ABSTRACT
A novel genome editing method for repeated introduction of foreign DNA, including insertion of rather large DNA fragments, into predesigned points in the Corynebacterium glutamicum chromosome was developed. The method is based on the implementation of the Dual-In/Out strategy, which was previously provided in Escherichia coli according to recombineering-based methods (Minaeva et al., 2008) and allowed step-by-step construction of marker-less plasmid free recombinant strains. The strategy, suggested in the current study, is based on (i) E. coli Rac prophage RecE564/RecT-dependent recombineering; (ii) corynephage Ï16 (Int/Xis)- and E. coli phage P1 Cre-mediated site-specific recombination systems; and (iii) the development of a C. glutamicum electrotransformation protocol with donor chromosomal DNA for combining of obtained modifications. It was found, that for each tested C. glutamicums strain, the efficiency of the different modifications for electrotransformation fluctuated significantly (up to two orders of magnitude), likely due to the recombinogenic accessibility of the corresponding locus of the bacterial chromosome. To avoid this difficulty, we proposed the phage Mu-driven transposition as a powerful approach for pre-selection of chromosomal regions convenient for single insertions and their further combination in a one strain. Additionally, it was found that the expression of RecE564/RecT coding genes in the recipient strain facilitated the inheritance of the penetrated DNA. It is proposed that the developed strategy in general and its separate elements should be helpful for broadening the genetic toolbox needed for genome editing of targeted C. glutamicum strains.
Subject(s)
Corynebacterium glutamicum , Chromosomes, Bacterial/genetics , Corynebacterium glutamicum/genetics , Escherichia coli/genetics , Gene Editing/methods , Plasmids/geneticsABSTRACT
The genomes of two new lytic phages of Corynebacterium glutamicum ATCC 13032, φ673 and φ674, were sequenced and annotated (GenBank: MG324353, MG324354). Electron microscopy studies of both virions revealed that taxonomically they belong to the Siphoviridae family and have a polyhedral head with a width of 50 nm and a non-contractile tail with a length of 250 nm. The genomes of φ673 and φ674 consist of linear double-stranded DNA molecules with lengths of 44,530 bp (G+C = 51.1%) and 43,193 bp (G+C = 50.7%) and identical, protruding, cohesive 3' ends 13 nt in length. The level of identity between the φ673 and φ674 genomes is 85.2%. Two major structural proteins of each virion were separated via SDS-PAGE and identified using peptide mass fingerprinting. Based on bioinformatic analysis, 56 and 54 ORFs were predicted for φ673 and φ674, respectively. Only 20 of the putative gene products of φ673 and 20 of φ674 could be assigned to known functions. Both genomes were divided into functional modules. Nine putative promoters in the φ673 genome and eight in the φ674 genome were predicted. One bidirectional Rho-independent transcription terminator was identified and experimentally confirmed in each phage genome.
Subject(s)
Bacteriophages/genetics , Bacteriophages/isolation & purification , Corynebacterium glutamicum/virology , Siphoviridae/genetics , Siphoviridae/isolation & purification , Amino Acid Sequence , Bacteriophages/classification , Base Composition , Genome, Viral , Molecular Sequence Annotation , Open Reading Frames , Phylogeny , Sequence Analysis, DNA , Siphoviridae/classificationABSTRACT
A dual-component Mu-transposition system was modified for the integration/amplification of genes in Corynebacterium. The system consists of two types of plasmids: (i) a non-replicative integrative plasmid that contains the transposing mini-Mu(LR) unit bracketed by the L/R Mu ends or the mini-Mu(LER) unit, which additionally contains the enhancer element, E, and (ii) an integration helper plasmid that expresses the transposition factor genes for MuA and MuB. Efficient transposition in the C. glutamicum chromosome (≈ 2 × 10-4 per cell) occurred mainly through the replicative pathway via cointegrate formation followed by possible resolution. Optimizing the E location in the mini-Mu unit significantly increased the efficiency of Mu-driven intramolecular transposition-amplification in C. glutamicum as well as in gram-negative bacteria. The new C. glutamicum genome modification strategy that was developed allows the consequent independent integration/amplification/fixation of target genes at high copy numbers. After integration/amplification of the first mini-Mu(LER) unit in the C. glutamicum chromosome, the E-element, which is bracketed by lox-like sites, is excised by Cre-mediated fashion, thereby fixing the truncated mini-Mu(LR) unit in its position for the subsequent integration/amplification of new mini-Mu(LER) units. This strategy was demonstrated using the genes for the citrine and green fluorescent proteins, yECitrine and yEGFP, respectively.
Subject(s)
Bacteriophage mu , Chromosomes, Bacterial , Corynebacterium glutamicum/genetics , DNA Transposable Elements , Gene Editing/methods , Genetics, Microbial/methods , Gene Dosage , Genetic Vectors , Plasmids , Recombination, GeneticABSTRACT
The complete genome of Ï16, a temperate corynephage from Corynebacterium glutamicum ATCC 21792, was sequenced and annotated (GenBank: KY250482). The electron microscopy study of Ï16 virion confirmed that it belongs to the family Siphoviridae. The Ï16 genome consists of a linear double-stranded DNA molecule of 58,200 bp (G+C = 52.2%) with protruding cohesive 3'-ends of 14 nt. Four major structural proteins were separated by SDS-PAGE and identified by peptide mass fingerprinting technique. Using bioinformatics analysis, 101 putative ORFs and 5 tRNA genes were predicted. Only 27 putative gene products could be assigned to known biological functions. The Ï16 genome was divided into functional modules. Seven putative promoters and eight putative unidirectional intrinsic terminators were predicted. One site of putative «-1¼ programmed ribosomal frameshifting was proposed in the phage tail assembly genome region. C. glutamicum genetic tools could be broadened by exploiting the known integrase gene (gp33) and the newly identified excisionase gene (gp47), participating in site-specific recombination between Ï16-attP/attB.