Multiple Functional Interactions Between Components of the Lsm2-Lsm8 Complex, U6 snRNA, and the Yeast La Protein

Multiple Functional Interactions Between Components of the Lsm2–Lsm8 Complex, U6 snRNA, and the Yeast La Protein

Barbara K. Pannone^a, Sang Do Kim^a, Dennis A. Noe^a, and Sandra L. Wolin^a
^a Departments of Cell Biology and Molecular Biophysics and Biochemistry, Howard Hughes Medical Institute, Yale University School of Medicine, New Haven, Connecticut 06536

Corresponding author: Sandra L. Wolin, Departments of Cell Biology and Molecular Biophysics and Biochemistry, Howard Hughes Medical Institute, Yale University School of Medicine, 295 Congress Ave., New Haven, CT 06536., sandra.wolin{at}yale.edu (E-mail)

Communicating editor: S. SANDMEYER

ABSTRACT

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

The U6 small nuclear ribonucleoprotein is a critical componentof the eukaryotic spliceosome. The first protein that bindsthe U6 snRNA is the La protein, an abundant phosphoprotein thatbinds the 3' end of many nascent small RNAs. A complex of sevenSm-like proteins, Lsm2–Lsm8, also binds the 3' end ofU6 snRNA. A mutation within the Sm motif of Lsm8p causes Saccharomycescerevisiae cells to require the La protein Lhp1p to stabilizenascent U6 snRNA. Here we describe functional interactions betweenLhp1p, the Lsm proteins, and U6 snRNA. LSM2 and LSM4, but notother LSM genes, act as allele-specific, low-copy suppressorsof mutations in Lsm8p. Overexpression of LSM2 in the lsm8 mutantstrain increases the levels of both Lsm8p and U6 snRNPs. Inthe presence of extra U6 snRNA genes, LSM8 becomes dispensablefor growth, suggesting that the only essential function of LSM8is in U6 RNA biogenesis or function. Furthermore, deletionsof LSM5, LSM6, or LSM7 cause LHP1 to become required for growth.Our experiments are consistent with a model in which Lsm2p andLsm4p contact Lsm8p in the Lsm2–Lsm8 ring and suggestthat Lhp1p acts redundantly with the entire Lsm2–Lsm8complex to stabilize nascent U6 snRNA.

THE process of pre-mRNA splicing requires five small ribonucleoproteinparticles, the U1, U2, U4, U5, and U6 snRNPs. These small RNPsassociate with each other, with the mRNA, and with a large numberof splicing factors to form the spliceosome (reviewed by BURGEet al. 1998 ). The U1, U2, U4, and U5 snRNPs each consist ofan RNA molecule, seven common proteins known as Sm proteins,and additional snRNP-specific proteins. In vertebrates, bindingof the Sm proteins to the snRNA occurs in the cytoplasm andis required for hypermethylation of the 5' cap structure andreimport of the snRNPs into the nucleus (KAMBACH et al. 1999A). All Sm proteins share a conserved Sm motif consisting oftwo short submotifs, Sm1 and Sm2. The crystal structures oftwo Sm heterodimers have revealed that the Sm motif folds intoan N-terminal ${alpha}$ -helix, followed by a five-stranded antiparallelß sheet (KAMBACH et al. 1999B ). From these structures,a model has been proposed in which the seven Sm proteins interactvia their Sm motifs to form a heptameric ring around the snRNA(KAMBACH et al. 1999B ).

In addition to the canonical Sm proteins, other Sm motif-containingproteins have been identified in many eukaryotes and certainarchaebacteria (COOPER et al. 1995 ; HERMANN et al. 1995 ; SERAPHIN 1995 ; FROMONT-RACINE et al. 1997 ; ACHSEL et al.1999 ; MAYES et al. 1999 ; SALGADO-GARRIDO et al. 1999 ).In yeast, there are nine of these Sm-like proteins (named Lsm1–Lsm9for Like Sm). Two distinct heptameric complexes of these Sm-likeproteins have been described. One complex, consisting of theLsm2–Lsm8 proteins, binds to the 3' end of the U6 snRNAand is required for the stable accumulation of U6 snRNPs (PANNONEet al. 1998 ; ACHSEL et al. 1999 ; MAYES et al. 1999 ; SALGADO-GARRIDOet al. 1999 ; VIDAL et al. 1999 ). A second complex, consistingof the Lsm1–Lsm7 proteins, functions in mRNA degradation,most likely at the decapping step (BOECK et al. 1998 ; BOUVERETet al. 2000 ; THARUN et al. 2000 ). The Lsm2–Lsm8 complexwas recently purified from human cells and found to resemblea doughnut, similar in size and shape to the core Sm snRNPs(ACHSEL et al. 1999 ). This finding, coupled with the fact thateach of the Lsm2–Lsm8 proteins can be specifically alignedwith one of the bona fide Sm proteins (FROMONT-RACINE et al.1997 ; SALGADO-GARRIDO et al. 1999 ), suggests that the Lsmproteins assemble into analogous heptameric ring structures.The order of the Lsm2–Lsm8 proteins within the ring isunknown.

Although the Lsm2–Lsm8 complex binds the 3' end of U6RNA and is required for the stable accumulation of U6 snRNPs,the precise role of this complex in U6 biogenesis and functionis unknown. The first protein known to bind U6 RNA is the Laprotein, an abundant nuclear phosphoprotein that binds and stabilizesmany newly synthesized small RNAs (RINKE and STEITZ 1982 , RINKE and STEITZ 1985 ; PANNONE et al. 1998 ; KUFEL et al.2000 ; XUE et al. 2000 ). The La protein binds the UUU_OH atthe 3' end of these RNAs (STEFANO 1984 ), which, for U6 RNA,overlaps the binding site of the Lsm2–Lsm8 complex (ACHSELet al. 1999 ; VIDAL et al. 1999 ). Thus, binding by the Lsm2–Lsm8complex to the 3' end of U6 RNA may displace the La protein.Consistent with this idea, yeast cells containing a mutationin LSM8 require Lhp1p, the yeast La protein homologue, to stabilizenewly synthesized U6 RNA (PANNONE et al. 1998 ). However, itis unclear whether mutations in other Lsm proteins cause cellsto require Lhp1p.

