The Sequence of a 1.8-Mb Bacterial Linear Plasmid Reveals a Rich Evolutionary Reservoir of Secondary Metabolic Pathways

Medema, Marnix H.; Trefzer, Axel; Kovalchuk, Andriy; Berg, Marco van den; Müller, Ulrike; Heijne, Wilbert H. M.; Wu, Liang; Alam, Mohammad Tauqeer; Ronning, Catherine M.; Nierman, William C.; Bovenberg, Roel A. L.; Breitling, Rainer; Takano, Eriko

doi:10.1093/gbe/evq013

Cited by 182 publications

(201 citation statements)

References 95 publications

(104 reference statements)

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“…It seems to present us with the potential hopes for the identification of the tunicamycin gene cluster; however, efforts with bioinformatic and genetic analysis of the genome data were unsuccessful because of the paucity of the knowledge on tunicamycin biosynthesis (Price and Tsvetanova, 2007;Medema et al, 2010).…”

Section: Identification Of the Tunicamycin Biosynthetic Gene Cluster mentioning

confidence: 99%

Characterization of the tunicamycin gene cluster unveiling unique steps involved in its biosynthesis

Chen

Zhai

et al. 2010

Protein Cell

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Tunicamycin, a potent reversible translocase I inhibitor, is produced by several Actinomycetes species. The tunicamycin structure is highly unusual, and contains an 11-carbon dialdose sugar and an α, β-1″,11′-glycosidic linkage. Here we report the identification of a gene cluster essential for tunicamycin biosynthesis by high-throughput heterologous expression (HHE) strategy combined with a bioassay. Introduction of the genes into heterologous non-producing Streptomyces hosts results in production of tunicamycin by these strains, demonstrating the role of the genes for the biosynthesis of tunicamycins. Gene disruption experiments coupled with bioinformatic analysis revealed that the tunicamycin gene cluster is minimally composed of 12 genes (tunAtunL). Amongst these is a putative radical SAM enzyme (Tun B) with a potentially unique role in biosynthetic carbon-carbon bond formation. Hence, a seven-step novel pathway is proposed for tunicamycin biosynthesis. Moreover, two gene clusters for the potential biosynthesis of tunicamycin-like antibiotics were also identified in Streptomyces clavuligerus ATCC 27064 and Actinosynnema mirums DSM 43827. These data provide clarification of the novel mechanisms for tunicamycin biosynthesis, and for the generation of new-designer tunicamycin analogs with selective/enhanced bioactivity via combinatorial biosynthesis strategies.

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Section: Identification Of the Tunicamycin Biosynthetic Gene Cluster mentioning

confidence: 99%

Characterization of the tunicamycin gene cluster unveiling unique steps involved in its biosynthesis

Chen

Zhai

et al. 2010

Protein Cell

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“…34,35 pSCL4 of S. clavuligerus is composed of a 7-kb pSCL1 sequence flanked by the two chromosomal arms. 67 In this connection, I discussed on horizontal transfer of the extremely condensed biosynthetic clusters on pSLA2-L. 3 We could not detect any transposition-related genes or sequences surrounding the clusters, except for several truncated genes. 43 This is true for the methylenomycin cluster on SCP1.…”

Section: Other Giant Linear Plasmidsmentioning

confidence: 91%

“…Nucleotide sequencing of pSLC1 and pSLC2 neither revealed any genes for cephamycin or clavulanic acid biosynthesis. 65,66 Recently, Madema et al 67 isolated an extremely large linear plasmid, pSCL4, from S. clavuligerus ATCC 27064 and determined its 1.8-Mb nucleotide sequence. Surprisingly, this plasmid was densely packed with an exceptionally large number of gene clusters for the potential production of antibiotics, such as staurosporine, moenomycin, b-lactams and enediynes.…”

Section: Pksl In S Lasaliensismentioning

confidence: 99%

Giant linear plasmids in Streptomyces: a treasure trove of antibiotic biosynthetic clusters

Kinashi

2010

J Antibiot

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Many giant linear plasmids have been isolated from Streptomyces by using pulsed-field gel electrophoresis and some of them were found to carry an antibiotic biosynthetic cluster(s); SCP1 carries biosynthetic genes for methylenomycin, pSLA2-L for lankacidin and lankamycin, and pKSL for lasalocid and echinomycin. Accumulated data suggest that giant linear plasmids have played critical roles in genome evolution and horizontal transfer of secondary metabolism. In this review, I summarize typical examples of giant linear plasmids whose involvement in antibiotic production has been studied in some detail, emphasizing their finding processes and interaction with the host chromosomes. A hypothesis on horizontal transfer of secondary metabolism involving giant linear plasmids is proposed at the end.

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“…Ever since the introduction of next-generation sequencing, the amount of genome information for natural product-producing organisms has been increasing rapidly, leading to the identification of an unexpectedly large number of biosynthetic gene clusters: typically up to a few dozen per genome, tens of thousands in total. It has become clear that most of the products of these gene clusters are not produced at detectable levels under laboratory conditions [1][2][3]; the gene clusters are 'silent', 'sleeping' or 'cryptic'. Sequence-guided genome mining and heterologous expression of biosynthesis gene clusters have been successful in awakening some cryptic clusters through knocking out or overexpressing regulatory genes [4,5,6 ], but no high-throughput methodology has been fully developed yet.…”

Section: Introductionmentioning

confidence: 99%

Design-based re-engineering of biosynthetic gene clusters: plug-and-play in practice

Frasch

Medema

Takano

et al. 2013

Current Opinion in Biotechnology

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The Sequence of a 1.8-Mb Bacterial Linear Plasmid Reveals a Rich Evolutionary Reservoir of Secondary Metabolic Pathways

Cited by 182 publications

References 95 publications

Characterization of the tunicamycin gene cluster unveiling unique steps involved in its biosynthesis

Characterization of the tunicamycin gene cluster unveiling unique steps involved in its biosynthesis

Giant linear plasmids in Streptomyces: a treasure trove of antibiotic biosynthetic clusters

Design-based re-engineering of biosynthetic gene clusters: plug-and-play in practice

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