Monovalent cation-induced structure of telomeric DNA: the G-quartet model

We have investigated the structures formed by oligonucleotides composed of two or four repeats of the telomeric sequences from Oxytricha and Tetrahymena. The Oxytricha four-repeat molecule (d(T4G4)4 = Oxy-4) forms structures with increased electrophoretic mobility in nondenaturing gels containing Na+, K+, or Cs+, but not in gels containing Li+ or no added salt. Formation of the folded structure results in protection of a set of dG's from methylation by dimethyl sulfate. Efficient UV-induced cross-links are observed in Oxy-4 and the related sequence from Tetrahymena (d(T2G4)4 = Tet-4), and join thymidine residues in different repeats. Models proposed to account for these data involve G-quartets, hydrogen-bonded structures formed from four guanosine residues in a square-planar array. We propose that the G-quartet structure must be dealt with in vivo by the telomere replication machinery.     

A comparative study on the interaction of acridine and synthetic bis-acridine with G-quadruplex structure

DNA from the telomeres contains a stretch of simple tandemly repeated sequences in which clusters of G residues alternate with clusters of T/A sequences along one DNA strand. Model telomeric G-clusters form four-stranded structures in presence of Na(I), K(I) and NH(4)(I) ions. Electrophoretic and spectroscopic studies were made with the telomeric related sequences d(T6G16) or d(G4T2G4T2G4T2G4). It was noticed earlier that G-quadruplex may either be inter-molecular, or intra-molecular, or a mixture of both. CD spectral characteristics of various G-quadruplex DNA suggests that the CD maximum at 293 nm corresponds to that of an intra-molecular G-quadruplex structure or hairpin dimers. Fluorescence titration studies also show that acridine and the bis-acridine are interacting with G-quadruplex DNA and destabilize the K(I)-quadruplex structure more efficiently than the quadruplex formed by NH(4)(I) ion. Among the two drugs studied, acridine is more capable of breaking the G-quadruplex structure than bis-acridine. This result is further confirmed by the CD experiments.     

Telomeric DNA oligonucleotides form novel intramolecular structures containing guanine-guanine base pairs

Structural properties of DNA oligonucleotides corresponding to the single-stranded molecular terminus of telomeres from several organisms were analyzed. Based on physical studies including nondenaturing polyacrylamide gel electrophoresis, absorbance thermal denaturation analysis, and 1H and 31P nuclear magnetic resonance spectroscopy, we conclude that these molecules can self-associate by forming non-Watson-Crick, guanine.guanine based-paired, intramolecular structures. These structures form below 40 degrees C at moderate ionic strength and neutral pH and behave like hairpin duplexes in nondenaturing polyacrylamide gels. Detailed analysis of the hairpin structure formed by the telomeric sequence from Tetrahymena, (T2G4)4, shows that it is a unique structure stabilized by hydrogen bonds and contains G residues in the syn conformation. We propose that this novel form of DNA is important for telomere function and sets a precedent for the biological relevance of non-Watson-Crick base-paired DNA structures.     

The solution structure of d(G(4)T(4)G(3))(2): a bimolecular G-quadruplex with a novel fold

The G-rich 11-mer oligonucleotide d(G(4)T(4)G(3)) forms a bimolecular G-quadruplex in the presence of sodium ions with a topology that is distinct from the folds of the closely related and well-characterized sequences d(G(4)T(4)G(4)) and d(G(3)T(4)G(3)). The solution structure of d(G(4)T(4)G(3))(2) has been determined using a combination of NMR spectroscopy and restrained molecular dynamics calculations. d(G(4)T(4)G(3))(2) forms an asymmetric dimeric fold-back structure consisting of three stacked G-quartets. The two T(4) loops that span diagonally across the outer faces of the G-quartets assume different conformations. The glycosidic torsion angle conformations of the guanine bases are 5'-syn-anti-syn-anti-(T(4) loop)-anti-syn-anti in one strand and 5'-syn-anti-syn-anti-(T(4) loop)-syn-anti-syn in the other strand. The guanine bases of the two outer G-quartets exhibit a clockwise donor-acceptor hydrogen-bonding directionality, while those of the middle G-quartet exhibit the anti-clockwise directionality. The topology of this G-quadruplex, like other bimolecular fold-back structures with diagonal loops, places each strand of the G-quartet region next to a neighboring parallel and an anti-parallel strand. The two guanine residues not involved in G-quartet formation, G4 and G12 (i.e. the fourth guanine base of one strand and the first guanine base of the other strand), adopt distinct conformations. G4 is stacked on top of an adjacent G-quartet, and this base-stacking continues along with the bases of the loop residues T5 and T6. G12 is orientated away from the core of G-quartets; stacked on the T7 base and apparently involved in hydrogen-bonding interactions with the phosphodiester group of this same residue. The cation-dependent folding of the d(G(4)T(4)G(3))(2) quadruplex structure is distinct from that observed for similar sequences. While both d(G(4)T(4)G(4)) and d(G(3)T(4)G(3)) form bimolecular, diagonally looped G-quadruplex structures in the presence of Na(+), K(+) and NH(4)(+), we have observed this folding to be favored for d(G(4)T(4)G(3)) in the presence of Na(+), but not in the presence of K(+) or NH(4)(+). The structure of d(G(4)T(4)G(3))(2) exhibits a "slipped-loop" element that is similar to what has been proposed for structural intermediates in the folding pathway of some G-quadruplexes, and therefore provides support for the feasibility of these proposed transient structures in G-quadruplex formation.     

