Two RNA Polymerase I Subunits Control the Binding and Release of Rrn3 during Transcription

Rpa34 and Rpa49 are nonessential subunits of RNA polymeraseI, conserved in species from Saccharomyces cerevisiae and Schizosaccharomycespombe to humans. Rpa34 bound an N-terminal region of Rpa49 ina two-hybrid assay and was lost from RNA polymerase in an rpa49mutant lacking this Rpa34-binding domain, whereas rpa34 ${Delta}$ weakenedthe binding of Rpa49 to RNA polymerase. rpa34 ${Delta}$ mutants were caffeinesensitive, and the rpa34 ${Delta}$ mutation was lethal in a top1 ${Delta}$ mutantand in rpa14 ${Delta}$ , rpa135(L656P), and rpa135(D395N) RNA polymerasemutants. These defects were shared by rpa49 ${Delta}$ mutants, were suppressedby the overexpression of Rpa49, and thus, were presumably mediatedby Rpa49 itself. rpa49 mutants lacking the Rpa34-binding domainbehaved essentially like rpa34 ${Delta}$ mutants, but strains carryingrpa49 ${Delta}$ and rpa49-338::HIS3 (encoding a form of Rpa49 lackingthe conserved C terminus) had reduced polymerase occupancy at30°C, failed to grow at 25°C, and were sensitive to6-azauracil and mycophenolate. Mycophenolate almost fully dissociatedthe mutant polymerase from its ribosomal DNA (rDNA) template.The rpa49 ${Delta}$ and rpa49-338::HIS3 mutations had a dual effect onthe transcription initiation factor Rrn3 (TIF-IA). They partiallyimpaired its recruitment to the rDNA promoter, an effect thatwas bypassed by an N-terminal deletion of the Rpa43 subunitencoded by rpa43-35,326, and they strongly reduced the releaseof the Rrn3 initiation factor during elongation. These datasuggest a dual role of the Rpa49-Rpa34 dimer during the recruitmentof Rrn3 and its subsequent dissociation from the elongatingpolymerase.

INTRODUCTION

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INTRODUCTION

Fast-growing Saccharomyces cerevisiae and Schizosaccharomycespombe cells mobilize some 70% of their transcriptional capacityto produce the 6.8-kb precursor of the 18S, 5.8S, and 25S rRNAsby transcribing the highly repeated ribosomal DNA (rDNA) locus(44, 50). Genetic studies (43) have established that this isthe only role or, at least, the only essential role of yeastRNA polymerase I (Pol I). rDNA transcription starts with thebinding of Pol I to its specificity factor Rrn3 (7, 39-41, 48,57). The Rrn3-Pol I dimer is then directed to a preinitiationcomplex residing at the rDNA promoter region. This complex combinesthe TATA box-binding protein (also operating in the Pol II andPol III systems) with the core and upstream activation factorsthat are specific to the Pol I system (31, 32). In mammals,Pol I first binds transcription initiation factor IA, akin toRrn3 and functionally interchangeable with that protein in vivo(7, 40, 41). The Pol I-transcription initiation factor IA dimeris then targeted to the rDNA promoter by interacting with SL1,a factor made of the TATA box-binding protein associated withfour protein subunits, TAF_I95, TAF_I68, TAF_I48, and TAF_I41 (11,22, 23, 40, 59); TAF_I68 is distantly related to the yeast corefactor at the level of the core factor's Rrn7/TAF_I68 subunit(9). Pol I is also associated with the upstream binding factor(UBF; mammals) and Hmo1 (yeast) HMG box proteins, which stimulaterDNA transcription by a still poorly understood mechanism (19,46, 52).

Pol I has 14 polypeptide subunits in S. cerevisiae (20, 27)and S. pombe (2, 28). Five of these subunits, including thetwo largest ones, are akin to the bacterial core enzyme (58).Seven others are related or even identical to subunits of thePol II and Pol III core structures (1, 16, 29) and are homologousto archaeal RNA polymerase subunits (35, 55). Rpa49 and Rpa34,on the other hand, are Pol I-specific subunits with unknownfunctions (20, 36) that are also homologous to PAF53 and PAF49in the mammalian Pol I system (47, 56). We show here that thesesubunits bind each other in the Pol I structure and play animportant role in transcription by improving the recruitmentof the Rrn3-Pol I complex to the rDNA and by triggering therelease of Rrn3 from the elongating Pol I.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Tables listing the plasmids, yeast strains, and DNA primersused in this study are included in the supplemental material.Yeast strains were constructed by meiotic crossing, DNA transformation,and plasmid shuffling through selection on fluoroorotic acid(FOA) medium with 0.1% 5-fluoroorotate (8). Null alleles withKanMX4 insertions were obtained from EUROSCARF (http://web.uni-frankfurt.de/fb15/mikro/euroscarf/index.html)and were checked by ad hoc PCR amplifications. The rpa135(D395N)and rpa135(L656P) alleles were isolated after UV mutagenesisof the rpa34::HIS3 strain OG1-1C transformed by plasmid pOG1-A34(20) and were selected by a method based on the lack of whitesectoring in the UV-mutagenized clones (33), which signals theirinability to lose pOG1-A34, therefore indicating that the rpa34::HIS3allele is now essential for growth.