To better understand the functions of individual members ofthe Lsm2–Lsm8 complex, we examined the genetic interactionsbetween Lhp1p, U6 RNA, and the Lsm proteins in the yeast Saccharomycescerevisiae. We report that LSM2 and LSM4 function as allele-specificsuppressors of two mutations in LSM8, consistent with the speculation(HE and PARKER 2000 ; PANNONE and WOLIN 2000 ) that Lsm2p andLsm4p directly contact Lsm8p in the Lsm2–Lsm8 ring. Consistentwith a direct interaction, overexpression of LSM2 in the lsm8-1mutant strain increases the levels of the mutant Lsm8 protein.In the presence of high levels of U6 RNA, the normally essentialLSM8 becomes dispensable for growth, indicating that the onlyessential function of LSM8 is in U6 RNA biogenesis and/or stability.Furthermore, deletions of LSM5, LSM6, or LSM7, but not LSM1,are synthetically lethal with deletions of LHP1. Our experimentssupport the idea (ACHSEL et al. 1999 ) that Lhp1p acts redundantlywith the assembled Lsm2–Lsm8 complex to stabilize newlysynthesized U6 RNA.

MATERIALS AND METHODS

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ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Yeast media, strains, and plasmids:
Yeast media and manipulations were as described in SHERMAN1991 . The strains used in this study are listed in Table 1.The lsm1 ${Delta}$ strain (DIEZ et al. 2000 ) was a gift of P. Ahlquist(University of Wisconsin).

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Table 1. Yeast strains used in this study

Synthetic lethal screen:
The synthetic lethal screen was performed as described by PANNONEet al. 1998 with the following modifications. CY2 cells carryingpATL, a centromeric plasmid containing LHP1, TRP1, and ADE2(PANNONE et al. 1998 ), were mutagenized with ethylmethane sulfonateto 15% survival and plated on synthetic complete media containinglimiting amounts of adenine (SCiade). Colonies were screenedat 25° for the inability to lose pATL and form red sectors.Of 185,000 colonies screened, 68 did not form red sectors. Thesecandidates were transformed with a second plasmid, pSLL28 (YOOand WOLIN 1997 ), which contains LHP1, URA3, and LYS2, and testedfor the ability to lose pATL. Forty-nine candidates were ableto form sectoring colonies. Of the 49 that sectored, 15 weredead on media containing 1 µg/ml 5-fluoroorotic acid,indicating they could not lose pSLL28. Backcrossing to CY4 revealedthat five strains carried a single recessive mutation that causedthem to require pATL. Complementation analysis with BP2 demonstratedthat one strain failed to complement the lsm8-1 mutation. Thisstrain was backcrossed three times to CY2 to generate BP26aand BP26 ${alpha}$ . The characterization of the other strains will bepresented elsewhere (S. D. KIM and S. L. WOLIN, unpublishedresults).

Subcloning LSM genes into pRS316:
Each LSM gene was subcloned into pRS316 (CEN, URA3; SIKORSKIand HIETER 1989 ) as described below. Plasmids carrying theLSM3, LSM5, LSM6, and LSM7 genes fused to two IgG-binding domainsof Staphylococcus aureus protein A (PrA) were gifts of B. Seraphin(SERAPHIN 1995 ; SALGADO-GARRIDO et al. 1999 ). The plasmidpBS959 was digested with BamHI and HindIII and the LSM5-PrA-containingfragment was subcloned into the same sites of pRS316 to createpLSM5-PrA. The plasmid pBS1296 was digested with BamHI and SacIand the fragment containing LSM6-PrA was ligated into the BamHI-SacIsites of pRS316 to create pLSM6-PrA. The plasmid pBS957 wasdigested with BamHI and HindIII and the fragment containingLSM7-ProtA was subcloned into the BamHI-HindIII sites of pRS316to create pLSM7-PrA. The plasmid pBS867 contains LSM3-PrA invector pRS316. To create untagged versions, PCR was used toamplify the LSM genes from plasmids pLSM5-PrA, pLSM6-PrA, pLSM7-PrA,and pBS867. In each case, the oligonucleotide used to amplifythe 3' portion of each LSM gene introduced a stop codon at theend of the LSM coding sequence. The resulting DNAs were clonedinto the BamHI-EcoRI sites of pRS316 to create pLSM3, pLSM5,pLSM6, and pLSM7. Plasmid pSDB23-1 (COOPER et al. 1995 ; a giftfrom J. Beggs) was digested with HindIII and the 1.4-kb fragmentcontaining LSM4 was subcloned into the HindIII site in pRS316to create pLSM4. Plasmid pJD09 (a gift from P. Ahlquist, Universityof Wisconsin) was digested with HindIII and EcoRI and the 1.5-kbLSM1 fragment was subcloned into the HindIII-EcoRI sites ofpRS316 to create pLSM1. Plasmids p22U and pSNPU (PANNONE etal. 1998 ) contain the LSM8 and LSM2 genes, respectively, inpRS316. pLSM1, pSNPU, pBS867, pLSM4, pLSM5, pLSM6, pLSM7, p22U,pRS426-SNR6 (a gift from D. Brow, University of Wisconsin),and pRS316 were transformed individually into strains BP5 andBP8.

