Novel, highly constrained, 7,5-bicyclic dipeptides (1-aza-6-oxa-2-oxobicyclo[5.3.0]decane ring skeletons, 3Sa and 7Sa) have been synthesized on a 40 mmol scale in similar to 50% yield by a one-step electrochemical cyclization from the dipeptides Boc-L-homoserine-L-proline-OMe (Boc-Hse-Pro-OMe) and Boc-Hse-D-Pro-OMe. The reaction involved a selective anodic amide oxidation which was highly diastereoselective, generating a new chiral center having an S configuration from both precursors. In terms of conformation, the bicyclic system restricts two (psi 2 and phi 3) of the four torsion angles that characterize a reverse turn. Conformational analysis of these molecules and analogs having an R configuration at the ring fusion revealed some families of minimum energy conformations with torsion angles close to those of classical beta-turns, a secondary structural feature found in many bioactive peptides. This new ring skeleton was stable to trifluoroacetic acid, dilute base, and anhydrous hydrofluoric acid, making it compatible with standard solid phase peptide synthesis methodologies.