Complete sequence and analysis of the stability functions of pPSX, a vector that allows stable cloning and expression of Streptomycete genes in Escherichia coli K12

The modular pYT vector series employed for chromosomal gene integration and expression to produce carbazoles and glycolipids in P. putida

The expression of biosynthetic genes in bacterial hosts can enable access to high-value compounds, for which appropriate molecular genetic tools are essential. Therefore, we developed a toolbox of modular vectors, which facilitate chromosomal gene integration and expression in Pseudomonas putida KT2440. To this end, we designed an integrative sequence, allowing customisation regarding the modes of integration (random, at attTn7, or into the 16S rRNA gene), promoters, antibiotic resistance markers as well as fluorescent proteins and enzymes as transcription reporters. We thus established a toolbox of vectors carrying integrative sequences, designated as pYT series, of which we present 27 ready-to-use variants along with a set of strains equipped with unique 'landing pads' for directing a pYT interposon into one specific copy of the 16S rRNA gene. We used genes of the well-described violacein biosynthesis as reporter to showcase random Tn5-based chromosomal integration leading to constitutive expression and production of violacein and deoxyviolacein. Deoxyviolacein was likewise produced after gene integration into the 16S rRNA gene of rrn operons. Integration in the attTn7 site was used to characterise the suitability of different inducible promoters and successive strain development for the metabolically challenging production of mono-rhamnolipids. Finally, to establish arcyriaflavin A production in P. putida for the first time, we compared different integration and expression modes, revealing integration at attTn7 and expression with NagR/PnagAa to be most suitable. In summary, the new toolbox can be utilised for the rapid generation of various types of P. putida expression and production strains.

Chromobacterium violaceum and its important metabolites--review

C. violaceum appeared as important bacterium in different applications and mainly these aspects are related to the production of violacein. This review discusses the last reports on biosynthetic pathways, production, genetic aspects, biological activities, pathological effects, antipathogenic screening through quorum sensing, environmental effects and the products of C. violaceum with industrial interest. An important discussion is on biological applications in medicine and as industrial products such as textile and in cosmetics.

Stable high level expression of the violacein indolocarbazole anti-tumour gene cluster and the Streptomyces lividans amyA gene in E. coli K12

Previous studies showed that when pPSX-vioABCDE was used to transform E. coli K12 DH5alpha the strain retained the plasmid even after 100 generations of unselected growth but produced a low level of the anti-tumour antibiotic violacein. Markedly higher levels of violacein synthesis were obtained from E. coli K12 DH5alpha pUC18-vioABCDE and Sphingomonas sp. JMP4092 pPSX-vioABCDE. Unfortunately, both strains were extremely unstable regardless of presence or absence of antibiotic selection to retain the plasmid. The current study was undertaken to determine if strains of E. coli K12 could be isolated which stably over produce violacein. When a range of E. coli K12 strains were transformed with pPSX-vioABCDE, most produced small amounts of violacein. However, a small number of related strains of E. coli K12 JM101, JM105 and JM109 not only over-produced violacein, but also maintained the high stability. In addition, E. coli K12 JM109 strongly expressed an alpha amylase gene (amyA) from Streptomyces lividans indicating that the S. lividans amyA promoter is highly active in E. coli K12 JM109. In another set of experiments, a violacein overproduction mutation (opv-1) of the plasmid pPSX-vioABCDE was isolated which enabled E. coli K12 DH5alpha to overproduce violacein while retaining high stability. The plasmid pPSX-vioABCDEopv-1 possesses a single base pair deletion in the promoter region of the violacein operon. By combining the over producing strain E. coli K12 JM109 and the over producing plasmid pPSX-vioABCDEopv-1, a stable hyper producing strain (E. coli K12 JM109 pPSX-vioABCDEopv-1) was constructed. Finally, two additional stable vectors, pPSX10 and pPSX20, were constructed to facilitate subcloning and functional analysis studies.