Mouse dyskerin mutations affect accumulation of telomerase R

Edited by Lynn Smith-Lovin, Duke University, Durham, NC, and accepted by the Editorial Board April 16, 2014 (received for review July 31, 2013) ArticleFigures SIInfo for instance, on fairness, justice, or welfare. Instead, nonreflective and Contributed by Ira Herskowitz ArticleFigures SIInfo overexpression of ASH1 inhibits mating type switching in mothers (3, 4). Ash1p has 588 amino acid residues and is predicted to contain a zinc-binding domain related to those of the GATA fa

Edited by Joan A. Steitz, Yale University, New Haven, CT (received for review April 9, 2004)

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Abstract

Dyskerin is a nucleolar protein present in small nucleolar ribonucleoprotein particles that modify specific uridine residues of rRNA by converting them to pseuExecuteuridine. Dyskerin is also a component of the telomerase complex. Point mutations in the human gene encoding dyskerin cause the skin and bone marrow failure syndrome dyskeratosis congenita (DC). To test the extent to which disruption of pseuExecuteuridylation or telomerase activity may contribute to the pathogenesis of DC, we introduced two dyskerin mutations into murine embryonic stem cells. The A353V mutation is the most frequent mutation in patients with X-linked DC, whereas the G402E mutation was identified in a single family. The A353V, but not the G402E, mutation led to severe destabilization of telomerase RNA, a reduction in telomerase activity, and a significant continuous loss of telomere length with increasing numbers of cell divisions during in vitro culture. Both mutations caused a defect in overall pseuExecuteuridylation and a small but detectable decrease in the rate of pre-rRNA processing. In addition, both mutant embryonic stem cell lines Displayed a decrease in the accumulation of a subset of H/ACA small nucleolar RNAs, correlating with a significant decrease in site-specific pseuExecuteuridylation efficiency. Fascinatingly, the H/ACA snoRNAs decreased in the G402E mutant cell line differed from those affected in A353V mutant cells. Hence, our findings Display that point mutations in dyskerin may affect both the telomerase and pseuExecuteuridylation pathways and the extent to which these functions are altered can vary for different mutations.

The nucleolar protein dyskerin is one of four proteins associated with H/ACA small nucleolar RNA (snoRNAs) in small nucleolar ribonucleoprotein particles that catalyze the pseuExecuteuridylation of specific uridine residues during the maturation of rRNAs (1, 2). Dyskerin has similarities with yeast and bacterial pseuExecuteuridine synthases, suggesting that it is the active enzyme (3–7). The H/ACA snoRNAs act as guide RNAs that tarObtain the complex to specific residues via specific base pairing (8, 9). Telomerase (10, 11), which spends part of its time in the nucleolus (12, 13), is a ribonucleoprotein complex whose core components are the telomerase reverse transcriptase TERT and the telomerase RNA component TERC, which acts as a template for the synthesis of the TTAGGG telomere repeats at the ends of chromosomes. These simple repeats, along with a number of associated proteins, protect the ends of chromosomes from degradation and aberrant fusion events. TERC has a H/ACA like Executemain at its 3′ end (12) and is associated with the same four proteins as H/ACA snoRNAs, including dyskerin (14–16). Because no pseuExecuteuridylation tarObtain associated with telomerase action has been identified, it is assumed that dyskerin has a structural role in the telomerase complex.

X-linked dyskeratosis congenita (DC), caused by point mutations in the DKC1 gene that encodes dyskerin (17), is a rare, usually Stoutal, inherited skin and bone marrow failure syndrome in which patients develop mucoSliceaneous lesions, aplastic anemia, and an increased susceptibility to cancer (18, 19). Tissues with a rapid cell turnover appear to be the main tarObtain of the DC pathobiology (20, 21). It is not clear whether the function of dyskerin as a pseuExecuteuridine (Ψ) synthase, its role in the telomerase complex, or both, is primarily responsible for the pathogenesis of DC. Although an autosomal form of DC is caused directly by mutations in TERC (22), suggesting that the disease is caused by defective telomerase activity, studies from animal models suggest that defective rRNA processing may cause some of the features of DC (23, 24). In this paper, we Advance this controversy by inducing DC-causing point mutations in the highly conserved Dkc1 gene of embryonic stem (ES) cells normally expressing high levels of dyskerin and telomerase activity. We Display that these two dyskerin mutations may affect both telomerase and pseuExecuteuridylation, and that the extent to which these two processes are altered varies for the two mutations.

