Identification of a Human Decapping Complex Associated with hUpf Proteins in Nonsense-Mediated Decay

Decapping is a key step in general and regulated mRNA decay.In Saccharomyces cerevisiae it constitutes a rate-limiting stepin the nonsense-mediated decay pathway that rids cells of mRNAscontaining premature termination codons. Here two human decappingenzymes are identified, hDcp1a and hDcp2, as well as a homologof hDcp1a, termed hDcp1b. Transiently expressed hDcp1a and hDcp2proteins localize primarily to the cytoplasm and form a complexin human cell extracts. hDcp1a and hDcp2 copurify with decappingactivity, an activity sensitive to mutation of critical hDcpresidues. Importantly, coimmunoprecipitation assays demonstratethat hDcp1a and hDcp2 interact with the nonsense-mediated decayfactor hUpf1, both in the presence and in the absence of theother hUpf proteins, hUpf2, hUpf3a, and hUpf3b. These data suggestthat a human decapping complex may be recruited to mRNAs containingpremature termination codons by the hUpf proteins.

INTRODUCTION

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Introduction

Regulation of mRNA stability plays an important role in cellularmodulation of gene expression (reviewed in references 4, 42,50, and 65). mRNAs that are normally rapidly turned over canbe stabilized upon cellular cues to cause accumulation of theprotein product. For example, in mammals many proto-oncogeneand interleukin mRNAs contain destabilizing AU-rich elements(AREs) in their 3' untranslated regions (reviewed in reference10). When the proteins are needed, specific cellular signalsoverride the ARE destabilizing elements, resulting in stabilizationof the mRNAs. mRNAs that are normally stable can also be destabilizedto repress protein expression. For example, histone mRNAs arerapidly destabilized upon exit of the cell cycle S phase whenDNA replication ceases and histone production is no longer needed(48). Proteins that regulate mRNA turnover do so by interactionwith the cellular mRNA decay machinery, a machinery which iscurrently poorly understood for mammals. To understand how mRNAturnover is regulated, it is of fundamental importance to dissectthe general mRNA decay pathways.

mRNA decapping is a key step in general and regulated mRNA decayin eukaryotes. In Saccharomyces cerevisiae the predominant pathwayof mRNA decay proceeds via slow removal of the poly(A) tailby deadenylation, followed by decapping and 5'-to-3' exonucleolyticdecay (5, 14, 25, 43, 56, 58, 59). Alternatively, deadenylatedtranscripts can be degraded from the 3' end by the exosome,a complex of 3'-to-5' exonucleases (1, 26). Although deadenylateddecapped mRNA species can be detected (12), exosome-mediatedmRNA decay may be the predominant pathway in mammalian cells(9, 45, 63).

Eukaryotes possess specific mRNA surveillance pathways thatserve to deplete the cell of irregular mRNAs (reviewed in reference61). One recently discovered mRNA surveillance process, callednonstop decay, uses an EF1A-like GTPase, Ski7, that recruitsthe exosome to degrade mRNAs that lack translation terminationcodons (20, 60). Such mRNAs are believed to arise mainly frompremature polyadenylation within the open reading frame (ORF)(20). Other irregular mRNAs, which have acquired premature terminationcodons (PTCs) by mutation or erroneous processing, are degradedby the process of nonsense-mediated decay (NMD) (reviewed inreferences 19, 23, 24, 27, 34, 36, 39, and 61). In mammals,PTCs are recognized by their position relative to the last mRNAexon-exon junction (46). Recent studies have shown that a multisubunitexon-junction complex (EJC) is deposited 20 to 24 nucleotidesupstream of exon-exon junctions after pre-mRNA splicing (32).A translation termination event upstream of one or more EJCstriggers NMD (38). This is mediated by three hUpf proteins,hUpf1, -2, and -3, which interact with both the EJC (29, 31,38) and translation termination factors eRF1 and eRF3 (13, 62).How the Upf proteins that mediate the NMD process trigger decayis largely unknown. In S. cerevisiae the first step in NMD isdecapping, which is followed by 5'-to-3' exonucleolytic decay(44).

Decapping is thus a key step in both NMD and general mRNA decay.In S. cerevisiae, two interacting proteins involved in decappinghave been identified, called Dcp1p and Dcp2p (5, 16, 30). Dcp1pappears to be responsible for the actual decapping activity,whereas Dcp2p is necessary for Dcp1p activity. Very little isknown about decapping in mammals. A decapping activity thatis activated on mRNAs lacking a poly(A) tail or containing AREshas been detected in mammalian cell extracts (6, 21). Moreover,a separate decapping activity associated with the exosome isresponsible for ridding the cell of the m7GpppN product of acomplete 3'-to-5' exonucleolytic degradation (63).

