A novel investigation of microbiome from vermicomposting liquid produced by Thai earthworm, Perionyx sp. 1
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Abstract
The whole microbiota structure in vermicomposting liquid derived from Thai earthworm, Perionyx sp. 1 was estimated. It showed high richness microbial species and belongs to 127 species, separated in 3 fungal phyla (Ascomycota, Basidiomycota, Mucoromycota), 1 Actinomycetes and 16 bacterial phyla (Acidobacteria, Armatimonadetes, Bacteroidetes, Balneolaeota, Candidatus, Chloroflexi, Deinococcus, Fibrobacteres, Firmicutes, Gemmatimonadates, Ignavibacteriae, Nitrospirae, Planctomycetes, Proteobacteria, Tenericutes and Verrucomicrobia). The OTUs data analysis revealed the highest taxonomic abundant ratio in bacteria and fungi belong to Proteobacteria (70.20 %) and Ascomycota (5.96 %). The result confirmed that Perionyx sp. 1 VCL was high microbiota product which suitable for using for organic agriculture. Consequently, it is firstly reported in analysing the Thai-VCL microbiota by NGS technology. We successfully build up the microbial genetic database for Thai VCL for further application improvement
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References
Arraktham, S., Tancho, A., Niamsup, P. and Rattanawaree, P. (2016). The potential of bacteria isolated from earthworm intestines, vermicompost and liquid vermicompost to produce Indole-3- acetic acid (IAA). Journal of Agricultural Technology, 12:229-239.
Behjati, S. and Tarpey, S. P. (2013). What is next generation sequencing. Archives of Disease in Childhood Education and Practice, 98:236-238.
Choa, H., Kong, L., Zhang, H., Sun, M., Ye, M., Huang, D., Zhang, Z., Sun, D., Zhang, S., Yuan, Y., Liu, M., Hu, F. and Jiang, X. (2019). Metaphire guillelmi gut as hospitable micro-environment for the potential transmission of antibiotic resistance genes. Science of the Total Environment, 669:353-361.
Edwards, C. A. and Arancon, N. Q. (2004). The influence of vermicomposts on plant growth and pest incidence. In: Shakir SH and Mikhail WZA (eds) Soil zoology for sustainable development in the 21st Century. Self-Publisher Cairo, Egypt, pp.397-420.
Gate, G. E. (1939). Thailand Earthworm. Journal Thailand Research Society, 12:65-114.
Koo, H., Hakim, A. J., Morrow, D. C., Crowley, R. M., Andersen, T. D. and Bej, K. A. (2018). Metagenomic analysis of microbial community compositions and cold-responsive stress genes in selected antarctic lacustrine and soil ecosystems. Life, 8:29.
Koskey, G., Avio, L., Lazzaro, M., Pellegrini, F., Sbrana, C., Turrini, A. and Baberi, P. (2020). Smart use of microbial-rich vermicomposting to enhance tripartite plant-microbe-soil-interations. European Geosciences Union, Online conference 9 may 2021.
Sripan, D. (2016). Metagenomics for study diversity of microbial population in central gulf of Thailand (Master Thesis). Chulalongkorn University, Thailand.
Tancho, A. (2013). Natural Farming. Trio Advertising and Media Co., Ltd. pp.135-144.
Wang, H. T., Zhu, D., Li, G., Zheng, F., Ding, J., O’connor, J.P., Zhu, Y. G. and Xue, X. M. (2019). Effect of arsenic on gut microbiota and its biotransformation genes in earthworm Metaphire sieboldin. Environmental Science and Technology, 53:3841-3849.