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Intraspecific Diversity in Thermal Performance Determines Phytoplankton Ecological Niche

Arianna I. Krinos, Sara K. Shapiro, Weixuan Li, Sheean T. Haley, Sonya T. Dyhrman, Stephanie Dutkiewicz, Michael J. Follows, Harriet Alexander

2025Ecology Letters14 citationsDOIOpen Access PDF

Abstract

ABSTRACT Temperature has a primary influence on phytoplankton physiology and ecology. We grew 12 strains of Gephyrocapsa huxleyi isolated from different‐temperature regions for ~45 generations (2 months) and characterised acclimated thermal response curves across a temperature range. Even with similar temperature optima and overlapping cell size, strain growth rates varied between 0.45 and 1 day −1 . Thermal niche widths varied from 16.7°C to 24.8°C, suggesting that strains use distinct thermal response mechanisms. We investigated the implications of this thermal intraspecific diversity using an ocean ecosystem simulation resolving phytoplankton thermal phenotypes. Model analogues of thermal ‘generalists’ and ‘specialists’ resulted in a distinctive global biogeography of thermal niche widths with a nonlinear latitudinal pattern. We leveraged model output to predict ranges of the 12 lab‐reared strains and demonstrated how this approach could broadly refine geographic range predictions. Our combination of observations and modelled biogeography highlights the capacity of diverse groups to survive temperature shifts.

Topics & Concepts

EcologyIntraspecific competitionNichePhytoplanktonEcological nicheDiversity (politics)Ecosystem diversityBiologyMacroecologyBiodiversityGeographyNutrientHabitatAnthropologySociologyPhysiological and biochemical adaptationsOcean Acidification Effects and ResponsesMarine Biology and Ecology Research
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