Stoichiometric Shifts in Soil C:N:P Promote Bacterial Taxa Dominance, Maintain Biodiversity, and Deconstruct Community Assemblages

Aanderud, Zachary T.; Saurey, Sabrina; Ball, Becky A.; Wall, Diana H.; Barrett, John E.; Muscarella, Mario E.; Griffin, Natasha A.; Virginia, Ross A.; Barberán, Albert; Adams, Byron J.

doi:10.3389/fmicb.2018.01401

Cited by 61 publications

(34 citation statements)

References 109 publications

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“…McKnight et al (2007) also demonstrated a rapid increase in cyanobacterial mat biomass and biological activity after introduction of water to a relic stream, showing that biological communities maintain the potential to respond quickly to renewed flow (McKnight et al, 2007). While these experiments differed substantially from the wetting experiment described here, results of these and other studies (e.g., Schwartz et al, 2014; Aanderud et al, 2018) demonstrate that endemic communities in the MDV can respond within timeframes considerably shorter than previously hypothesized, thereby challenging long-held perceptions regarding the MDV of extremely slow response rates (Burkins et al, 2001; Elberling et al, 2006; Barrett et al, 2007).…”

Section: Discussioncontrasting

confidence: 74%

Rapid Microbial Dynamics in Response to an Induced Wetting Event in Antarctic Dry Valley Soils

et al. 2019

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The cold deserts of the McMurdo Dry Valleys (MDV), Antarctica, host a high level of microbial diversity. Microbial composition and biomass in arid vs. ephemerally wetted regions are distinctly different, with wetted communities representing hot spots of microbial activity that are important zones for biogeochemical cycling. While climatic change is likely to cause wetting in areas not historically subject to wetting events, the responses of microorganisms inhabiting arid soils to water addition is unknown. The purpose of this study was to observe how an associated, yet non-wetted microbial community responds to an extended addition of water. Water from a stream was diverted to an adjacent area of arid soil with changes in microbial composition and activities monitored via molecular and biochemical methods over 7 weeks. The frequency of genetic signatures related to both prokaryotic and eukaryotic organisms adapted to MDV aquatic conditions increased during the limited 7 week period, indicating that the soil community was transitioning into a typical “high-productivity” MDV community. This work is consistent with current predictions that MDV microbial communities in arid regions are highly sensitive to climate change, and further supports the notion that changes in community structure and associated biogeochemical cycling may occur much more rapidly than predicted.

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Section: Discussioncontrasting

confidence: 74%

Rapid Microbial Dynamics in Response to an Induced Wetting Event in Antarctic Dry Valley Soils

et al. 2019

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“…Changes in media (water or soil) N:P ratios affect the structure of terrestrial (Fanin et al, ; Scharler et al, ; Zechmeister‐Bolstenstren et al, ) and aquatic (Sitters, Atkinson, Guelzow, Kelly, & Sullivan, ) food webs, but associated impacts on community diversity are unclear. For example, some studies have reported increases in N:P ratios due to N deposition or land‐use change associated with reduced diversity of microbes (Zhang, Chen, & Ruan, ), plants (DeMalach, ; Güsewell, Bailey, Roem, & Bedford, ), and animals (Vogels, Verbek, Lamers, & Siepel, ; Wei et al, ), but other studies have found increases in microbial (Aanderud et al, ; Ren et al, ; ) and plant (Laliberté et al, ; Pekin, Boer, Wittkuhn, Macfarlane, & Grieson, ; Wassen et al, ; Yang et al, ) diversity. The diversity of plant species has been associated with an optimum plant N:P mass ratio near 20 (Sasaki et al, ), but the tendency for biodiversity to depend on concentrations of N and P in soil hinders the establishment of a generalized hypothesis for the relationship between N:P ratios and diversity for all components of terrestrial communities (DeMalach, ).…”

Section: Impacts Of Shifts In the N:p Ratios Of Human Inputs On Organmentioning

confidence: 99%

Anthropogenic global shifts in biospheric N and P concentrations and ratios and their impacts on biodiversity, ecosystem productivity, food security, and human health

Peñuelas

Janssens

Ciais

et al. 2020

Global Change Biology

170

133

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The availability of carbon (C) from high levels of atmospheric carbon dioxide (CO2) and anthropogenic release of nitrogen (N) is increasing, but these increases are not paralleled by increases in levels of phosphorus (P). The current unstoppable changes in the stoichiometries of C and N relative to P have no historical precedent. We describe changes in P and N fluxes over the last five decades that have led to asymmetrical increases in P and N inputs to the biosphere. We identified widespread and rapid changes in N:P ratios in air, soil, water, and organisms and important consequences to the structure, function, and biodiversity of ecosystems. A mass‐balance approach found that the combined limited availability of P and N was likely to reduce C storage by natural ecosystems during the remainder of the 21st Century, and projected crop yields of the Millennium Ecosystem Assessment indicated an increase in nutrient deficiency in developing regions if access to P fertilizer is limited. Imbalances of the N:P ratio would likely negatively affect human health, food security, and global economic and geopolitical stability, with feedbacks and synergistic effects on drivers of global environmental change, such as increasing levels of CO2, climatic warming, and increasing pollution. We summarize potential solutions for avoiding the negative impacts of global imbalances of N:P ratios on the environment, biodiversity, climate change, food security, and human health.

