Flow cytometry-based biomarker assay forin vitroidentification of heat tolerance conferring coral symbionts

Abstract

ABSTRACTCorals’ tolerance to high temperature stress largely depends on their symbiotic microalgae (Symbiodiniaceae). However, the contributing microalgal traits are largely unclear. Here we compare thein vitrocellular profiles of sevenCladocopium C1acromicroalgal strains (derived from the same ancestral strain) during a four-week exposure to 27°C or 31°C. One was an unselected wild-type strain (WT), three were selected at 31°C for nine years and shown to confer thermal tolerance on the coral host (SS+) and three others were similarly selected but did not confer tolerance (SS-). Flow cytometry was used to measure the intracellular stress indicators reactive oxygen species (ROS), reduced glutathione (rGSH) and mitochondrial-membrane potential (ΔΨm), as well as cell size/shape and photosynthetic pigments. Cell densities and photosynthetic efficiency (ΦPSII, Fv/Fm) were also measured. WT showed the highest levels of intracellular ROS and ΔΨm, lowest rGSH and largest cell sizes at both temperatures. SS+ strains had the lowest ROS and highest rGSH values and a unique pattern of correlations among parameters at 31°C. Our results support previous reports implicating the role of microalgal ROS, ΔΨm and rGSH in holobiont thermal tolerance and suggest flow cytometry is a useful pre-screening tool for identifying microalgal strains with enhanced thermal tolerance.