It has been shown previously that some immortalized human cells maintain their telomeres in the absence of significant levels of telomerase activity by a mechanism referred to as alternative lengthening of telomeres (ALT). Cells utilizing ALT have telomeres of very heterogeneous length, ranging from very short to very long. Here we report the effect of telomerase expression in the ALT cell line GM847. Expression of exogenous hTERT in GM847 (GM847/hTERT) cells resulted in lengthening of the shortest telomeres; this is the first evidence that expression of hTERT in ALT cells can induce telomerase that is active at the telomere. However, rapid fluctuation in telomere length still occurred in the GM847/hTERT cells after more than 100 population doublings. Very long telomeres and ALT-associated promyelocytic leukemia (PML) bodies continued to be generated, indicating that telomerase activity induced by exogenous hTERT did not abolish the ALT mechanism. In contrast, when the GM847 cell line was fused with two different telomerase-positive tumor cell lines, the ALT phenotype was repressed in each case. These hybrid cells were telomerase positive, and the telomeres decreased in length, very rapidly at first and then at the rate seen in telomerase-negative normal cells. Additionally, ALT-associated PML bodies disappeared. After the telomeres had shortened sufficiently, they were maintained at a stable length by telomerase. Together these data indicate that the telomerase-positive cells contain a factor that represses the ALT mechanism but that this factor is unlikely to be telomerase. Further, the transfection data indicate that ALT and telomerase can coexist in the same cells.Telomeres are specialized structures consisting, in human cells, of TTAGGG repeat sequences (4, 33) which, together with specific binding proteins (5), form caps at the ends of chromosomes that are essential for chromosome stability (11,17). Telomeres shorten with each round of cell division (1, 2, 18, 21, 28, 34) due, at least in part, to the "end replication problem" (26,44). It is hypothesized that critically shortened telomeres can trigger growth arrest and senescence (19) and that this is a key factor in cellular aging and control of cell division potential (reviewed in reference 36). There may be additional factors, however, that also act as a mitotic clock and cause a permanent exit from the cell cycle (37). All immortalized human cell lines and most tumors that have been studied to date have an active telomere maintenance mechanism, which strongly suggests that prevention of telomere shortening is necessary for the unlimited proliferative potential of these cells (9).The telomere maintenance mechanism in most immortalized cells and tumor cells utilizes the ribonucleoprotein enzyme telomerase, which compensates for sequential telomere shortening at each cell division by catalyzing the addition of repeat sequences (15). Telomerase is either absent or present at low levels in most normal human somatic cells (3,24). Previous studies, however, h...