Newly constructed plasmids were prepared from PCR-amplifiedDNA. In most cases, we used the Gateway cloning system withpreviously described destination vectors (54). All inserts wereresequenced to detect spurious mutations generated by DNA amplification.Chimeras including the Rpa43 coding sequences of S. cerevisiaeand S. pombe were constructed by overlap extension PCR usingPfu DNA polymerase. Primer sequences are available upon request.

Chromatin immunoprecipitation (ChIP) assays were systematicallydone on three independent cultures of 100 ml harvested at anA₆₀₀ of 0.6, with slight modifications of a previously describedexperimental protocol (34) and with the rDNA primers listedin the tables in the supplemental material. Yeast cells werecultivated in yeast extract-peptone-dextrose (YPD) medium, exceptin experiments involving mycophenolate, in which we used syntheticdextrose medium supplemented with histidine, arginine, tryptophan,and adenine sulfate, each at 20 mg/liter, and leucine and lysine,each at 30 mg/liter (SD+aa medium). rDNA copy numbers were estimatedby comparing the kinetics of PCR amplification on rDNA primersand on PYK1 primers used as a single-gene control, giving anaverage value (± the standard deviation) of 186 ±54 copies.

RESULTS

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RESULTS

The Pol I-specific subunits Rpa49 and Rpa34 bind each other in two-hybrid assays. Viable rpa49 ${Delta}$ mutants fail to grow at 25°C and are sensitiveto mycophenolate, and the rpa49 ${Delta}$ mutation is lethal in cellslacking the nonessential Rpa14 subunit or the HMG box proteinHmo1 (13, 19, 20, 36). Rpa49 has close homology to the humanPAF53 protein (Fig. 1) and can be replaced in vivo by Rpa51,its S. pombe counterpart (42). A homology search revealed agene for an Rpa49-like product in most eukaryotic genomes, withconserved motifs scattered over the entire subunit. In particular,all Rpa49-like subunits contain a highly conserved C-terminaldomain, located between positions 326 and 371 in S. cerevisiae(detailed sequence alignments are provided in Fig. S1 in thesupplemental material). Proteins distantly related to Rpa34have also been identified in fission yeast, mice, and humans(2, 47). However, their sequence homology is restricted to twoshort conserved domains and to C-terminal KKE/D repeats oftenfound in nucleolar proteins (21), and the mammalian subunit(PAF49) is much larger than its fungal counterpart (see Fig.S2 and S3 in the supplemental material).

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FIG. 1. Properties of the Rpa49 subunit. (A) Homology between Rpa49 (S. cerevisiae) and its S. pombe (Rpa51) and human (PAF53) counterparts, shown by Blosum 62 matrices drawn at a 5/35 stringency. H. sapiens, Homo sapiens. (B) Two-hybrid screening with Gal4_BD-Rpa34. Six Gal4_AD-Rpa49 plasmids were isolated by genome-wide screening of a previously described two-hybrid library (17) by using Gal4_BD-Rpa34. Vertical lines denote the limits of the RPA49 inserts. β-Galactosidase (β-Gal) was tested as previously described (17). Data are shown for the Gal4_AD::RPA49(36,119) plasmid and for a reciprocal two-hybrid interaction between Gal4_BD-Rpa34 and Gal4_AD-Rpa49. The RPA49 open reading frame is shown with gray boxes representing four conserved parts of Rpa49, corresponding to positions 60 to 89, 128 to 154, 201 to 216, and 326 to 371 in S. cerevisiae (see Fig. S1 in the supplemental material). (C) Deletion mapping of the Rpa34-interacting domain on Rpa49. N-terminal and C-terminal deletion forms of Rpa49 were cloned as Gal4_BD fusions into the pVV213 vector (54) and tested against Gal4_BD-Rpa34 in a two-hybrid assay.

Rpa49 and Rpa34 were fused to the binding domain of Gal4 (Gal4_BD)and tested for two-hybrid interactions in a genome-wide screenbased on a library of genomic fragments fused to the Gal4 activationdomain (Gal4_AD) (17, 18). The Gal4_BD-Rpa49 screen yielded twoGal4_AD clones encoding the entire Rpa34 subunit, whereas theGal4_BD-Rpa34 fusion yielded six clones with products overlappingbetween positions 63 and 119 of Rpa49 (Fig. 1A). Subunits withN-terminal deletions (encoded by rpa49-63,416, rpa49-89,416,and rpa49-119,416) and C-terminal deletions (encoded by rpa49-1,260and rpa49-1,366) were also fused to pVV213, a Gal4_BD fusionvector based on a Gateway cassette. This new round of two-hybridassays, done with a slightly different vector, confirmed thatthe interaction between Gal4_BD-Rpa34 and Gal4_BD-Rpa49 was lostthrough the deletion of the N terminus of Rpa49 and was insensitiveto C-terminal deletions (Fig. 1B).

The genome-wide screening performed with Gal4_BD-Rpa34 also yieldedtwo Top1 clones (suggesting that the synthetic lethality ofrpa34 ${Delta}$ and top1 ${Delta}$ [20] may involve direct Top1-Rpa34 binding) andfour clones encoding Gno1 (two isolates), Nop56, and Nop58.Like Rpa34, these three proteins are nucleolar and contain KKD/Erepeats that are commonly encountered in nucleolar proteins.Gno1 contributes to the first cleavage steps of pre-rRNA processing(24). Nop56 and Nop58 are components of the U3 ribonucleoproteincomplex required for 18S rRNA biogenesis (14).

