Optimizing twin prime editing components for scalable genome editing and therapy in spinocerebellar ataxia type 3

Recent advances in prime editing technologies using CRISPR modules fused with reverse transcriptase (RT) have enabled efficient and precise reprogramming of target genomic sequences. Twin prime editing using two coordinated prime editor complexes is a promising strategy for inducing extensive genomic modifications via reverse transcribed complementary templates. However, current twin prime editing systems still require improvements in editing efficiency, accuracy, and intended edit predictability. Here, efficiency and precision of twin prime editing were enhanced via engineering and optimizing conventional SpCas9(H840A)-RT-based prime editor components. A La domain–fused prime editor (La-SpCas9(H840A)-RT) and optimized pegRNAs were developed, achieving a 1.75 ± 0.21-fold increase in gene editing efficiency at multiple genomic loci in human-derived cell lines without increasing off-target activity. La-SpCas9(H840A)-RT facilitated efficient ∼2.8 kb GFP transgene knock-in at target loci and eliminated the expanded polyQ tract in ATXN3 in patient-derived mutant cell lines modeling spinocerebellar ataxia type 3. The advanced twin prime editing platform expands genome engineering capabilities beyond existing CRISPR-based systems and holds great promise for diverse biotechnological and therapeutic applications.