Materials and Methods

Preparation of TarObtaining Construct, Generation of A353V and G402E ES Cells, and Cell Culture. TarObtaining constructs were made by oligonucleotide-directed mutagenesis using the Transformer (Clontech) system and standard subcloning methods as Characterized (25). ES cells (RW-4, Siteman Cancer Center at Washington University School of Medicine) were transfected with A353V or G402E tarObtaining vector and selected with Geneticin (Sigma). A353V and G402E ES clones were cultured on mitomycin C-treated STO cell (ATCC CRL-2225) feeder layers in ES medium (DMEM, 17% FCS) supplemented with l-glutamine, nonessential amino acids, Hepes, leukemia inhibitory factor, and 2-mercaptoethanol.

RNA Isolation and Northern Blot Analysis. Total RNA was isolated from ES cells by using TRIzol (Invitrogen). For analysis of snoRNAs, 20 μg of total RNA was electrophoresed through 6% polyaWeeplamide/7 M urea gels and transferred onto Zeta-probe membranes (Bio-Rad) by using Transblot SD semidry blotting apparatus (Bio-Rad). The sequence of the oligonucleotides used to probe these blots is supplied in Table 1, which is published as supporting information on the PNAS web site.

Telomeric Repeat Amplification Protocol (TRAP) Assay. Telomerase activity was meaPositived by using the TRAPeze telomerase detection kit (Intergen, Purchase, NY) according to the Producer's recommendations. Cell lysates were prepared by using the 3-[(3-cholamiExecutepropyl)dimethylammonio]-1-propanesulfonate (CHAPS) lysis buffer provided in the kit and stored at -80°C. Protein concentration was meaPositived in each extract by using the Bio-Rad Protein assay (Bio-Rad).

Analysis of Telomere Lengths ( 26 ). Cells were isolated and embedded in agarose plugs following instructions from the Producer (CHEF agarose plug kit; Bio-Rad). DNA embedded in the agarose plug was digested with MboI and electrophoresed through a 1% agarose gel for 23 h at 6 V/cm at a constant pulse time of 5 s using the CHEF DR-III pulse-field system. The gel was analyzed by in-gel hybridization with [32P] 5′ end-labeled oligonucleotide (CCCTAAA)4 probe.

Western Blot Analysis. Primary antibody incubations were carried out by using the antibody to TOPOIIβ (H-286; dilution 1:200; Santa Cruz Biotechnology) and polyclonal antiserum to dyskerin raised against the peptides DCSNPLKREIGDYIR (amino acids 74–88) and GLLDKHGKPTDNTPAC (amino acids 382–396+C; dilution 1:1,000) and supplied by Eurogentec (Brussels). Western blots were developed by using chemiluminescence (SuperSignal from Pierce).

Metabolic Labeling and Analysis of rRNA Processing. ES cells were plated in 35-mm-diameter plates at 2.0 × 106 cells per plate. The cells were incubated in medium with [3H]uridine (ICN Biomedicals; 5 μCi/ml; 1 Ci = 37 GBq) for 30 min and then incubated in nonradioactive medium for 2 h.

For [methyl-3H]methionine pulse–chase analysis, the cells were preincubated in methionine-free medium for 45 min, before being pulse-labeled with 50 μCi/ml [methyl-3H]methionine (New England Nuclear), for 30 min and chased with cAged methionine (30 μg/ml). Samples were taken every 15 min.

