Microbial Communities Associated With Long-Term Tillage and Fertility Treatments in a Corn-Soybean Cropping System

Srour, Ali; Ammar, Hala A.; Subedi, Arjun; Pimentel, Mirian F.; Cook, Rachel L.; Bond, Jason P.; Fakhoury, Ahmad M.

doi:10.3389/fmicb.2020.01363

Cited by 63 publications

(58 citation statements)

References 106 publications

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“…This may owe to chisel tillage being less aggressive than typical conventional tillage methods, thus the microbial responses to tillage could be more clear-cut under practices like moldboard plowing [24]. The CT-favored oligotrophs in PC2 and PC3 responding positively to chisel tillage contradicts past studies [27,90], yet these analyses were limited to the phyla level, thereby highlighting the discrepancy between the collective microbial behaviors at higher taxonomic ranks and those of individual microbes.…”

Section: Discussionmentioning

confidence: 78%

“…Community-level inferences, however, only superficially explain how the soil microbiome responds to CC and tillage. New metagenomics research allows for a closer look into the soil microbial composition and function and the changes brought about by agricultural practices [ 25 , 26 , 27 ]. This usually involves using β-diversity measures to detect shifts in the microbial community structure between samples [ 28 ], interpreting the changes with further analyses targeting specific functional genes, such as amo A, involved in nitrification [ 29 ], and characterizing the compositional shifts that identify the responsive taxa [ 30 , 31 ].…”

Section: Introductionmentioning

confidence: 99%

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Microbial Shifts Following Five Years of Cover Cropping and Tillage Practices in Fertile Agroecosystems

et al. 2020

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Metagenomics in agricultural research allows for searching for bioindicators of soil health to characterize changes caused by management practices. Cover cropping (CC) improves soil health by mitigating nutrient losses, yet the benefits depend on the tillage system used. Field studies searching for indicator taxa within these systems are scarce and narrow in their scope. Our goal was to identify bioindicators of soil health from microbes that were responsive to CC (three levels) and tillage (chisel tillage, no-till) treatments after five years under field conditions. We used rRNA gene-based analysis via Illumina HiSeq2500 technology with QIIME 2.0 processing to characterize the microbial communities. Our results indicated that CC and tillage differentially changed the relative abundances (RAs) of the copiotrophic and oligotrophic guilds. Corn–soybean rotations with legume–grass CC increased the RA of copiotrophic decomposers more than rotations with grass CC, whereas rotations with only bare fallows favored stress-tolerant oligotrophs, including nitrifiers and denitrifiers. Unlike bacteria, fewer indicator fungi and archaea were detected; fungi were poorly identified, and their responses were inconsistent, while the archaea RA increased under bare fallow treatments. This is primary information that allows for understanding the potential for managing the soil community compositions using cover crops to reduce nutrient losses to the environment.

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Section: Discussionmentioning

confidence: 78%

Section: Introductionmentioning

confidence: 99%

Microbial Shifts Following Five Years of Cover Cropping and Tillage Practices in Fertile Agroecosystems

et al. 2020

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“…Tillage can act as a selective pressure leading to a difference in soil microbial community composition under contrasting soil disturbance regimes (Navarro-Noya et al, 2013). Breaking apart soil aggregates exposes previously protected soil organic matter to oxidizing conditions (Six et al, 2000;Van Groenigen et al, 2010) favorable to fast growing copiotrophic bacteria (Srour et al, 2020). However, findings on the effects of tillage on soil microbial communities are not consistent.…”

Section: Differences Between Cropping Systemsmentioning

confidence: 99%

Temporal Soil Bacterial Community Responses to Cropping Systems and Crop Identity in Dryland Agroecosystems of the Northern Great Plains

Ouverson

Eberly

Seipel

et al. 2021

Front. Sustain. Food Syst.