The N-terminal part of Rpa49 enables Rpa34 to bind Pol I. A Pol I subform lacking Rpa34 and Rpa49 is catalytically activeon nonspecific DNA templates and can be chromatographicallyseparated from the 14-subunit enzyme (27). Moreover, Rpa49 dissociatesfrom a highly purified preparation of Pol I in rpa34 ${Delta}$ mutants(20), suggesting that Rpa49 and Rpa34 may stabilize each otherwithin the Pol I structure. We further investigated this pointby ChIP assays of rpa49 mutants. As shown in Fig. 2, Rpa34 wasentirely lost from the rDNA-bound Pol I in an N-terminal deletionmutant (rpa49-119,416) lacking the putative Rpa34-binding domain.A fortiori, it was also lost in rpa49 ${Delta}$ mutants, which also displayedan overall reduction in the amount of Pol I residing on rDNA(as detected by anti-Rpa190 antibodies), consistent with theslow growth of these mutants at 30°C. rpa34 ${Delta}$ , on the otherhand, slightly reduced the Rpa49 signal but had no effect onPol I itself, in keeping with the wild-type growth rate of rpa34 ${Delta}$ mutants (Fig. 2).

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FIG. 2. Association of Rpa34 and Rpa49 with Pol I in rpa34 ${Delta}$ or rpa49 mutants. ChIP assays were done on three independent cultures (comprising 100 ml of YPD) harvested at an A₆₀₀ of 0.6. Pol I was revealed by polyclonal anti-Rpa190 and anti-Rpa34 or anti-Rpa49 rabbit antibodies (49). DNA occupancy was defined by the ratio between the immunoprecipitation (IP) signal and the DNA input (IN) signal. The diagram at the bottom shows the approximate positions of the primers used for reverse transcription-PCR (RT-PCR) amplification. Arrows denote the start sites and transcription orientations of the 5S and 35S rRNA transcripts. NTS1 and NTS2, nontranscribed spacers 1 and 2; nt, nucleotides. (Left panels) Effect of rpa49 mutations on the binding of Rpa34 to Pol I. Strain D704-6C was transformed with pVV200 plasmids bearing the mutant (rpa49-119,416) and wild-type (WT) RPA49 alleles. (Right panels) Effect of rpa34 ${Delta}$ on the binding of Rpa49 in YPH499 (WT) and T4-1C (rpa34 ${Delta}$ ).

The adverse phenotypes of rpa34 ${Delta}$ mutants are suppressed by Rpa49 overexpression. Unlike rpa49 ${Delta}$ , rpa34 ${Delta}$ caused no growth defect in its own right,and rpa34 ${Delta}$ mutants were not particularly sensitive to mycophenolateor 6-azauracil (Fig. 3A). Like rpa49 ${Delta}$ mutants, however, rpa34 ${Delta}$ mutants were sensitive to caffeine (trimethylxanthine), andthe mutation was synthetically lethal with rpa14 ${Delta}$ and top1 ${Delta}$ (Fig.3B and C). It should be noted that we previously obtained aviable top1 ${Delta}$ rpa49 ${Delta}$ double mutant (20), but further analysis hasnow shown that this was an exceptional case, almost certainlydue to some unrecognized suppression.

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FIG. 3. Growth phenotypes of RNA Pol I mutants. (A) Sensitivity of RNA Pol I mutants to low temperature (25°C), mycophenolate (MPA), and 6-azauracil (AZA). Strains YPH499 (wild type [WT]), D704-6C (rpa49 ${Delta}$ ), D360-1A (rpa14 ${Delta}$ ), T4-1C (rpa34 ${Delta}$ ), OG36-1A [rpa135(L656P)], SL46-1D [rpa135(D395N)], SL9-2C (rpa12 ${Delta}$ ), and D101-CHIM2 (rpa43-chim2) were serially diluted and spotted onto YPD and onto synthetic complete medium lacking uracil but containing mycophenolate (10 µg/ml) or 6-azauracil (20 µg/ml). Plates were incubated for 3 days at 30°C. The box on the right summarizes the synthetic growth defects seen in rpa14 ${Delta}$ and top1 ${Delta}$ strains as monitored by plasmid shuffle tests (8) based on the counterselection of URA3 centromeric plasmids (with RPA12, RPA14, RPA34, or RPA49) on FOA medium. Lethality is indicated by a minus sign. Mutant strains that grew on FOA were streaked onto YPD for 3 days at 30°C. The + and (+) symbols denote a growth pattern identical or partially impaired relative to that of the corresponding wild-type control tested before the FOA chase. (B) Suppression of the caffeine sensitivity of the rpa34 ${Delta}$ mutant by RPA49 overexpression. The YPH499 wild type (WT), the isogenic mutant strain T4-1C (rpa34 ${Delta}$ ), and T4-1C transformed with pGEN-A49 (rpa34 ${Delta}$ 2µ RPA49) were spotted onto YPD and onto YPD with caffeine at 1 g/liter and grown for 3 days at 30°C. (C) Suppression of rpa34 ${Delta}$ synthetically lethal defects by RPA49 overexpression. Strains OG1-L656P [rpa135(L656P) rpa34 ${Delta}$ ], OG1-D395N [rpa135(D395N) rpa34 ${Delta}$ ], and OG17-1C (top1 ${Delta}$ rpa34 ${Delta}$ ) bearing the pOG1-A34 plasmid (2µm RPA34 URA3) were transformed with pGEN-A49 (2µm RPA49 TRP1) by using pGEN as an empty vector control (–). Suppression was detected by a plasmid shuffle assay on FOA, as described above. (D) Suppression of the rpa14 ${Delta}$ rpa34 ${Delta}$ synthetic lethality by RPA49 overexpression. Strains Y11277 (rpa34 ${Delta}$ ::KanMX4) and D360-1A (rpa14 ${Delta}$ ::HIS3) were crossed and transformed with pSLA49 (2µm RPA49 URA3), and meiotic tetrads were isolated by microdissection. The results presented show a tetratype with two parental and two recombinant segregants after replica plating onto 5-FOA, demonstrating that the rpa14 ${Delta}$ rpa34 ${Delta}$ strain (white frame) is unable to lose pSLA49. (E) Synthetic lethality of rpa49 ${Delta}$ with the RRN3::RPA43 fusion. Strains D781-10B [(RPA49 rpa43 ${Delta}$ )/2µm TRP1 RRN3::RPA43/CEN URA3 RPA43] and D780-6D [(rpa49 ${Delta}$ rpa43 ${Delta}$ )/2µm TRP1 RRN3::RPA43/CEN URA3 RPA43] were tested for their ability to lose the YCpA43-12 (CEN URA3 RPA43) plasmid by using a plasmid shuffle assay on FOA. The white frame around the D780-6D replica indicates the inability to lose YcpA43-12 in the rpa49 ${Delta}$ context.