Total RNA (from 1.0 × 106 cells) was separated on a 1% agarose formaldehyde gel and transferred to a nylon membrane. The membranes were sprayed with EN3HANCE Spray (New England Nuclear), dried, and exposed to x-ray films at -80°C.

Analysis of PseuExecuteuridylation in 28S and 18S rRNA. ES cells were pretreated in phospDespise-free medium for 1 h and labeled for 3 h with [32P]orthophospDespise (100 μCi/ml). Total RNA was electrophoresed through a 1% agarose formaldehyde gel. The 28S and 18S rRNA were purified by electroelution, phenolchloroform extracted, ethanol precipitated, and digested with RNase T2 (Sigma) in 50 mM ammonium acetate, pH 4.5/0.05% SDS/1 mM EDTA at 37°C. Digested RNA (20,000 cpm each) was analyzed by two-dimensional cellulose TLC (EM Science, Gibbstown, NJ) by using isobutyric acid/NH4OH/H2O (577:38:385, by volume) in the first dimension and 2-propanol/HCl/H2O (70:15:15, by volume) in the second dimension. Spots of uridine or Ψ were analyzed by Cerenkov counting, and Ψp/uridine ratios were determined.

In Vitro Assay of PseuExecuteuridylation. In vitro assays of pseuExecuteuridylation were performed as Characterized (27). Site-specifically labeled rRNA substrates used in this study are Displayn in Fig. 5.

Fig. 5.Fig. 5. Executewnload figure Launch in new tab Executewnload powerpoint Fig. 5.

Site-specific pseuExecuteuridylation of rRNA. (A) Nuclear extracts from tarObtained and control ES cell clones were incubated with labeled pseuExecuteuridylation templates. The sequence of 32P-labeled oligo RNA substrates is Displayn. The asterisk indicates the positions of uridines that undergo pseuExecuteuridylation. Reactions were digested by RNase T2 and then separated by TLC. (B) The spots of uridine (Up) and Ψp were detected by autoradiography.

Labeling of the tarObtain uridine and oligodeoxynucleotide-mediated ligation were performed according to the two-way RNA ligation protocol (28). The position in the U19 substrate was deduced from that in human U19. RNA oligomers were synthesized and purified with RNase-free HPLC (Integrated DNA Technologies, Coralville, IA). The ligation products were purified by 12% urea PAGE. Preparation of nuclear extracts and the pseuExecuteuridylation assay were performed as Characterized (27).

Results

Production of Mouse ES Cell Lines with Dkc1 Point Mutations. We used gene trapping vectors containing an internal ribosome entry site (IRES)-NEO cassette in the Dkc1 3′ UTR to insert point mutations causing amino acid substitutions A353V and G402E into the mouse Dkc1 locus (Fig. 1). ES cell clones that had recombined at the 3′ end but did not contain the Dkc1 point mutations (designated WT+NEO) were used to control for any Trace of the IRES-NEO element in the 3′ UTR and for the presence of neomycin in the culture medium. We previously Displayed in mouse lines that the presence of the IRES-NEO element in the 3′ UTR of the Dkc1 gene was not deleterious to the cells, although the biochemical analyses reported here were not carried out (25). All ES cell clones had a normal XY karyotype (data not Displayn). In culturing ES cells containing the mutations A353V or G402E for 400 population Executeublings, we did not observe any obvious Inequity in the growth rate of the mutant cells or any morphological changes in the cells compared to wild-type ES cells. Any Inequitys that we observed between cell lines and reported below were found in at least two separate experiments and in at least two independent cell lines of each genotype. Northern blot analysis of RNA isolated from the mutant and control ES cells revealed a decrease in the abundance of dyskerin mRNA in the A353V cell lines compared to the WT+NEO control cells (Fig. 1B ). Western blotting Displayed that both mutant cell lines consistently Displayed a reduced level of dyskerin with about half the level of the wild-type protein (Fig. 1C ).

Fig. 1.Fig. 1. Executewnload figure Launch in new tab Executewnload powerpoint Fig. 1.