DNA recognition and binding by the Euplotes telomere protein.

The 51-kDa telomere protein from Euplotes crassus binds to the extreme terminus of macronuclear telomeres, generating a very salt-stable telomeric DNA-protein complex. The protein recognizes both the sequence and the structure of the telomeric DNA. To explore how the telomere protein recognizes and binds telomeric DNA, we have examined the DNA-binding specificity of the purified protein using oligonucleotides that mimic natural and mutant versions of Euplotes telomeres. The protein binds very specifically to the 3' terminus of single-stranded oligonucleotides with the sequence (T4G4) > or = 3 T4G2; even slight modifications to this sequence reduce binding dramatically. The protein does not bind oligonucleotides corresponding to the complementary C4A4 strand of the telomere or to double-stranded C4A4.T4G4-containing sequences. Digestion of the telomere protein with trypsin generates an N-terminal protease-resistant fragment of approximately 35 kDa. This 35-kDa peptide appears to comprise the DNA-binding domain of the telomere protein as it retains most of the DNA-binding characteristics of the native 51-kDa protein. For example, the 35-kDa peptide remains bound to telomeric DNA in 2 M KCl. Additionally, the peptide binds well to single-stranded oligonucleotides that have the same sequence as the T4G4 strand of native telomeres but binds very poorly to mutant telomeric DNA sequences and double-stranded telomeric DNA. Removal of the C-terminal 15 kDa from the telomere protein does diminish the ability of the protein to bind only to the terminus of a telomeric DNA molecule.     

A dumbbell-shaped, double-hairpin structure of DNA: a thermodynamic investigation

We report the first calorimetric and spectroscopic investigation on a member of a new class of nucleic acid secondary structures in which both ends of a duplex core are closed by single-stranded loops. Such structures can be formed intramolecularly from appropriately designed base sequences. We have synthesized the 24-mer sequence shown, and we present calorimetric, spectroscopic, and electrophoretic (formula; see text) evidence that it adopts a dumbbell-shaped, double-hairpin structure. Our data allow us to reach the following conclusions: (1) The phosphodiester gap in the center of the core duplex of the dumbbell does not reduce the transition enthalpy relative to that measured for the corresponding octameric duplex d(GGAATTCC)2. (2) Incorporation of a 5'-phosphate group into the gap decreases the thermal stability of the dumbbell relative to its unphosphorylated sequence. On the basis of the salt dependence of this effect, we propose that the phosphorylation--induced decrease in thermal stability is electrostatic in origin. From the changes in the transition enthalpy and entropy, we suggest that the phosphorylation-induced decrease in thermal stability of the double hairpin arises from electrostatically induced based unstacking at the nick. (3) The thymine residues in the loop behave both electrostatically and enthalpically like denatured single strands. Published nuclear magnetic resonance studies reveal partial stacking of thymine residues in the loops of linear hairpin structures. If this feature persists in the double-hairpin structure, then the spatial overlap of thymine residues in the loops does not necessarily produce a favorable enthalpic contribution. (4) When both ends of the nicked octameric core duplex are constrained by loops of only four thymine residues, the dumbbell structure may adopt conformations in which the 5' and 3' ends at the nick are twisted relative to the helical axis and therefore are not in phase. Such conformations would account for the observed resistance of the double-hairpin structure to ligation, since the 3'OH and 5'P would no longer be collinear.     