Using an ad hoc procedure to select mutations that were syntheticallylethal with rpa34 ${Delta}$ (see Materials and Methods), we obtained twoadditional Pol I mutants, the rpa135(L656P) and rpa135(D395N)strains. These mutants grew like the wild type but were moderately[rpa135(D395N)] or strongly [rpa135(L656P)] sensitive to mycophenolateand 6-azauracil. The rpa135(L656P) and rpa135(D395N) mutationswere also lethal with rpa49 ${Delta}$ , but this synthetic lethality wasspecific to the Rpa49 subunit since strains carrying the rpa135(L656P)and rpa135(D395N) mutations combined with rpa12 ${Delta}$ and rpa14 ${Delta}$ wereviable (Fig. 3A and B). Intriguingly, the rpa135-(L656P) mutationcorresponds to a highly conserved position shared by the archaealand eukaryotic polymerases, and this conservation extends tobacteria in the case of position D395 (Fig. 4). The equivalentpositions belong to the lobe and external domains of the yeastPol II crystal structure (12) and are fairly close to the Rpb9subunit paralogous to Rpa12.

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FIG. 4. Positions of the rpa135(D395N) and rpa135(L656P) mutations as deduced from the Pol II structure. Local sequence alignments are shown for the second-largest subunit of the three yeast RNA polymerases, for the corresponding archaeal subunits of Methanocaldococcus jannaschii (MjB' and MjB''), and for the β subunit of Thermus aquaticus (Taq β). Two views of the Pol II spatial structure (Protein Data Bank coordinate 1WCM) are provided, showing the positions of Rpa12 (blue ribbons) and of the lobe and external folds. Asterisks indicate mutant positions.

rpa34 ${Delta}$ mutants, therefore, had a wild-type growth pattern butwere sensitive to caffeine and presented a small number of syntheticallylethal defects shared with rpa49 ${Delta}$ mutants. Importantly, all thecurrently identified phenotypes associated with the rpa34 ${Delta}$ mutationwere suppressed when Rpa49 was overexpressed from a multicopyplasmid (Fig. 3C). Together with the above-cited data showingthat rpa34 ${Delta}$ slightly reduced the Rpa49 ChIP signal, these observationsargue that Rpa34 alters the spatial organization of the correspondingRpa49, therefore stabilizing this subunit in the Pol I structure,and that this activity accounts for all the adverse effectscurrently associated with rpa34 ${Delta}$ . It should be noted that previouslarge-scale screening for synthetically lethal yeast mutationshad suggested that Rpa34 might contribute to cell wall synthesis,due to synthetic lethality occurring with rpa34 ${Delta}$ in chitin synthase-defectivemutants (53). However, we were unable to reproduce these observations.

The conserved C terminus of Rpa49 is critical in vivo. Rpa49 mutants were constructed by progressive N- and C-terminaldeletions (Fig. 5A). Deleting the first 89 amino acids of Rpa49(rpa49-63,416 and rpa49-89,416) had no adverse effects underany conditions tested, despite the strongly conserved motifbetween positions 60 and 90 (see Fig. S1 in the supplementalmaterial). The rpa49-119,416 mutation, which removed the next20 amino acids, also produced a wild-type phenotype but wasnearly lethal with rpa14 ${Delta}$ , consistent with the data discussedabove (Fig. 2) showing that Pol I was unable to recruit theRpa34 subunit in the rpa49-119,416 mutant. We then turned tothe rpa49-338::HIS3 strain, a previously described mutant (36)with a C-terminal insertion of the sequence encoded by the HIS3cassette. This mutant forms a truncated Rpa49 lacking the highlyconserved C-terminal domain mentioned above (see Fig. S1 inthe supplemental material). Since the truncated Rpa49 subunitis still stably incorporated into the multisubunit structureof RNA Pol I (36), the defects associated with rpa49-338::HIS3directly result from the absence of the Rpa49 C terminus.