Anti-Lsm8p antibody synthesis:
Anti-Lsm8p peptide antibodies were generated by AnaSpec. A C-terminalLsm8p peptide (H-Cys-Asn-Lys-Ile-Glu-Asn-Glu-His-Val-Ile-Trp-Glu-Lys-Val-Tyr-Glu-Ser-Lys-Thr-Lys-OH)was conjugated to BSA and injected into rabbits. The antiserawas affinity purified against the peptide following the fifthbleed.

Native gels, Northern blots, and oligonucleotides:
Extracts were prepared by vortexing 5 OD₆₀₀ units of cells in4 volumes of buffer A (50 mM Tris HCl pH 7.5, 25 mM NaCl, 5mM MgCl₂) with 0.25 µM phenylmethylsulfonyl fluoride inthe presence of glass beads. The extract was sedimented at 100,000x g in a Beckman TLA100 rotor for 20 min. A total of 0.1 OD₂₆₀units of each supernatant was mixed with an equal volume ofbuffer A containing 8% glycerol and loaded on a 4% polyacrylamidegel (80:1 acrylamide:bis) in 25 mM Tris, 25 mM boric acid, and1 mM EDTA that had been prerun at 250 V for 30 min at 4°.Gels were run at 300 V until the bromophenol blue dye reachedthe bottom. RNA was transferred to ZetaProbe GT membranes (Bio-Rad)in 0.5x TBE at 150 mA for 16 hr. Hybridization with [ ${gamma}$ -³²P]ATP-labeledoligonucleotides was done as described by TARN et al. 1995. Oligonucleotides used were U4: 5'-AGGTATTCCAAAAATTCCCTAC-3'and U6D2: 5'-CGAAATAAATCTCTTTGTAAAACGG-3'.

Disruption of the LSM5, LSM6, and LSM7 genes:
To disrupt LSM5, the HIS3 gene from pRS313 (SIKORSKI and HIETER1989 ) was amplified using forward and reverse primers thatcontained 45 and 49 nucleotides (nt) of LSM5 sequence at their5' ends, respectively. This PCR product was transformed intoCYY0, where it replaced one allele of the LSM5 open readingframe with HIS3, leaving only 11 nt of LSM5 coding sequenceat the 5' terminus and 13 nt at the 3' terminus. This generatedstrain DNY8. To disrupt LSM6, the URA3 gene from pRS316 (SIKORSKIand HIETER 1989 ) was amplified using forward and reverse primersthat contained 39 and 53 nt of LSM6 sequence at their 5' ends,respectively. This PCR product was transformed into CYY0 whereit replaced one allele of LSM6 with URA3, leaving only 17 ntof LSM6 coding sequence at the 5' terminus and 15 nt at the3' terminus. This generated strain DNY4. To disrupt LSM7, theTRP1 gene from pRS314 (SIKORSKI and HIETER 1989 ) was amplifiedusing forward and reverse primers that contained 48 and 50 ntof LSM7 sequence at their 5' ends, respectively. This PCR productwas transformed into CYY0 where it replaced one allele of LSM7with TRP1, leaving 10 nt of LSM7 coding sequence at both the5' and 3' termini. This generated strain DNY9.

RESULTS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Allele-specific suppression of lsm8 mutations by Lsm proteins:
To identify additional mutations that cause cells to requireLHP1, we performed a genetic screen using a previously describedstrategy (PANNONE et al. 1998 ; XUE et al. 2000 ). An ade2strain lacking LHP1 in the genome, but containing LHP1, ADE2,and TRP1 on a centromeric plasmid, was mutagenized with ethylmethanesulfonate and screened for the inability to lose the plasmid.As a red pigment accumulates in ade2 strains, cells that losethe plasmid are red, while cells that retain it are white. Todetermine if any mutants were allelic to previously isolatedmutations (YOO and WOLIN 1997 ; PANNONE et al. 1998 ; XUEet al. 2000 ), we performed complementation analyses. Each mutantstrain was mated to our previously isolated mutant strains,and the diploids were tested for the ability to lose the LHP1-containingplasmid. One strain, which we refer to as lsm8-2, failed tocomplement the lsm8-1 strain. Sequencing of LSM8 in the strainrevealed a single base change that converted the tryptophanat position 119 to a stop codon. Because the requirement forLHP1 in this strain could be complemented by a low-copy plasmidcontaining LSM8, we conclude that the requirement for LHP1 isdue to truncation of Lsm8p. The positions of the lsm8-1 andlsm8-2 mutations are shown in Fig 1. Similar to the lsm8-1strain (PANNONE et al. 1998 ), the lsm8-2 strain was slightlycold sensitive for growth (data not shown).

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Figure 1. Sequence of Lsm-8p. The sites of the lsm8-1 and lsm8-2 mutations are indicated, as is the sequence of the peptide used to generate anti-Lsm8p antibodies. The positions of the ${alpha}$ -helix and five ß-strands that make up the Sm motif are modeled on the crystal structures of the SmD₃B and SmD₁D₂ heterodimers (KAMBACH et al. 1999B

Previously, we identified LSM2, which encodes another Sm-likeU6 snRNP protein, as a low-copy suppressor of the lsm8-1 mutation(PANNONE et al. 1998 ). To determine whether other Sm-like proteinswere able to eliminate the requirement for LHP1, we performedsuppression analyses. Each of the LSM1–LSM8 genes wassubcloned into the low-copy plasmid pRS316 and tested for theability to eliminate the requirement for LHP1 in the lsm8 strains.For these experiments, we used lsm8 mutant strains that containedLHP1 under control of the MET3 promoter. Because the MET3 promoteris repressed by high concentrations of methionine (CHEREST etal. 1987 ), the lsm8 strains are unable to grow on plates containing2 mM methionine (not shown, but see Fig 2A and Fig B). Inour initial experiments, LSM3, LSM5, LSM6, and LSM7 were testedas fusion proteins, as we used plasmids in which the C terminusof each coding sequence was fused to two IgG-binding domainsof the S. aureus protein A (PrA; SALGADO-GARRIDO et al. 1999). For the lsm8-1 mutant strain, introduction of either LSM2,LSM3-PrA, or LSM8 on the low-copy plasmid eliminated the requirementfor LHP1 (Fig 2A), as these strains were able to grow on highmethionine-containing media. Overexpression of LSM1, LSM4, LSM5-PrA,LSM6-PrA, LSM7-PrA, or the parent vector failed to eliminatethe requirement for LHP1, although the background growth wasreproducibly higher in the presence of extra copies of LSM4(Fig 2A).