Features in short guanine-rich sequences that stimulate DNA polymerization in vitro

We have discovered that short guanine-rich oligonucleotides are able to self-associate into higher order structures that stimulate DNA synthesis in vitro without the addition of a conventional template [Ying, J., Bradley, R. K., Jones, L. B., Reddy, M. S., Colbert, D. T., Smalley, R. E., and Hardin, S. H. (1999) Biochemistry 38, 16461-16468]. Our initial analysis indicated the importance of the presence of three contiguous guanines (G) in an oligonucleotide that stimulates DNA polymerization. To gain insight into and to refine sequence requirements for the unexpected DNA synthesis, we analyzed a 231-member guanine-rich octamer library in a fluorescent nucleotide polymerization assay. We observe that, in addition to three contiguous Gs, the presence of a secondary G cluster within the octamer is essential. Furthermore, the location of the primary G cluster in the center of the molecule is most stimulatory. The majority of the octamers that form extended DNA products have a single non-G base separating the primary and secondary G clusters, the identity of which is predominantly thymine (T). Further, a T 5' or 3' of the primary G cluster positively influences the stimulatory function of the oligonucleotide. Overall, the occurrence of bases in the octamer is in the descending order of G > T > A > C. Our studies demonstrate that structures stabilized by noncanonical base pairings are recognized by a DNA polymerase in vitro, and these findings may have relevance within the cell. In particular, the features of these G-rich stimulatory sequences show striking similarities to telomeric sequences that form diverse G-quartet structures in vitro.     

Conformational polymorphism in telomeric structures: Loop orientation and interloop pairing in d(G4TnG4)

Sequence repeats constituting the telomeric regions of chromosomes are known to adopt a variety of unusual structures, consisting of a G tetraplex stem and short stretches of thymines or thymines and adenines forming loops over the stem. Detailed model building and molecular mechanics studies have been carried out for these telomeric sequences to elucidate different types of loop orientations and possible conformations of thymines in the loop. The model building studies indicate that a minimum of two thymines have to be interspersed between guanine stretches to form folded-back structures with loops across adjacent strands in a G tetraplex (both over the small as well as large groove), while the minimum number of thymines required to build a loop across the diagonal strands in a G tetraplex is three. For two repeat sequences, these hairpins, resulting from different types of folding, can dimerize in three distinct ways—i.e., with loops across adjacent strands and on same side, with loops across adjacent strands and on opposite sides, and with loops across diagonal strands and on opposite sides—to form hairpin dimer structures. Energy minimization studies indicate that all possible hairpin dimers have very similar total energy values, though different structures are stabilized by different types of interactions. When the two loops are on the same side, in the hairpin dimer structures of d(G₄T_nG₄), the thymines form favorably stacked tetrads in the loop region and there is interloop hydrogen bonding involving two hydrogen bonds for each thymine–thymine pair. Our molecular mechanics calculations on various folded-back as well as parallel tetraplex structures of these telomeric sequences provide a theoretical rationale for the experimentally observed feature that the presence of intervening thymine stretches stabilizes folded-back structures, while isolated stretches of guanines adopt a parallel tetraplex structure. © 1994 John Wiley & Sons, Inc.     

Substitution of adenine for guanine in the quadruplex-forming human telomere DNA sequence G(3)(T(2)AG(3))(3)

We have studied the formation and structural properties of quadruplexes of the human telomeric DNA sequence G(3)(T(2)AG(3))(3) and related sequences in which each guanine base was replaced by an adenine base. None of these single base substitutions hindered the formation of antiparallel quadruplexes, as shown by circular dichroism, gel electrophoresis, and UV thermal stability measurements in NaCl solutions. Effect of substitution did differ, however, depending on the position of the substituted base. The A-for-G substitution in the middle quartet of the antiparallel basket scaffold led to the most distorted and least stable structures and these sequences preferred to form bimolecular quadruplexes. Unlike G(3)(T(2)AG(3))(3), no structural transitions were observed for the A-containing analogs of G(3)(T(2)AG(3))(3) when sodium ions were replaced by potassium ions. The basic quadruplex topology remained the same for all sequences studied in both salts. As in vivo misincorporation of A for a G in the telomeric sequence is possible and potassium is a physiological salt, these findings may have biological relevance.     

