Abstract
The shelterin complex protects chromosome ends from aberrant DNA repair and regulates telomerase access to telomeres. Shelterin is composed of six proteins (TRF1, TRF2, TIN2, TPP1, POT1, and RAP1) that can assemble into various subcomplexes in vitro, but their stoichiometry and dynamics in cells remain poorly understood. To quantitatively analyze shelterin function, we generated a panel of human cancer cell lines expressing HaloTagged shelterin proteins from their endogenous loci. We determined both the total and telomeric abundance of each subunit, demonstrating that shelterin proteins are present at telomeres in equal numbers. Using single-molecule live-cell imaging, we showed that TRF1-TIN2-TPP1-POT1 and TRF2-RAP1 form distinct subcomplexes that bind non-overlapping sites on telomeric chromatin. TRF1-TIN2-TPP1-POT1 tightly associates with telomeres, whereas TRF2-RAP1 binds more dynamically, facilitating the recruitment of co-factors that protect chromosome ends. Altogether, our work provides mechanistic insight into shelterin function in telomere maintenance and advances our understanding of telomeric chromatin architecture.