Abstract
Microorganisms play a critical role in the structure and functioning of soil ecosystems. Within acidic soil across the northeastern United States and Canada, we have little understanding of the microbial diversity present and its relationship to the biochemical cycles. The current study is aimed at understanding the taxonomical and functional diversities in the acidic soil obtained from near various types of trees, how the diversities change as a function of depth, and the linkage between taxonomical and functional diversities. From eight sampling locations, soil samples were collected from three horizons (depths). The three depths were 0–10 cm (A), 11–25 cm (B), and 26–40 cm (C). Results indicate that across all the samples analyzed, Bradyrhizobium and Candidatus Solibacter are the most abundant bacteria in the soil microbiome. The differences in the soil microbiome across the samples were attributed to the abundance of individual organism’s present in the soil and not to the presence or absence of individual organisms. Subsystem level analysis of the soil microbiome sequences indicate that there is higher level of abundance of genes attributed to regulation and cell signaling. A low level of sequences were detected for sulfur metabolism, potassium metabolism, iron acquisition and metabolism, and phosphorous metabolism. Structure-functional analysis indicate that Bradyrhizobium, Rhodopseudomonas, and Burkholderia are the major organisms involved in the nutritional ecosystem functioning within acidic soil. Based on the results, we propose utilizing a consortium of these organisms as an environmentally friendly alternative to the use of chemicals to maintain soil fertility and ecosystem functioning.
Highlights
Soil microorganisms are the largest biodiversity pool on earth, with more than 1030 microbial cells, 104–106 species, and nearly 1,000 Gbp of microbial genome per gram of soil (Vogel et al, 2009; Mendes and Tsai, 2018)
We address three questions in the study: 1) what are the major microorganisms that are common to acidic soil types and depth? 2) what are the biochemical pathways that can be generalized across all acidic soil types and depth? 3) What role do each of these organisms play in the ecosystem functioning in the soil?
We investigated the microbial structural and functional diversity within the top acidic soil associated with a wide variety of plants
Summary
Soil microorganisms are the largest biodiversity pool on earth, with more than 1030 microbial cells, 104–106 species, and nearly 1,000 Gbp of microbial genome per gram of soil (Vogel et al, 2009; Mendes and Tsai, 2018). They are the primary factors that affect the soil ecosystem functioning and play key roles in forming and maintaining a multitude of soil characteristics including integrity, fertility, ecology, and overall soil function (Shah et al, 2011). Much is known of the microbial taxa present in soils from across the planet and the impact of perturbation of soil conditions. Soil Microbial Community Structure and Function Site No. Plant
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