Project description:Ribonucleoprotein enzymes require specific and dynamic conformations of their RNA constituents for regulated catalysis. Telomerase RNA components (TRs) rely on two conserved domains, a pseudoknot/template sequence and a three-way junction (CR4/5), each of which binds the telomerase reverse transcriptase protein (TERT). Vertebrate TRs evolved a third element, the H/ACA domain, involved in assembly and trafficking of telomerase through binding telomerase cofactors, dyskerin and TCAB1, respectively. Here, we show that telomerase unexpectedly requires TCAB1 for enzyme catalysis and for shaping the conformation of the TR CR4/5 domain. Human and mouse cells lacking TCAB1 exhibit a marked reduction in telomerase activity, but show no defect in enzyme assembly. Instead, loss of TCAB1 causes specific unfolding of critical RNA helices in TR CR4/5 required for catalysis, and impairs TR-TERT association. CR4/5 mutations derived from patients with the telomere disorder dyskeratosis congenita phenocopy the loss of enzyme activity and disruption of TERT binding observed with TCAB1 deletion. These findings show that the H/ACA element acquired by telomerase during vertebrate evolution serves an unanticipated role in controlling folding of the essential TR CR4/5 domain, facilitating optimal TERT engagement and enabling telomerase catalysis through the action of TCAB1 protein tethered at the H/ACA domain.

Project description:Localization of a variety of RNAs to non-membrane-bound cellular compartments such as nucleoli and Cajal bodies is critical for their stability and function. The molecular mechanisms that underly the recruitment and exclusion of RNAs from these phase-separated organelles is incompletely understood. Telomerase is a ribonucleoprotein composed of the reverse transcriptase protein telomerase reverse transcriptase (TERT), the telomerase RNA (TR), and several auxiliary proteins, including TCAB1. Here we show that in the absence of TCAB1, a large fraction of TR is tightly bound to the nucleolus, while TERT is largely excluded from the nucleolus, reducing telomerase assembly. This suggests that nuclear compartmentalization by the non-membrane-bound nucleolus counteracts telomerase assembly, and TCAB1 is required to retain TR in the nucleoplasm. Our work provides insight into the mechanism and functional consequences of RNA recruitment to organelles formed by phase separation and demonstrates that TCAB1 plays an important role in telomerase assembly.

Project description:We have used single-molecule fluorescence microscopy to study the folded state of human telomerase RNA (hTR). Here we show that hTR adopts a new conformation on binding to human telomerase reverse transcriptase (hTERT) and reconstitution of an active ribonucleoprotein complex. Our data are consistent with the formation of an RNA pseudoknot in active human telomerase.

Project description:The ability of most cancer cells to grow indefinitely relies on the enzyme telomerase and its recruitment to telomeres. In human cells, recruitment depends on the Cajal body RNA chaperone TCAB1 binding to the RNA subunit of telomerase (hTR) and is also thought to rely on an N-terminal domain of the catalytic subunit, hTERT. We demonstrate that coilin, an essential structural component of Cajal bodies, is required for endogenous telomerase recruitment to telomeres but that overexpression of telomerase can compensate for Cajal body absence. In contrast, recruitment of telomerase was sensitive to levels of TCAB1, and this was not rescued by overexpression of telomerase. Thus, although Cajal bodies are important for recruitment, TCAB1 has an additional role in this process that is independent of these structures. TCAB1 itself localizes to telomeres in a telomerase-dependent but Cajal body-independent manner. We identify a point mutation in hTERT that largely abolishes recruitment yet does not affect association of telomerase with TCAB1, suggesting that this region mediates recruitment by an independent mechanism. Our results demonstrate that telomerase has multiple independent requirements for recruitment to telomeres and that the function of TCAB1 is to directly transport telomerase to telomeres.

Project description:Dyskeratosis congenita (DC) is a genetic disorder of defective tissue maintenance and cancer predisposition caused by short telomeres and impaired stem cell function. Telomerase mutations are thought to precipitate DC by reducing either the catalytic activity or the overall levels of the telomerase complex. However, the underlying genetic mutations and the mechanisms of telomere shortening remain unknown for as many as 50% of DC patients, who lack mutations in genes controlling telomere homeostasis. Here, we show that disruption of telomerase trafficking accounts for unknown cases of DC. We identify DC patients with missense mutations in TCAB1, a telomerase holoenzyme protein that facilitates trafficking of telomerase to Cajal bodies. Compound heterozygous mutations in TCAB1 disrupt telomerase localization to Cajal bodies, resulting in misdirection of telomerase RNA to nucleoli, which prevents telomerase from elongating telomeres. Our findings establish telomerase mislocalization as a novel cause of DC, and suggest that telomerase trafficking defects may contribute more broadly to the pathogenesis of telomere-related disease.

