Splicing of pre-mRNA is initiated by binding of U1 snRNP to the 5’ splice site and of Msl5-Mud2 heterodimer to the branch site (BS), together forming the commitment complex (CC). Subsequent binding of U2 snRNP to the pre-mRNA, facilitated by DEAD-box protein Prp5, forms the prespliceosome. How U2 is recruited to the pre-mRNA to replace Msl5-Mud2 and what triggers dissociation of Prp5 during prespliceosome formation is unknown. The research group of Dr. Soo-Chen Cheng previously identified a prespliceosome precursor complex using BS-mutated ACT1 pre-mRNA that causes arrest of Prp5 on the spliceosome, forming a complex called FIC (for Prp five-associated intermediate complex). By immunoprecipitation and cross-linking analyses, I show that Msl5 stalls on the FIC and binds mainly at the upstream cryptic branch site sequence (CBS). In contrast, instead of interacting with the BS, U2 interacts with sequences downstream of it. Deletion of the CBS weakens binding of Msl5 and U2 to BS-mutated pre-mRNA, and the relative position of the CBS to the mutated BS is important for recruitment of U2 snRNP. Restoring base-pairing between U2 and the mutated BS promotes dissociation of Prp5 from the FIC and rescues the splicing defect in a CBS-dependent manner. Mutating sequences downstream of the mutated BS to enhance the pairing strength between U2 and the pre-mRNA reduced the rate of the splicing reaction, suggesting that U2 may be loaded downstream of the BS and then seeks the BS along the pre-mRNA. My results demonstrate that proper interaction of Msl5 with the pre-mRNA is important for U2 recruitment, and that Prp5 dissociates possibly due to a conformational change of U2 snRNA after base-pairing with the BS to drive the reaction forward.