Intra-Molecular Homologous Recombination of Scarless Plasmid

Evolution of plasmid-construction

Developing for almost half a century, plasmid-construction has explored more than 37 methods. Some methods have evolved into new versions. From a global and evolutionary viewpoint, a review will make a clear understand and an easy practice for plasmid-construction. The 37 methods employ three principles as creating single-strand overhang, recombining homology arms, or serving amplified insert as mega-primer, and are classified into three groups as single strand overhang cloning, homologous recombination cloning, and mega-primer cloning. The methods evolve along a route for easy, efficient, or/and seamless cloning. Mechanism of plasmid-construction is primer annealing or/and primer invasion. Scar junction is a must-be faced scientific problem in plasmid-construction.

Abortive ligation intermediate blocks seamless repair of double-stranded breaks

Because indel results in frame-shift mutations, seamless repair of double-stranded break (DSB)s plays a pivotal role in synthetic biology, molecular biology, and genome integrity. However, DSB repair is not well documented. T4 DNA ligase (T4lig) served to ligate intra-molecularly a zero bp break-apart DSB linear plasmid DNA pET22b(28a)-xylanase. An ATP T4lig ligation reaction joined one single-stranded break (SSB) into a phosphodiester-bond, whereas the opposite SSB into an abortive ligation intermediate blocking the DSB sequential repair. The intermediate proved to be fluorescent Cy5-AMP-SSB by a T4lig ligation reaction in the aid of Alexa Fluor 647 ATP having Cy5-AMP fluorescence. The fluorescent Cy5-AMP-SSB was de-adenylated into SSB by an ATP-free T4lig or Mg²⁺-free T4ligL159L reaction. The de-adenylated SSB was re-joined into another phosphodiester-bond by a sequential ATP T4lig re-ligation reaction. Thereby, DSB repair proceeds an abortive ligation, a reverse de-adenylation, and a sequential re-ligation reaction. The result has a potential usage in synthetic biology, molecular biology, and cancer-curing.