(A) LV gene therapy: An antisickling β-like globin gene or BCL11A shRNA flanked by erythroid regulatory elements is inserted into a replication-deficient LV that is packaged into vector particles. The LV integrates semi-randomly into the host HSPC genome and is expressed in erythroid progeny. The β-like globin forms functional hemoglobin, while the BCL11A shRNA induces γ-globin expression to raise HbF levels. (B) Genome editing: The RNA-guided Cas9 nuclease binds the DNA target site via its associated guide RNA (gRNA) and creates a precise DSB that is repaired either by NHEJ, generating insertion-deletion mutations that induce HbF; or by HDR, which utilizes a donor DNA repair template to correct the SCD codon. (C) Base editing: Catalytically impaired Cas9n fused to either a cytosine or adenosine deaminase introduces precise base pair alterations. Adenosine (A) base editors convert A:T to G:C; cytosine base editors convert C:G to T:A. Base editors are used to induce HbF or convert the SCD codon to a benign variant. (D) Prime editing: Cas9n fused to a reverse transcriptase binds the target site via base pairing with the guide portion of the associated prime editing guide RNA (pegRNA) and creates a single-stranded DNA nick. The reverse transcriptase domain uses the pegRNA template to synthesize the desired edit following the nick. Cellular DNA repair machinery removes the endogenous DNA “flap” and repairs the nick to generate a heteroduplex intermediate that is converted to the edited product by DNA repair.