Laboratory Evolution and Multi-platform Genome Re-sequencing of the Cellulolytic Actinobacterium Thermobifida fusca

Deng, Yu; Fong, Stephen S.

doi:10.1074/jbc.m111.239616

Cited by 31 publications

(21 citation statements)

References 49 publications

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“…reesei Rut-C30 [36], or by more targeted metabolic engineering. Furthermore, approaches using adaptive and directed evolution have provided novel strains with increased cellulase activities or improved functionality of cellulases for both fungi and bacteria [42,43]. With more and more genomes becoming available for ascomycetes it is advantageous to use bioinformatic tools in combination with metabolic engineering to express interesting enzymes.…”

Section: Selection Of the Best Fungal Strainmentioning

confidence: 99%

Production of cellulolytic enzymes from ascomycetes: Comparison of solid state and submerged fermentation

Hansen

Lübeck

Frisvad

et al. 2015

Process Biochemistry

153

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Section: Selection Of the Best Fungal Strainmentioning

confidence: 99%

Production of cellulolytic enzymes from ascomycetes: Comparison of solid state and submerged fermentation

Hansen

Lübeck

Frisvad

et al. 2015

Process Biochemistry

153

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“…These initial rumen microbial genomes were produced from type strains that were maintained as single cultures for years. It has to be noted that these type strain might have some differences with strains evolving in their natural habitat, as their genetic makeup can change over generations (Papadopoulos et al, 1999) and mutations can arise induced by the culture media (Deng and Fong, 2011). In addition, variability within single species also exists .…”

Section: Rumen Microbial Genome Projectsmentioning

confidence: 99%

Rumen microbial (meta)genomics and its application to ruminant production

Morgavi

Kelly

Janssen

et al. 2013

Animal

211

163

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Meat and milk produced by ruminants are important agricultural products and are major sources of protein for humans. Ruminant production is of considerable economic value and underpins food security in many regions of the world. However, the sector faces major challenges because of diminishing natural resources and ensuing increases in production costs, and also because of the increased awareness of the environmental impact of farming ruminants. The digestion of feed and the production of enteric methane are key functions that could be manipulated by having a thorough understanding of the rumen microbiome. Advances in DNA sequencing technologies and bioinformatics are transforming our understanding of complex microbial ecosystems, including the gastrointestinal tract of mammals. The application of these techniques to the rumen ecosystem has allowed the study of the microbial diversity under different dietary and production conditions. Furthermore, the sequencing of genomes from several cultured rumen bacterial and archaeal species is providing detailed information about their physiology. More recently, metagenomics, mainly aimed at understanding the enzymatic machinery involved in the degradation of plant structural polysaccharides, is starting to produce new insights by allowing access to the total community and sidestepping the limitations imposed by cultivation. These advances highlight the promise of these approaches for characterising the rumen microbial community structure and linking this with the functions of the rumen microbiota. Initial results using high-throughput culture-independent technologies have also shown that the rumen microbiome is far more complex and diverse than the human caecum. Therefore, cataloguing its genes will require a considerable sequencing and bioinformatic effort. Nevertheless, the construction of a rumen microbial gene catalogue through metagenomics and genomic sequencing of key populations is an attainable goal. A rumen microbial gene catalogue is necessary to understand the function of the microbiome and its interaction with the host animal and feeds, and it will provide a basis for integrative microbiome–host models and inform strategies promoting less-polluting, more robust and efficient ruminants.

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“…Advances in genomic tools have led to the development of reverse engineering tools for the determination of the underlying genetic determinants (points on the adaptive landscape) and molecular mechanisms associated with complex phenotypes; such as transcriptome analysis (Oh et al, 2002;Rutherford et al, 2010), genomic enrichment (Borden and Papoutsakis, 2007;Reyes et al, 2011), SCALEs (Lynch et al, 2007), TRMR (Warner et al, 2010), and coupling high throughput genomic technology with the use of adaptive laboratory evolution (Conrad et al, 2011;Deng and Fong, 2011;Minty et al, 2011). In adaptive laboratory evolution, adaptive mutants (strains with increased fitness) arise spontaneously and expand in a population under a specific selective pressure (Agrawal et al, 2011;Cooper and Lenski, 2010;Fong et al, 2005;Lee and Palsson, 2010;Minty et al, 2011;Paquin and Adams, 1983a;Paquin and Adams, 1983b).…”

Section: Introductionmentioning

confidence: 99%

Visualizing evolution in real time to determine the molecular mechanisms of n-butanol tolerance in Escherichia coli

Reyes

Almario

Winkler

et al. 2012

Metabolic Engineering

104

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Laboratory Evolution and Multi-platform Genome Re-sequencing of the Cellulolytic Actinobacterium Thermobifida fusca

Cited by 31 publications

References 49 publications

Production of cellulolytic enzymes from ascomycetes: Comparison of solid state and submerged fermentation

Production of cellulolytic enzymes from ascomycetes: Comparison of solid state and submerged fermentation

Rumen microbial (meta)genomics and its application to ruminant production

Visualizing evolution in real time to determine the molecular mechanisms of n-butanol tolerance in Escherichia coli

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