Diurnal cycling of rhizosphere bacterial communities is associated with shifts in carbon metabolism

Staley, Christopher; Ferrieri, Abigail P.; Tfaily, Malak M.; Cui, Yaya; Chu, Rosalie K.; Wang, Ping; Shaw, Jared; Ansong, Charles; Brewer, Heather M.; Norbeck, Angela D.; Markillie, Meng; Amaral, Fernanda do; Tuleski, Thalita Regina; Pellizzaro, Tomás; Agtuca, Beverly; Ferrieri, Richard A.; Tringe, Susannah G.; Paša‐Tolić, Ljiljana; Stacey, Gary; Sadowsky, Michael J.

doi:10.1186/s40168-017-0287-1

Cited by 69 publications

(70 citation statements)

References 71 publications

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“…This provides support for the hypothesis that these specific taxa are directly associated with genome duplication, although the causal physiological mechanisms remain unclear. Previous studies suggest that carbon root exudates strongly affect the presence-absence and abundance of microbial taxa in the rhizosphere (Chaparro et al ., 2013; Staley et al ., 2017), and these exudates can be influenced by genome duplication (Vergara et al ., 2016). Consequently, shifts in root exudates, or other metabolites produced by the plant, in response to WGD could be partially responsible for the association between ploidy and the relative abundance of microbial taxa that we observed (Edger et al ., 2015; Lebeis et al ., 2015).…”

Section: Discussionmentioning

confidence: 99%

Whole-genome duplication and host genotype affect rhizosphere microbial communities

Ponsford

Hubbard

Harrison

et al. 2019

Preprint

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The composition of complex microbial communities found in association with plants is influenced in part by host phenotype. Yet, the salient genetic architecture is often unknown. Genome duplication events are common in the evolutionary history of plants, influence many important plant traits, and may affect associated microbial communities. Using experimentally induced whole genome duplication (WGD), we tested the effect of WGD on rhizosphere bacterial communities in Arabidopsis thaliana. Specifically, we performed 16S rRNA amplicon sequencing to characterize differences between microbiomes associated with specific host genotypes (Columbia vs. Landsberg) and ploidy levels (diploid vs. tetraploid). We modeled abundances of individual bacterial taxa by utilizing a hierarchical Bayesian framework, based on the Dirichlet and multinomial distributions. We found that host genotype and host ploidy level affected rhizosphere community composition, for instance, the microbiome of the tetraploid Columbia genotype differed from that of other host genotypes. We then tested to what extent microbiomes derived from a given host genotype or ploidy level affected plant performance by inoculating sterile seedlings of each genotype with microbial communities harvested from a prior generation. We found a negative effect of the tetraploid Columbia microbiome on growth of all four plant genotypes. The findings suggest that while both host genotype and ploidy affect microbial community assembly, bacterial communities found in association with only some host genotypes may affect growth of subsequent plant generations.ImportancePlants influence the composition of their associated microbial communities; yet the underlying host genetic factors are often unknown. Genome duplication events are common in the evolutionary history of plants and affect many plant traits, including the quality and quantity of compounds exuded into the root zone, which can affect root-bound microbes. In Arabidopsis thaliana, we characterized how whole-genome duplication affected the composition of rhizosphere bacterial communities, and how bacterial communities associated with two host plant genotypes and ploidy levels affected subsequent plant growth. We observed an interaction in which ploidy level within one host genotype affected both bacterial community composition and function. This research reveals how genome duplication, a widespread genetic feature of both wild and crop plant species, influences the coexistence of bacterial taxa and affects plant growth.

