# Leaf Traits Mediate Phyllosphere Bacterial Community Assembly and Their Role in Degrading Traffic-Derived Polycyclic Aromatic Hydrocarbons

**Authors:** Zheng Yang, Qingyang Liu, Shili Tian, Yanju Liu, Ming Yang, Ying Liang, Xin Chen

PMC · DOI: 10.3390/microorganisms14020334 · 2026-02-01

## TL;DR

This study explores how leaf traits and environmental factors influence bacterial communities on tree leaves that help break down harmful traffic-related pollutants in urban areas.

## Contribution

The study identifies specific leaf traits and bacterial taxa that influence PAH degradation in urban traffic environments.

## Key findings

- Leaf area, morphology, and sampling height significantly affect bacterial community assembly.
- Certain bacterial taxa, such as Kocuria rosea and Serratia symbiotica, show potential for degrading high molecular weight PAHs.
- Deterministic processes dominate bacterial community assembly on medium-sized and simple leaves.

## Abstract

Transport emissions are a major source of urban polycyclic aromatic hydrocarbons (PAHs), posing risks to human health. While plant leaves and their epiphytic microbes contribute to PAH degradation, how plant traits and environmental factors affect this process remains unclear. This study examined 20 tree species in Beijing’s traffic corridors to explore PAH enrichment on leaves and the structure of phyllospheric bacterial communities. Results show that leaf area, morphology, and sampling height significantly influenced bacterial community assembly. Normalized Stochasticity Ratio (NST) analysis indicated that deterministic processes dominate on medium-sized leaves (11.8–40.1 cm2), simple leaves, and those below 2.3 m or above 3 m in height, whereas stochastic factors prevail on nano leaves, compound leaves, and leaves at low-position (<2.3 m). Although low-molecular-weight PAHs (2–4 rings) were predominant in leaves, Mantel tests revealed significant positive correlations between bacterial communities and high molecular weight PAHs (4–6 rings), such as benz(a)anthracene, benzo[e]pyrene, and picene. Spearman analysis identified 10 dominant bacterial taxa with PAH degradation potential, including Kocuria rosea, Serratia symbiotica, Massilia sp. WG5, and seven unclassified species from Hymenobacter, Sphingomonas, Roseomonas, Curtobacterium, and Deinococcus. Functional Annotation of Prokaryotic Taxa(FAPROTAX) prediction further associated 14 species across six genera, including Acinetobacter, Nocardioides, Gordonia, Rhodococcus, Clostridium_sensu_stricto_18, and Geobacter, with PAH degradation function. This work clarifies the composition and function of phyllospheric PAH-degrading bacteria in an urban traffic environment, offering a theoretical basis for enhancing degradation via bacterial consortia, biosurfactants, and optimized plant selection.

## Linked entities

- **Chemicals:** benz(a)anthracene (PubChem CID 5954), benzo[e]pyrene (PubChem CID 9128), picene (PubChem CID 9162)
- **Species:** Kocuria rosea (taxon 1275), Serratia symbiotica (taxon 138074), Massilia sp. WG5 (taxon 1707785), Hymenobacter (taxon 89966), Sphingomonas (taxon 13687), Roseomonas (taxon 125216), Curtobacterium (taxon 2034), Deinococcus (taxon 1298), Acinetobacter (taxon 469), Nocardioides (taxon 1839), Gordonia (taxon 2053), Rhodococcus (taxon 1827), Geobacter (taxon 28231)

## Full-text entities

- **Diseases:** injury to (MESH:D014947), toxicity (MESH:D064420), carcinogenic (MESH:D011230)
- **Chemicals:** PAH (MESH:D011084), polyethylene (MESH:D020959), chrysene (MESH:C031180), naphthalene (MESH:C031721), alumina (MESH:D000537), water (MESH:D014867), Flt (MESH:C007738), carbon (MESH:D002244), fluorene (MESH:C041509), benzo[e]pyrene (MESH:C026487), aromatic hydrocarbon (MESH:D006841), dichloromethane (MESH:D008752), steel (MESH:D013232), n-hexane (MESH:C026385), benz(a)anthracene (MESH:C030935), benzo(b)fluoranthene (MESH:C006703), picene (MESH:C056699), pyrene (MESH:C030984), phenanthrene (MESH:C031181), retene (MESH:C447880), hydrocarbon (MESH:D006838), silica (MESH:D012822), aromatic compound (-)
- **Species:** Gordonia (genus) [taxon 79255], Massilia sp. (species) [taxon 1882437], Curtobacterium sp. (species) [taxon 1869344], Acinetobacter johnsonii (species) [taxon 40214], Sphingomonas (genus) [taxon 13687], Curtobacterium (genus) [taxon 2034], Deinococcus (genus) [taxon 1298], Acinetobacter (genus) [taxon 469], Geobacter (genus) [taxon 28231], Roseomonas (genus) [taxon 125216], Nocardioides plantarum (species) [taxon 29299], Kocuria rosea (species) [taxon 1275], Deinococcus sp. (species) [taxon 47478], Hymenobacter (genus) [taxon 89966], Homo sapiens (human, species) [taxon 9606], Rhodococcus (genus) [taxon 1661425], Serratia symbiotica (species) [taxon 138074], Acetobacteraceae (family) [taxon 433], Nocardioides (genus) [taxon 1839], Sphingomonas sp. (species) [taxon 28214], Roseomonas sp. (species) [taxon 1869190]
- **Mutations:** P14H, P11H, P16L, P17H, P19H, P19L, P17L, P16H, P12L, P20L, P14L, P12H, P10H, P18L, P15L, P13H, P11L, P20H, P15H, P13L, P10L, P18H

## Figures

8 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12943549/full.md

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Source: https://tomesphere.com/paper/PMC12943549