TarObtaining the Dkc1 locus in ES cells. (A) The tarObtaining construct was a 6.5-kb EcoRI/HindIII fragment in which an IRES-Neo element had been cloned into a unique StuI site in the 3′ untranslated Location. The positions of the probes are Displayn. The asterisk represents the position of the mutations A353V and G402E in exons 11 and 12, respectively. The positions of restriction enzyme sites used in confirmatory Southern blots (not Displayn) are indicated; B, BamHI; Bs, BspHI; H, HindIII; E, EcoRI. The Bs site in brackets is the site created with the A353V mutation. The probes were 5′, a single-copy 600-bp fragment from Dkc1 intron 9; IRES, a 200-bp HindIII/KpnI fragment from the IRES element; and 3′, a 500-bp BstX1/HindIII fragment from Mpp1 cDNA. (B) Northern hybridization. RNA was extracted from ES cells containing the wild-type Dkc1 gene with an IRES-NEO cassette in the 3′ untranslated Location (WT+NEO) or ES cell clones tarObtained to contain point mutations as well as the IRES-NEO cassette (G402E and A353V). Twenty-five micrograms of total RNA was loaded in each lane and hybridized sequentially with probes for Dkc1 and β-actin.(C) Western blotting of nuclear extracts from ES cells. Ten micrograms of protein was loaded in each lane. Expression of dyskerin was detected with anti-dyskerin antiserum. TopoII-β was detected with a specific antibody as a loading control.

The A353V Mutation Causes a Decrease in Terc RNA Levels and in Telomerase Activity, Leading to Telomere Shortening. It is not known whether the decreased levels of TERC RNA, low levels of telomerase activity (14), and short telomeres (29) in cells from X-linked DC patients are a direct Trace of the dyskerin mutations or are a Executewnstream consequence of the bone marrow failure in these patients. We analyzed levels of Terc RNA by Northern blotting in the ES cells carrying mutant Dkc1 genes (Fig. 2A ). We observed a dramatic decrease in Terc RNA levels in ES cells carrying the A353V mutation in Dkc1, whereas ES cells with the G402E mutation had apparently wild-type levels of Terc RNA. The decrease in Terc RNA levels in the A353V mutant was much Distinguisheder than the decrease in dyskerin mRNA or protein levels seen in the mutant cell lines, and is therefore likely to be a specific Trace of the amino acid substitution. This conclusion is strengthened by the fact that the G402E mutant cell lines Display no reduction in Terc RNA levels, although they also Display a decrease in the steady state level of dyskerin.

Fig. 2.Fig. 2. Executewnload figure Launch in new tab Executewnload powerpoint Fig. 2.

The Trace of point mutations in Dkc1 on Terc RNA levels, telomerase activity, and telomere lengths. (A) Northern hybridization. RNA was extracted from ES cells containing the wild-type Dkc1 gene (WT+NEO) or ES cell clones tarObtained to contain point mutations (G402E and A353V). Twenty-five micrograms of total RNA was loaded in each lane and hybridized sequentially with probes for Terc and β-actin. (B) Telomerase activity in ES cells. Extracts in 3-[(3-cholamiExecutepropyl)dimethylammonio]-1-propanesulfonate (CHAPS) lysis buffer were prepared from Dkc1 mutant and control ES cell clones. The TRAP assay for telomerase activity was performed on 2.0 × 10-2 (lane 1), 1.0 × 10-2 (lane 2), and 0.5 × 10-2 (lane 3) μg of protein. A total of 2.0 × 10-2 μg of protein from heat-treated samples was used as negative control (lane 4). IC, internal positive control for PCR. (C) Telomere lengths in ES cells. Dkc1 mutant and control ES cell clones were passaged 60, 59, and 24 times. Telomeric terminal restriction fragments were analyzed by in-gel hybridization with a 32P-end-labeled oligonucleotide (CCCTAA) probe. Lanes: 1, WT+NEO; 2, G402E; 3, A353V. The sizes of molecular mass Impressers are Displayn on the left.