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Section: Discussionmentioning

confidence: 99%

Whole-genome duplication and host genotype affect rhizosphere microbial communities

Ponsford

Hubbard

Harrison

et al. 2019

Preprint

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“…In this regard, systems biology [1,2] is well-equipped to integrate findings and define the genetic variability and functional metabolites [3] in a model plant system. Model plant research, such as that of well-known Arabidopsis thaliana [4][5][6][7] and the extensively-studied medicinal plant, Papaver somniferum [8][9][10][11][12], highlight the significance of gathering information about regulation of plant fitness and homeostatic mechanisms of metabolites [13] orchestrated by the host genome and its affiliated microbial metagenome [14]. Such an approach notably reveals the importance of the plant's genome-microbiome interactions [15], which changes under stress or disease conditions [16,17] as plants selectively source their microbiomes to suit their needs [18,19].…”

Section: Introductionmentioning

confidence: 99%

Scientific Prospects for Cannabis-Microbiome Research to Ensure Quality and Safety of Products

et al. 2020

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Cannabis legalization has occurred in several countries worldwide. Along with steadily growing research in Cannabis healthcare science, there is an increasing interest for scientific-based knowledge in plant microbiology and food science, with work connecting the plant microbiome and plant health to product quality across the value chain of cannabis. This review paper provides an overview of the state of knowledge and challenges in Cannabis science, and thereby identifies critical risk management and safety issues in order to capitalize on innovations while ensuring product quality control. It highlights scientific gap areas to steer future research, with an emphasis on plant-microbiome sciences committed to using cutting-edge technologies for more efficient Cannabis production and high-quality products intended for recreational, pharmaceutical, and medicinal use.

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“…Conversely, the lack of enrichment in denitrification genes in TWW-irrigated metatranscriptomes could be a result of time of sampling. The root microbiome functional profile is expected to fluctuate by diurnal or hydration-dehydration cycles (64, 65, 66). Therefore, gene abundance is indicative of the chronic, long term exposure to stress imposed by TWW, while expression levels may represent transient conditions.…”

Section: Discussionmentioning

confidence: 99%

The microbiome as a biosensor: functional profiles elucidate hidden stress in hosts

Zolti

Green

Sela

et al. 2019

Preprint

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Microbial communities are highly responsive to environmental cues, and both their structure and activity can be altered in response to changing conditions. We hypothesized that host-associated microbial communities, particularly those colonizing host surfaces, can serve as in situ sensors to reveal environmental conditions experienced by both microorganisms and the host. For a proof-of-concept, we studied a model plant-soil system and employed a non-deterministic gene-centric approach. A holistic analysis was performed using plants of two species and irrigation with water of low quality to induce host stress. Our analyses examined the genetic potential (DNA) and gene expression patterns (RNA) of plant-associated microbial communities, as well as transcriptional profiling of host plants. Transcriptional analysis of plants irrigated with treated wastewater revealed significant enrichment of general stress-associated root transcripts relative to plants irrigated with fresh water. Metagenomic analysis of root-associated microbial communities in treated wastewater-irrigated plants, however, revealed enrichment of more specific stress-associated genes relating to high levels of salt, high pH and lower levels of oxygen. Meta-analysis of these differentially abundant genes obtained from other metagenome studies provided evidence of the link between environmental factors such as pH and oxygen and these genes. Analysis of microbial transcriptional response demonstrated that enriched gene content was actively expressed, which implies contemporary response to elevated levels of pH and salt. We demonstrate here that microbial profiling can elucidate stress signals that cannot be observed even through interrogation of host transcriptome, leading to an alternate mechanism for evaluating in situ conditions experienced by host organisms.Significance StatementThis study examines the potential for microbial communities to provide insight into stresses experienced by their eukaryotic host organisms, through profiling of metagenomes and metatranscriptomes. Our study uses plant host-associated microorganisms as an in vivo and in situ microsensor to identify environmental stresses experienced by the microbial community and by the plant. Transcriptionally active host-associated microbial communities are responsive in a highly specific manner to environmental conditions. Conversely, host transcriptome sequencing provides only a very general stress response. This study is a proof-of-concept for the use of microbial communities as microsensors, with a great potential for interrogation of a wide range of host systems.

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Diurnal cycling of rhizosphere bacterial communities is associated with shifts in carbon metabolism

Cited by 69 publications

References 71 publications

Whole-genome duplication and host genotype affect rhizosphere microbial communities

Whole-genome duplication and host genotype affect rhizosphere microbial communities

Scientific Prospects for Cannabis-Microbiome Research to Ensure Quality and Safety of Products

The microbiome as a biosensor: functional profiles elucidate hidden stress in hosts

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