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FIG. 5. Mutagenesis of RPA49. (A) Growth defects of rpa49 mutants. Strain D704-7C (rpa49 ${Delta}$ ) was transformed with pVV200 plasmids (54) bearing the relevant wild-type sequences and rpa49 mutations corresponding to progressive N- and C-terminal deletions. Plasmid pVV214 was used as an empty vector control. Strain 49::HIS3 (see the tables in the supplemental material) was used to test the rpa49-338::HIS3 allele, in which the HIS3 insertion interrupts the Rpa49 coding sequence at H338 with a sequence encoding a GSAARSCSLACT extension beyond H338 (36). Four gray boxes represent conserved parts of Rpa49 (Fig. 1). Yeast cultures were serially diluted and spotted onto YPD (at 25 and 30°C and at 30°C with 1 g of caffeine [CAF]/liter) and synthetic complete medium with or without mycophenolate (MPA) at 20 µg/ml. Plates were incubated at 30°C for 3 days. The synthetic lethality of rpa49 mutations was tested in strains D699-13C (rpa14 ${Delta}$ rpa49 ${Delta}$ ) and D684-2B (hmo1 ${Delta}$ rpa49 ${Delta}$ ) bearing the pFB74 (RPA49 URA3) plasmid and transformed with the same plasmids indicated above. The resulting transformants were replica plated onto FOA medium to chase pFB74. Synthetically lethal effects were revealed by the lack of growth on FOA (8). In the case of rpa49-338::HIS3, synthetic lethality was deduced from meiotic crosses based on 12 tetrads. Lethality is indicated by a minus sign. (–) indicates very slow growth. The + and (+) symbols denote a growth pattern identical or partially impaired relative to that of the corresponding wild-type control. (B) Effect of rpa49 mutations on rDNA occupancy by Pol I. ChIP assays were done on D704-6C (rpa49 ${Delta}$ ) transformed with the appropriate pVV200-derived plasmids. Pol I was revealed by polyclonal anti-Rpa190 rabbit antibodies (49). DNA occupancy was defined by the ratio between the immunoprecipitation (IP) signal and the DNA input (IN) signal. The diagram below shows the approximate positions of the primers used for RT-PCR amplification (see the tables in the supplemental material). Arrows denote the start sites and transcription orientations of the 5S and 35S rRNA transcripts. WT, wild type; NTS1 and NTS2, nontranscribed spacers 1 and 2.

The rpa49 ${Delta}$ and rpa49-338::HIS3 mutations produced the syntheticallylethal defects and caffeine sensitivity mentioned above forrpa34 ${Delta}$ mutants but also engendered many phenotypes of their own,causing an almost complete lack of growth at 25°C, strongsensitivity to mycophenolate and 6-azauracil, and syntheticlethality with hmo1 ${Delta}$ (Fig. 5A). A mutant with a somewhat shorterC-terminal deletion, corresponding to rpa49-1,366, also failedto grow at 25°C but had slightly milder drug sensitivity,and a strain carrying rpa49-1,366 and hmo1 ${Delta}$ was viable. The importanceof the Rpa49 C-terminal domain was also underscored by resultsfrom ChIP assays showing strongly reduced Pol I occupancy ofrDNA in rpa49 ${Delta}$ and rpa49-1,366 mutants (Fig. 5B).

rpa49 ${Delta}$ and rpa49-338::ITHIS3 have a dual effect on the recruitment and release of Rrn3. Earlier ChIP assays have shown that Rrn3 is present on the rDNApromoter but not on the rDNA 3' end, as befits a Pol I-associatedinitiation factor (5). Using Rrn3-hemagglutinin (HA)-taggedstrains, we showed that Rrn3 was strictly restricted to thepromoter region. The rpa43-chim2 strain, a slow-growing mutantexpressing a form of Rpa43 constructed by domain swapping withthe S. pombe subunit (F. Beckouet, S. Labarre-Mariotte, Y. Nogi,and P. Thuriaux, unpublished results), exhibited strongly reducedRrn3-HA occupancy at the rDNA promoter (Fig. 6A) but littleor no effect on the Rrn7 and Rrn9 subunits of the core and upstreamactivating factors. This finding further supports earlier datashowing that Rpa43 is specialized in transcription initiationand that Rrn3 needs to bind Rpa43 in order to be recruited tothe rDNA promoter region as a preformed Rrn3-Pol I complex (34,48, 57). Rrn3 appears to be released from rDNA (and thereforefrom Pol I) at the onset of transcription, although we cannotrule out that it undergoes a dramatic change in conformationthat masks the Rrn3-HA tag at elongation. These two possibilitiescannot be distinguished in ChIP assays, but the in vitro dataof Bier et al. (5) strongly argue that Rrn3 no longer bindsthe elongating Pol I.

