To identify sequence-specific motifs associated with the formation of an ionic pore, we systematically evaluated the channel-forming activity of synthetic peptides with sequence of predicted transmembrane segments of the voltage-gated calcium channel. The amino acid sequence of voltage-gated, dihydropyridine (DHP)-sensitive calcium channels suggests the presence in each of four homologous repeats (I-IV) of six segments (SI-S6) predicted to form membrane-spanning, a-helical structures. Only peptides representing amphipathic segments S2 or S3 form channels in lipid bilayers. To generate a functional calcium channel based on a four-helix bundle motif, four-helix bundle proteins representing IVS2 (T4CaIVS2) or IVS3 (T4CaIVS3) were synthesized. Both proteins form cationselective channels, but with distinct characteristics: the single-channel conductance in 50 mM BaCI, is 3 pS and 10 pS. For T4CaIVS3, the conductance saturates with increasing concentration of divalent cation. The dissociation constants for Ba2+, Ca2+, and SrZf are 13.6 mM, 17.7 mM, and 15.0 mM, respectively. The conductance of T4CaIVS2 does not saturate up to 150 mM salt. Whereas T4CaIVS3 is blocked by pM Ca2+ and Cd2+, T4CaIVS2 is not blocked by divalent cations. Only T4CaIVS3 is modulated by enantiomers of the DHP derivative BayK 8644, demonstrating sequence requirement for specific drug action. Thus, only T4CaIVS3 exhibits pore properties characteristic also of authentic calcium channels. The designed functional calcium channel may provide insights into fundamental mechanisms of ionic permeation and drug action, information that may in turn further our understanding of molecular determinants underlying authentic pore structures.Keywords: calcium channel; dihydropyridines; lipid bilayer; protein design; four-helix bundle; single-channel recording Voltage-gated channels, comprising a large superfamily of integral membrane proteins fundamentally involved in electrical excitability (Hille, 1992), facilitate the flux of ions across the cell membrane in response to changes in transmembrane electric field. Because voltage-gated channel proteins have not yet yielded to high-resolution structural analysis, the unequivocal localization of even fundamental motifs, such as the actual ionic pathway, is lacking. However, understanding the unique functional attributes of channel proteins requires that structural elements underlying specific properties are identified. Extensive efforts are currently directed toward elucidating molecular determinants underlying the ionic pore.