Exploration of microbial signature and carbon footprints of the Nilgiri Hill Region in the Western Ghats global biodiversity hotspot of India

Land use change (LUC), alters the multifarious biodiversity hotspots directly and indirectly through the loss of soil quality. A comparative study on soil carbon status and soil microbiome in undisturbed natural forest ecosystems with that of other land uses which gradually altered over time can ser...

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Published in:Applied soil ecology : a section of Agriculture, ecosystems & environment ecosystems & environment, 2024-02, Vol.194, p.105176, Article 105176
Main Authors: Jagadesh, M., Selvi, Duraisamy, Thiyageshwari, Subramanium, Kalaiselvi, Thangavel, Allan, Victor, Dash, Munmun, Lourdusamy, Keisar, Kumaraperumal, Ramalingam, Raja, Pushpanathan, Surendran, U.
Format: Article
Language:English
Subjects:
16s Illumina sequencing
Active carbon pools
biodiversity
carbon cycle
Carbon dioxide
climate change
comparative study
conservation areas
cropland
deciduous forests
evergreen forests
forest plantations
India
Land use change
Microbiome
Recalcitrant carbon
shrublands
soil carbon
soil ecology
soil microorganisms
soil profiles
soil quality
tea
total organic carbon
Ultisols
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Summary:Land use change (LUC), alters the multifarious biodiversity hotspots directly and indirectly through the loss of soil quality. A comparative study on soil carbon status and soil microbiome in undisturbed natural forest ecosystems with that of other land uses which gradually altered over time can serve as a suitable indicator for understanding LUC impact on carbon cycles. With this aim, the current investigation was initiated to infer the cyclic effects of LUC on the soil carbon status under six major ecosystems viz., cropland (CL), deciduous forest (DF), evergreen forest (EF), forest plantation (FP), scrubland (SL) and tea plantation (TP) of the Nilgiri Hill Region (NHR) (India's first biosphere reserve). The total organic carbon (TOC) and carbon stocks were highest in evergreen forest (10.25 %, 322.06 t ha−1) and they decreased with increasing depth of the soil profile across the pools of varying carbon lability. The proportion of active carbon pools (AP) in total carbon was higher in crop land and tea plantation (57.47 %, 58.38 %), however, in the case of evergreen forest, deciduous forest, forest plantation and scrub land the passive carbon pools (PP) (54.99 %, 61.28 %, 59.43 % and 60.70 %) was higher. We discovered LUC has altered the proportion of soil carbon pools, and the efficiency of soil microbiome and has resulted in higher carbon dioxide (CO2) emissions in tea plantation (71.87 t ha−1) and crop land (82.39 t ha−1). However, the native ecosystems (evergreen forest and deciduous forest) with higher recalcitrant carbon pools (46.96 g kg−1 and 34.89 g kg−1) prevent such carbon degradation and thereby hinder the soil carbon emissions as recorded in evergreen forest (48.43 t ha−1) and deciduous forest (56.47 t ha−1). Conclusively, our study demonstrates that LUC has substantially influenced the carbon cycle by altering the carbon stocks and CO2 emissions in relation to soil microbes. Henceforth, in order to maintain carbon footprints and attain carbon net neutrality under the current climate change scenario, suitable carbon management measures must be implemented in carbon-degraded ecosystems (crop land and tea plantation) of NHR. Conversion of natural ecosystems (evergreen and deciduous forests) to agriculture and other commercial activities influences the carbon dynamics by decreasing its recalcitrance and enhancing carbon dioxide emission which in turn can have a far-reaching consequence of climate change. [Display omitted]
ISSN:0929-1393
DOI:10.1016/j.apsoil.2023.105176