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FIG. 6. Effect of RNA Pol I mutations on Rrn3-HA and Rrn7-HA occupancy. (A) Rrn3 occupancy in rpa43-chim2, rpa49 ${Delta}$ , and rpa49-338::HIS3 strains. ChIP assays were done on strain SL97-17C (rpa43 ${Delta}$ Rrn3-HA) bearing plasmid pGEN-A43 (wild type [WT]) or pGA43-chim2 (rpa43-chim2) and strains SL112-1C (rpa49 ${Delta}$ ) and D612-5A (rpa49-338::HIS3) by using the same conditions described above. Rrn3-HA was revealed with anti-hemagglutinin A mouse antibody (12CA5). A schematic representation of the rpa43-chim2 strain is shown below. Numbers denote amino acid positions and correspond to the limits of the domains swapped between S. cerevisiae and S. pombe. IP, immunoprecipitation signal; IN, DNA input signal. (B) Rrn7 occupancy. ChIP assays were done on strains SL105-7A (rpa43 ${Delta}$ Rrn7-HA) and SL111-4A (rpa49 ${Delta}$ Rrn7-HA) bearing the same plasmids and under the same conditions described above.

Turning to the rpa49 ${Delta}$ and rpa49-338::HIS3 mutants, we also foundthe Rrn3-HA signal at the promoter to be decreased, but muchless so than that in the rpa43-chim2 strain. However, in contrastto the Rrn3 in the wild-type or rpa43-chim2 strain, a substantialfraction of the Rrn3 in the rpa49 ${Delta}$ and rpa49-338::HIS3 mutantsremained bound to the elongating Pol I, with a decreasing signaltoward the 3' end of the transcript. The core and upstream activatingfactors (Rrn7-HA and Rrn9-HA), on the other hand, were stillrestricted to the promoter domain (as shown in Fig. 6B for Rrn7-HA).Intriguingly, rpa49 ${Delta}$ and rpa49-338::HIS3 were lethal when Rpa43was replaced by an Rrn3-Rpa43 fusion in which Rrn3 was, by construction,permanently associated with the elongating Pol I (34) and whichwas previously shown to yield a viable strain when introducedinto a wild-type background (data for rpa49 ${Delta}$ are shown in Fig.7C).

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FIG. 7. Effect of mycophenolate (MPA) on wild-type (WT), rpa12 ${Delta}$ , and rpa43-chim2 strains. Cells were cultivated in SD+aa medium until they reached an A₆₀₀ of 0.2, treated (or left untreated) with 20 µg of mycophenolate/ml, and further grown for 30 min. In the case of Pol I, ChIP assays were done on strains SL97-17C [(rpa43::LEU2 Rrn3-HA)/YCPA43], used here as the wild-type control, SL9-2C (rpa12 ${Delta}$ ), and D101-chim2 (rpa43-chim2). Pol I was revealed by polyclonal anti-Rpa190 rabbit antibodies (49). Five additional primers (5, 6, 7, 9, 10) were used for RT-PCR amplification and are listed in the tables in the supplemental material. The diagram at the bottom shows the approximate positions of the primers used for RT-PCR amplification (see the tables in the supplemental material). Arrows denote the start sites and transcription orientations of the 5S and 35S rRNA transcripts. SC, synthetic complete medium; IP, immunoprecipitation signal; IN, DNA input signal; NTS1 and NTS2, nontranscribed spacers 1 and 2.

The data cited above suggest that rpa49 ${Delta}$ and rpa49-338::HIS3have a dual effect on Rrn3, partially reducing its associationwith the rDNA promoter but also impairing its release from theelongating Pol I. We therefore anticipated that conditions dissociatingPol I from its rDNA template should also dissociate the PolI-bound Rrn3 of rpa49 ${Delta}$ and rpa49-338::HIS3 mutants, and we exploitedthe effect of mycophenolate on the elongating Pol I to testthis possibility. As shown in Fig. 7, mycophenolate increasedthe Pol I signal seen at the rDNA promoter region, which maybe due to a lower rate of elongation, and progressively decreasedthe amount of rDNA-bound Pol I as the Pol I moved toward the3' end of the rDNA, indicating a processivity defect similarto the one recently described for Pol II (38). In contrast,mycophenolate had no effect on Rrn3 occupancy, indicating thatRrn3 leaves the promoter before or shortly after the start oftranscription (Fig. 8, right panels).

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FIG. 8. Effect of mycophenolate (MPA) on rpa49 ${Delta}$ , rpa49-338::HIS3, and rpa135(L656P) mutants. (Left panels) Effect on Pol I (Rpa190) in wild-type (WT), rpa49 ${Delta}$ , rpa49-338::HIS3, and rpa135(L656P) strains. Cells were cultivated in SD+aa medium until they reached an A₆₀₀ of 0.2, treated (or left untreated) with 20 µg of mycophenolate/ml, and further grown for 30 min. ChIP assays were done on strains SL97-17C [(rpa43::LEU2 Rrn3-HA)/YCPA43], used here as the wild-type control, SL112-1C (Rrn3-HA rpa49 ${Delta}$ ), SL107-3b (Rrn3-HA rpa49-338::HIS3), and OG36-1a [rpa135(L656P)]. Pol I was revealed by polyclonal anti-Rpa190 rabbit antibodies (49). (Right panels) Effect on Rrn3-HA. Cells were cultivated in SD+aa medium until they reached an A₆₀₀ of 0.2, treated (or left untreated) with 20 µg of mycophenolate/ml, and further grown for 30 min. ChIP assays were done on strains SL97-17C [(rpa43::LEU2 Rrn3-HA)/YCPA43], used here as the wild-type control, SL112-1C (Rrn3-HA rpa49 ${Delta}$ ), SL107-3b (Rrn3-HA rpa49-338::HIS3), and D769-2C [Rrn3-HA rpa135(L656P)]. Rrn3-HA was revealed with anti-hemagglutinin A mouse antibody (12CA5). SC, synthetic complete medium; IP, immunoprecipitation signal; IN, DNA input signal.