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“…The ratio of C:N in natural environments such as soil affects bacterial diversity and growth and is often tuned in order to favor desired bacterial metabolisms in industrial settings (42, 43). It is therefore notable that even when grown in pyruvate defined medium with no ammonium (117 mM carbon, 5.5 mM nitrogen, C:N of the medium = 21.4, equal to glycerol defined medium), M. smegmatis had a relatively low cellular C:N ratio of 5.23 (stdev 0.38, p = 0.01 compared to glycerol grown cells) and grew as mostly planktonic cells (Fig.…”

Section: Resultsmentioning

confidence: 99%

Aggregation of nontuberculous mycobacteria is regulated by carbon:nitrogen balance

DePas

Bergkessel

Newman

2019

Preprint

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19Nontuberculous mycobacteria (NTM) are emerging opportunistic pathogens that 20 form biofilms in environmental reservoirs such as household water systems and 21 aggregate into phagocytosis-resistant clusters during infection. NTM constitutively 22 aggregate in vitro, a phenotype typically considered to be a by-product of the mycolic-23 acid-rich cell wall. While culturing a model NTM, Mycobacterium smegmatis, in rich 24 medium, we fortuitously discovered that planktonic cells accumulated in the culture after 25 ~3 days. By providing selective pressure for bacteria that disperse earlier, we isolated a 26 strain with two mutations in the oligopeptide permease operon (opp). A mutant lacking 27 the opp operon (Δopp) dispersed earlier and more completely than wildtype (WT). We 28show that Δopp's aggregation defect was nutrient related; aggregation was restored by 29 non-peptide carbon sources. Experiments with WT M. smegmatis revealed that growth 30 as aggregates is favored when carbon is replete, while dispersal can be induced by 31 carbon starvation. In addition, under conditions of low available carbon relative to 32 available nitrogen, M. smegmatis grows as planktonic cells. By adjusting carbon and 33 nitrogen sources in defined medium, we tuned the cellular C:N ratio such that M. 34 smegmatis grows either as aggregates or planktonic cells. Lastly, we tested the effect of 35 C:N balance on aggregation in clinically relevant NTM. Altogether, we show that NTM 36 aggregation is a controlled process that is regulated by the relative availability of carbon 37 and nitrogen for metabolism. Because NTM aggregation is correlated with increased 38 virulence, these results may contribute to targeted anti-biofilm therapeutics. 39 40 Importance: 41 Free-living bacteria can assemble into multicellular aggregates called biofilms. 42 Biofilms help bacteria tolerate multiple stresses, including antibiotics and the host 43 immune system. Differing environmental pressures have resulted in biofilm architecture 44 and regulation varying among bacterial species and strains. Nontuberculous 45 mycobacteria are a group of emerging opportunistic pathogens that utilize biofilms to 46 adhere to household plumbing and showerheads and to avoid phagocytosis by host 47 immune cells. Mycobacteria harbor a unique cell wall built chiefly of long chain mycolic 48 acids that confers hydrophobicity and has been thought to cause constitutive 49 aggregation in liquid media. Here we show that aggregation is instead a regulated 50 process dictated by the balance of available carbon and nitrogen. Understanding that 51 mycobacteria utilize metabolic cues to regulate the transition between planktonic and 52 aggregated cells reveals an inroad to controlling aggregation through targeted 53 therapeutics. 54 55 56 57 58 59 60 61 4Introduction: 62 The adhesive biofilm matrix can serve as a physical barrier against external 63 stresses such as desiccation and predation, can interact with and sequester 64 antimicrobial agents, and can short-circuit phagocyte...

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Stoichiometric Shifts in Soil C:N:P Promote Bacterial Taxa Dominance, Maintain Biodiversity, and Deconstruct Community Assemblages

Cited by 61 publications

References 109 publications

Rapid Microbial Dynamics in Response to an Induced Wetting Event in Antarctic Dry Valley Soils

Rapid Microbial Dynamics in Response to an Induced Wetting Event in Antarctic Dry Valley Soils

Anthropogenic global shifts in biospheric N and P concentrations and ratios and their impacts on biodiversity, ecosystem productivity, food security, and human health

Aggregation of nontuberculous mycobacteria is regulated by carbon:nitrogen balance

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