N,N-Dimethylformamide (DMF) provides a useful small-molecule model for studying features of the peptide bond that forms the backbone of proteins. We report results from a comprehensive multimass velocity-map imaging study into the ultraviolet (UV) photolysis of the N,N-dimethylformamide cation (DMF+) at wavelengths of 225, 245, and 280 nm. Electronic structure calculations on DMF and DMF+ were employed to help interpret the experimental results. DMF+ ions are generated by 118 nm single-photon ionization of neutral DMF. Subsequent UV photolysis is found to lead to selective cleavage of the N-CO amide bond. This yields HCO + NC2H6+ as major products, with virtually all of the excess energy released into internal modes of the fragments. The data also indicate a small branching ratio into the HCO+ + NC2H6 product pair, which can be accessed from the 32A' electronic state of DMF+. N-CO bond dissociation can also be accompanied by simultaneous intramolecular hydrogen transfer from the oxygen to the nitrogen end of the amide bond, in which case NCH4+ can be formed efficiently at all three wavelengths. The primary NC2H6+ product is relatively long-lived, but the high degree of internal excitation often results in secondary fragmentation via a variety of pathways to form CH3+, NH4+, NCH2+, and NC2H4+, with secondary dissociation more likely at higher photon energies. The isotropic velocity-map images recorded for the various fragments attest to the long lifetime of NC2H6+ and also imply that dissociation most probably occurs from the same set of electronic states at all wavelengths studied; these are thought to be the 12A' ground state and 22A' first excited state of the DMF+ cation.