# Contrasting Responses of Oceanic and Coastal Synechococcus to Iron Limitation and Warming Interactions

**Authors:** Ran Duan, Min Xu, Xiaopeng Bian, Conner Y. Kojima, Shengwei Hou, Qiang Zheng, Seth G. John, David A. Hutchins, Fei‐Xue Fu

PMC · DOI: 10.1111/1758-2229.70158 · 2025-07-18

## TL;DR

This study compares how two types of Synechococcus bacteria from different ocean environments respond to iron shortages and warming, finding that the open ocean strain adapts more effectively.

## Contribution

The study reveals distinct physiological and transcriptional strategies in oceanic and coastal Synechococcus under iron limitation and warming.

## Key findings

- Oceanic Synechococcus upregulates photosynthesis and nutrient transport genes under iron limitation and warming.
- Coastal Synechococcus has higher iron quotas and faster D1 gene turnover but fewer regulatory responses to stress.
- Fe-temperature interactions may influence marine biogeochemistry and plankton dynamics in warmer oceans.

## Abstract

This study explored the contrasting physiological and transcriptional responses to iron (Fe) and warming temperature interactions in two South China Sea Synechococcus isolates belonging to clade II from the open ocean and CB5 from the coastal ocean. The two picocyanobacterial strains utilised contrasting photosynthesis, Fe uptake, and nutrient acquisition strategies to cope with Fe limitation. In the oceanic strain, moderate warming under Fe limitation upregulated expression of photosynthesis and nutrient and Fe transport genes, increasing its growth and photosynthesis. In contrast, gene expression under low Fe in the coastal strain was less affected by warming. The oceanic isolate exhibited substrate regulation of Fe acquisition and preferred organic nutrient sources. The coastal strain had a much higher Fe quota, faster turnover of the D1 gene in photosystem II, and was optimised for inorganic nitrogen sources. Both strains showed multi‐tiered Fe uptake strategies and general stress responses to heat shock and oxidative stress. In general, gene regulation in the oceanic strain responded more effectively to both stressors than in the coastal isolate. Fe‐temperature interactions in both strains are complex and may lead to synergistic and antagonistic responses, potentially influencing global biogeochemical cycles in warmer oceans.

Oceanic Synechococcus respond to the interactive effects of iron (Fe) limitation and ocean warming by regulating photosynthesis, nutrient metabolism, and heat shock gene expression, while a coastal strain has fewer regulatory mechanisms. The oceanic strain may be a superior competitor with more comprehensive and flexible responses in Fe‐poor subtropical open ocean regimes. Fe‐temperature interactions may lead to complex synergistic and antagonistic responses, with significant implications for future plankton community dynamics and marine biogeochemistry.

## Linked entities

- **Genes:** LMOD1 (leiomodin 1) [NCBI Gene 25802]
- **Chemicals:** iron (PubChem CID 23925)
- **Species:** Synechococcus (taxon 1129)

## Figures

8 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12274634/full.md

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Source: https://tomesphere.com/paper/PMC12274634