Recombineering 101: Making an in-Frame Deletion Mutant.
Nara Figueroa-BossiRoberto BalbontínLionello BossiPublished in: Cold Spring Harbor protocols (2023)
DNA recombineering uses phage λ Red recombination functions to promote integration of DNA fragments generated by polymerase chain reaction (PCR) into the bacterial chromosome. The PCR primers are designed to have the last 18-22 nt anneal on either side of the donor DNA and to carry 40- to 50-nt 5' extensions homologous to the sequences flanking the chosen insertion site. The simplest application of the method results in knockout mutants of nonessential genes. Deletions can be constructed by replacing a portion or the entirety of a target gene with an antibiotic-resistance cassette. In some commonly used template plasmids, the antibiotic-resistance gene can be coamplified with a pair of flanking FRT (Flp recombinase recognition target) sites that, following insertion of the fragment into the chromosome, allow excision of the antibiotic-resistance cassette via the activity of the site-specific Flp recombinase. The excision step leaves behind a "scar" sequence comprising an FRT site and flanking primer annealing sequences. Removal of the cassette minimizes undesired perturbations on the expression of neighboring genes. Even so, polarity effects can result from the occurrence of stop codons within, or downstream of, the scar sequence. These problems can be avoided by the appropriate choice of the template and by designing primers so that the reading frame of the target gene is maintained past the deletion end point. This protocol is optimized for use with Salmonella enterica and Escherichia coli .
Keyphrases
- genome wide identification
- genome wide
- copy number
- escherichia coli
- circulating tumor
- cell free
- single molecule
- genome wide analysis
- poor prognosis
- dna methylation
- dna damage
- dna repair
- transcription factor
- mental health
- nucleic acid
- risk assessment
- klebsiella pneumoniae
- molecularly imprinted
- binding protein
- bioinformatics analysis
- decision making
- high resolution
- oxidative stress
- candida albicans
- circulating tumor cells
- simultaneous determination