User:Wikibiodude/Agricultural microbiology

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Agricultural microbiology is a branch of microbiology dealing with plant-associated microbes and plant and animal diseases. The primary goal of agricultural microbiology is to comprehensively explore the interactions between beneficial microorganisms like bacteria and fungi with crops.^[1] It also deals with the microbiology of soil fertility, such as microbial degradation of organic matter and soil nutrient transformations.

Microbiology in Sustainable Agriculture

Effective Microorganisms

Effective microorganisms (EM) are essential to the development of sustainable agriculture and consist of a diverse, mixed culture of microorganisms that is naturally occurring in nature. Biopreparations containing effective microorganisms play a crucial role across various sectors, such as environmental protection, food production, and medicine. Furthermore, this application of effective microorganism biotechnology spans a range of agricultural areas, including soil rejuvenation, crop cultivation, livestock farming, and food preservation. These biopreparations prove particularly beneficial for land preparation and field preparation. Effective microorganisms can be applied to crops during the growing season or directly to the soil during preparation, enhancing both soil health and promoting plant growth. The broad utility of effective microorganisms stems from their high enzymatic specificity, allowing them to thrive in various conditions. Moreover, effective microorganism technology is now utilized in more than 140 countries worldwide, with Brazil being the leading adopter. The widespread usage of effective microorganisms displays the power to enhance the agricultural industry and environmentally sustainable farming.^[2]

Effective Microorganisms in Sustainable Agriculture

Conventional farming methods use chemical fertilizers, pesticides, and herbicides to safeguard crops from pests and diseases. However, these chemical agents have adverse environmental impacts, contributing to environmental pollution. The use of agricultural chemicals has been linked to the decline of plant and animal species, as well as harm to soil biodiversity, including bacterial and fungal communities. Chemical plant protection products can alter agricultural soils by affecting their physical properties such as texture, permeability, and porosity. Additionally, these products disrupt the nutrient cycles of phosphorus and nitrogen and reduce the diversity of the soil microbiome. Given the challenges posed by a growing global population and the need for more and higher-quality food, the future of agriculture lies in using effective microorganisms to boost yields. This approach offers a sustainable alternative to traditional chemical methods, fostering environmental health and agricultural resilience.^[3]

Successful crop production hinges on the health of the soil, which is influenced by a network of biological, chemical, and physical processes driven by microorganisms. Effective microorganisms enhance the soil's beneficial microbial community, paving the way for sustainable agriculture. These microorganisms consist of naturally occurring microbes, such as photosynthesizing bacteria, lactic acid bacteria, yeasts, and fermenting fungi, which can be applied to increase soil microbial diversity. The application of effective microorganisms improves soil structure and fertility while significantly boosting biological diversity. They can inhibit the proliferation of soil-borne pathogens, assist in nitrogen fixation, and enhance plant nutrient uptake. Effective microorganisms also accelerate the decomposition of organic waste, which promotes composting and, therefore, increases the availability of valuable minerals and bolsters the activities of indigenous microbes. By dominating the soil's microbial environment, effective microorganisms encourage other beneficial microbes to thrive and outcompete smaller groups of pathogenic or opportunistic microbes. This natural balancing act leads to stronger, more resilient plants and higher crop yields, positioning effective microorganisms as a key player in the future of sustainable agriculture.^[1]

References

1. Suganya, Thangaiyan; Renuga Devi, Navaneethan; Vignesh, Sounderrajan; Rajendran, Susai; Dorothy, R.; Nguyen, Tuan Anh (2022-01-01), Denizli, Adil; Nguyen, Tuan Anh; Rajendran, Susai; Yasin, Ghulam (eds.), "3 - Microbiology in agriculture: an introduction", Nanosensors for Smart Agriculture, Micro and Nano Technologies, Elsevier, pp. 41–51, doi:10.1016/b978-0-12-824554-5.00023-9, ISBN 978-0-12-824554-5, retrieved 2024-04-16
2. Pszczółkowski, Piotr; Sawicka, Barbara; Barbaś, Piotr; Skiba, Dominika; Krochmal-Marczak, Barbara (2023-01). "The Use of Effective Microorganisms as a Sustainable Alternative to Improve the Quality of Potatoes in Food Processing". Applied Sciences. 13 (12): 7062. doi:10.3390/app13127062. ISSN 2076-3417. {{cite journal}}: Check date values in: |date= (help)
3. Antoszewski, Marcel; Mierek-Adamska, Agnieszka; Dąbrowska, Grażyna B. (2022-11). "The Importance of Microorganisms for Sustainable Agriculture—A Review". Metabolites. 12 (11): 1100. doi:10.3390/metabo12111100. ISSN 2218-1989. PMC 9694901. PMID 36422239. {{cite journal}}: Check date values in: |date= (help)