Herein, we report a systematic evaluation of backbone modification strategies to enhance peptide membrane permeability, focusing on chloroalkene dipeptide isosteres (CADIs) as amide bond surrogates. A direct comparison with classical modifications─including N-methylation, esterification, and thioamidation─reveals that CADI substitution consistently provides the highest improvement in both passive diffusion and cellular uptake. Mechanistic analyses combining A log P calculations, HPLC profiling, and molecular dynamics simulations attribute this effect primarily to improved lipophilicity and reduced hydration, rather than conformational changes. Notably, CADI substitution is successfully extended to longer polar sequences and cyclic scaffolds, and it preserves or enhances RNA-binding affinity and selectivity in G-quadruplex-binding RGG peptides. Overall, this study establishes CADI substitution as a robust backbone modification strategy that enables the design of peptidomimetics with enhanced membrane permeability and improved resistance to hydrolytic stability.