Over the last century, natural habitats and semi-natural environments have been under increasing environmental pressure, leading to significant changes and a decline in biodiversity. Biodiversity is the variety of life forms in an ecosystem and is essential for preserving genetic resources and sustaining populations. The soil is fundamental to terrestrial ecosystem function and environmental health, contributing significantly to support and regulation services. To address these challenges, a new resilience index named Biodiversity Soil Resilience (BSR) is proposed. This index focuses on the intricate relationship between biodiversity and soil health. It involves a comprehensive analysis of soil biodiversity, with a particular emphasis on entomopathogenic nematodes (EPN), entomopathogenic fungi (EPF), earthworms, and soil microarthropods. Numerous studies support the crucial roles of these components in ecosystem resilience, offering diverse benefits that contribute to environmental stability. For example, entomopathogenic nematodes (EPNs) and entomopathogenic fungi (EPFs) play a significant role in biological control, the food chain, nutrient cycling, adaptability, and interactions with soil. Earthworms enhance soil aeration, promote the mixing of organic and mineral material, increase microbial biomass, provide biological control against pathogens, and foster beneficial symbioses. These organisms exhibit adaptability to various environmental conditions, contributing to the ecosystems ability to withstand and recover from environmental stresses. Microarthropods, including mites and collembola, also play a crucial role in the BSR-Index by contributing to soil properties such as decomposition, nutrient cycling, soil structure, biodiversity, adaptability, and resilience. Additionally, they engage in fundamental interactions with vegetation and other microorganisms, further influencing ecosystem health. A key innovation in this research is the development of a dedicated app/software for real-time data collection in the field. This tool streamlines the gathering of information on specific organisms and contributes to a global database of soil biodiversity data. This collaborative effort facilitates worldwide monitoring and maintenance of soil health. The BSR-Index is envisioned as a monitoring tool for the scientific community and government authorities. It provides valuable insights for the implementation of sustainable and effective environmental planning measures. The Index, incorporating environmental stresses, soil biodiversity, and soil biological quality (QBS-ar and QBS-e), supported by chemical and physical parameters, aims to enhance our understanding of ecosystem health and promote informed decision-making for a resilient and sustainable future.
Biodiversity Soil Resilience (BSR): A new Index to asses resilience in environmentally stressed ecosystems by including entomopathogenic nematodes
Giambattista Maria Altieri;Vito Santarcangelo;Giuseppe Bari;Eustachio Tarasco
2024-01-01
Abstract
Over the last century, natural habitats and semi-natural environments have been under increasing environmental pressure, leading to significant changes and a decline in biodiversity. Biodiversity is the variety of life forms in an ecosystem and is essential for preserving genetic resources and sustaining populations. The soil is fundamental to terrestrial ecosystem function and environmental health, contributing significantly to support and regulation services. To address these challenges, a new resilience index named Biodiversity Soil Resilience (BSR) is proposed. This index focuses on the intricate relationship between biodiversity and soil health. It involves a comprehensive analysis of soil biodiversity, with a particular emphasis on entomopathogenic nematodes (EPN), entomopathogenic fungi (EPF), earthworms, and soil microarthropods. Numerous studies support the crucial roles of these components in ecosystem resilience, offering diverse benefits that contribute to environmental stability. For example, entomopathogenic nematodes (EPNs) and entomopathogenic fungi (EPFs) play a significant role in biological control, the food chain, nutrient cycling, adaptability, and interactions with soil. Earthworms enhance soil aeration, promote the mixing of organic and mineral material, increase microbial biomass, provide biological control against pathogens, and foster beneficial symbioses. These organisms exhibit adaptability to various environmental conditions, contributing to the ecosystems ability to withstand and recover from environmental stresses. Microarthropods, including mites and collembola, also play a crucial role in the BSR-Index by contributing to soil properties such as decomposition, nutrient cycling, soil structure, biodiversity, adaptability, and resilience. Additionally, they engage in fundamental interactions with vegetation and other microorganisms, further influencing ecosystem health. A key innovation in this research is the development of a dedicated app/software for real-time data collection in the field. This tool streamlines the gathering of information on specific organisms and contributes to a global database of soil biodiversity data. This collaborative effort facilitates worldwide monitoring and maintenance of soil health. The BSR-Index is envisioned as a monitoring tool for the scientific community and government authorities. It provides valuable insights for the implementation of sustainable and effective environmental planning measures. The Index, incorporating environmental stresses, soil biodiversity, and soil biological quality (QBS-ar and QBS-e), supported by chemical and physical parameters, aims to enhance our understanding of ecosystem health and promote informed decision-making for a resilient and sustainable future.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.