Rap1p, the major telomere repeat binding protein in yeast, has been implicated in both de novo telomere formation and telomere length regulation. To characterize the role of Rap1p in these processes in more detail, we studied the generation of telomeres in vivo from linear DNA substrates containing defined arrays of Rap1p binding sites. Consistent with previous work, our results indicate that synthetic Rap1p binding sites within the internal half of a telomeric array are recognized as an integral part of the telomere complex in an orientationindependent manner that is largely insensitive to the precise spacing between adjacent sites. By extending the lengths of these constructs, we found that several different Rap1p site arrays could never be found at the very distal end of a telomere, even when correctly oriented. Instead, these synthetic arrays were always followed by a short (Ϸ100-bp) "cap" of genuine TG repeat sequence, indicating a remarkably strict sequence requirement for an end-specific function(s) of the telomere. Despite this fact, even misoriented Rap1p site arrays promote telomere formation when they are placed at the distal end of a telomere-healing substrate, provided that at least a single correctly oriented site is present within the array. Surprisingly, these heterogeneous arrays of Rap1p binding sites generate telomeres through a RAD52-dependent fusion resolution reaction that results in an inversion of the original array. Our results provide new insights into the nature of telomere end capping and reveal one way by which recombination can resolve a defect in this process.Telomeres, the specialized protein-DNA complexes that constitute the ends of eukaryotic chromosomes, permit the complete replication of chromosome ends and allow the cell to distinguish these natural ends from accidental DNA breaks (reviewed recently in reference 27). The complete replication of telomeric DNA, which cannot be accomplished by conventional DNA polymerases, is carried out in most organisms by a cellular reverse transcriptase, called telomerase, that carries its own RNA template (42). Telomerase generates simple repeat sequences (TTAGGG in mammals and most other eukaryotes but TG 1-3 in the yeast Saccharomyces cerevisiae) in which the GT-rich strand forms the 3Ј end of the chromosome. TG 1-3 repeat tracts in yeast, which vary in length from Ϸ250 to 350 bp, form very high affinity binding sites for the multifunctional regulatory protein Rap1 (26). Because of the irregular nature of the repeats, the disposition of Rap1p binding sites does not appear to be constant, though an average of one site per Ϸ18 bp has been measured in one study (11). In mammalian cells, the regular TTAGGG telomeric repeats are longer (and more heterogeneous in length) than the related repeats in yeast (Ϸ10 kb in humans and up to 50 kb in the mouse, Mus musculus). Telomere repeat DNA in mammalian cells is bound by at least two distinct, related proteins, TRF1 and TRF2 (2, 4, 7).The unusual mechanism of telomere DNA replication imposes a regul...