To gain insight into the process of mRNA decapping in mammals,human homologs of S. cerevisiae decapping enzymes Dcp1p andDcp2p, termed hDcp1a, hDcp1b, and hDcp2, were identified. hDcp1aand hDcp2 proteins interact with each other and coimmunopurifywith decapping activity in vitro, an activity sensitive to mutationof critical hDcp residues. Transiently expressed hDcp1a andhDcp2 localize to the cytoplasm of human HeLa cells. Moreover,hDcp1a and hDcp2 coimmunoprecipitate with the NMD protein hUpf1,providing a possible link between NMD and decapping.

MATERIALS AND METHODS

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Materials and Methods

Plasmids. Plasmids pcDNA3-FLAG-hDcp1a and pcDNA3-Myc-hDcp1a contain thefull-length ORF of hDcp1a cDNA inserted between EcoRI and NotIsites of plasmids pcDNA3-FLAG and pcDNA3-Myc, which are derivativesof pcDNA3 (Invitrogen) containing a FLAG or a Myc tag, respectively,upstream of a modified polylinker (sequences available uponrequest). pcDNA3-FLAG-hDcp1a D20A and R59A contain GAC-to-GCCand AGG-to-GCG mutations at codons 20 and 59, respectively.pcDNA3-FLAG-hDcp1a 1-411, 1-251, and 1-146 contain N-terminalfragments of hDcp1a of 411, 251, and 146 codons, respectively.pcDNA3-FLAG-hDcp2 and pcDNA3-Myc-hDcp2 contain the full-lengthORF of hDcp2 cDNA inserted between BamHI and NotI sites of pcDNA3-FLAGand pcDNA3-Myc. pcDNA3-FLAG-hDcp2 E148Q contains a GAA-to-CAAmutation at codon 148. Plasmids pcDNA3-FLAG-RNPS1, -hUpf3b,and -hUpf1 have been described earlier (37, 38). pcDNA3-Myc-hUpf1contains the hUpf1 ORF inserted between BamHI and NotI sitesof pcDNA3-Myc.

In vitro decapping assays. Human embryonic kidney 293 (HEK293) cells were grown in Dulbeccomodified Eagle medium (Invitrogen) containing 10% fetal bovineserum (Invitrogen) in 150-mm-diameter dishes and transientlytransfected with a total of 20 µg of plasmid expressingFLAG-tagged hDcp proteins, by using Lipofectamine accordingto the manufacturer's directions (Invitrogen). Forty hours aftertransfection, $~$ 2.5 x 10⁷ cells were washed and scraped in phosphate-bufferedsaline, and after pelleting, they were lysed in 1 ml of hypotonicgentle lysis buffer (10 mM Tris-HCl [pH 7.5], 10 mM NaCl, 2mM EDTA, 0.5% Triton X-100, 0.5 mM phenylmethylsulfonyl fluoride,2 µg of leupeptin/ml, 2 µg of aprotinin/ml) for10 min on ice. NaCl was added to 150 mM, and the extracts wereincubated for another 5 min on ice. Cell debris was removedby centrifugation, and the supernatant was nutated with 50 µlof anti-FLAG M2 agarose (Sigma) for 4 h at 4°C. Beads werewashed eight times with 1 ml of NET-2 (50 mM Tris-HCl [pH 7.5],150 mM NaCl, 0.05% Triton X-100), and FLAG-tagged protein waseluted by gently shaking the beads in 50 µl of NET-2 containing1 mg of FLAG peptide/ml and 0.1 mg of bovine serum albumin/mlat 4°C for 2 h. Eluates were stored at -80°C.

A 5' ^m7cap-labeled RNA substrate was produced by incubatingan 88-nucleotide T7 RNA polymerase transcript with [ ${alpha}$ -³²P]GTP,S-adenosyl-L-methionine (Sigma), and bacterially expressed vacciniavirus capping enzyme (construct kindly provided by Stewart Shuman)as described by Zhang et al. (67). Decapping reactions werecarried out at 30°C for 2 h in a total of 10 µl of50 mM Tris-HCl (pH 8.0)-30 mM (NH₄)₂SO₄-1 mM MgCl₂ containing $~$ 30 nCi of cap-labeled RNA and 0.2 to 10 µl of immunopurifieddecapping enzyme. In one experiment, the decapping reactionmixture was subsequently incubated with 0.5 mM ATP and 0.5 Uof nucleoside diphosphate kinase (Sigma) at 30°C for 30min. All reactions were terminated by addition of EDTA to 10mM, and 3 µl was separated by thin-layer chromatographyas described by Zhang et al. (67).