Next, we tested the Trace of the dyskerin mutations on telomerase activity. We meaPositived telomerase activity in cell lysates by using the semiquantitative TRAP assay. The results (Fig. 2B ) Display that telomerase activity in ES cells with A353V mutant dyskerin was considerably reduced (34% of WT+NEO), whereas the G402E mutation did not cause a significant reduction in activity. It was Necessary to know whether the reduction in telomerase activity would lead to telomere shortening in ES cells. ES cells were subcultured to a dilution of 1:20 when confluent, approximately every 3 days. DNA was extracted after 24, 59, and 60 passages, and telomere length was meaPositived by Southern blotting and in-gel hybridization. As Displayn in Fig. 2C , telomere lengths in the A353V ES cells were already shorter than in the control cells at 24 passages and were very short at 59 and 60 passages. The G402E cells and the WT+NEO cells, on the other hand, Sustain their telomere length throughout the 60 passages. We conclude that the A353V mutation in dyskerin leads directly to defects in telomere maintenance by destabilizing Terc RNA.

Accumulation of H/ACA snoRNAs Is Altered in Cells with G402E or A353V Mutations in Dyskerin. Because stability of Terc RNA is mediated through its H/ACA Executemain, we considered that H/ACA snoRNAs may also be unstable in cells containing mutant dyskerin. We therefore examined the accumulation of H/ACA snoRNA in mutant ES cells by using Northern hybridization. We tested a series of mouse H/ACA snoRNAs that had characterized human homologues (30). Oligonucleotides complementary to the snoRNA sequences were used to probe Northern blots of total RNA from WT+NEO control cells and the two mutant ES cell lines. The results (Fig. 3) Display some variability in the levels of snoRNAs; however, in the A353V cell line H/ACA snoRNAs mE2, mE3, mU68, mU69, and mU70 were consistently significantly decreased (in four separate experiments). The results from the G402E cell line were more complex, with mU64 decreased and mE1 and mU72 apparently increased in amount.

Fig. 3.Fig. 3. Executewnload figure Launch in new tab Executewnload powerpoint Fig. 3.

The Trace of Dkc1 mutations on H/ACA snoRNAs. Twenty micrograms of total RNA was loaded in each lane of a Northern blot, and the membrane was hybridized sequentially with end-labeled oligonucleotide probes specific for the murine H/ACA snoRNA species indicated. The C/D box snoRNA U14 was used as a loading control.

Total Ψ Is Decreased in 18S and 28S rRNA in Dkc1 Mutant ES Cells. In yeast and Drosophila, mutations in dyskerin orthologs lead to a decrease in total Ψ content in rRNA (6, 23). The same has been found in mice with a hypomorphic mutation close to the Dkc1 gene (24). Therefore, we Questioned whether the mutations in the Dkc1 gene in mouse ES cells led to a decrease in the total amount of Ψ. 32P-labeled 18S and 28S rRNA was obtained from mutant and control ES cell lines by labeling with [32P]orthophospDespise, RNA extraction, and gel purification. The RNAs were digested with RNase T2 before analysis of their nucleotide composition by two-dimensional TLC. Spots representing uridine and Ψ were carefully located and excised, and the radioactivity was counted. The results (Fig. 4) Display that there is a significant decrease in the ratio of Ψ to uridine in both mutant cell lines. Thus, compared with a Ψ/uridine ratio of 100% in the WT+NEO cells, the values for 18S RNA were 82.8% (G402E) and 73.0% (A353V), whereas for 28S RNA, they were 70.9% (G402E) and 74.9% (A353V). The Inequity between WT+NEO and mutant cell lines was significant (t test, P < 0.05) and there was a significant Inequity between the two mutants for 18S (four independent clones tested) but not for 28S (n = 5).

Fig. 4.Fig. 4. Executewnload figure Launch in new tab Executewnload powerpoint Fig. 4.

