Two decades of progress in the field of living and controlled polymerizations, combined with the elaboration of efficient conjugation reactions, greatly contributed to the elegant preparation of functionalized macromolecular architectures. However, these state-of-the-art methodologies, while providing a high degree of structural and topological control, are inadequate tools for controlling the polymer microstructure. Crucial parameters like primary structure (i.e. monomer sequence) and tacticity largely remain unmastered by current man-made approaches. Expectations for the next generation synthetic polymers include their performance as single chains, ability to fold and self-regulate, and to sense specific molecules and/or catalyze reactions. These precisely functionalized linear polymers should exhibit sharply defined and tailored structure-activity relationships, analogous to Nature’s delicately engineered macromolecules. Therefore, progress towards reliable sequence-controlled polymerization, enabling preprogrammed distribution of multiple functional groups along the backbone, is drawing attention in a growing number of research groups worldwide. Pioneering efforts to control the primary structure of functionalized polymers have been based on several approaches, such as different reactivity ratios of vinyl monomers, spatial prearrangement of monomers on a (macromolecular) template or, as recently demonstrated, the action of a small-molecule machine. Other attempts use (automated) sequential addition of building blocks on a solid or liquid support, leading to sequence control as a result of iterative coupling steps, thereby omitting the need for pre-organization. These protocols, established for peptide and oligonucleotide synthesis, present considerable drawbacks for sequence-controlled polymerization: they generally require the use of protecting groups and the restricted number of readily available building blocks (‘monomer alphabet’) equipped with the appropriate functional handle can further hamper the preparation of tailor-made functionalized sequences. The development of new chemical protocols for chain elongation, often on a solid support, resulting in sequence-defined (macro)molecular structures with unique backbones and side chain functionalities, or fragments thereof that could be combined to obtain sequence controlled polymers, is therefore highly desirable. We here report on a new coupling strategy for the controlled generation of sequence-defined multi-functionalized oligomers on solid support in a protecting group-free approach, inspired by the ‘submonomer’ synthetic protocol for the preparation of functionalized peptoids, via thiolactone-based chemistry. While the generated oligomers are small in size, reconstitution approaches could further allow the synthesis of larger chains, featuring designed and repetitive display of carefully selected and well-positioned functional entities.