Monovalent cation induced structural transitions in telomeric DNAs: G-DNA folding intermediates

Telomeric DNA consists of G- and C-rich strands that are always polarized such that the G-rich strand extends past the 3' end of the duplex to form a 12-16-base overhang. These overhanging strands can self-associate in vitro to form intramolecular structures that have several unusual physical properties and at least one common feature, the presence of non-Watson-Crick G.G base pairs. The term "G-DNA" was coined for this class of structures (Cech, 1988). On the basis of gel electrophoresis, imino proton NMR, and circular dichroism (CD) results, we find that changing the counterions from sodium to potassium (in 20 mM phosphate buffers) specifically induces conformational transitions in the G-rich telomeric DNA from Tetrahymena, d(T2G4)4 (TET4), which results in a change from the intramolecular species to an apparent multistranded structure, accompanied by an increase in the melting temperature of the base pairs of greater than 25 degrees, as monitored by loss of the imino proton NMR signals. NMR semiselective spin-lattice relaxation rate measurements and HPLC size-exclusion chromatography studies show that in 20 mM potassium phosphate (pH 7) buffer (KP) TET4 is approximately twice the length of the form obtained in 20 mM sodium phosphate (pH 7) buffer (NaP) and that mixtures of Na+ and K+ produce mixtures of the two forms whose populations depend on the ratio of the cations. Since K+ and NH4+ are known to stabilize a parallel-stranded quadruplex structure of poly[r(I)4], we infer that the multistranded structure is a quadruplex. Our results indicate that specific differences in ionic interactions can result in a switch in telomeric DNAs between intramolecular hairpin-like or quadruplex-containing species and intermolecular quadruplex structures, all of which involve G.G base pairing interactions. We propose a model in which duplex or hairpin forms of G-DNA are folding intermediates in the formation of either 1-, 2-, or 4-stranded quadruplex structures. In this model monovalent cations stabilize the duplex and quadruplex forms via two distinct mechanisms, counterion condensation and octahedral coordination to the carbonyl groups in stacked planar guanine "quartet" base assemblies. Substituting one of the guanosine residues in each of the repeats of the Tetrahymena sequence to give the human telomeric DNA, d(T2AG3)4, results in less effective K(+)-dependent stabilization. Thus, the ion-dependent stabilization is attenuated by altering the sequence. Upon addition of the Watson-Crick (WC) complementary strand, only the Na(+)-stabilized structure dissociates quickly to form a WC double helix.(ABSTRACT TRUNCATED AT 400 WORDS)     

Potassium-dependent folding: a key to intracellular delivery of G-quartet oligonucleotides as HIV inhibitors

Several groups have demonstrated that G-rich oligonucleotides forming G-quartet structures display activity as potential drugs, such as potent HIV inhibitors. The delivery of G-quartet oligonucleotides to their intracellular targets is a key obstacle to overcome for their clinical success. Here we have developed a novel system to deliver G-rich oligonucleotides into the cell nucleus, e.g., the site of HIV integration. On the basis of the property of potassium-induced formation of G-quartet structure, we explored the difference of K(+) concentrations inside (140 mM) and outside (4 mM) cells to induce the G-rich oligonucleotides to form different structures inside and outside cells. The key steps of this delivery system include the following: (i) First, the G-quartet structure is denatured to form a lipid-DNA complex, so that the molecules can be well delivered into cells. (ii) Then the delivered molecules are induced to form G-quartet structures by potassium inside cells since the G-quartet structure is the primary requirement for inhibition of HIV-1 HIV integrase (IN) activity. The molecules of a novel G-quartet HIV inhibitor, T40214, with the sequence of (GGGC)(4) were successfully delivered into the nuclei of target cells, which significantly decreased HIV-1 replication and increased the probability to target HIV-1 IN in infected cells.     

Stability of intramolecular DNA quadruplexes: comparison with DNA duplexes

We have determined the stability of intramolecular quadruplexes that are formed by a variety of G-rich sequences, using oligonucleotides containing appropriately placed fluorophores and quenchers. The stability of these quadruplexes is compared with that of the DNA duplexes that are formed on addition of complementary C-rich oligonucleotides. We find that the linkers joining the G-tracts are not essential for folding and can be replaced with nonnucleosidic moieties, though their sequence composition profoundly affects quadruplex stability. Although the human telomere repeat sequence d[G(3)(TTAG(3))(3)] folds into a quadruplex structure, this forms a duplex in the presence of the complementary C-rich strand at physiological conditions. The Tetrahymena sequence d[G(4)(T(2)G(4))(3)], the sequence d[G(3)(T(2)G(3))(3)], and sequences related to regions of the c-myc promoter d(G(4)AG(4)T)(2) and d(G(4)AG(3)T)(2) preferentially adopt the quadruplex form in potassium-containing buffers, even in the presence of a 50-fold excess of their complementary C-rich strands, though the duplex predominates in the presence of sodium. The HIV integrase inhibitor d[G(3)(TG(3))(3)] forms an extremely stable quadruplex which is not affected by addition of a 50-fold excess of the complementary C-rich strand in both potassium- and sodium-containing buffers. Replacing the TTA loops of the human telomeric repeat with AAA causes a large decrease in quadruplex stability, though a sequence with AAA in the first loop and TTT in the second and third loops is slightly more stable.     

