Self-assembled polymers such as block copolymers are usually formed through covalent linkages in conventional polymer chemistry, including bonds connecting monomer units and attaching functional groups to the polymer backbone. Recently, novel structural organizations of self-assembled polymers formed through highly directional and sufficiently strong non-covalent host-guest pairs have attracted great attention. These new polymers utilize non-covalent multiple-hydrogen-bonding interactions similar to those found in bio-molecules such as protein, DNA, and RNA to direct and modulate their 3-D topology. In addition, the moderately strong and highly directional multiple-hydrogen-bonding interactions within these new generation polymers also result in unique physical properties, such as high specificity, controlled affinity, and reversibility. In previous studies, the study on the complementary nature and its effect on material properties can be broadly classified into side chain and chain ends types. Until now, studying and controlling the microstructures within supramolecular polymers with different hydrogen-bonding motifs still remain as a challenging task. In this study, the amphiphilic alkylated nucleobase, hexadecyluracil (U16) was incorporated into poly(amide urethane) which was synthesized ourselves with self-complementary group and several hydrogen bonding motifs for the study on the heterodimer recognition behavior within the alternative polymer. Biocomplementary PAU/U16 supramolecular complexes formed in dilute DMF through molecular recognition, that is, the hydrogen bonding between the diaminopyridine (DAP) groups of the PAU and the Uracil (U) of U16. Moreover, FTIR, DSC, WAXD, SAXS, and TEM analysis provided furthur detail into the nature of self-assembly of these systems. The effect of the heterodimer recognition on the microphase separation was investigated, revealing that the heterodimer recognition led the poly(amide urethane) to possessing the “plug and play” behavior even the heterodimer recognition coincided with several other hydrogen bonding motifs. The period and morphlogies of PAU/U16 complexes can be rationally tuned by the amount of U16. Upon the adding of U16, the lamellar structure within long-range lamellar changes from bilayer to bilayer with interclated and further to monolayer.