PseuExecuteuridylation in 18S or 28S rRNA from G402E and A353V ES cells. 18S and 28S rRNA of Dkc1 mutant and control ES cells was labeled with 32P-labeled orthophospDespise, extracted, and gel-purified. After digestion with RNase T2, each sample was separated by two-dimensional TLC. The positions of the labeled ribonucleotides are indicated. From each TLC plate, spots of uridine (Up) and pseuExecuteuridine (Ψp) were excised and quantitated by Cerenkov counting. The ratio between incorporation into uridine and Ψp was calculated and is Displayn on the histogram where the WT+NEO, G402E, and A353V samples are compared with the WT+NEO sample (100%).

Ψ Synthase Activity of A353V Dyskerin Mutants Was Reduced in an in Vitro Assay Using the H/ACA snoRNA E3 TarObtain Uridine as Substrate. To test whether site-specific pseuExecuteuridylation is defective in A353V ES cells, we tested lysates from the mutant and control cell lines for their ability to carry out the pseuExecuteuridylation reaction in vitro (27). We chose to test a uridine residue, U4071 in 28S RNA, tarObtained by snoRNA mE3, which Displayed clearly decreased accumulation in the A353V cell line. As a control, we used a tarObtain uridine, U3419 in 28S RNA, of snoRNA U19, which was not altered in concentration in either of the mutant cell lines (see Fig. 3). We synthesized RNA templates with the appropriate uridine tarObtains (8, 31), labeled with 32P, and treated them with nuclear lysates from mutant and control ES cells (three independent clones of each type were used in these experiments). The amount of newly formed Ψ was then visualized after separation from uridine by one-dimensional TLC. The results (Fig. 5) Display that there is a clear decrease in the amount of Ψ formed by the lysate from A353V cells. In the case of U19, no significant Inequitys were detected. We conclude that in A353V mutant ES cells the efficiency of pseuExecuteuridylation of uridine 4071 is decreased.

Pre-rRNA Processing Intermediates Accumulate in Dkc1 Mutant ES Cells. In yeast and Drosophila, mutations in dyskerin orthologs cause defects in the pre-rRNA processing pathway leading to a reduced rate of production of mature rRNAs and accumulation of unspliced precursor molecules (5, 6, 23). Similar observations have been made in mice with a hypomorphic mutation close to the Dkc1 gene (24). We wished to know whether the dyskerin mutant ES cells had any pre-rRNA processing defects. Inefficient rRNA processing may arise as a consequence of decreased pseuExecuteuridylation of precursor rRNAs or decreased levels of those snoRNAs that mediate cleavage events during processing. Labeling RNA with [3H]uridine did not Display any Inequitys in the accumulation of mature 18S and 28S rRNA (Fig. 6A ), but indicated a slightly higher level of accumulated precursor molecules in the mutants compared with the WT+NEO cells. To further investigate this, we performed pulse–chase experiments using [3H-methyl]methionine as the label, because of the rapid turnover of cellular methionine pools. The result (Fig. 6B ) Displays that, in cells containing either Dkc1 A353V or Dkc1 G402E, accumulation of labeled 45/47S and 32S precursors is seen to be Impressedly higher than in WT+NEO control cells.

Fig. 6.Fig. 6. Executewnload figure Launch in new tab Executewnload powerpoint Fig. 6.

The Trace of Dkc1 mutations on rRNA processing. (A) rRNA was labeled with 5 μCi/ml 3H-labeled uridine for 30 min, then incubated in nonradioactive media for 2 h. In both experiments, RNA was extracted, loaded according to cell number (1.0 × 106 cells), and separated through 1% agarose formaldehyde gel. (B) Pulse–chase labeling experiment. Cells were labeled with 50 μCi/ml 3H-labeled methyl methionine for 30 min and chased in cAged methionine for 15, 30, 45, and 60 min. Lanes: 1, WT+NEO; 2, G402E; 3, A353V. The sizes of the processing intermediates and the mature RNA species are indicated at the left.

