# Regional climate variation structures the phyllosphere microbiome of flue-cured tobacco

**Authors:** Cheng Zhang, Lei Yang, Xiaohua Zhang, Yuhang Zhao, Jiati Tang, Zhijun Cheng, Yi Cao, Shengjiang Wu, Guanhui Li, Long Yang, Kesu Wei

PMC · DOI: 10.3389/fpls.2025.1733198 · Frontiers in Plant Science · 2026-01-15

## TL;DR

This study shows how climate variations shape the leaf microbiome of tobacco, influencing its structure and metabolism to help the plant adapt.

## Contribution

The study reveals how microbial networks and metabolic functions adapt to climate gradients, emphasizing the role of rare taxa in maintaining resilience.

## Key findings

- Bacterial communities are shaped by precipitation, while fungal communities are driven by temperature.
- Microbial networks in arid regions are simplified and dominated by drought-tolerant taxa like Sphingomonas and Methylobacterium.
- Low-precipitation areas show increased potential for starch degradation, while high-precipitation areas favor sucrose synthesis.

## Abstract

Climate change poses major challenges to agriculture, with phyllosphere microbiota playing a key but poorly understood role in plant adaptation.

We examined structural and functional responses of the phyllosphere microbiome in flue-cured tobacco (Nicotiana tabacum L.) across climatic gradients, using multi-regional sampling, high-throughput sequencing (16S rRNA/ITS), and functional prediction (PICRUSt2).

Leaf starch, total sugar, and reducing sugar contents varied significantly (26.87–32.25%, 14.24–16.74%, and 9.96–11.26%, respectively). Bacterial communities were primarily shaped by precipitation (41.7% variance explained), whereas fungal communities were mainly driven by temperature (27.3%). Microbial networks showed climate-adaptive patterns: complex, cooperative networks (85.99% positive edges) in high-precipitation areas versus simplified, drought-tolerant networks (Nodes: 93, Edges: 1124) dominated by Sphingomonas (86.50%) and Methylobacterium (10.24%) in arid regions. Metabolic potential shifted along the gradient: Communities in low-precipitation areas were enriched with genes potentially encoding starch-degrading enzymes (e.g., α-amylase), while those in high-precipitation areas showed enhanced potential for sucrose synthesis (e.g., via sucrose synthase).

This study reveals the adaptive strategies of phyllosphere microbial communities in response to climate variations. Under low-rainfall conditions, community metabolism shifts toward starch degradation, which may aid host osmoregulation. In contrast, under humid conditions, dominant taxa such as Sphingomonas and Methylobacterium collaboratively enhance sucrose synthesis. This metabolic reprogramming aligns with structural changes in microbial networks: transitioning from complex, cooperative networks in humid regions to simplified, stress-tolerant networks in low-rainfall areas. Key metabolic functions are primarily contributed by low-abundance taxa, suggesting the vital role of the rare biosphere in maintaining functional redundancy. Based on these findings, we propose that microbial communities may enhance adaptability by retaining core metabolic functions, such as starch degradation, within rare taxa when facing drought or temperature fluctuations. This study provides a theoretical framework for improving crop climate resilience through microbiome management.

## Linked entities

- **Genes:** SUS2 (sucrose synthase 2) [NCBI Gene 834978]
- **Species:** Sphingomonas (taxon 13687), Methylobacterium (taxon 407)

## Full-text entities

- **Genes:** sucrose synthase [NCBI Gene 107789131]
- **Chemicals:** starch (MESH:D013213), sucrose (MESH:D013395), sugar (MESH:D000073893)
- **Species:** Nicotiana tabacum (American tobacco, species) [taxon 4097], Sphingomonas (genus) [taxon 13687], Methylobacterium (genus) [taxon 407]

## Full text

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## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12866982/full.md

## References

54 references — full list in the complete paper: https://tomesphere.com/paper/PMC12866982/full.md

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Source: https://tomesphere.com/paper/PMC12866982