# Elevated temperature simulating heatwaves restructures active nitrifying communities and associated viruses in tidal flats and agricultural soils

**Authors:** Baozhan Wang, Ping Gao, Ping Zhang, Yue Zheng, Xu Liu, Ning Ling, Jun Shan, Rongjiang Yao, Shuai Zhao, Zhiguo Zhang, Guibing Zhu, Man-Young Jung, Jianwen Zou, Xiaoyuan Yan, Sungeun Lee, Christina Hazard, Graeme W Nicol, Jizhong Zhou, Yunfeng Yang, Yongguan Zhu, David A Stahl, Michael Wagner, Yanzheng Gao, Jiandong Jiang, Wei Qin

PMC · DOI: 10.1093/ismejo/wrag037 · 2026-02-20

## TL;DR

Heatwaves caused by climate change change nitrifying communities and their viruses in tidal flats and agricultural soils, affecting the nitrogen cycle.

## Contribution

This study reveals how heatwaves reshape active nitrifier communities and their virus interactions in different ecosystems.

## Key findings

- Heatwaves reduced ammonia-oxidizing archaea and bacteria in tidal flats, shifting to thermotolerant terrestrial ecotypes.
- Agricultural soils showed suppressed AOB but increased activity in thermotolerant AOA under heatwave conditions.
- High temperatures altered virus-host interactions, favoring temperate infections and reducing virus-to-host abundance ratios.

## Abstract

Global heatwave intensification under climate change will impact the nitrogen cycle; yet, its effect on active nitrifier groups or their interactions with viruses remains unclear. Using 13CO2-DNA-based stable-isotope probing coupled with metagenomics, we show that elevated temperatures under heatwave conditions fundamentally restructure active nitrifying communities and their associated viruses in Yangtze River estuary upper tidal flats and adjacent agricultural soils. In tidal flats, sustained high temperature constrained nitrification by reducing the abundance of active ammonia-oxidizing archaea and bacteria (AOA, AOB) and canonical nitrite-oxidizing bacteria (NOB). This was accompanied by a shift in the active community from marine to more thermotolerant but less salt-tolerant terrestrial ecotypes. Conversely, heatwave conditions in agricultural soils suppressed AOB but enhanced nitrification activity in thermotolerant terrestrial AOA ecotypes. Across both ecosystems, inferred virus–nitrifier interactions were temperature dependent. 13C-labeled nitrifier-infecting viruses exhibited coordinated shifts in virus-to-host abundance ratios and predicted lifestyles with their hosts, with sustained high temperatures reducing virus-to-host abundance ratios and favoring temperate infections, relative to higher abundance ratios and a greater proportion of predicted lytic cycles at lower temperatures. We identified AOA-infecting viruses that carry plastocyanin (pcy), encoding a key copper-dependent electron carrier in the AOA respiratory chain, with conserved active sites and a predicted protein fold that supports its capacity for electron transfer, potentially augmenting host energy metabolism. Together, our findings demonstrate that prolonged heatwaves drive coupled shifts in nitrifier community composition and virus–host interaction strategies in a land-use–dependent manner, with implications for nitrogen transformations and ecosystem feedbacks under climate extremes.

## Linked entities

- **Species:** Aoa (taxon 320291)

## Full-text entities

- **Genes:** APTX (aprataxin) [NCBI Gene 54840] {aka AOA, AOA1, AXA1, EAOH, EOAHA, FHA-HIT}
- **Chemicals:** copper (MESH:D003300), 13CO2 (-), salt (MESH:D012492), nitrogen (MESH:D009584)

## Figures

4 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12998224/full.md

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Source: https://tomesphere.com/paper/PMC12998224