Abstract
Genome-walking protocols have been extensively used to clone unknown genomic sequences next to known DNAs. Existing genome-walking protocols need further improvement in methodological specificity or operation. Here, we describe a novel genome-walking protocol based on fusion primer-driven racket PCR (FPR-PCR). FPR-PCR involves four sequence-specific oligos (SSO), SSO1, SSO2, SSO3, and SSO4, which are sequentially chosen from known DNA in the direction 5'→3'. The fusion primer, mediating primary FPR-PCR, is generated by attaching SSO3 to the 5' end of SSO1. The SSO3 encourages the target DNA of primary PCR to form a racket-like structure by mediating intra-strand annealing. SSO2 and SSO4 are directly used as sequence-specific primers (SSP) in secondary FPR-PCR, which selectively amplifies this racket-like DNA. This protocol was verified by cloning several unknown genomic sequences. Compared to traditional PCRs, FPR-PCR offers the advantages of higher specificity and fewer rounds, primarily attributed to the omission of arbitrary walking primers typically required in traditional methods. Key features • This FPR-PCR protocol builds upon the method constructed by Pei et al. [1]. • The FPR-PCR protocol relies on a multi-functional fusion primer (FP) that mediates the primary amplification and the formation of racket-like DNA. • The FPR-PCR comprises only two rounds of amplification reactions.