posted on 2007-10-09, 00:00authored byLiana Oganesian, Mark E. Graham, Phillip J. Robinson, Tracy M. Bryan
Telomeric DNA can assemble into a nonlinear, higher-order conformation known as a
G-quadruplex. Here, we demonstrate by electrospray ionization mass spectrometry that the two repeat
telomeric sequence d(TGGGGTTGGGGT) from Tetrahymena thermophila gives rise to a novel parallel
four-stranded G-quadruplex in the presence of sodium. The G-quadruplex directly interacts with the catalytic
subunit of Tetrahymena telomerase (TERT) with micromolar affinity, and the presence of telomerase
RNA is not obligatory for this interaction. Both N- and C-terminal halves of TERT bind the G-quadruplex
independently. This G-quadruplex is a robust substrate for both recombinant and cell extract-derived
telomerase in vitro. Furthermore, the G-quadruplex weakens the affinity of wild-type telomerase for the
incoming nucleotide (dTTP) and likely perturbs the nucleotide binding pocket of the enzyme. In agreement
with this, a lysine to alanine substitution at amino acid 538 (K538A) within motif 1 of TERT dramatically
reduces the ability of telomerase to extend G-quadruplex but not linear DNA. The K538A mutant retains
binding affinity for the quadruplex. This suggests that telomerase undergoes changes in conformation in
its active site to specifically accommodate binding and subsequent extension of G-quadruplex DNA. We
propose that telomerase recognizes G-quadruplex DNA as a substrate that is distinct from linear DNA.