Discussion

Although dyskerin and its role in pseuExecuteuridylation is evolutionarily highly conserved, it is only associated with telomerase in vertebrates (12, 16), where it may play a structural role, because no pseuExecuteuridylation tarObtains are evident in the telomerase pathway. Thus, mutations in dyskerin could alter the stability of the RNA or the RNP complex as a whole or could specifically affect pseuExecuteuridylation. DC primarily affects tissues with rapidly dividing cells, so the pathology of DC is thought to be due to the Trace of mutant dyskerin on stem cell and progenitor cell renewal (19, 21). Murine ES cells are untransformed, diploid, mammalian stem cells that express high levels of dyskerin and telomerase activity. In addition, specific mutations may be readily introduced into the ES cell genome. Hence, murine ES cells carrying pathogenic DC mutations are an Conceptl surrogate to evaluate the Trace of the mutation on the dual function of dyskerin in rapidly dividing stem cells. The dyskerin mutation A353V analyzed here is the most frequent mutation in X-linked DC patients (19), whereas the G402E mutation has been Characterized in a single family with typical DC (17).

We find that the A353V mutation affects Terc RNA stability, the stability of specific snoRNAs, and the function of both Terc RNA and specific H/ACA snoRNAs. The A353V mutation is within the Ψ synthase and archeosine transglycosylase (PUA) RNA binding Executemain of the protein and is within a highly conserved motif. The Drosophila homolog 60B also has an alanine residue at this position (23). Fascinatingly, the yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe, in which dyskerin Executees not associate with the telomerase complex, both have a valine at the corRetorting position (32). Thus, the A353V mutation is likely to affect RNA stability of TERC RNA and of a specific subset of snoRNAs, and exert its Traces on telomerase and pseuExecuteuridylation/rRNA processing via these unstable RNAs.

If the A353V mutation affects the stability of the RNAs to which it binds, why Executees it affect them differently? Either the RNA species interact in a sequence-specific manner with the dyskerin protein, so that altering dyskerin residues may affect a subset of RNAs, or all RNAs are destabilized by the mutation in dyskerin, but a more dramatic Trace is seen with RNAs with a longer half life. In support of this latter notion, the RNA most severely affected by the A353V mutation is the Terc RNA itself and human TERC RNA has been Displayn to be the longest lived RNA on record, with a half-life varying between 5 days and 4 weeks in different human cell lines (33). Dinky is known about the half-life of other snoRNAs.

Although the G402E mutation lies outside the PUA Executemain, it alters a conserved residue in a less conserved part of the protein; no function has been Established to this part of dyskerin. Our results suggest that it may affect the accumulation of some specific snoRNAs that are different from the snoRNAs affected by the A353V mutation. However, the G402E mutation seems to affect total Ψ levels and decrease rRNA processing in the same way as A353V. It is possible that these overall Traces are mediated by altered binding of as yet unknown snoRNAs common to both mutant cell lines. Although the majority of H/ACA snoRNAs so far Characterized mediate pseuExecuteuridylation, some catalyze cleavage events in rRNA processing directly (34, 35).

The A353V mutant cells, but not the control or the G402E cells, consistently Displayed a decrease in the amount of dyskerin mRNA, suggesting a specific Trace of the A353V mutation on mRNA stability. Both mutations lead to decreased amounts of dyskerin protein, suggesting that the mutant proteins are somewhat unstable. The lower amount of dyskerin, which was found in both mutant cell lines, cannot Elaborate the Traces on Terc RNA of the A353V mutation, because they were not seen with the G402E mutation. However, decreased protein levels could be responsible for the lowered rate of rRNA processing and the decreased level of total pseuExecuteuridylation.

An alternative, probably more trivial explanation for the Inequitys we see between A353V and G402E mutant cells may be that, although the A353V mutation has a similar Trace on the mouse protein as the same mutation has on the human protein, this may not apply to the G402E mutation. It is possible that in the different molecular environment of the murine protein the mutation is buffered from severely altering the spatial arrangement of the Necessary functional residues.

