The non-structural protein RNA-dependent RNA polymerase (RdRp) NS5B plays a key role in hepatitis C virus (HCV) replication and is currently considered as one of the most relevant target to develop safe anti-HCV agents. Although many small molecules have been identified as inhibitors of NS5B, very few are active in clinic. The structure and function of NS5B have been well characterized and as other polymerases, NS5B adopts a typical “right-hand” conformation containing the characteristic fingers, palm and thumb subdomains. The activation of NS5B requires conformational changes involving intramolecular contacts as well interactions with viral proteins and host factors in the replication complex. We developed a new strategy for NS5B inhibition based on short interfacial peptides derived from NS5B surface accessible motifs that target protein-protein interfaces or essential motifs involved in NS5B-activation. Combining the NS5B crystallogaphic structure and molecular modelling, we have designed short peptides derived from NS5B surface “hotspots” that were screened using HCV genotype 1b replicon cell system. We have identified Moon1, a short 15-residu peptide, derived from a well-conserved motif located in the NS5B thumb domain that inhibits HCV replication in the low nanomolar range. Moon1 tightly binds NS5B in a conformational-dependent manner and induces NS5B conformational changes. This peptide specifically inhibits double-stranded RNA/NS5B interactions in a dose-dependent and metal ions-independent manner. Moon1 blocks the transition between RNA de novo initiation and primer-extension. We showed that residues required for Moon-1 anti-polymerase activity are well-conserved among HCV genotypes and subtypes and a minimal Moon1 active motif was established. Taken together, these results demonstrate that NS5B structural dynamics constitute an attractive target for HCV chemotherapeutics and for the design of more specific new antiviral drugs.