Inverse-Folding Design of Yeast Telomerase RNA Increases Activity In Vitro.

telomerase RNA, TLC1, is an 1157 nt non-coding RNA that functions as both a template for DNA synthesis and a flexible scaffold for telomerase RNP holoenzyme protein subunits. The tractable budding yeast system has provided landmark discoveries about telomere biology in vivo, but yeast telomerase research has been hampered by the fact that the large TLC1 RNA subunit does not support robust telomerase activity in vitro. In contrast, 155-500 nt miniaturized TLC1 alleles comprising the catalytic core domain and lacking the RNA's long arms do reconstitute robust activity.

Inverse-folding design of yeast telomerase RNA increases activity .

telomerase RNA, TLC1, is an 1157 nt non-coding RNA that functions as both a template for DNA synthesis and a flexible scaffold for telomerase RNP holoenzyme protein subunits. The tractable budding yeast system has provided landmark discoveries about telomere biology , but yeast telomerase research has been hampered by the fact that the large TLC1 RNA subunit does not support robust telomerase activity . In contrast, 155-500 nt miniaturized TLC1 alleles comprising the catalytic core domain and lacking the RNA's long arms do reconstitute robust activity.

A 4-Base-Pair Core-Enclosing Helix in Telomerase RNA Is Essential for Activity and for Binding to the Telomerase Reverse Transcriptase Catalytic Protein Subunit.

The telomerase ribonucleoprotein (RNP) counters the chromosome end replication problem, completing genome replication to prevent cellular senescence in yeast, humans, and most other eukaryotes. The telomerase RNP core enzyme is composed of a dedicated RNA subunit and a reverse transcriptase (telomerase reverse transcriptase [TERT]). Although the majority of the 1,157-nucleotide (nt) telomerase RNA, TLC1, is rapidly evolving, the central catalytic core is largely conserved, containing the template, template-boundary helix, pseudoknot, and core-enclosing helix (CEH).

Yeast Telomerase RNA Flexibly Scaffolds Protein Subunits: Results and Repercussions.

It is said that "hindsight is 20-20", so, given the current year, it is an opportune time to review and learn from experiences studying long noncoding RNAs. Investigation of the telomerase RNA, TLC1, has unveiled striking flexibility in terms of both structural and functional features. Results support the "flexible scaffold" hypothesis for this 1157-nt telomerase RNA.

Repositioning the Sm-Binding Site in Telomerase RNA Reveals RNP Organizational Flexibility and Sm-Directed 3'-End Formation.

Telomerase RNA contains a template for synthesizing telomeric DNA and has been proposed to act as a flexible scaffold for holoenzyme protein subunits in the RNP. In , the telomerase RNA, TLC1, is bound by the Sm protein complex, which is required for stabilization of the predominant, non-polyadenylated (poly(A)-) TLC1 isoform. However, it remains unclear (1) whether Sm retains this function when its binding site is repositioned within TLC1, as has been shown for other TLC1-binding telomerase subunits, and (2) how Sm stabilizes poly(A)- TLC1.

Structural Insights into Yeast Telomerase Recruitment to Telomeres.

Telomerase maintains chromosome ends from humans to yeasts. Recruitment of yeast telomerase to telomeres occurs through its Ku and Est1 subunits via independent interactions with telomerase RNA (TLC1) and telomeric proteins Sir4 and Cdc13, respectively. However, the structures of the molecules comprising these telomerase-recruiting pathways remain unknown.

Long Noncoding RNAs in the Yeast S. cerevisiae.

Long noncoding RNAs have recently been discovered to comprise a sizeable fraction of the RNA World. The scope of their functions, physical organization, and disease relevance remain in the early stages of characterization. Although many thousands of lncRNA transcripts recently have been found to emanate from the expansive DNA between protein-coding genes in animals, there are also hundreds that have been found in simple eukaryotes.

Identification of novel noncoding transcripts in telomerase-negative yeast using RNA-seq.

Telomerase is a ribonucleoprotein that maintains the ends of linear chromosomes in most eukaryotes. Loss of telomerase activity results in shortening of telomeric DNA and eventually a specific G2/M cell-cycle arrest known as senescence. In humans, telomere shortening occurs during aging, while inappropriate activation of telomerase is associated with approximately 90% of cancers.

Physical Connectivity Mapping by Circular Permutation of Human Telomerase RNA Reveals New Regions Critical for Activity and Processivity.

Telomerase is a specialized ribonucleoprotein complex that extends the 3' ends of chromosomes to counteract telomere shortening. However, increased telomerase activity is associated with ∼90% of human cancers. The telomerase enzyme minimally requires an RNA (hTR) and a specialized reverse transcriptase protein (TERT) for activity in vitro.

The Ku subunit of telomerase binds Sir4 to recruit telomerase to lengthen telomeres in S. cerevisiae.

In Saccharomyces cerevisiae and in humans, the telomerase RNA subunit is bound by Ku, a ring-shaped protein heterodimer best known for its function in DNA repair. Ku binding to yeast telomerase RNA promotes telomere lengthening and telomerase recruitment to telomeres, but how this is achieved remains unknown. Using telomere-length analysis and chromatin immunoprecipitation, we show that Sir4 - a previously identified Ku-binding protein that is a component of telomeric silent chromatin - is required for Ku-mediated telomere lengthening and telomerase recruitment.

A second essential function of the Est1-binding arm of yeast telomerase RNA.

The enzymatic ribonucleoprotein telomerase maintains telomeres in many eukaryotes, including humans, and plays a central role in aging and cancer. Saccharomyces cerevisiae telomerase RNA, TLC1, is a flexible scaffold that tethers telomerase holoenzyme protein subunits to the complex. Here we test the hypothesis that a lengthy conserved region of the Est1-binding TLC1 arm contributes more than simply Est1-binding function.

