Unlocking the bacterial and fungal communities assemblages of sugarcane microbiome

Souza, Rafael Soares Correa de; Okura, Vagner Katsumi; Armanhi, Jaderson Silveira Leite; Jorrín, Beatriz; Lozano, Núria; Silva, Márcio José da; González‐Guerrero, Manuel; Araújo, Laura Migliorini de; Verza, Natalia C.; Bagheri, Homayoun C.; Imperial, Juan; Arruda, Paulo

doi:10.1038/srep28774

Cited by 239 publications

(205 citation statements)

References 53 publications

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“…We found differences in the fungal communities between root systems and bulk‐soil, confirming that roots provide a selective environment for microbes (Bulgarelli et al ., ; De Souza et al ., ). Strikingly, more than half of the OTUs identified inside maize roots were specific for one or the other root type (Fig.…”

Section: Discussionmentioning

confidence: 97%

“…This demonstrates that maize root types influence the endophytic fungal community in a realistic field situation. Differences in bacterial and fungal communities between roots and leaves and/or stalks have been described previously for Arabidopsis and sugar cane (Bai et al ., ; De Souza et al ., ). We show that fungal communities diverge even among different parts of the same plant organ (the root system).…”

Section: Discussionmentioning

confidence: 97%

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Root type and soil phosphate determine the taxonomic landscape of colonizing fungi and the transcriptome of field‐grown maize roots

Wang

Baldauf

et al. 2017

New Phytologist

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Different root types of plants are colonized by a myriad of soil microorganisms, including fungi, which influence plant health and performance. The distinct functional and metabolic characteristics of these root types may influence root type-inhabiting fungal communities. We performed internal transcribed spacer (ITS) DNA profiling to determine the composition of fungal communities in field-grown axial and lateral roots of maize (Zea mays) and in response to two different soil phosphate (P) regimes. In parallel, these root types were subjected to transcriptome profiling by RNA sequencing (RNA-Seq). We demonstrated that fungal communities were influenced by soil P levels in a manner specific to root types. Moreover, maize transcriptome sequencing revealed root type-specific shifts in cell wall metabolism and defense gene expression in response to high P. Furthermore, lateral roots specifically accumulated defense-related transcripts at high P levels. This observation was correlated with a shift in fungal community composition, including a reduction in colonization by arbuscular mycorrhizal fungi, as observed in ITS sequence data and microscopic evaluation of root colonization. Our findings suggest soil nutrient-dependent changes in functional niches within root systems and provide new insights into the interaction of individual root types with soil microbiota.

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Section: Discussionmentioning

confidence: 97%

Section: Discussionmentioning

confidence: 97%

Root type and soil phosphate determine the taxonomic landscape of colonizing fungi and the transcriptome of field‐grown maize roots

Wang

Baldauf

et al. 2017

New Phytologist

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“…Although contaminants can enter the process through different ways, sugarcane is the major source and new strategies based on non-cultural techniques have been applied to access microbial communities that can affect industrial processes of bioethanol production 79, 80. Besides wild yeasts, bacteria compete for sugars and nutrients with starter yeast strains causing many problems, such as inhibition of fermentation, production of organic acids, reduction of industrial yields and flocculation 81, 82, 83…”

Section: Contaminating Yeast and Bacteriamentioning

confidence: 99%

Ethanol production in Brazil: a bridge between science and industry

Lopes

Paulillo

Godoy

et al. 2016

Brazilian Journal of Microbiology

275

153

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In the last 40 years, several scientific and technological advances in microbiology of the fermentation have greatly contributed to evolution of the ethanol industry in Brazil. These contributions have increased our view and comprehension about fermentations in the first and, more recently, second-generation ethanol. Nowadays, new technologies are available to produce ethanol from sugarcane, corn and other feedstocks, reducing the off-season period. Better control of fermentation conditions can reduce the stress conditions for yeast cells and contamination by bacteria and wild yeasts. There are great research opportunities in production processes of the first-generation ethanol regarding high-value added products, cost reduction and selection of new industrial yeast strains that are more robust and customized for each distillery. New technologies have also focused on the reduction of vinasse volumes by increasing the ethanol concentrations in wine during fermentation. Moreover, conversion of sugarcane biomass into fermentable sugars for second-generation ethanol production is a promising alternative to meet future demands of biofuel production in the country. However, building a bridge between science and industry requires investments in research, development and transfer of new technologies to the industry as well as specialized personnel to deal with new technological challenges.

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“…These microbes exploit the niches provided by plant hosts and form complex microbial communities (Bulgarelli et al. , 2012; Ofek-Lalzar et al , 2014; Cardinale et al , 2015; Edwards et al , 2015; Beckers et al , 2016; de Souza et al , 2016; Niu et al , 2017). Such plant-associated microbiomes are able to affect the development and health of the hosts profoundly (Berendsen et al , 2012).…”

Section: Introductionmentioning

confidence: 99%

Quantification of the Composition Dynamics of a Maize Root-associated Simplified Bacterial Community and Evaluation of Its Biological Control Effect

Niu¹,

Kolter²

2018

BIO-PROTOCOL

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Besides analyzing the composition and dynamics of microbial communities, plant microbiome research aims to understanding the mechanism of plant microbiota assembly and their biological functions. Here, we describe procedures to investigate the role of bacterial interspecies interactions in root microbiome assembly and the beneficial effects of the root microbiota on hosts by using a maize root-associated simplified seven-species (Stenotrophomonas maltophilia, Ochrobactrum pituitosum, Curtobacterium pusillum, Enterobacter cloacae, Chryseobacterium indologenes, Herbaspirillum frisingense and Pseudomonas putida) synthetic bacterial community described in our previous work. Surface-sterilized maize seeds were grown in a gnotobiotic system based on double-tube growth chambers after being soaked in suspensions containing multiple species of bacteria. The dynamics of the composition of the bacterial communities colonized on maize roots were tracked by a culture-dependent method with a selective medium for each of the seven strains. The impact of bacterial interactions on the community assembly was evaluated by monitoring the changes of community structure. The plant-protection effects of the simplified seven-species community were assessed by quantifying (1) the growth of a fungal phytopathogen, Fusarium verticillioides on the surfaces of the seeds and (2) the severity of seedling blight disease the fungus causes, in the presence and absence of the bacterial community. Our protocol will serve as useful guidance for studying plant-microbial community interactions under the laboratory conditions.

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Unlocking the bacterial and fungal communities assemblages of sugarcane microbiome

Cited by 239 publications

References 53 publications

Root type and soil phosphate determine the taxonomic landscape of colonizing fungi and the transcriptome of field‐grown maize roots

Root type and soil phosphate determine the taxonomic landscape of colonizing fungi and the transcriptome of field‐grown maize roots

Ethanol production in Brazil: a bridge between science and industry

Quantification of the Composition Dynamics of a Maize Root-associated Simplified Bacterial Community and Evaluation of Its Biological Control Effect

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