# Microbial Selection and Functional Adaptation in Technical Snow: A Molecular Perspective from 16S rRNA Profiling

**Authors:** Anna Lenart-Boroń, Piotr Boroń, Bartłomiej Grad, Klaudia Bulanda, Natalia Czernecka-Borchowiec, Anna Ratajewicz, Klaudia Stankiewicz

PMC · DOI: 10.3390/ijms26199712 · 2025-10-06

## TL;DR

This study explores how artificial snow affects microbial communities, revealing cold-adapted bacteria and potential pathogens in snowmaking systems.

## Contribution

The paper introduces a molecular ecological framework for assessing microbial impacts of technical snowmaking in alpine regions.

## Key findings

- Technical snow hosts cold-adapted bacteria like Brevundimonas and Massilia with stress tolerance traits.
- Functional analysis shows dominance of chemoheterotrophy and potential pathogenic genera in sediments and meltwater.
- Snowmaking systems act as selective environments for microbial survival and persistence of environmental resilience traits.

## Abstract

Artificial (technical) snow production is an increasingly common practice in alpine regions, yet little is known about its role in shaping microbial communities at the molecular level. In this study, we combined culture-based methods with high-throughput 16S rRNA gene sequencing and functional trait prediction (FAPROTAX) to investigate bacterial communities across the full technical snowmaking cycle in one of Polish ski resorts. The molecular profiling revealed that technical snow harbors dominant taxa with known cold-adaptation mechanisms, biofilm-forming abilities, and stress tolerance traits (e.g., Brevundimonas, Lapillicoccus, Massilia, with a relative abundance of 2.95, 2.14, 3.38 and 5.61%, respectively). Functional inference revealed a consistent dominance of chemoheterotrophy (up to 38% in relative abundance) and aerobic chemoheterotrophy (up to 36%), with localized enrichment of fermentation (6.9% in cannon filter and 6.5% in sediment) and aromatic compound degradation (3.7% in source waters, 3.8% in cannon filter and 4.6% in sediment). Opportunistic and potentially pathogenic genera (e.g., Acinetobacter, Flavobacterium, Nocardia) persisted in sediments (7.4%, 21.4% and 3.5%) and meltwater (34.9% and 2.31% for the latter two), raising concerns about their environmental reintroduction. Our findings indicate that technical snowmaking systems act as selective environments not only for microbial survival but also for the persistence of molecular traits relevant to environmental resilience and potential pathogenicity. Our study provides a molecular ecological framework for assessing the impacts of snowmaking on alpine ecosystems and underscores the importance of monitoring microbial functions in addition to taxonomic composition.

## Linked entities

- **Species:** Brevundimonas (taxon 41275), Lapillicoccus (taxon 402170), Massilia (taxon 149698), Acinetobacter (taxon 469), Flavobacterium (taxon 237), Nocardia (taxon 1817)

## Full-text entities

- **Chemicals:** aromatic compound (-)
- **Species:** Nocardia (genus) [taxon 1817], Flavobacterium (genus) [taxon 237], Acinetobacter (genus) [taxon 469]

## Figures

8 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12525098/full.md

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Source: https://tomesphere.com/paper/PMC12525098