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Figure 2. Extra copies of certain LSM genes or U6 snRNA eliminate the requirement for LHP1 in lsm8 mutants. Plasmids containing the indicated LSM or LSM-PrA genes in the low-copy plasmid pRS316 were introduced into lhp1::LEU2 strains carrying the lsm8-1 (A) or lsm8-2 (B) mutation. The strains also contained the pMETLHP1 plasmid (PANNONE et al. 1998

) in which LHP1 is under the control of the MET3 promoter. Cells were streaked to single colonies on medium containing 2 mM methionine, which represses the MET3 promoter (CHEREST et al. 1987

), and grown at 25°. As controls, strains were transformed with the pRS316 vector. To determine whether multiple U6 RNA genes would eliminate the requirement for LHP1, the lsm8 strains were transformed with SNR6 in the high-copy plasmid pRS426. Introduction of pRS426 had no effect on the requirement for LHP1 in lsm8-1 (PANNONE et al. 1998

) or lsm8-2 cells (data not shown).

To determine whether the protein A tags affected the abilityof LSM3 and LSM5-7 to suppress the lsm8 mutations, each of thesegenes was cloned without the tag into pRS316 and tested in themutant strains. This revealed that, while the LSM3-PrA fusionsuppressed the requirement for LHP1, wild-type LSM3 did not(Fig 2A, fourth panel). Similar to the result obtained withthe PrA fusions, the wild-type LSM5-LSM7 failed to suppressthe requirement for LHP1 in the mutant strain (data not shown).

Interestingly, the second lsm8 mutant allele, lsm8-2, exhibiteda different pattern of suppression by LSM genes. Neither LSM2,LSM3, or LSM3-PrA, when present on the low-copy plasmid, allowedthe mutant cells to grow on the 2-mM methionine medium (Fig 2B,also data not shown). In contrast, expression of LSM4 allowedsome growth, although less than when LSM8 was expressed in themutant cells (Fig 2B). Thus, while both LSM2 and LSM3-PrA areable to suppress the requirement for LHP1 in the lsm8-1 mutantcells, only LSM4 partially suppresses the LHP1 requirement inthe lsm8-2 cells. However, as previously reported for the lsm8-1allele (PANNONE et al. 1998 ), expression of U6 snRNA on thehigh-copy plasmid pRS426 eliminates the LHP1 requirement ofthe lsm8-2 strain (Fig 2B, pSNR6 sector). Thus, despite thedifferences in suppression of the two alleles by LSM genes,at least part of the requirement for LHP1 in both strains islikely due to defects in U6 snRNP biogenesis or stability.

Extra copies of LSM2 and LSM3-PrA increase pre-mRNA splicing efficiency in the lsm8-1 mutant strain:
To explore the mechanism by which extra copies of LSM and U6genes eliminated the requirement for Lhp1p, we created lsm8strains in which LHP1 was replaced by extra copies of thesegenes. We started with lsm8 ade2 strains in which the only copyof LHP1 was supplied on an ADE2-containing plasmid. These strainsare white as long as the ADE2 plasmid is present. Followingtransformation with plasmids containing LSM or U6 RNA genes,the strains were screened for the ability to lose the LHP1 andADE2-containing plasmid and form colonies with red sectors.In the presence of either LSM2 or LSM3-PrA on a centromericplasmid, or SNR6 on a high-copy plasmid, the lsm8-1 strainswere able to lose the LHP1-containing plasmid. However, whenLSM4 was expressed in the lsm8-2 strain, the strain was unableto lose the LHP1 plasmid and remained white, suggesting thatat least a low level of LHP1 expression was required for efficientgrowth. Thus, while expression of LSM4 allows lsm8-2 strainsto grow under conditions where LHP1 transcription is repressed(Fig 2B), it may not completely eliminate the requirement forLHP1. Even though the MET3 promoter is tightly regulated bymethionine (CHEREST et al. 1987 ), a small amount of Lhp1p maystill be synthesized under repressive conditions.

Since the lsm8-1 mutation results in a pre-mRNA splicing defect(PANNONE et al. 1998 ), we determined whether extra copies ofLSM2 and LSM3-PrA increased the efficiency of pre-mRNA splicingin the mutant strains. Total RNA was extracted from each strainand subjected to Northern analysis to detect the U3 small nucleolarRNA, since this RNA contains an mRNA-type intron (MYSLINSKIet al. 1990 ). As previously described (PANNONE et al. 1998), cells containing the lsm8-1 mutant allele accumulate unsplicedpre-U3 RNA (Fig 3A, lane 3). In the presence of extra copiesof LSM2 or LSM3-PrA, the splicing defect was less evident (lanes4 and 5), consistent with the finding that these genes functionas low-copy suppressors of the lsm8-1 mutation. However, whileextra copies of SNR6 also allow lsm8-1 cells to grow in theabsence of LHP1, only a slight decrease in pre-U3 RNA was detectedin this strain (lane 7). Thus, while extra copies of LSM2, LSM3-PrA,and SNR6 all allow lsm8-1 cells to grow in the absence of LHP1,LSM2 and LSM3-PrA are more efficient at suppressing the pre-mRNAsplicing defect than is SNR6.