Protein binding to expanded telomere repeats in Tetrahymena thermophila

The ends of eukaryotic chromosomes are protected by DNA-protein structures called telomeres. Telomeric DNA is highly conserved, usually consisting of long tracts of a repeating G-rich sequence. Tetrahymena thermophila telomeric DNA consists of alternating blocks of GGGG and TT sequences (i.e. a G4T2 repeat sequence). We examined the relative importance of the guanine and thymine elements of the repeat sequence in promoting in vitro binding by T. thermophila proteins. We identified single- and, for the first time, double-stranded telomere binding activities from a crude T. thermophila protein extract and tested the binding of these activities to altered telomere repeat sequences. All deletions or substitutions made to the guanine element virtually abolished binding, indicating that four G's are essential for recognition by the binding activity. However, G's alone are not sufficient for efficient binding, as elimination of the thymine element dramatically reduced binding. By contrast, substantial expansion of the thymine element was well tolerated, even though one such change, G4T4, is lethal in vivo. We tested up to a four-fold expansion of the thymine element and found that highly efficient binding was still achieved. These results suggest a minimal recognition sequence for T. thermophila proteins, with the T element providing an important spacer between essential G elements.     

Sr2+ facilitates intermolecular G-quadruplex formation of telomeric sequences.

Electrophoretic and spectroscopic studies were made with the telomere-related sequences d(G4T2G4T2G4T2G4) (T2) and d(G4T4G4T4G4T4G4) (T4) in the presence of Na+, K+, and Sr2+. Electrophoretic evidence indicates that these two oligomers exist in multiconformational states in solutions. A band identified as that of intermolecular (tetramolecular) G-quadruplex is apparent in both T2 and T4, whereas a band identified as intramolecular (monomeric) G-quartet is only evident in T4. The remaining electrophoretic bands that exhibit mobilities intermediate of these two extremes are identified as those of hairpin-related duplexes and tetraplexes. In the presence of millimolar concentrations of Sr2+ and subsequent thermal treatment, the intensity corresponding to the band attributable to the intermolecular G-quadruplex is dramatically enhanced in T2 while those of the hairpin-related bands of intermediate mobility are greatly reduced. Similar but less dramatic enhancement of the intermolecular quadruplex band is also observed in T4. Although these effects can also be induced by K+, orders of magnitude higher concentrations are needed. The intensity of the intramolecular G-quartet band, apparent in T4 but not in T2, appears to be relatively insensitive to the type of cation present in the solution. These results demonstrate that both Sr2+ and K+ facilitate the intermolecular G-tetraplex formation, with the divalent cation being much more effective. Comparison with the corresponding CD spectral characteristics suggests that the electrophoretic intensity enhancement of the intermolecular G-quadruplex band is correlated to the intensity enhancement of of the positive CD maximum at 265 nm.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of divalent cations on antiparallel G-quartet structure of d(G4T4G4)

The thermodynamic parameters of an antiparallel G-quartet formation of d(G4T4G4) with 1 mM divalent cation (Mg(2+), Ca(2+), Mn(2+), Co(2+), and Zn(2+)) were obtained. The thermodynamic parameters showed that the divalent cation destabilizes the antiparallel G-quartet of d(G4T4G4) in the following order: Zn(2+)>Co(2+)>Mn(2+)>Mg(2+)>Ca(2+). In addition, a higher concentration of a divalent cation induced a transition from an antiparallel to a parallel G-quartet structure. These results indicate that these divalent cations are a good tool for regulating the G-quartet structures.     

The contribution of thymine-thymine interactions to the stability of folded dimeric quadruplexes.