Refined secondary-structure models of the core of yeast and human telomerase RNAs directed by SHAPE.

Telomerase catalyzes the addition of nucleotides to the ends of chromosomes to complete genomic DNA replication in eukaryotes and is implicated in multiple diseases, including most cancers. The core enzyme is composed of a reverse transcriptase and an RNA subunit, which provides the template for DNA synthesis. Despite extensive divergence at the sequence level, telomerase RNAs share several structural features within the catalytic core, suggesting a conserved enzyme mechanism.

RNA connectivity requirements between conserved elements in the core of the yeast telomerase RNP.

Telomerase is a specialized chromosome end-replicating enzyme required for genome duplication in many eukaryotes. An RNA and reverse transcriptase protein subunit comprise its enzymatic core. Telomerase is evolving rapidly, particularly its RNA component.

Stiffened yeast telomerase RNA supports RNP function in vitro and in vivo.

The 1157-nt Saccharomyces cerevisiae telomerase RNA, TLC1, in addition to providing a 16-nt template region for reverse transcription, has been proposed to act as a scaffold for protein subunits. Although accessory subunits of the telomerase ribonucleoprotein (RNP) complex function even when their binding sites are relocated on the yeast telomerase RNA, the physical nature of the RNA scaffold has not been directly analyzed. Here we explore the structure-function organization of the yeast telomerase RNP by extensively stiffening the three long arms of TLC1, which connect essential and important accessory protein subunits Ku, Est1, and Sm(7), to its central catalytic hub.

Ku can contribute to telomere lengthening in yeast at multiple positions in the telomerase RNP.

Unlike ribonucleoprotein complexes that have a highly ordered overall architecture, such as the ribosome, yeast telomerase appears to be much more loosely constrained. Here, we investigate the importance of positioning of the Ku subunit within the 1157-nt yeast telomerase RNA (TLC1). Deletion of the 48-nt Ku-binding hairpin in TLC1 RNA (tlc1Δ48) reduces telomere length, survival of cells with gross chromosomal rearrangements, and de novo telomere addition at a broken chromosome end.

Inhibition of yeast telomerase action by the telomeric ssDNA-binding protein, Cdc13p.

Appropriate control of the chromosome end-replicating enzyme telomerase is crucial for maintaining telomere length and genomic stability. The essential telomeric DNA-binding protein Cdc13p both positively and negatively regulates telomere length in budding yeast. Here we test the effect of purified Cdc13p on telomerase action in vitro.

A flexible template boundary element in the RNA subunit of fission yeast telomerase.

Telomerase adds telomeric repeat sequences to chromosome ends using a short region of its RNA subunit as a template. Telomerase RNA subunits are phylogenetically highly divergent, and different strategies have evolved to demarcate the boundary of the template region. The recent identification of the gene encoding telomerase RNA in the fission yeast Schizosaccharomyces pombe (ter1+) has opened the door for structure-function analyses in a model that shares many features with the telomere maintenance machinery of higher eukaryotes.

Rtt107/Esc4 binds silent chromatin and DNA repair proteins using different BRCT motifs.

Background: By screening a plasmid library for proteins that could cause silencing when targeted to the HMR locus in Saccharomyces cerevisiae, we previously reported the identification of Rtt107/Esc4 based on its ability to establish silent chromatin. In this study we aimed to determine the mechanism of Rtt107/Esc4 targeted silencing and also learn more about its biological functions.

Results: Targeted silencing by Rtt107/Esc4 was dependent on the SIR genes, which encode obligatory structural and enzymatic components of yeast silent chromatin.

A miniature yeast telomerase RNA functions in vivo and reconstitutes activity in vitro.

The ribonucleoprotein enzyme telomerase synthesizes DNA at the ends of chromosomes. Although the telomerase catalytic protein subunit (TERT) is well conserved, the RNA component is rapidly evolving in both size and sequence. Here, we reduce the 1,157-nucleotide (nt) Saccharomyces cerevisiae TLC1 RNA to a size smaller than the 451-nt human RNA while retaining function in vivo.

Yeast telomerase RNA: a flexible scaffold for protein subunits.

In the yeast Saccharomyces cerevisiae, distinct regions of the 1.2-kb telomerase RNA (TLC1) bind to the catalytic subunit Est2p and to accessory proteins. In particular, a bulged stem structure binds the essential regulatory subunit Est1p.

One-hybrid screens at the Saccharomyces cerevisiae HMR locus identify novel transcriptional silencing factors.

In Saccharomyces cerevisiae, genes located at the telomeres and the HM loci are subject to transcriptional silencing. Here, we report results of screening a Gal4 DNA-binding domain hybrid library for proteins that cause silencing when targeted to a silencer-defective HMR locus.

Esc1, a nuclear periphery protein required for Sir4-based plasmid anchoring and partitioning.

A targeted silencing screen was performed to identify yeast proteins that, when tethered to a telomere, suppress a telomeric silencing defect caused by truncation of Rap1. A previously uncharacterized protein, Esc1 (establishes silent chromatin), was recovered, in addition to well-characterized proteins Rap1, Sir1, and Rad7. Telomeric silencing was slightly decreased in Deltaesc1 mutants, but silencing of the HM loci was unaffected.

Control of replication timing by a transcriptional silencer.

Background: Eukaryotic DNA replication starts at many origins. Some origins are used early in S phase, while others are programmed to fire later. In general, late replication is correlated with transcriptional inactivity and with location near the nuclear periphery.