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Figure 3. In the presence of extra copies of LSM2, pre-mRNA splicing in the lsm8-1 strain is more efficient and the levels of Lsm8p increase. (A) Total RNAs isolated from wild-type cells (lane 1), lhp1::LEU2 cells (lane 2), lsm8-1 cells containing chromosomal LHP1 (lane 3), lsm8-1 lhp1::LEU2 cells containing the indicated LSM genes in the low-copy plasmid pRS316 (lanes 4–6) or SNR6 in the high-copy plasmid pRS426 (lane 7) were subjected to Northern analysis and probed to detect U3 RNA. The asterisk indicates a degradation product of pre-U3 RNA (HUGHES and ARES 1991

). (B) Extracts of wild-type (lane 1), lsm8-1 cells containing chromosomal LHP1 (lane 2), and lsm8-1 cells containing LHP1 on a centromeric plasmid (lane 3) were analyzed for the presence of Lsm8p by Western blotting with anti-Lsm8p antibodies. To verify that the detected band was Lsm8p, lane 4 contains extract from a strain in which three copies of the human c-myc epitope (KOLODZIEJ and YOUNG 1991

) were fused to the C terminus of Lsm8p. (C) Extracts of wild-type cells (lane 1), lhp1::LEU2 cells (lane 2), lsm8-1 cells containing chromosomal LHP1 (lane 3), and lsm8-1 lhp1::LEU2 cells containing either the indicated LSM genes in the low-copy plasmid pRS316 (lanes 4–6) or SNR6 in the high-copy plasmid pRS426 (lane 7) were subjected to Western blotting to detect Lsm8p.

The level of the lsm8-1 protein increases in the presence of extra copies of LSM2:
To understand how extra copies of LSM2, LSM3-PrA, and SNR6 suppressthe requirement for Lhp1p in lsm8-1 cells, we examined the levelsof Lsm8p in the various strains. To this end, we prepared antibodiesagainst the C-terminal 19 amino acids of Lsm8p and performedprotein immunoblots (Fig 3B). The antibodies detected a polypeptideof 14 kD in wild-type extracts (lane 1), consistent with thepredicted molecular weight of 14.5 kD. This band was greatlyreduced in extracts from lsm8-1 mutant cells (lanes 2 and 3).To confirm the identification of the 14-kD protein as Lsm8p,we examined extracts from a strain in which three copies ofthe human c-myc epitope were fused to the C terminus of Lsm8p(PANNONE et al. 1998 ). As expected, the 14-kD band was replacedby a band of $~$ 20 kD (lane 4). Because the mutation in lsm8-2cells truncates Lsm8p, we were unable to detect Lsm8p in thesecells with the antibody against the C terminus (data not shown).

We next determined the levels of Lsm8p in the lsm8-1 mutantstrains. In the presence of the LSM2-containing plasmid, thelevels of the mutant Lsm8p increased, although not to wild-typelevels (Fig 3C, compare lanes 3 and 4). Expression of LSM3-PrAon the centromeric plasmid did not result in a significant increasein the levels of Lsm8p (lane 5), while LSM8 restored Lsm8p towild-type levels (lane 6), as expected. Curiously, in the presenceof extra copies of SNR6, the mutant Lsm8p was further reduced(lane 7). Thus, expression of LSM2, but not LSM3-PrA or SNR6,in the lsm8-1 mutant strain results in an increase in the steady-statelevel of the mutant protein. Although we have not establishedthe molecular mechanism by which this occurs, we note that Lsm8pand Lsm2p interact strongly in two-hybrid analyses (FROMONT-RACINEet al. 1997 , FROMONT-RACINE et al. 2000 ; MAYES et al. 1999; UETZ et al. 2000 ) and that these proteins have been proposedto be adjacent in the Lsm2–Lsm8 complex (HE and PARKER2000 ; PANNONE and WOLIN 2000 ). Thus, binding of Lsm2p toLsm8p may stabilize the mutant Lsm8 protein.

LSM8 is not essential in the presence of multiple U6 RNA genes:
The observation that the levels of the mutant Lsm8p were drasticallyreduced in the presence of extra copies of SNR6 was surprising,since LSM8 is essential for yeast viability (FROMONT-RACINEet al. 1997 ; PANNONE et al. 1998 ). We thus determined whetherLSM8 becomes dispensable for growth in the presence of multiplecopies of SNR6. We transformed the high-copy plasmid containingSNR6, or the empty vector alone, into a diploid strain in whichone allele of LSM8 was replaced with HIS3 (PANNONE et al. 1998). In the presence of the empty vector, sporulation of the diploidand tetrad dissection yielded only two viable segregants pertetrad (Fig 4A), all of which required histidine for growth(data not shown). However, when SNR6 was present on the high-copyplasmid, tetrad dissection yielded two, three, or four viablesegregants per tetrad (Fig 4B). A total of 26 tetrads were dissected.In all cases, two segregants per tetrad were auxotrophic forhistidine, indicating that they contained the wild-type LSM8gene. In addition, 12 tetrads contained one or two additionalviable progeny, all of which were His⁺. The His⁺ segregantswere variable in size (arrowheads, Fig 4B), but tended to besmaller than the segregants containing LSM8. One explanationfor the size variation may be that the lsm8::HIS3 progeny containdifferent numbers of the SNR6 plasmid, since the copy numberof these plasmids ranges from 10 to 40 per cell (SHERMAN 1997). Consistent with this, in all tetrads that contained onlytwo viable segregants, the cells required both histidine anduracil for growth, revealing that they also lacked the SNR6-containingplasmid. Thus, those diploid cells that gave rise to only twohis^- ura^- progeny may have lost the SNR6 plasmid during sporulation.Nonetheless, the fact that a large fraction of the tetrads yieldedviable His⁺ progeny reveals that LSM8 is dispensable for growthin the presence of multiple copies of SNR6. This result stronglysuggests that the only essential function of Lsm8p is in U6snRNP biogenesis or stability.