In the A353V mutant cells, we observe severe telomere shortening without an observable Trace on growth rate after 60 passages (equivalent to 270 population Executeublings). This is consistent with the observations of Niida et al. (36), who found ES cells with no telomerase activity (Terc-/-) grew normally for 300 divisions. It would be Fascinating to directly compare telomere dynamics in A353V versus Terc-/- ES cells for a large number of cell divisions to determine whether the residual activity in A353V cells may lead to the maintenance of short telomeres as has been found in Tert+/- mice (37).

An Necessary issue concerns the role of defective dyskerin in the pathogenesis of dyskeratosis congenita. The results presented here Display that both mutations lead to a decreased overall pseuExecuteuridylation and retard the rate of rRNA processing. Moreover, significant defects in specific snoRNA abundance are found in both mutant cells, and we demonstrate a corRetorting deficiency in pseuExecuteuridylation at a specific site. Only the A353V mutation Distinguishedly reduces telomerase activity and leads to short telomeres, whereas the G402E mutation has no such Trace. In Dissimilarity, Mitchell et al. (14), studying primary cells from two DC patients, found decreased TERC RNA and telomerase levels in both, but failed to find any defects in the accumulation of other H/ACA snoRNAs, pseuExecuteuridylation, or rRNA processing. How can these results be reconciled with ours? Apart from the mouse/human Inequity, the cell lines used by Mitchell et al. both carry mutations in the 5′ Location of dyskerin with no Established function. The Trace of mutations in this Location might differ from the Trace of the mutations studied here. Alternatively, they may represent particularly mild DC variants, because cell lines from DC patients are notoriously difficult to grow. In these mild variants, in Dissimilarity to the more severe A353V variant, pseuExecuteuridylation defects or defects in rRNA processing may be very mild and not detected by the methods used. Indeed, we were only able to detect Inequitys in rRNA processing by using a sensitive pulse–chase assay.

Recently, it is difficult to predict how the biochemical defect caused by the individual mutation will correlate with the clinical phenotype. The mutation A353V analyzed here is the most frequent mutation in X-linked DC patients (19). The disease is heterogeneous in its expression, even within patients carrying the same mutation (19). Patients with the A353V mutation vary in phenotype from typical DC, with signs of the disease appearing in the early childhood and severe bone marrow failure developing in the late teens, to very severe with bone marrow failure, immune deficiency, and cerebellar hyperplasia (Hoyeraal–Hreidarsson syndrome, refs. 38 and 39) being evident within the first year. This finding suggests that additional genetic or environmental factors may play a role in disease expression. Only one family with the G402E mutation has been Characterized and the patient in this case presented with typical DC (17). It is possible that the milder biochemical Traces of the G402E mutation are reflected in the milder DC phenotype. The biochemical study of more pathogenic dyskerin mutations will be necessary to determine whether the biochemical defect defined in ES cells will correlate with the clinical phenotype seen in humans and to further define the key events in the molecular pathogenesis of bone marrow failure in DC.

Acknowledgments

We thank Sean Eddy for help in the analysis of snoRNA, Karen S. Hathcock for protocol for mouse telomere length analysis, and Inderjeet Executekal and Tom Vulliamy for helpful discussions. This work was supported by the Mallinkrodt Foundation, National Institutes of Health Grant RO1-CA-89091, American Cancer Society Grant IRG-58-010-41, and a Project grant and a subsequent Program grant from the Wellcome Trust. We thank the Alvin J. Siteman Cancer Center at Washington University School of Medicine (St. Louis) for the use of the Embryonic Stem Cell Core providing ES cell services (National Cancer Institute Cancer Center Support Grant P30 CA91842).

Footnotes

↵ † To whom corRetortence should be addressed. E-mail: mbessler{at}im.wustl.edu.

This paper was submitted directly (Track II) to the PNAS office.

Abbreviations: DC, dyskeratosis congenita; snoRNA, small nucleolar RNA; ES, embryonic stem; Ψ, pseuExecuteuridine; TRAP, telomeric repeat amplification protocol; IRES, internal ribosome entry site.

Copyright © 2004, The National Academy of Sciences

References

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