Abstract Recurrent chromosomal translocations are hallmarks of many hematological malignancies, including lymphomas and leukemias. Accurate breakpoint detection is essential for diagnostics, treatment optimization, and disease monitoring. Long-read sequencing (Oxford Nanopore Technologies) enables unambiguous mapping and translocation identification. We designed a Cas9-based enrichment panel targeting common translocations in lymphoid malignancies. To accommodate both well-defined and promiscuous translocation partners, we employed single-side and dual-side sequencing strategies. Using well-established lymphoid cell lines, we benchmarked three enrichment approaches: (i) Cas9 read-out, (ii) Cas9 excision with multiplexing, and (iii) adaptive sampling. Cas9-mediated enrichment achieved superior on-target coverage, particularly in densely targeted regions (such as the IGH locus), while single-probe targets showed lower coverage depth. Adaptive sampling offered higher throughput, flexibility, and better pore occupancy, however with limited breakpoint detection. Cas9 excision has been demonstrated as a fast and reliable method to detect canonical translocation partners in clinical lymphoma samples. Our findings indicate that long-read enrichment strategies are suitable for targeting breakpoint hotspots, although the choice of approach depends heavily on the laboratory's specific goal. We propose a decision algorithm for selecting the optimal method based on experimental and clinical needs: Cas9-mediated enrichment suits focused diagnostic intent, while adaptive sampling is preferable for broader research use.
Pardy et al. (Wed,) studied this question.