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Figure 4. LSM8 is dispensable in cells containing multiple U6 snRNA genes. Either the high-copy vector pRS426 (A) or SNR6 cloned into pRS426 (B) was introduced into lsm8::HIS3/LSM8 diploids. Following sporulation at 25°, the resulting tetrads were dissected and incubated at 30°. Arrowheads indicate segregants carrying the lsm8::HIS3 allele.

U6 snRNP levels in lsm8-1 cells are increased by extra copies of LSM2:
To further examine the mechanism by which extra copies of LSM2,LSM3-PrA, and SNR6 suppress the requirement for Lhp1p in lsm8-1cells, we examined the various U6 RNA-containing particles.We fractionated whole-cell extracts from wild-type and lsm8-1strains using native gel electrophoresis and detected the U6and U4 RNA-containing particles using Northern hybridization(Fig 5). Four distinct U6 RNA-containing complexes are presentin wild-type extracts: the U4/U6.U5 tri-snRNP, the U4/U6 snRNP,the free U6 snRNP, and the Lhp1p/U6 RNA complex (Fig 5A, lane1). As previously described (PANNONE et al. 1998 ), the freeU6 snRNP is undetectable in lsm8-1 cells carrying chromosomalLHP1, and both the U4/U6 complex and U4/U6.U5 tri-snRNP aredrastically reduced (lane 3). In addition, free U4 snRNPs accumulatein the mutant strain, consistent with a defect in U6 snRNP assembly(Fig 5B, lane 3; also PANNONE et al. 1998 ). When the solecopy of LHP1 is supplied on a centromeric plasmid (which raisesthe levels of Lhp1p two- to threefold), the levels of the U4/U6.U5tri-snRNP increase, consistent with the presence of more functionalU6 snRNPs in this strain (Fig 5A, lane 4; also PANNONE et al.1998 ). Interestingly, expression of extra copies of LSM2 (lane5), but not LSM3-PrA (lane 6), in the lsm8-1 strain resultedin a large increase in the levels of U6-containing snRNPs anda decrease in the levels of free U4 snRNPs. In the presenceof the LSM2 plasmid, both the tri-snRNP and U4/U6 snRNP levelsincreased to $~$ 90% of wild-type levels and mature U6 snRNPs becamedetectable (Fig 5A, lane 5). However, while the LSM3-PrA plasmidalso eliminated the requirement of lsm8-1 cells for LHP1, theonly detectable change from the lsm8-1 LHP1 extracts was a smallincrease in the levels of the U4/U6 snRNPs (Fig 5A; comparelanes 3 and 6), with a concomitant decrease in the free U4 snRNPs(Fig 5B, lane 6). Thus, while both LSM2 and LSM3-PrA suppressthe requirement for LHP1, only LSM2 restores the levels of U6-containingsnRNPs in lsm8-1 cells to near wild-type levels.

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Figure 5. The levels of the free U6 snRNP increase when LSM2 is overexpressed in the lsm8-1 strain. Extracts from wild-type cells (lane 1), lhp1::LEU2 cells (lane 2), lsm8-1 cells containing chromosomal LHP1 (lane 3), lsm8-1 cells containing LHP1 on a centromeric plasmid (lane 4), and lsm8-1 lhp1::LEU2 cells containing either LSM2 (lane 5), LSM3-PrA (lane 6), or LSM8 (lane 7) in the centromeric plasmid pRS316 were fractionated in 4% polyacrylamide gels and subjected to Northern analysis. The blot was probed with an oligonucleotide complementary to U6 snRNA (A) or U4 snRNA (B). Lane 8 contains extract from lsm8-1 lhp1::LEU2 cells containing SNR6 in the high-copy plasmid pRS426. The asterisk denotes the position at which naked U6 RNA migrates on these gels (data not shown).

Expression of the high-copy plasmid containing SNR6 in the lsm8-1strain also did not significantly increase the level of theU4/U6.U5 tri-snRNP (Fig 5A and Fig B, lane 8). Instead, a heterogeneoussmear of U6 RNA-containing particles migrated both with andahead of the U4/U6 snRNP (lane 8). The smallest detectable band(asterisk, lane 8) comigrated with free U6 snRNA (data not shown).However, probing the blot to detect U4 RNA revealed that U4/U6snRNP levels were restored to near wild-type levels (Fig 5B,lane 8). Thus, in the presence of additional copies of SNR6,U6 RNA assembles with U4 RNA to form the U4/U6 snRNP. However,assembly with the U5 snRNP remains impaired in the mutant strain.

