frequency domain from hours to years. Convergent cross mapping (CCM) was subsequently used to isolate cause-and-effect interactions in PSII-energy partitioning response. The CWT method revealed that the three PSII-energy allocation pathways all had distinct daily periodicities, oscillating abruptly at intermediate timescales from days to weeks. On a diurnal scale, WTC revealed that all three pathways were influenced by photosynthetically active radiation (PAR), air temperature (T _a), and vapor pressure deficit (VPD). By comparing associated time lags for the three forms of energy partitioning at diurnal scales, revealed that the sensitivity of response was more acutely influenced by PAR, declining thereafter with the other environmental variables, such that the order of influence was greatest for T _a, followed by VPD, and then soil water content (SWC). PSII-energy partitioning on a seasonal scale, in contrast, displayed greater variability among the different environmental variables, e.g., Φ _PSII and Φ _NO being more predisposed to changes in T _a, and Φ _NPQ to changes in VPD. CCM confirmed the causal relationship between pairings of PSII-energy allocation pathways, according to shrub phenology. A. ordosica is shown to have an innate ability to (i) repair damaged PSII-photochemical apparatus (maximum quantum yield of PSII photochemistry, with F _v/F _m > 0.78), and (ii) acclimatize to excessive PAR, dry-air conditions, and prolonged drought. A. ordosica is relatively sensitive to extreme temperature and exhibits photoinhibition.

Keywords: arid regions; chlorophyll fluorescence; desert plant; diurnal variation; seasonal fluctuations; wavelet analysis.