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Industrialized agriculture results in simplified landscapes where many of the regulatory ecosystem functions driven by soil biological and physicochemical characteristics have been hampered or replaced with intensive, synthetic inputs. To restore long-term agricultural sustainability and soil health, soil should function as both a resource and a complex ecosystem. In this study, we examined how cropping systems impact soil bacterial community diversity and composition, important indicators of soil ecosystem health. Soils from a representative cropping system in the semi-arid Northern Great Plains were collected in June and August of 2017 from the final phase of a 5-year crop rotation managed either with chemical inputs and no-tillage, as a USDA-certified organic tillage system, or as a USDA-certified organic sheep grazing system with reduced tillage intensity. DNA was extracted and sequenced for bacteria community analysis via 16S rRNA gene sequencing. Bacterial richness and diversity decreased in all farming systems from June to August and was lowest in the chemical no-tillage system, while evenness increased over the sampling period. Crop species identity did not affect bacterial richness, diversity, or evenness. Conventional no-till, organic tilled, and organic grazed management systems resulted in dissimilar microbial communities. Overall, cropping systems and seasonal changes had a greater effect on microbial community structure and diversity than crop identity. Future research should assess how the rhizobiome responds to the specific phases of a crop rotation, as differences in bulk soil microbial communities by crop identity were not detectable.

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“…A fall in α-diversity under conservation tillage practices is common and attributable to a reduction in evenness as much as in richness (Degrune et al, 2016;Piazza et al, 2019;Tyler, 2019). Nevertheless, conservation tillage and no-till practices favor slower organic matter degradation and the establishment of less diverse but more oligotrophic, complex, and stable microbial communities (Degrune et al, 2017;Song et al, 2017;Wang et al, 2017;Tyler, 2019;Srour et al, 2020). Babin et al (2019) consistently observed a higher abundance of predicted genes involved in oligotrophic lifestyles under low tillage conditions.…”

Section: Impact Of Tillage Practices On Soil Microbiotamentioning

confidence: 97%

“…From a metagenomic perspective, the impact of tilling on soil microbial diversity is usually investigated through αor β-diversity indexes describing respective differences within and between communities. Conventional tillage has a low impact on fungal α-diversity, while increasing prokaryotic αdiversity has a significant impact on prokaryotic β-diversity favoring opportunistic commensal and copiotroph microbes (Degrune et al, 2017;Hartman et al, 2018;Sommermann et al, 2018;Babin et al, 2019;Banerjee et al, 2019;Piazza et al, 2019;Srour et al, 2020). Tilling facilitates fast organic matter decomposition resulting in a sudden nutrient release that is homogeneously distributed in tilled soil columns, thus increasing the abundance of r-strategists or fast-growing microorganisms (Degrune et al, 2017;Schmidt et al, 2018).…”

Section: Impact Of Tillage Practices On Soil Microbiotamentioning

confidence: 99%

Plant Microbiota Beyond Farming Practices: A Review

Delitte

Caulier

Bragard

et al. 2021

Front. Sustain. Food Syst.

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Plants have always grown and evolved surrounded by numerous microorganisms that inhabit their environment, later termed microbiota. To enhance food production, humankind has relied on various farming practices such as irrigation, tilling, fertilization, and pest and disease management. Over the past few years, studies have highlighted the impacts of such practices, not only in terms of plant health or yields but also on the microbial communities associated with plants, which have been investigated through microbiome studies. Because some microorganisms exert beneficial traits that improve plant growth and health, understanding how to modulate microbial communities will help in developing smart farming and favor plant growth-promoting (PGP) microorganisms. With tremendous cost cuts in NGS technologies, metagenomic approaches are now affordable and have been widely used to investigate crop-associated microbiomes. Being able to engineer microbial communities in ways that benefit crop health and growth will help decrease the number of chemical inputs required. Against this background, this review explores the impacts of agricultural practices on soil- and plant-associated microbiomes, focusing on plant growth-promoting microorganisms from a metagenomic perspective.

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Microbial Communities Associated With Long-Term Tillage and Fertility Treatments in a Corn-Soybean Cropping System

Cited by 63 publications

References 106 publications

Microbial Shifts Following Five Years of Cover Cropping and Tillage Practices in Fertile Agroecosystems

Microbial Shifts Following Five Years of Cover Cropping and Tillage Practices in Fertile Agroecosystems

Temporal Soil Bacterial Community Responses to Cropping Systems and Crop Identity in Dryland Agroecosystems of the Northern Great Plains

Plant Microbiota Beyond Farming Practices: A Review

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