Novel fluorescent genome editing reporters for monitoring DNA repair pathway utilization at endonuclease-induced breaks.

The creation of a DNA break at a specific locus by a designer endonuclease can be harnessed to edit a genome. However, DNA breaks may engage one of several competing repair pathways that lead to distinct types of genomic alterations. Therefore, understanding the contribution of different repair pathways following the introduction of a targeted DNA break is essential to further advance the safety and efficiency of nuclease-induced genome modification.

Coupling endonucleases with DNA end-processing enzymes to drive gene disruption.

Targeted DNA double-strand breaks introduced by rare-cleaving designer endonucleases can be harnessed for gene disruption applications by engaging mutagenic nonhomologous end-joining DNA repair pathways. However, endonuclease-mediated DNA breaks are often subject to precise repair, which limits the efficiency of targeted genome editing. To address this issue, we coupled designer endonucleases to DNA end-processing enzymes to drive mutagenic break resolution, achieving up to 25-fold enhancements in gene disruption rates.

Engineering domain fusion chimeras from I-OnuI family LAGLIDADG homing endonucleases.

Although engineered LAGLIDADG homing endonucleases (LHEs) are finding increasing applications in biotechnology, their generation remains a challenging, industrial-scale process. As new single-chain LAGLIDADG nuclease scaffolds are identified, however, an alternative paradigm is emerging: identification of an LHE scaffold whose native cleavage site is a close match to a desired target sequence, followed by small-scale engineering to modestly refine recognition specificity. The application of this paradigm could be accelerated if methods were available for fusing N- and C-terminal domains from newly identified LHEs into chimeric enzymes with hybrid cleavage sites.