Deep sequencing of non-ribosomal peptide synthetases and polyketide synthases from the microbiomes of Australian marine sponges

Woodhouse, Jason N.; Fan, Lu; Brown, Mark V.; Thomas, Torsten; Neilan, Brett A.

doi:10.1038/ismej.2013.65

Cited by 49 publications

(36 citation statements)

References 54 publications

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“…The use of amplicon sequencing to profile soil microbiomes is an attractive approach for assessing the biosynthetic potential of diverse microbiomes to a depth that is still inaccessible via shotgun sequencing. Previously, investigation of natural product biodiversity using amplicon sequencing had only been applied to a small number of marine and terrestrial environments (21)(22)(23)(24)(25). Our study of nearly 100 unique soil samples builds on these earlier small-scale studies to provide a more detailed picture of the distribution of secondary metabolite gene clusters throughout soil microbiomes.…”

Section: Predicting the Distribution Of Gene Clusters That Are Evolutmentioning

confidence: 99%

Chemical-biogeographic survey of secondary metabolism in soil

Charlop–Powers

Owen

Reddy

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

131

128

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In this study, we compare biosynthetic gene richness and diversity of 96 soil microbiomes from diverse environments found throughout the southwestern and northeastern regions of the United States. The 454-pyroseqencing of nonribosomal peptide adenylation (AD) and polyketide ketosynthase (KS) domain fragments amplified from these microbiomes provide a means to evaluate the variation of secondary metabolite biosynthetic diversity in different soil environments. Through soil composition and AD- and KS-amplicon richness analysis, we identify soil types with elevated biosynthetic potential. In general, arid soils show the richest observed biosynthetic diversity, whereas brackish sediments and pine forest soils show the least. By mapping individual environmental amplicon sequences to sequences derived from functionally characterized biosynthetic gene clusters, we identified conserved soil type–specific secondary metabolome enrichment patterns despite significant sample-to-sample sequence variation. These data are used to create chemical biogeographic distribution maps for biomedically valuable families of natural products in the environment that should prove useful for directing the discovery of bioactive natural products in the future.

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Section: Predicting the Distribution Of Gene Clusters That Are Evolutmentioning

confidence: 99%

Chemical-biogeographic survey of secondary metabolism in soil

Charlop–Powers

Owen

Reddy

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

131

128

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“…NGS can be very useful in sequence-based approach as it has been demonstrated recently by deep sequencing of amplicons obtained using degenerate primers and eDNA or library as a template. This strategy uncovered more than 50% of the unique PKS and NRPS domains that are accessible from metagenome (Reddy et al 2012;Woodhouse et al 2013).…”

Section: Conclusion and Future Prospectsmentioning

confidence: 99%

Bioprospecting microbial metagenome for natural products

Nováková

Farkašovský

2013

Biologia

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Mining of natural sources for new secondary metabolites has a successful history, which is reflected by the fact that over 50% of all drugs, currently on the market, are derived from natural products. Bacteria are one of the most important sources of bioactive natural products destined for drug discovery. However, less than 1% of the microorganisms observed in different habitats have been cultivated and characterized. To explore the genomic and functional diversity of the vast majority of the microbial world, novel methods were introduced, which are based on analysis of a DNA isolated from environmental communities. Metagenomics represents a strategy offering access to the genetic information present in uncultured bacteria by screening of libraries constructed from DNA isolated from different habitats. Functional-and sequence-driven screens are the major approaches employed to mine metagenomic libraries. This review aims to highlight discoveries in this area and discusses the possible future directions of the field.

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“…Pyrosequencing of ketosynthase and condensation domains from marine sponge metagenomes uncovered hundreds of previously unknown sequences, including several clades that had not been previously observed by extensive Sanger sequencing of these sponge metagenomes. (23) Furthermore, a head-to-head comparison of shotgun sequencing of the same samples demonstrated that PCR-based approaches were often 10 to 100 times more sensitive in identifying unique sequences from a metagenome of interest. (23) Even greater biosynthetic biodiversity was observed in desert soil microbiomes, where 1,000s of unique adenylation domain sequences were detected with only a fraction of them shared among distinct microbiomes.…”

Section: Introductionmentioning

confidence: 99%

“…(23) Furthermore, a head-to-head comparison of shotgun sequencing of the same samples demonstrated that PCR-based approaches were often 10 to 100 times more sensitive in identifying unique sequences from a metagenome of interest. (23) Even greater biosynthetic biodiversity was observed in desert soil microbiomes, where 1,000s of unique adenylation domain sequences were detected with only a fraction of them shared among distinct microbiomes. A similar pattern was observed for amplicons derived from Type I (ketosynthase) and Type II (ketosynthase alpha) polyketide biosynthesis, suggesting that soil metagenomes are likely to be a rich source of novel bioactive compounds.…”

Section: Introductionmentioning

confidence: 99%

Metagenomic small molecule discovery methods

Charlop–Powers

Milshteyn

Brady

2014

Current Opinion in Microbiology

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Metagenomic approaches to natural product discovery provide the means of harvesting bioactive small molecules synthesized by environmental bacteria without the requirement of first culturing these organisms. Advances in sequencing technologies and general metagenomic methods are beginning to provide the tools necessary to unlock the unexplored biosynthetic potential encoded by the genomes of uncultured environmental bacteria. Here, we highlight recent advances in sequence- and functional- based metagenomic approaches that promise to facilitate antibiotic discovery from diverse environmental microbiomes.

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Deep sequencing of non-ribosomal peptide synthetases and polyketide synthases from the microbiomes of Australian marine sponges

Cited by 49 publications

References 54 publications

Chemical-biogeographic survey of secondary metabolism in soil

Chemical-biogeographic survey of secondary metabolism in soil

Bioprospecting microbial metagenome for natural products

Metagenomic small molecule discovery methods

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