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Degradation of soil microbiome and carbon dynamics in response to overgrazing in Austral wetland ecosystems

Wetlands (mallines) of Southern Patagonia are key ecosystems for biodiversity, forage production, and carbon (C) sequestration. However, overgrazing threatens their ecological integrity, causing varying levels of degra­ dation that alter soil physical, chemical, and biological properties. The impact...

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Main Authors: Toledo, Santiago, Diaz, Boris Gaston, Duarte Guardia, Sandra, Peri, Pablo Luis
Format: info:ar-repo/semantics/artículo
Language:Inglés
Published: Elsevier 2025
Subjects:
Wetlands
Carbon Sequestration
Soil
Microbiomes
Carbon
Nitrogen
Indicator Organisms
Monitoring and Evaluation
Degradation
Overgrazing
Tierras Húmedas
Secuestro de Carbono
Suelo
Microbiomas
Carbono
Nitrógeno
Organismos Indicadores
Seguimiento y Evaluación
Degradación
Santa Cruz
Sobrepastoreo
Microbial Biomass
Basal Respiration
Soil Microbial Communities
Biomasa Microbiana
Respiración Basal
Comunidades Microbianas del Suelo
Sustainable land-use strategies
Estrategias de uso sostenible de la tierra
Región Patagónica
Online Access:http://hdl.handle.net/20.500.12123/24437
https://www.sciencedirect.com/science/article/pii/S3050641725000412
https://doi.org/10.1016/j.temicr.2025.100041
Summary:Wetlands (mallines) of Southern Patagonia are key ecosystems for biodiversity, forage production, and carbon (C) sequestration. However, overgrazing threatens their ecological integrity, causing varying levels of degra­ dation that alter soil physical, chemical, and biological properties. The impacts of grazing-induced degradation on soil microbiome function and C dynamics remain poorly understood. This study evaluated soil microbial attributes and C dynamics across eighteen wetlands under light, moderate, and severe degradation along a regional climatic gradient. Measured soil physicochemical and biological properties, such as microbial biomass C and N (MBC, MBN), basal respiration (SBR), microbial efficiency indices (qCO₂, qMC), and estimated both mi­crobial and soil C stocks and CO₂ fluxes. Severe degradation reduced MBC and MBN by up to 46 % and 36 %, respectively, and SBR by 75 %, while increasing bulk density (0.57 to 0.92 g.cm− 3) and reducing nutrient levels (N: 80 %, P: 30 % and K: 35 %). Soil organic carbon (SOC) stocks and associated potential CO₂ removal were 2.5 to 3 times higher in lightly (8.63 and 31.68 kg.m− 2) degraded wetlands compared to moderate (4.52 and 16.59 kg.m− 2) and severe (2.75 and 10.08 kg.m− 2), respectively. Microbial efficiency declined with severe degradation, represented by low qCO₂ (0.13 µg.mg− 1) and high qMC values (1.35 %). Random Forest models identified bulk density, vegetation cover, soil N, and litter as key drivers of microbial and C-related processes. Our findings reveal that degradation alters the functional capacity of soil microbial communities, consequently affecting carbon sequestration. Microbial variables are early bioindicators of soil functional integrity. Integrating micro­ bial and soil physicochemical parameters into monitoring frameworks can help detect early degradation and guide sustainable land-use strategies for wetland ecosystems.

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