Mammalian 5' C-rich telomeric overhangs are a mark of recombination-dependent telomere maintenance.

Recent evidence for 5'-cytosine (C)-rich overhangs at the telomeres of the nematode Caenorhabditis elegans provided the impetus to re-examine the end structure of mammalian telomeres. Two-dimensional (2D) gel electrophoresis, single telomere-length analysis (STELA), and strand-specific exonuclease assays revealed the presence of a 5'-C-rich overhang at the telomeres of human and mouse chromosomes. C-overhangs were prominent in G1/S arrested as well as terminally differentiated cells, indicating that they did not represent replication intermediates. C-rich overhangs were far more prevalent in tumor cells engaged in the alternative lengthening of telomeres (ALT) pathway of telomere maintenance, which relies on the homologous recombination (HR) machinery. Transient siRNA-based depletion of the HR-specific proteins RAD51, RAD52, and XRCC3 resulted in changes in C-overhang levels, implicating the involvement of 5'-C-overhangs in the HR-dependent pathway of telomere maintenance.

Telomeric armor: the layers of end protection.

The linear nature of eukaryotic chromosomes necessitates protection of their physical ends, the telomeres, because the DNA-repair machinery can misconstrue the ends as double-stranded DNA breaks. Thus, protection is crucial for avoiding an unwarranted DNA-damage response that could have catastrophic ramifications for the integrity and stability of the linear genome. In this Commentary, we attempt to define what is currently understood by the term ;telomere protection'. Delineating the defining boundaries of chromosome-end protection is important now more than ever, as it is becoming increasingly evident that, although unwanted DNA repair at telomeres must be avoided at all costs, the molecular players involved in recognition, signaling and repair of DNA damage might also serve to protect telomeres.

Rapid induction of alternative lengthening of telomeres by depletion of the histone chaperone ASF1.

The mechanism of activation of the alternative lengthening of telomeres (ALT) pathway of mammalian chromosome-end maintenance has been unclear. We have now discovered that co-depletion of the histone chaperones ASF1a and ASF1b in human cells induced all hallmarks of ALT in both primary and cancer cells. These included the formation of ALT-associated PML (promyelocytic leukemia) bodies (APBs), the presence of extrachromosomal telomeric DNA species, an elevated frequency of telomeric sister chromatid exchanges (t-SCE) events and intertelomeric exchange of an integrated tag. The induction of ALT characteristics in this setting led to the simultaneous suppression of telomerase. We determined that ALT induction is positively regulated by the proteins RAD17 and BLM and negatively regulated by EXO1 and DNA2. The induction of ALT phenotypes as a consequence of ASF1 depletion strongly supports the hypothesis that ALT is a consequence of histone management dysfunction.

5' C-rich telomeric overhangs are an outcome of rapid telomere truncation events.

A subset of human tumors ensures indefinite telomere length maintenance by activating a telomerase-independent mechanism known as Alternative Lengthening of Telomeres (ALT). Most tumor cells of ALT origin share a constellation of unique characteristics, which include large stores of extra-chromosomal telomeric material, chronic telomere dysfunction and a peculiar enrichment in chromosome ends with 5' C-rich overhangs. Here we demonstrate that acute telomere de-protection and the subsequent DNA damage signal are not sufficient to facilitate formation of 5' C-overhangs at the chromosome end. Rather chromosome ends bearing 5' C-overhangs are a by-product of rapid cleavage events, processing of which occurs independently of the DNA damage response and is partly mediated through the XRCC3 endonuclease.

Physiological relevance of telomeric G-quadruplex formation: a potential drug target.

The concept of a G-quartet, a unique structural arrangement intrinsic to guanine-rich DNA, was first introduced by Gellert and colleagues over 40 years ago. For decades, it has been uncertain whether the G-quartet and the structure that it gives rise to, the G-quadruplex, are purely in vitro phenomena. Nevertheless, the presence of signature G-rich motifs in the eukaryotic genome, and the plethora of proteins that bind to, modify or resolve this nucleic acid structure in vitro have provided circumstantial evidence for its physiological relevance. More recently, direct visualisation of G-quadruplex DNA at native telomeres was achieved, bolstering the evidence for its existence in the cell. Furthermore, G-quadruplex folded telomeric DNA has been found to perturb telomere function and to impede the action of telomerase, an enzyme overexpressed in >85% of human cancers, hence opening up a novel avenue for cancer therapy in the form of G-quadruplex stabilising agents.

Telomerase recognizes G-quadruplex and linear DNA as distinct substrates.

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.

Extension of G-quadruplex DNA by ciliate telomerase.

Telomeric DNA can fold into four-stranded structures known as G-quadruplexes. Here we investigate the ability of G-quadruplex DNA to serve as a substrate for recombinant Tetrahymena and native Euplotes telomerase. Inter- and intramolecular G-quadruplexes were gel-purified and their stability examined using native gel electrophoresis, circular dichroism (CD) and thermal denaturation. While intermolecular G-quadruplexes were highly stable, they were excellent substrates for both ciliate telomerases in primer extension assays. In contrast, intramolecular G-quadruplexes formed in K+ exhibited biphasic unfolding and were not extended by ciliate telomerases. Na+-stabilised intramolecular G-quadruplexes were extended by telomerase owing to their rapid rate of dissociation. The Tetrahymena telomerase protein component bound to inter- but not intramolecular K+-stabilised G-quadruplexes. This study provides evidence that parallel intermolecular G-quadruplexes can serve as substrates for telomerase in vitro, their extension being mediated through direct interactions between this higher-order structure and telomerase.

Reduced switching in SCID B cells is associated with altered somatic mutation of recombined S regions.

Deoxyribonucleic acid double-stranded breaks act as intermediates in Ig V(D)J recombination and probably perform a similar function in class switch recombination between IgH C genes. In SCID mice, V(D)J recombination is blocked because the DNA-dependent protein kinase catalytic subunit (DNA-PKcs) protein is defective. We show in this study that switching to all isotypes examined was detectable when the SCID mutation was introduced into anti-hen egg lysozyme transgenic B cells capable of undergoing class switch recombination, but switching was significantly reduced in comparison with control B cells of the same specificity lacking the RAG1 gene. Thus, DNA-PKcs is involved in switching to all isotypes, but plays a lesser role in the switching process than it does in V(D)J-coding joint formation. The higher level of switching observed by us in SCID B cells compared with that observed by others in DNA-PKcs(null) cells raises the possibility that kinase-deficient DNA-PKcs can function in switching. Point mutation of G:C base pairs with cytidines on the sense strand was greatly reduced in recombined switch regions from SCID cells compared with control RAG1(-/-) B cells. The preferential loss of sense strand cytidine mutations from hybrid S regions in SCID cells suggests the possibility that nicks might form in S regions of activated B cells on the template strand independently of activation-induced cytidine deaminase and are converted to double-strand breaks when activation-induced cytidine deaminase deaminates the non-template strand.