LHP1 is essential in strains lacking LSM5, LSM6, or LSM7:
Since our synthetic lethal screens identified two lsm8 allelesthat cause yeast to require LHP1, but did not reveal mutationsin other LSM genes, we asked whether mutations in other componentsof the Lsm2–Lsm8 complex would cause a requirement forLhp1p. LSM2, LSM3, and LSM4 are all essential for viability(COOPER et al. 1995 ; MAYES et al. 1999 ; SALGADO-GARRIDOet al. 1999 ), and nonlethal mutations in these genes have notbeen described. However, LSM6 and LSM7 are both nonessentialgenes (MAYES et al. 1999 ; SALGADO-GARRIDO et al. 1999 ), andLSM5 has been reported to be both essential (MAYES et al. 1999) and nonessential (SALGADO-GARRIDO et al. 1999 ). To determinewhether LHP1 becomes essential in cells lacking one of thesegenes, we disrupted the genes encoding LSM5, LSM6, and LSM7in a LHP1/lhp1::LEU2 diploid strain. When our diploid strain(lsm5::HIS3/LSM5, lhp1::LEU2/LHP1) was sporulated at 25°,followed by incubation of the dissected spores at 30°, weobtained two viable segregants per tetrad (Fig 6A, left), consistentwith the report that LSM5 is essential (MAYES et al. 1999 ).However, when the dissected spores were incubated at 25°,we obtained tetrads containing either two, three, or four viableprogeny (Fig 6A, right). In all cases, two segregants were largeand lacked the LSM5 disruption marker. The remaining progenywere all small (Fig 6A) and His⁺, indicating that they containedthe disrupted LSM5 gene. Thus, at 25°, segregants lackingLSM5 are viable in our strain background. Examination of theleucine requirement revealed that all His⁺ progeny requiredleucine for growth, indicating that they contained the wild-typeLHP1 allele. Furthermore, all double mutants containing boththe lhp1::LEU2 and lsm5::HIS3 alleles were dead (as deducedfrom the genotypes of the live segregants in each tetrad). Thus,LHP1 is required for viability in strains lacking LSM5. Similarly,sporulation of the lsm6::URA3/LSM6 lhp1::LEU2/LHP1 (data notshown) and lsm7::TRP1/LSM7 lhp1::LEU2/LHP1 (Fig 6B) diploidsand tetrad dissection revealed that LHP1 was also required forviability in strains lacking either LSM6 or LSM7.

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Figure 6. Mutations in other components of the Lsm2p–Lsm8p complex cause yeast cells to require LHP1. (A) An lsm5::HIS3/LSM5, lhp1::LEU2/ LHP1 diploid was sporulated at 25°, and the resulting tetrads dissected and incubated at either 30° (left) or 25° (right). At 30°, only two viable progeny were recovered per tetrad, all of which were auxotrophic for histidine. At 25°, tetrads contained two, three, or four viable progeny. In all cases, two haploid spores gave rise to two large colonies that were auxotrophic for histidine. The additional colonies were all small, His⁺, and required leucine for growth. (B) An lsm7::TRP1/LSM7, lhp1::LEU2/LHP1 diploid was sporulated at 25°, and the resulting tetrads dissected and incubated at 25°. All tetrads gave rise to two large colonies that required tryptophan for growth. In addition, some tetrads also gave rise to small colonies, all of which were Trp⁺ and required leucine for growth.

Another nonessential LSM protein, Lsm1p, associates with Lsm2–Lsm7to form a complex that participates in mRNA degradation (BOECKet al. 1998 ; BOUVERET et al. 2000 ; THARUN et al. 2000 ).To determine whether LHP1 is required in strains lacking functionalLsm1p, we mated our lhp1::LEU2 strain to a temperature-sensitivestrain carrying a large disruption within LSM1 (DIEZ et al.2000 ). Sporulation of the diploid and dissection of the resultingtetrads revealed that lsm1 mutant progeny lacking LHP1 wereable to grow at 30° (data not shown). Thus, LHP1 only exhibitsgenetic interactions with the LSM genes that encode componentsof the U6 snRNP.

DISCUSSION

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ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

In yeast, newly synthesized U6 RNA is bound and stabilized byLhp1p, the yeast La protein. Since both Lhp1p and the Lsm2–Lsm8complex bind the 3' end of U6 RNA (ACHSEL et al. 1999 ; VIDALet al. 1999 ), Lhp1p and the Lsm2–Lsm8 complex may bindconsecutively to U6 RNA during U6 snRNP assembly (PANNONE etal. 1998 ; ACHSEL et al. 1999 ). However, while Lhp1p and otherLa proteins preferentially bind RNAs terminating with UUU_OH(STEFANO 1984 ; TERNS et al. 1992 ; YOO and WOLIN 1994 ),mature U6 RNA ends with either a 2',3'-cyclic phosphate (inmammals) or a 3' monophosphate (in yeast; LUND and DAHLBERG1992 ). Thus, while either Lhp1p or the Lsm2–Lsm8 complexcan bind the nascent transcript, mature U6 RNA will only bebound by the Lsm2–Lsm8 complex. Consistent with the ideathat either Lhp1p or the Lsm2–Lsm8 complex can bind nascentU6 RNA, Lhp1p is not required for U6 RNA biogenesis in otherwisewild-type yeast. However, Lhp1p becomes required to stabilizenewly synthesized U6 RNA when cells contain a mutation in Lsm8p(PANNONE et al. 1998 ). Our experiments reveal that mutationsin at least four LSM genes (LSM5, LSM6, LSM7, and LSM8) causecells to require Lhp1p. Thus, the requirement for Lhp1p maybe caused by any mutation that slows or impairs binding of theLsm2–Lsm8 complex to U6 RNA. In this situation, Lhp1pmay be required to stabilize newly synthesized U6 RNA, thusallowing assembly of the U6 snRNP.

Our result that LSM8 becomes dispensable for growth in the presenceof excess U6 RNA genes strongly suggests that the only essentialfunction of the Lsm2–Lsm8 complex is in U6 snRNA metabolism.Consistent with these results, it was previously demonstratedthat U6 snRNA overproduction suppressed the growth defect causedwhen a strain harboring a GAL1-regulated copy of LSM8 was grownon glucose-containing medium (MAYES et al. 1999 ). However,in these experiments, it could not be ruled out that a smallamount of Lsm8p (due to incomplete depletion and/or leakinessof the GAL1 promoter) was required for viability. The fact thatLSM8 can be deleted in the presence of extra U6 snRNA genesestablishes that the requirement for Lsm8p in U6 biogenesisand function can be bypassed as long as sufficient U6 RNA ispresent. Furthermore, the fact that Lsm8p becomes undetectablein the presence of excess U6 snRNA (Fig 3) suggests that cellsmay possess mechanisms for downregulating LSM8 expression inresponse to increased U6 RNA levels.

