New strategies for drug discovery: activation of silent or weakly expressed microbial gene clusters

Ochi, Kozo; Hosaka, Takeshi

doi:10.1007/s00253-012-4551-9

Cited by 271 publications

(233 citation statements)

References 99 publications

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“…In addition to these targeted approaches, a whole array of more pleiotropic strategies can be applied in order to activate silent gene clusters: for instance microbial co‐cultivation; addition of rare earth elements or nutrition signals, such as the cell wall metabolite N‐acetylglucosamine; or application of stress conditions (e.g. ethanol or heat stress treatment) have successfully been show to elicit silent gene cluster expression (Ochi and Hosaka, 2013; Abdelmohsen et al ., 2015; Rutledge and Challis, 2015). Altogether, this allows to exploit the natural product producers more intensively as it has been possible in the years before and will lead to the identification of quite a number of new secondary metabolites in the near future.…”

Section: Novel Approaches For Drug Discoverymentioning

confidence: 99%

Antibiotic drug discovery

Wohlleben

Mast

Stegmann

et al. 2016

Microbial Biotechnology

137

113

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SummaryDue to the threat posed by the increase of highly resistant pathogenic bacteria, there is an urgent need for new antibiotics; all the more so since in the last 20 years, the approval for new antibacterial agents had decreased. The field of natural product discovery has undergone a tremendous development over the past few years. This has been the consequence of several new and revolutionizing drug discovery and development techniques, which is initiating a ‘New Age of Antibiotic Discovery’. In this review, we concentrate on the most significant discovery approaches during the last and present years and comment on the challenges facing the community in the coming years.

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Section: Novel Approaches For Drug Discoverymentioning

confidence: 99%

Antibiotic drug discovery

Wohlleben

Mast

Stegmann

et al. 2016

Microbial Biotechnology

137

113

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“…They mapped the mutation to a ribosomal protein and showed that only the mutant ribosome led to activation of the silent Act gene cluster (act), thus demonstrating translational control in Act biosynthesis. The method has been extended to other antibiotics and many successful applications have followed (Ochi 2007;Ochi and Hosaka 2013). Ochi and Hosaka (2013) have recently provided a comprehensive summary of the applications of ribosome engineering.…”

Section: Motivationmentioning

confidence: 99%

“…The method has been extended to other antibiotics and many successful applications have followed (Ochi 2007;Ochi and Hosaka 2013). Ochi and Hosaka (2013) have recently provided a comprehensive summary of the applications of ribosome engineering. Here we focus on the original studies that provided the impetus for the field as well as a molecular rationale for ribosome engineering.…”

Section: Motivationmentioning

confidence: 99%

“…In the model proposed, the mutated RNAP provides rifampicin resistance and behaves like a stringent RNAP. It demonstrates an enhanced affinity for promoters, increasing expression of actII-ORF4, which encodes an act-pathway-specific positive transcriptional regulator, whose expression levels are directly correlated with Act production (Ochi and Hosaka 2013).…”

Section: Mechanismmentioning

confidence: 99%

See 1 more Smart Citation

Antibiotic dialogues: induction of silent biosynthetic gene clusters by exogenous small molecules

Okada¹,

Seyedsayamdost²

2016

FEMS Microbiology Reviews

175

150

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One sentence summary: Microbial secondary metabolites represent a significant source of potential drug leads; however, the majority of the corresponding biosynthetic genes are not expressed under normal laboratory conditions. In this review, we assess the capacity of exogenous small molecules, especially antibiotics, to activate these silent gene clusters. Editor: Aimee Shen ABSTRACTNatural products have traditionally served as a dominant source of therapeutic agents. They are produced by dedicated biosynthetic gene clusters that assemble complex, bioactive molecules from simple precursors. Recent genome sequencing efforts coupled with advances in bioinformatics indicate that the majority of biosynthetic gene clusters are not expressed under normal laboratory conditions. Termed 'silent' or 'cryptic', these gene clusters represent a treasure trove for discovery of novel small molecules, their regulatory circuits and their biosynthetic pathways. In this review, we assess the capacity of exogenous small molecules in activating silent secondary metabolite gene clusters. Several approaches that have been developed are presented, including coculture techniques, ribosome engineering, chromatin remodeling and high-throughput elicitor screens. The rationale, applications and mechanisms attendant to each are discussed. Some general conclusions can be drawn from our analysis: exogenous small molecules comprise a productive avenue for the discovery of cryptic metabolites. Specifically, growth-inhibitory molecules, in some cases clinically used antibiotics, serve as effective inducers of silent biosynthetic gene clusters, suggesting that old antibiotics may be used to find new ones. The involvement of natural antibiotics in modulating secondary metabolism at subinhibitory concentrations suggests that they represent part of the microbial vocabulary through which inter-and intraspecies interactions are mediated.

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“…Many approaches, including isolation of mutants altered in transcription or translation, genetic manipulation of positive and negative regulation, heterologous expression in specialized hosts and others, have been described. 8,[21][22][23][24][25][26][27][28][29][30] For microbial genome mining to become a robust methodology to drive the discovery of new and novel NPs for drug discovery, it is important to have a set of bioinformatics tools that can predict which microorganisms are the most 'gifted' for SM production. antiSMASH 3.0 31 is particularly useful to identify the numbers and types of SMs encoded by microbes, and has been used to survey a wide range of bacteria and archaea for those microorganisms most gifted for SM production.…”

Section: Introductionmentioning

confidence: 99%

Molecular beacons to identify gifted microbes for genome mining

Baltz¹

2017

J Antibiot

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Microbial genome mining is a promising technology that is revitalizing natural product discovery. It is now well documented that many bacteria with large genomes, particularly actinomycetes, encode many more secondary metabolites (SMs) than was previously known from their expressed secondary metabolomes. There are effective bioinformatics tools for counting the numbers and nature of SMs, and determining the total coding capacity from finished microbial genomes. However, these methods do not translate well to draft genomes, particularly for large SM gene clusters that contain nonribosomal peptide synthetase (NRPS) or type I polyketide synthase (PKS-I) mega-genes which are prone to fragmentation and misassembly. Small molecular beacons are required to assess the numbers and variety of NRPS, PKS-I and mixed NRPS/PKS-I pathways. In this report, I show that concatenated peptidyl carrier protein-thioesterase di-domains and acyl carrier protein-thioesterase di-domains can be used as multi-probes to survey finished or draft genomes to estimate the numbers of NRPS, PKS-I and mixed NRPS/PKS-I gene clusters to identify gifted actinomycetes.

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New strategies for drug discovery: activation of silent or weakly expressed microbial gene clusters

Cited by 271 publications

References 99 publications

Antibiotic drug discovery

Antibiotic drug discovery

Antibiotic dialogues: induction of silent biosynthetic gene clusters by exogenous small molecules

Molecular beacons to identify gifted microbes for genome mining

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