Danila Vadimovich Zimenkov

Dual-In/Out strategy for genes integration into bacterial chromosome: a novel approach to step-by-step construction of plasmid-less marker-less recombinant E. coli strains with predesigned genome structure

BackgroundThe development of modern producer strains with metabolically engineered pathways poses special problems that often require manipulating many genes and expressing them individually at different levels or under separate regulatory controls. The construction of plasmid-less marker-less strains has many advantages for the further practical exploitation of these bacteria in industry. Such producer strains are usually constructed by sequential chromosome modifications including deletions and integration of genetic material. For these purposes complex methods based on in vitro and in vivo recombination processes have been developed.ResultsHere, we describe the new scheme of insertion of the foreign DNA for step-by-step construction of plasmid-less marker-less recombinant E. coli strains with chromosome structure designed in advance. This strategy, entitled as Dual-In/Out, based on the initial Red-driven insertion of artificial φ80-attB sites into desired points of the chromosome followed by two site-specific recombination processes: first, the φ80 system is used for integration of the recombinant DNA based on selective marker-carrier conditionally-replicated plasmid with φ80-attP-site, and second, the λ system is used for excision of inserted vector part, including the plasmid ori-replication and the marker, flanked by λ-attL/R-sites.ConclusionThe developed Dual-In/Out strategy is a rather straightforward, but convenient combination of previously developed recombination methods: phages site-specific and general Red/ET-mediated. This new approach allows us to detail the design of future recombinant marker-less strains, carrying, in particular, rather large artificial insertions that could be difficult to introduce by usually used PCR-based Recombineering procedure. The developed strategy is simple and could be particularly useful for construction of strains for the biotechnological industry.

Tuning the Expression Level of a Gene Located on a Bacterial Chromosome

A new method of constructing a set of bacterial cell clones varying in the strength of a promoter upstream of the gene of interest was developed with the use of Escherichia coli MG1655 and lacZ as a reporter. The gist of it lies in constructing a set of DNA fragments with tac-like promoters by means of PCR with the consensus promoter Ptac and primers ensuring randomization of the four central nucleotides in the −35 region. DNA fragments containing the tac-like promoters and a selective marker (CmR) were used to replace lacI and the regulatory region of the lactose operon in E. coli MG1655. Direct LacZ activity assays with independent integrant clones revealed 14 new promoters (out of 44 = 256 possible variants), whose strength varied by two orders of magnitude: LacZ activity in the corresponding strains gradually varied from 102 Miller units with the weakest promoter to 104 Miller units with consensus Ptac Sequencing of the modified promoters showed that randomization of three positions in the −35 region is sufficient for generating a representative promoter library, which reduces the number of possible variants from 256 to 64. The method of constructing a set of clones varying in expression of the gene or operon of interest is promising for modern metabolic engineering.

A new method for the construction of translationally coupled operons in a bacterial chromosome

A new method for the construction of translationally coupled operons in a bacterial chromosome was developed on the basis of the recombineering approach. The method includes the in vitro construction of an artificial operon with an efficiently translated proximal cistron, its insertion into the Escherichia coli chromosome, the modification of the operon via Red-driven insertion of a special “Junction” with an excisable selective marker into the intercistronic region of the initial operon, and the excision of the marker. The Junction structure was designed and tested. The Junction consists of three components. The first component is the E. coli rplC-rplD intercistronic region and serves for placing the TAA codon of the proximal gene in the SD sequence (TAAGGAG) of rplD. The second component is the CmR gene flanked by λattL/R sites in such a fashion that the residual λattB site after λInt/Xis-driven excision of the marker does not contain termination codons in frame with ATG of rplD. The third component is the E. coli trpE-trpD intercistronic region which is added so that TGA of trpE acts a termination codon of the new open reading frame (ORF), while the overlapping (TGATG) ATG of trpD is in the position of the initiation codon of the distal gene of the original operon. The general design of the Junction provides the conversion of the original two-cistron operon into a three-cistron operon with translationally coupled genes, where the coupling of the artificial ORF (rplD’-λattB-’trpE) with the proximal gene is due to the rplC-rplD intercistronic region and its coupling with the distal gene is due to trpE-trpD. The strategy was experimentally implemented to construct an artificial operon Ptac-aroG4-serA5, where the expression the distal serA5 gene was optimized owing to translational coupling in a three-cistron operon.