Development of a compartmentalised self-replication protocol for selection of superior blunt-end DNA ligases.

DNA ligases are widely used in molecular biology to generate recombinant DNA. However, having evolved for nick-sealing, they are inefficient at catalysing the blunt-ended ligations that are critical to many biotechnological applications, including next-generation sequencing. To facilitate engineering of superior blunt-ended DNA ligases, we have developed and validated a compartmentalised self-replication protocol that can select for the most effective ligases from a library of variants. Parallel cultures of Escherichia coli cells expressing different plasmid-encoded variants act as both a source of template DNA for discrete whole-plasmid PCR reactions, and a source of expressed ligase to circularise the corresponding PCR amplicons. The most efficient ligases generate the greatest number of self-encoding plasmids, and are thereby selected over successive rounds of transformation, amplification and ligation. By individually optimising critical steps, we arrived at a coherent protocol that, over five rounds of selection, consistently enriched for cells expressing the more efficient of two recombinant DNA ligases.

Methods for competitive enrichment and evaluation of superior DNA ligases.

DNA ligases have numerous applications in molecular biology and biotechnology. However, many of these applications require the ligation of blunt-ended DNA termini, which is an inefficient activity for existing commercial ligases. To address this limitation, we describe a compartmentalised self-replication protocol that enables enrichment of the most active ligase variants from an arrayed gene library, e.g., for directed evolution. This protocol employs microwell cultures of Escherichia coli cells expressing individual ligase gene variants as both a source of template DNA to generate blunt-ended linear plasmid amplicons, and a source of expressed ligase to circularise its own plasmid amplicon. Transformation of E. coli with the pooled ligation products enables enrichment for clones expressing the most active ligase variants over successive rounds. To facilitate the evaluation of selected ligases, we also describe an in vitro ligation protocol utilising fluorescently labelled, phosphorylated oligonucleotides that are resolved by electrophoresis on a denaturing acrylamide gel to separate the substrate and product bands resulting from blunt-ended, cohesive-ended or nick-sealing ligations.