The loop of four thymines in the sodium form of the dimeric folded quadruplex [d(G3T4G3)]2 assumes a well-defined structure in which hydrogen bonding between the thymine bases appears to contribute to the stability and final conformation of the quadruplex. We have investigated the importance of the loop interactions by systematically replacing each thymine in the loop with a cytosine. The quadruplexes formed by d(G3CT3G3), d(G3TCT2G3), d(G3T2CTG3) and d(G3T3CG3) in the presence of 150 mM Na+ were studied by gel mobility, circular dichroism and 1H NMR spectroscopy. The major species formed by d(G3CT3G3), d(G3TCT2G3) and d(G3T3CG3) at 1 mM strand concentration at neutral pH is a dimeric folded quadruplex. d(G3T2CTG3) has anomalous behaviour and associates into a greater percentage of linear four-stranded quadruplex than the other three oligonucleotides at neutral pH and at the same concentration. The linear four-stranded quadruplex has a greater tendency to oligomerize to larger ill-defined structures, as demonstrated by broad 1H NMR resonances. At pH 4, when the cytosine is protonated, there is a greater tendency for each of the oligonucleotides to form some four-stranded linear quadruplex, except for d(G3T2CTG3), which has the reverse tendency. The experimental results are discussed in terms of hydrogen bonding within the thymine loop.     

Formation of novel hairpin structures by telomeric C-strand oligonucleotides.

Telomeres are specialized structures at the ends of chromosomes that are required for long term chromosome stability and replication of the chromosomal terminus. Telomeric DNA consists of simple repetitive sequences with one strand G-rich relative to the other, C-rich, strand. Evolutionary conservation of this feature of telomeric repeat sequences suggests that they have specific structural characteristics involved in telomere function. Absorbance thermal denaturation, chemical modification and non-denaturing gel electrophoretic analyses showed that telomeric C-strand oligonucleotides form stable non-Watson-Crick hairpin structures containing C.C+ base pairs. Formation of such hairpins may facilitate previously reported G-strand exclusive interactions.     

Progressive myoclonus epilepsy [EPM1] repeat d(CCCCGCCCCGCG)n forms folded hairpin structures at physiological pH.

The secondary structure of DNA has been shown to be an important component in the mechanism of expansion of the trinucleotide repeats that are associated with many neurodegenerative disorders. Recently, expansion of a dodecamer repeat, (CCCCGCCCCGCG)n upstream of cystatin B gene has been shown to be the most common mutation associated with Progressive Myoclonus Epilepsy (EPM1) of Unverricht-Lundborg type. We have investigated structure of oligonucleotides containing one, two and three copies of the EPM1 repeat sequences at physiological pH. CD spectra and anomalous faster gel electrophoretic mobilty indicates formation of intramolecularly folded structures that are formed independent of concentration. Hydroxylamine probing allowed us to identify the C residues that are involved in C.G base pairing. P1 nuclease studies elucidated the presence of unpaired regions in the folded back structures. UV melting studies show biphasic melting curves for the oligonucleotides containing two and three EPM1 repeats. Our data suggests multiple hairpin structures for two and three repeat containing oligonucleotides. In this paper we show that oligonucleotides containing EPM1 repeat adopt secondary structures that may facilitate strand slippage thereby causing the expansion.     

Recognition and elongation of telomeres by telomerase

Telomeres stabilize chromosomal ends and allow their complete replication in vivo. In diverse eukaryotes, the essential telomeric DNA sequence consists of variable numbers of tandem repeats of simple, G + C rich sequences, with a strong strand bias of G residues on the strand oriented 5' to 3' toward the chromosomal terminus. This strand forms a protruding 3' over-hang at the chromosomal terminus in three different eukaryotes analyzed. Analysis of yeast and protozoan telomeres showed that telomeres are dynamic structures in vivo, being acted on by shortening and lengthening activities. We previously identified and partially purified an enzymatic activity, telomere terminal transferase, or telomerase, from the ciliate Tetrahymena. Telomerase is a ribonucleoprotein enzyme with essential RNA and protein components. This activity adds repeats of the Tetrahymena telomeric sequence, TTGGGG, onto the 3' end of a single-stranded DNA primer consisting of a few repeats of the G-rich strand of known telomeric, and telomere-like, sequences. The shortest oligonucleotide active as a primer was the decamer G4T2G4. Structural analysis of synthetic DNA oligonucleotides that are active as primers showed that they all formed discrete intramolecular foldback structures at temperatures below 40 degrees C. Addition of TTGGGG repeats occurs one nucleotide at a time by de novo synthesis, which is not templated by the DNA primer. Up to 8000 nucleotides of G4T2 repeats were added to the primer in vitro. We discuss the implications of this finding for regulation of telomerase in vivo and a model for telomere elongation by telomerase.