rpa43-chim2 and rpa12 ${Delta}$ strains responded essentially like thewild type when treated with mycophenolate (Fig. 7), consistentwith their normal (rpa43-chim2) and mildly increased (rpa12 ${Delta}$ )drug sensitivities in vivo. However, a very different responseby rpa49 ${Delta}$ and rpa49-338::HIS3 mutants was seen (Fig. 8, leftpanels). These mutants were strongly sensitive to mycophenolate,and their Pol I was almost entirely absent from rDNA after 30min of exposure to this drug. In addition, and in sharp contrastto the wild-type situation, there was a massive loss of Rrn3,even at the promoter region, supporting the view that Rrn3 andPol I were physically associated in these mutants and that Rrn3was therefore lost together with Pol I itself (Fig. 8, rightpanels). As a control, these assays were also done with a straincarrying rpa135(L565P), shown as described above to cause sensitivityto mycophenolate and to be synthetically lethal with rpa49 ${Delta}$ andrpa49-338::HIS3. As shown in Fig. 8 (lower panels), there wasan almost complete loss of Pol I in rpa135(L565P) cells exposedto mycophenolate, but Rrn3 remained bound to the rDNA promoter,as in the wild type.

An rpa43 mutation suppresses the cold-sensitive defect of rpa49 mutants. In the course of this study, we observed that the rpa43-35,326mutation, yielding a wild type-like mutant with a deletion ofthe nonconserved N terminus of Rpa43 (Beckouet et al., unpublished),acted as a gain-of-function mutation suppressing the cold sensitivityof rpa49 mutants (Fig. 9, upper panels). Consistent with thissuppression, Pol I occupancy was restored to a nearly wild-typelevel, which coincided with better Rrn3 occupancy. However,rpa43-35,326 had little or no effect on the mycophenolate sensitivityof rpa49 mutants and did not change their defective Rrn3 release(Fig. 9, lower panels). These data further argue that rpa49 ${Delta}$ and rpa49-338::HIS3 have a dual effect on Rrn3, interferingwith its recruitment during transcription initiation and preventingits release from the elongating Pol I. The former defect wassuppressed by rpa43-35,326, thus possibly reflecting a directinteraction of Rpa49 with the N terminus of Rpa43. The defectin Rrn3 release, on the other hand, was independent of rpa43-35,326and correlated with strong sensitivity to mycophenolate.

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FIG. 9. Suppression of rpa49 mutations by an N-terminal deletion of Rpa43 (rpa43-35,326). (Upper panels) Strains D710-8A (rpa43 ${Delta}$ rpa49 ${Delta}$ ) and SL107-3B (rpa43 ${Delta}$ rpa49-338::HIS3) bearing the YCP43-12 (URA3 RPA43) plasmid were transformed with plasmids pGEN-RPA43 (TRP1 RPA43) and pFB63 (TRP1 rpa43-35,326). Transformants were replica plated onto FOA medium to chase YCP43-12, tested on YPD (25°C) and synthetic complete medium with mycophenolate (MPA) at 0, 5, and 20 g/liter (30°C), and incubated for 3 days at 25°C, as described in the legend to Fig. 3. Strain YPH500 was used as a wild-type (WT) control. (Lower panels) ChIP assays were done on strains SL97-17C (WT) and SL107-3b (rpa49-338::HIS3) bearing plasmid pFB63 (rpa43-35,326) or pGEN-RPA43 (RPA43⁺) by using the same conditions described above, except that cells were cultivated in SD+aa medium and were harvested at an A₆₀₀ of 0.2. IP, immunoprecipitation signal; IN, DNA input signal.

DISCUSSION

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DISCUSSION

Rpa49 and Rpa34 are noncatalytic components of Pol I (27), andtheir genetic inactivation in S. cerevisiae yields viable strains(20, 36). However, rpa49 ${Delta}$ mutants have severe growth defects(19, 20), and the rpa49 ${Delta}$ mutation was identified in genome-widescreening for mycophenolate-sensitive mutants (13), a firstclue to the importance of Rpa49 for transcript elongation. Wefound here that Rpa34 and Rpa49 specifically interacted in atwo-hybrid assay, which assigned the main Rpa34-binding domainto the N-terminal part of Rpa49. This binding may recruit Rpa34onto Pol I, as this subunit was lost from Pol I in rpa49 mutantslacking the binding domain. rpa34 ${Delta}$ had only a minor effect onthe association of Rpa49 with Pol I, suggesting that Rpa49 directlybinds the Pol I core structure. Previous data suggested thatRpa34 and Rpa49 do not make contact with each other in the PolI envelope (6), but results from recent structural studies supportthe idea that Rpa34 directly binds Rpa49, and modeling dataalso suggest that this binding operates at the level of theN-terminal domain of Rpa49 (33a). In S. pombe, the C terminusof the Rpa49-like subunit is critical in vivo (42), and we foundhere that a strain carrying rpa49-338::HIS3, a premature-terminationmutation removing the last 28 amino acids of Rpa49, behavedlike the rpa49 ${Delta}$ null mutant. The most important part of the Rpa34-Rpa49dimer, therefore, appears to be the C terminus of Rpa49, whichis strongly conserved in all eukaryotes.

