Quantifying the role of photoacclimation and self-facilitation for seagrass resilience to light deprivation

Front Plant Sci. 2023 Jul 21:14:1186538. doi: 10.3389/fpls.2023.1186538. eCollection 2023.

Abstract

Introduction: Light gradients are ubiquitous in marine systems as light reduces exponentially with depth. Seagrasses have a set of mechanisms that help them to cope with light stress gradients. Physiological photoacclimation and clonal integration help to maximize light capture and minimize carbon losses. These mechanisms can shape plants minimum light requirements (MLR), which establish critical thresholds for seagrass survival and help us predict ecosystem responses to the alarming reduction in light availability.

Methods: Using the seagrass Cymodocea nodosa as a case study, we compare the MLR under different carbon model scenarios, which include photoacclimation and/or self-facilitation (based on clonal integration) and that where parameterized with values from field experiments.

Results: Physiological photoacclimation conferred plants with increased tolerance to reducing light, approximately halving their MLR from 5-6% surface irradiance (SI) to ≈ 3% SI. In oligotrophic waters, this change in MLR could translate to an increase of several meters in their depth colonization limit. In addition, we show that reduced mortality rates derived from self-facilitation mechanisms (promoted by high biomass) induce bistability of seagrass meadows along the light stress gradient, leading to abrupt shifts and hysteretic behaviors at their deep limit.

Discussion: The results from our models point to (i) the critical role of physiological photoacclimation in conferring greater resistance and ability to recover (i.e., resilience), to seagrasses facing light deprivation and (ii) the importance of self-facilitating reinforcing mechanisms in driving the resilience and recovery of seagrass systems exposed to severe light reduction events.

Keywords: Cymodocea nodosa; bistability; minimum light requirements; physiological photoacclimation; resilience.

Grants and funding

Funding was provided by grant UMBRAL, CTM2017-86695-C3-3-R and CTM2017-86695-C3-1-R, as well as grant STORM, PID2020-113745RB-I00 from the Spanish Agency of Research (AEI-MICINN) and European funding (FEDER/ERDF). MM-F was funded by grant PRE2018-085778 from the Spanish FPI PhD scholarships program. JB acknowledges the support received by the Spanish Ministry of Science and Innovation under the JdC fellowship (FJC2018-035566-I) and the European Commission – European Union’s Horizon 2020 MSCA – SHIFT2SOLVE-1030591. MA’s contribution was funded by an Australian Research Council (ARC) Discovery Early Career Researcher Award (DE200100683).