Although the human Lsm2–Lsm8 complex forms a ring of similarsize and shape to the core Sm snRNPs, the order of the individualsubunits around the rings is unknown. From the crystal structuresof two Sm protein heterodimers, together with data from biochemicalfractionation and two hybrid experiments, a model has been proposedin which specific Sm proteins interact with one another throughtheir Sm motifs to form a heptameric ring (KAMBACH et al. 1999B). Because each of the Lsm2–Lsm8 proteins can be alignedwith one of the Sm proteins (FROMONT-RACINE et al. 1997 ; SALGADO-GARRIDOet al. 1999 ), Lsm proteins may interact in an analogous fashion(HE and PARKER 2000 ; PANNONE and WOLIN 2000 ; diagrammed in Fig 7). In this model, Lsm8p contacts Lsm2p and Lsm4p. We havedemonstrated that both Lsm8p and U6 snRNP levels increase whenLsm2p is overexpressed in cells carrying a mutation in the Smmotif of Lsm8p. These findings are consistent with the specificinteraction of these proteins within the Lsm2–Lsm8 complex.Our result that Lsm4p, when overexpressed in yeast carryinga truncation of Lsm8p, partially suppresses the requirementfor Lhp1p is consistent with the idea that Lsm4p and Lsm8p directlyinteract within the complex. Furthermore, the fact that LSM2does not suppress the requirement for LHP1 in the lsm8-2 truncationmutant suggests that Lsm2p may contact the C terminus of Lsm8p(in addition to the Sm motif).

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Figure 7. Functional interactions detected between LSM8 and other LSM genes. The model for the order of the Sm proteins within the heptameric ring is from KAMBACH et al. 1999B

. The order of the Lsm2–Lsm8 proteins in this heptameric ring is unknown, but has been speculated to be similar to the proposed order for the Sm ring (HE and PARKER 2000

; PANNONE and WOLIN 2000

). Arrows joined by solid lines indicate functional interactions detected between LSM8, LSM2, and LSM4. The genetic interaction between LSM3PrA and LSM8 is indicated by a dashed line.

Curiously, while LSM3-PrA is also a low-copy suppressor of thelsm8-1 mutation, Lsm3-PrAp overexpression did not increase Lsm8pand only moderately increased U4/U6 snRNP levels. Since LSM3-PrAoverexpression can substitute for LHP1 in the lsm8-1 strain,one possibility is that the excess Lsm3-PrA protein functionssimilar to Lhp1p in binding and stabilizing newly synthesizedU6 RNA. However, since we did not detect a Lsm3-PrA/U6 complexwhen the U6-containing particles were fractionated on nativegels (Fig 5), this complex would have to be considerably lessstable than the Lhp1p/U6 RNA complex. Since LSM3-PrA, but notwild-type LSM3, suppresses the requirement for LHP1, anotherpossibility is that the extra C-terminal sequences in the Lsm3-PrAfusion interact with the Lsm8p tail to stabilize or enhancethe function of the mutant Lsm2–Lsm8 complex. This enhancementof Lsm2–Lsm8 function could occur at a later stage ofthe U6 snRNP cycle, such as U4/U6 snRNP assembly or recyclingof the U6 snRNP following splicing. Consistent with an interactionwith the Lsm8p C terminus, excess Lsm3-PrA did not suppressthe requirement for Lhp1p in the lsm8-2 truncation mutant.

Interestingly, the genetic interactions that we have identifiedare far more restricted than those identified using two-hybridanalyses. In two-hybrid screens, Lsm8p interacts with each ofthe other six members of the Lsm2–Lsm7 complex (FROMONT-RACINEet al. 1997 , FROMONT-RACINE et al. 2000 ; MAYES et al. 1999; UETZ et al. 2000 ). We note that, in two-hybrid analyses,the two proteins being tested are expressed as fusion proteins.Thus, it is possible that if the fusion proteins are incorporatedinto the Lsm2–Lsm8 ring, the additional sequences appendedto one or both proteins could result in interactions that donot occur between the wild-type proteins. This scenario wouldbe compatible with the observation that Lsm3p only suppressesthe requirement for LHP1 when extra sequences are appended tothe C terminus.

Because a small fraction of yeast pre-RNase P RNA is bound bysix Sm-like proteins (Lsm2–Lsm7; SALGADO-GARRIDO et al.1999 ; B. K. PANNONE and S. L. WOLIN, unpublished data) andsmall changes in the levels of certain RNA polymerase III RNAshave been observed at late times after depletion of Lsm proteins(MAYES et al. 1999 ), it has been suggested that Sm-like proteinsmay function in the biogenesis of other small RNAs. Our resultthat LSM8 becomes dispensable when SNR6 is overexpressed revealsthat these other possible functions are not essential rolesof Lsm8p. In this regard, we note that Lsm8p, unlike Lsm2p–Lsm7p,is not detected bound to pre-RNase P RNA (SALGADO-GARRIDO etal. 1999 ; B. K. PANNONE and S. L. WOLIN, unpublished data).Thus, there may be yet another complex of Lsm proteins, distinctfrom the Lsm2–Lsm8 and Lsm1–Lsm7 complexes, thatfunctions in these other processes.

ACKNOWLEDGMENTS

We thank Doug Rubinson for help with the synthetic lethal screen.We are grateful to Bertrand Seraphin, Jean Beggs, Paul Ahlquist,and David Brow for gifts of plasmids and yeast strains. We alsothank Elisabetta Ullu for comments on the manuscript. This workwas supported by grant R01-GM48410 from the National Institutesof Health. S.L.W. is an Associate Investigator of the HowardHughes Medical Institute.

Manuscript received November 29, 2000; Accepted for publication February 13, 2001.

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