Excited electronic states in several radical chromophores representing photochemically active groups in peptide and protein radicals and cation radicals were investigated computationally using equation-of-motion coupled cluster (EOM-CCSD) and time-dependent density functional theory (TD-DFT) methods. The calculations identified the main transitions responsible for photodissociations of gas-phase peptide cation radicals in the near-UV region of the spectrum. Analysis of the EOM-CCSD benchmarks showed that no TD-DFT method was universally accurate across the various radical motifs that included C-alpha-amide, aminoketyl, formamidyl, guanidyl, carbamyl, benzyl, phenoxy, and tautomeric dihydrophenyl and imidazolyl radicals. Overall, the omega B97XD, M06-2X, and LC-BLYP hybrid functionals showed acceptable performance when benchmarked against EOM-CCSD calculations. However, the performance of these TD-DFT methods depended on the nature of the radical chromophore, emphasizing the need for benchmarking and careful analysis.