RPA regulates telomerase action by providing Est1p access to chromosome ends.

Replication protein A (RPA) is a highly conserved single-stranded DNA-binding protein involved in DNA replication, recombination and repair. We show here that RPA is present at the telomeres of the budding yeast Saccharomyces cerevisiae, with a maximal association in S phase. A truncation of the N-terminal region of Rfa2p (associated with the rfa2Delta40 mutated allele) results in severe telomere shortening caused by a defect in the in vivo regulation of telomerase activity. Cells carrying rfa2Delta40 show impaired binding of the protein Est1p, which is required for telomerase action. In addition, normal telomere length can be restored by expressing a Cdc13-Est1p hybrid protein. These findings indicate that RPA activates telomerase by loading Est1p onto telomeres during S phase. We propose a model of in vivo telomerase action that involves synergistic action of RPA and Cdc13p at the G-rich 3' overhang of telomeric DNA.

Target practice: aiming at satellite repeats with DNA minor groove binders.

Much progress has been made in recent years in developing small molecules that target the minor groove of DNA. Striking advances have led to the design of synthetic molecules that recognize specific DNA sequences with affinities comparable to those of eukaryotic transcription factors. This makes it feasible to modulate or inhibit DNA/protein interactions in vivo, a major step towards the development of general strategies of anti-gene therapy. Examples from anti-parasitic drugs also suggest that synthetic molecules can affect a variety of cellular functions crucial to cell viability by more generally targeting vast portions of genomes based on their biased base composition. This provides a rationale for developing approaches based on selective interactions with broad genomic targets such as satellite repeats that are associated with structural or architectural components of chromatin essential for cellular proliferation. Using examples drawn from the Drosophila melanogaster model system, we review here the use of synthetic polyamides or diamidines that bind the DNA minor groove and can be used as highly selective agents capable of interfering with specific protein/DNA interactions that occur in A+T-rich repeated sequences that constitute a significant portion of eukaryotic genomes. The satellite localization of cellular proteins that bind the minor groove of DNA via domains such as the AT hook motif is highly sensitive to these molecules. A major consequence of the competition between these proteins and their synthetic mimics is an alteration of the nuclear localization and function of proteins such as topoisomerase II, a major target of anti-cancer drugs.

The number of vertebrate repeats can be regulated at yeast telomeres by Rap1-independent mechanisms.

The number of telomeric DNA repeats at chromosome ends is maintained around a mean value by a dynamic balance between elongation and shortening. In particular, proteins binding along the duplex part of telomeric DNA set the number of repeats by progressively limiting telomere growth. The paradigm of this counting mechanism is the Rap1 protein in Saccharomyces cerevisiae. We demonstrate here that a Rap1-independent mechanism regulates the number of yeast telomeric repeats (TG(1-3)) and of vertebrate repeats (T(2)AG(3)) when TEL1, a yeast ortholog of the human gene encoding the ATM kinase, is inactivated. In addition, we show that a T(2)AG(3)-only telomere can be formed and maintained in humanized yeast cells carrying a template mutation of the gene encoding the telomerase RNA, which leads to the synthesis of vertebrate instead of yeast repeats. Genetic and biochemical evidences indicate that this telomere is regulated in a Rap1-independent manner, both in TEL1 and in tel1Delta humanized yeast cells. Altogether, these findings shed light on multiple repeat-counting mechanisms, which may share critical features between lower and higher eukaryotes.