Coimmunoprecipitation assays. RNase-treated cell lysates of $~$ 10⁷ transiently transfected HEK293cells from one 100-mm-diameter dish, generated as describedabove, were incubated for 4 h at 4°C with 25 µl ofanti-FLAG M2 agarose (Sigma). Beads were washed 10 times withNET-2. Bound protein was eluted by incubation with 20 µlof NET-2 containing 1 mg of FLAG peptide/ml for 2 h at 4°C,followed by addition of 20 µl of sodium dodecyl sulfate(SDS) sample buffer to the eluate. In some experiments, thecell lysates were immunodepleted prior to immunoprecipitation,by incubation for 4 h at 4°C with 10 mg of protein A-Sepharose(Amersham/Pharmacia) preincubated with 40 µl of rabbitanti-hUpf serum (37), followed by clearance of the extract byincubation for 30 min at 4°C with 5 mg of protein A-Sepharose.Immunoprecipitates were separated by SDS-polyacrylamide gelelectrophoresis followed by Western blotting.

Nucleotide sequence accession numbers. GenBank accession numbers for hDcp1a, hDcp1b, and hDcp2 areAY146651, AY146652, and AY146650, respectively.

RESULTS

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Results

Human homologs of S. cerevisiae decapping enzymes. In order to understand the process of mRNA decapping in mammals,the expressed sequence tag and human genome databases were searchedfor homologs of S. cerevisiae decapping enzymes Dcp1p and Dcp2p.Two distant human homologs of S. cerevisiae Dcp1p, called hDcp1aand hDcp1b, and a single homolog of S. cerevisiae Dcp2p, calledhDcp2, were identified (Fig. 1). hDcp1a and hDcp1b each havein the N terminus two regions of 26% identity to the N and Ctermini of the 231-amino-acid S. cerevisiae Dcp1p protein, respectively(Fig. 1A). Importantly, the regions of similarity include residuesimportant for S. cerevisiae Dcp1p activity as determined byalanine mutation scanning (57). In contrast, the C-terminal $~$ 450 amino acids of hDcp1 proteins show no similarity to S. cerevisiaeDcp1p. hDcp1a and hDcp1b share 31% identity over their entirelength and 68% identity within the N-terminal conserved region.hDcp2 exhibits 36% identity to a 218-amino-acid region of S.cerevisiae Dcp2p (Fig. 1B), including a mutT domain which isessential for Dcp2p function (16). Moreover, a C-terminal regionof $~$ 50 amino acids shows 30% identity between hDcp2 and S. cerevisiaeDcp2p. hDcp1a was recently identified as a Smad4-interactingprotein, called SMIF (2), whereas hDcp1b and hDcp2 are of unknownfunction.

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FIG. 1. Human homologs of S. cerevisiae decapping enzymes. (A) Schematics of S. cerevisiae Dcp1p (yDcp1) and the human homologs hDcp1a and hDcp1b. (B) Schematics of S. cerevisiae Dcp2p (yDcp2) and the human homolog hDcp2. Gray bars indicate regions of similarity (percent identity given below) between human and S. cerevisiae Dcps. The black bars in yDcp2 and hDcp2 indicate the conserved mutT domains. Residues critical for decapping activity are indicated (see Fig. 4). aa, amino acids.

hDcp1a and hDcp2 interact in an RNA-independent manner. S. cerevisiae Dcp1p and Dcp2p are interacting proteins (16).To test if hDcp1a and hDcp2 also interact, HEK293 cells weretransiently cotransfected with plasmids expressing FLAG-taggedhDcp2 and Myc-tagged hDcp1a and, as a negative control, Myc-taggedhnRNPA1. Forty hours after transfection, cell extracts wereprepared, RNase treated, and subjected to an anti-FLAG resin.Immunoprecipitates were subsequently tested for the presenceof Myc-hDcp1a by Western blotting. As seen in Fig. 2A, $~$ 3 to4% of total Myc-hDcp1a copurifies with FLAG-hDcp2 (compare theprecipitate in lane 3 to 5% of total extract in lane 1), whereasno Myc-hDcp1a is found in immunoprecipitates from cells transfectedwith an empty vector (lane 2). Under the conditions used here,hDcp1a is expressed at about 2-fold-lower levels than hnRNPA1but at about 10- to 15-fold-higher levels than hDcp2. Therefore,about 30 to 60% of FLAG-hDcp2 is complexed with Myc-hDcp1a.In contrast, no Myc-hnRNPA1 was observed in the precipitate(lower panel). To confirm these results, Myc-tagged hDcp2 wasalso tested for copurification with FLAG-hDcp1a. In this case,about 30 to 40% of Myc-hDcp2 copurified with FLAG-hDcp1a (Fig.2B, lane 3). hDcp1a consistently appears as a doublet in denaturinggels (Fig. 2; see also Fig. 6), perhaps due to protein modification.It is concluded that hDcp1a and hDcp2 interact in an RNA-independentmanner.