Project description:The RNA duplex, (5'GACGAGUGUCA)(2), has two conformations in equilibrium. The nuclear magnetic resonance solution structure reveals that the major conformation of the loop, 5'GAGU/3'UGAG, is novel and contains two unusual Watson-Crick/Hoogsteen GG pairs with G residues in the syn conformation, two A residues stacked on each other in the center of the helix with inverted sugars, and two bulged-out U residues. The structure provides a benchmark for testing approaches for predicting local RNA structure and a sequence that allows the design of a unique arrangement of functional groups and/or a conformational switch into nucleic acids.

Project description:Telomere maintenance by telomerase is impaired in the stem cell disease dyskeratosis congenita and during human aging. Telomerase depends upon a complex pathway for enzyme assembly, localization in Cajal bodies, and association with telomeres. Here, we identify the chaperonin CCT/TRiC as a critical regulator of telomerase trafficking using a high-content genome-wide siRNA screen in human cells for factors required for Cajal body localization. We find that TRiC is required for folding the telomerase cofactor TCAB1, which controls trafficking of telomerase and small Cajal body RNAs (scaRNAs). Depletion of TRiC causes loss of TCAB1 protein, mislocalization of telomerase and scaRNAs to nucleoli, and failure of telomere elongation. DC patient-derived mutations in TCAB1 impair folding by TRiC, disrupting telomerase function and leading to severe disease. Our findings establish a critical role for TRiC-mediated protein folding in the telomerase pathway and link proteostasis, telomere maintenance, and human disease.

Project description:Human and mouse telomerases show a high degree of similarity in both the protein and RNA components. Human telomerase is more active and more processive than the mouse telomerase. There are two key differences between hTR [human TR (telomerase RNA)] and mTR (mouse TR) structures. First, the mouse telomerase contains only 2 nt upstream of its template region, whereas the human telomerase contains 45 nt. Secondly, the template region of human telomerase contains a 5-nt alignment domain, whereas that of mouse has only 2 nt. We hypothesize that these differences are responsible for the differential telomerase activities. Mutations were made in both the hTR and mTR, changing the template length and the length of the RNA upstream of the template, and telomerase was reconstituted in vitro using mouse telomerase reverse transcriptase generated by in vitro translation. We show that the sequences upstream of the template region, with a potential to form a double-stranded helix (the P1 helix) as in hTR, increase telomerase activity. The longer alignment domain increases telomerase activity only in the context of the P1 helix. Thus the TR contributes to regulating the level of activity of mammalian telomerases.

Project description:Telomerase is a ribonucleoprotein (RNP) required for maintenance of telomeres. Although up-regulated telomerase activity is closely linked to the cellular immortality characteristic of late stage carcinogenesis, recently, mutations in the telomerase RNA gene in humans have been associated with dyskeratosis congenita and aplastic anemia, both typified by impaired haemopoietic function. These mutations include base changes in a highly conserved putative telomerase RNA pseudoknot. Here, by using in vitro telomerase assays, NMR, and UV absorbance melting analyses of model oligonucleotides designed to form a "trans-pseudoknot," we describe functional, structural, and energetic properties of this structure. We demonstrate that the pseudoknot domain exists in two alternative states of nearly equal stability in solution: one is the previously proposed pseudoknot formed by pairing P3 with the loop domain of P2b, and the other is a structured P2b loop alone. We show that the two-base mutation (GC1078 --> AG) present in one gene copy in a family with dyskeratosis congenita abrogates telomerase activity. This mutation hyperstabilizes the P2b intraloop structure, blocking pseudoknot formation. Conversely, when the P3 pseudoknot pairing is hyperstabilized by deleting a conserved bulge in P3, telomerase activity also decreases. We propose that the P2bP3 pseudoknot domain acts as a molecular switch, and interconversion between its two states is important for telomerase function. Phylogenetic covariation in the P2b and P3 sequences of 35 species provides a compelling set of "natural" compensatory base pairing changes supporting the existence of the crucial molecular switch.

Project description:Telomerase is a unique reverse transcriptase that catalyzes the addition of telomere DNA repeats onto the 3' ends of linear chromosomes and plays a critical role in maintaining genome stability. Unlike other reverse transcriptases, telomerase is unique in that it is a ribonucleoprotein complex, where the RNA component [telomerase RNA (TR)] not only provides the template for the synthesis of telomere DNA repeats but also plays essential roles in catalysis, accumulation, TR 3'-end processing, localization, and holoenzyme assembly. Biochemical studies have identified TR elements essential for catalysis that share remarkably conserved secondary structures across different species as well as species-specific domains for other functions, paving the way for high-resolution structure determination of TRs. Over the past decade, structures of key elements from the core, conserved regions 4 and 5, and small Cajal body specific RNA domains of human TR have emerged, providing significant insights into the roles of these RNA elements in telomerase function. Structures of all helical elements of the core domain have been recently reported, providing the basis for a high-resolution model of the complete core domain. We review this progress to determine the overall architecture of human telomerase RNA.