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High-copy-number plasmids are indispensable tools for gene overexpression studies in prokaryotes to engineer pathways or probe phenotypes of interest. The development of genetic tools for the industrially relevant Actinobacteria is of special interest, given their utility in producing keratolytic enzymes and biologically active natural products. Within the Actinobacteria, Streptomyces–Escherichia coli shuttle vectors based on the SCP2* and pIJ101 incompatibility groups are widely employed for molecular cloning and gene expression studies. Here, the sequences of two commonly used pIJ101-based Streptomyces–E. coli shuttle vectors, pEM4 and pUWL201, were determined using next-generation sequencing. These plasmids drive the expression of heterologous genes using the constitutive ermE*p promoter. pEM4 was found to be 8.3 kbp long, containing a β-lactamase gene, thiostrepton resistance marker, the lacZɑ fragment, a ColE1 origin of replication and the Streptomyces pIJ101 origin of replication. pUWL201 was found to be 6.78 kbp long, containing a β-lactamase gene, thiostrepton resistance marker, the lacZɑ fragment, a ColE1 origin of replication and the Streptomyces pIJ101 origin of replication. Interestingly, the sequences for both pEM4 and pUWL201 exceed their previously reported size by 1.1 and 0.4 kbp, respectively. This report updates the literature with the corrected sequences for these shuttle vectors, ensuring their compatibility with modern synthetic biology cloning methodologies. 

Background/Goal/Aim The tetracenomycins are aromatic anticancer polyketides that inhibit peptide translation via binding to the large ribosomal subunit. Here, we expressed the elloramycin biosynthetic gene cluster in the heterologous host Streptomyces coelicolor M1146 to facilitate the downstream production of tetracenomycin analogs. Main Methods and Major Results We developed a BioBricks® genetic toolbox of genetic parts for substrate precursor engineering in S. coelicolor M1146::cos16F4iE. We cloned a series of integrating vectors based on the VWB, TG1, and SV1 integrase systems to interrogate gene expression in the chromosome. We genetically engineered three separate genetic constructs to modulate tetracenomycin biosynthesis: 1) the vhb hemoglobin from obligate aerobe Vitreoscilla stercoraria to improve oxygen utilization; (2) the accA2BE acetyl-CoA carboxylase to enhance condensation of malonyl-CoA; (3) lastly, the sco6196 acyltransferase, which is a “metabolic regulatory switch” responsible for mobilizing triacylglycerols to β-oxidation machinery for acetyl-CoA. In addition, we engineered the tcmO 8-O-methyltransferase and newly identified tcmD 12-O-methyltransferase from Amycolatopsis sp. A23 to generate tetracenomycins C and X. We also co-expressed the tcmO methyltransferase with oxygenase urdE to generate the analog 6-hydroxy-tetracenomycin C. Conclusions and Implications Altogether, this system is compatible with the BioBricks® [RFC 10] cloning standard for the co-expression of multiple gene sets for metabolic engineering of Streptomyces coelicolor M1146::cos16F4iE. This production platform improves access to potent analogs, such as tetracenomycin X, and sets the stage for the production of new tetracenomycins via combinatorial biosynthesis. This article is protected by copyright. All rights reserved