Our data indicate a dual effect of rpa49 ${Delta}$ and rpa49-338::HIS3on the recruitment of Rrn3 and on its binding to the elongatingPol I. These two phenotypes were genetically dissociated byrpa43-35,326, encoding an N-terminal deletion of the Rpa43 subunitwhich specifically suppressed the recruitment defect and alsocorrected the cold-sensitive growth defect of rpa49 ${Delta}$ and rpa49-338::HIS3mutants. This suppression implies that Rpa43 and Rpa49 cooperateto load Pol I-Rrn3 onto the rDNA promoter but does not necessarilycall for direct physical interaction between these two subunits.It may be, for example, that Rpa49 favors the recruitment ofthe Pol I-Rrn3 complex by interacting with the core factor.Importantly, rpa43-35,326 had no effect on the mycophenolatesensitivity of rpa49 ${Delta}$ and rpa49-338::HIS3 mutants and did notaffect their defective release of Rrn3. However, the rpa49 ${Delta}$ andrpa49-338::HIS3 mutations were lethal in strains carrying anRRN3::RPA43 fusion product in which Rrn3 was, by construction,permanently associated with the elongating Pol I. Moreover,they were synthetically lethal with top1 ${Delta}$ (yielding a strainlacking a type I DNA topoisomerase) or hmo1 ${Delta}$ , a mutation inactivatingHmo1, an HMG box protein residing on rDNA (19, 25), and theseresults suggest that the progression of the mutant Pol I stronglydepends on the topology (Top1) or spatial organization (Hmo1)of rDNA. The findings of a recent study (Kuhn et al., submitted)also indicate that a Pol I form lacking Rpa34 and Rpa49 haselongation defects in vitro.

rpa34 ${Delta}$ produced no growth defect of its own and led only to syntheticallylethal effects that were shared by rpa49 ${Delta}$ and were suppressedby the overexpression of Rpa49. These findings raise the questionof whether Rpa34 has any role other than to stabilize Rpa49in the Pol I structure, thus optimizing the biological roleof that subunit. Indeed, the two-hybrid interaction found herebetween Rpa34 and three other nucleolar proteins, Gno1, Nop56,and Nop58, tentatively suggests that Rpa34 may have a functionof its own by favoring the cotranscriptional recruitment ofthe pre-rRNA maturation machine to the nascent transcript, sincethese putative partners intervene in the early maturation ofthe 35S pre-rRNA (14, 21, 24). Intriguingly, these proteinsare also endowed with KKE/D repeats, like Rpa34 itself, althoughthe biological meaning of these domains remains to be established.

Mammalian cells contain two Pol I-associated factors, PAF53and PAF49, with strong homology to Rpa49 (PAF53) and weakerhomology to Rpa34 (PAF49) (26, 47). In vitro, PAF53 and PAF49stimulate the faithful transcription of rDNA by Pol I and mayfunctionally and/or physically interact with UBF, an HMG boxprotein associated with animal Pol I (3). The name UBF, whichstands for upstream binding factor, points to a role in thepreinitiation steps of rDNA transcription (3), but recent evidencesuggests that UBF contributes to promoter escape (46) or mayeven modulate the progression of Pol I along its rDNA template,since UBF actually binds the entire Pol I-transcribed region(45, 51). rpa49 ${Delta}$ is suppressed by the overexpression of Hmo1,which is probably the yeast UBF (4, 19), and is lethal in anhmo1 ${Delta}$ context. In other words, the existence of Hmo1 explainswhy the rpa49 ${Delta}$ null allele still supports transcription, albeitinefficiently. Hmo1 binds the whole Pol I-transcribed unit andis also a Pol II factor that binds many members of the ribosomalprotein regulon (4, 25, 30). It is worth noting that, in vitro,Hmo1 unwinds DNA in the presence of DNA topoisomerase I (37)and that top1 ${Delta}$ and hmo1 ${Delta}$ are both synthetically lethal with rpa49 ${Delta}$ .The functional interplay between Rpa49-Rpa34 and Hmo1 needsto be investigated more thoroughly, but we would be surprisedif it did not reflect a conserved mechanism operating in speciesfrom yeast to humans.

ACKNOWLEDGMENTS

This work was supported by the Association pour la Recherchecontre le Cancer (F.B.), by an ATIP grant from CNRS, and bythe Agence Nationale de la Recherche (O.G.).

We thank M. Riva for polyclonal antibodies; M. Fromont-Racinefor a two-hybrid yeast library; M. Goussot for technical helpin two-hybrid screening; C. Carles, S. Chédin, M. Kwapisz,C. Mann, M. Riva, E. Shematorova, J. Soutourina, and M. Wéryfor useful suggestions; and P. Cramer for kindly communicatingunpublished data.

FOOTNOTES

* Corresponding author. Mailing address: CEA, IbiTec-S, Service de Biologie Intégrative & Génétique Moléculaire, Gif sur Yvette Cedex F-91191, France. Phone: 33 1 69 08 35 86. Fax: 33 1 69 08 47 12. E-mail: pierre.thuriaux{at}cea.fr

Published ahead of print on 17 December 2007.

Supplemental material for this article may be found at http://mcb.asm.org/.

REFERENCES

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