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FIG. 2. hDcp1a and hDcp2 interact in cell extracts. (A) Western blot for Myc-tagged hDcp1a and hnRNPA1 proteins, which were transiently expressed in HEK293 cells together with an empty vector (lanes 1 and 2) or a plasmid encoding FLAG-tagged hDcp2 (lane 3) and subjected to anti-FLAG immunoprecipitation after RNase treatment. (B) Western blot for Myc-tagged hDcp2 and hnRNPA1 proteins, transiently expressed in HEK293 cells together with an empty vector (lanes 1 and 2) or a plasmid encoding FLAG-tagged hDcp1a (lane 3) and subjected to anti-FLAG immunoprecipitation after RNase treatment. Immunoprecipitates (P; lanes 2 and 3) are compared to 5% of total extract (T; lane 1).

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FIG. 6. hDcp1a and hDcp2 interact with the NMD protein hUpf1. (A) Western blot for Myc-tagged hDcp1a, hDcp2, or hnRNPA1, transiently expressed in HEK293 cells together with an empty vector (lanes 1 and 2) or a plasmid encoding FLAG-tagged hUpf1 (lane 3) and subjected to anti-FLAG immunoprecipitation after RNase treatment. (B) Western blot for Myc-tagged hUpf1 or hnRNPA1, transiently expressed in HEK293 cells together with an empty vector (lanes 1, 2, 4, and 5) or a plasmid encoding FLAG-tagged hDcp1a (lane 3) or hDcp2 (lane 6) and subjected to anti-FLAG immunoprecipitation after RNase treatment. Immunoprecipitates (P; lanes 2, 3, 5, and 6) are compared to 5% of the total extract (T; lanes 1 and 4) in panels A and B. (C) RNase-treated extracts from HEK293 cells transiently expressing Myc-hDcp1a, Myc-hnRNPA1, and FLAG-hUpf1 were immunodepleted with preimmune serum (pi; lanes 1, 2, and 3) or anti-hUpf1 ( ${alpha}$ 1; lane 4), anti-hUpf2 ( ${alpha}$ 2; lane 5), or anti-hUpf3b ( ${alpha}$ 3b; lane 6) serum and subsequently immunoprecipitated with anti-FLAG antibody. Immunoprecipitates (upper two panels) were probed for the presence of Myc-hDcp1a and Myc-hnRNPA1 by Western blotting. Five percent of the total extract (T; lane 1) was compared to the pellets (P; lanes 2 to 5). Depleted extracts (D; lower five panels, lanes 3 to 6) were probed with monoclonal anti-Myc antibody or polyclonal rabbit antibodies against hUpf1, hUpf2, hUpf3a, and hUpf3b as indicated.

Decapping activity of hDcp proteins in vitro. To test if hDcp proteins are associated with decapping activity,N-terminally FLAG-tagged hDcp1a and hDcp2 were immunopurifiedfrom transiently transfected HEK293 cells by passing cell extractsover an anti-FLAG antibody column followed by elution with aFLAG peptide (see Materials and Methods). The eluates were testedfor decapping activity in vitro by incubation with an ^m7cap-labeledRNA substrate. As indicated by release of ^m7GDP, both FLAG-hDcp1aand FLAG-hDcp2 copurify with decapping activity (Fig. 3, lanes4 to 7). Eluates from cells transfected with an empty vectorserved as a negative control and showed no decapping (lanes2 and 3). The products released by immunopurified FLAG-hDcpscorrespond to ^m7GDP, because they can be chased into ^m7GTP byusing nucleoside diphosphate kinase and ATP as shown for hDcp1ain lane 10.

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FIG. 3. Decapping assays with immunopurified and recombinant hDcp1a and hDcp2. ${alpha}$ -³²P-^m7cap-labeled RNA was incubated with immunopurified FLAG-tagged hDcp1a (lanes 4, 5, 9, and 10; corresponding to 0.2 x 10⁶, 1 x 10⁶, 1 x 10⁶, and 1 x 10⁶ cells' worth of protein, respectively), hDcp2 (lanes 6 and 7; 1 x 10⁶ and 5 x 10⁶ cells' worth, respectively), mock-purified cell extract (lanes 2 and 3; 1 x 10⁶ and 5 x 10⁶ cells' worth, respectively), or no cell extract (lanes 1, 8, and 11) or with purified bacterially expressed GST (lanes 12 and 13; 10 and 100 ng, respectively), GST-hDcp1a (lanes 14 and 15; 10 and 100 ng, respectively), GST-hDcp2 (lanes 16 and 17; 10 and 100 ng, respectively), or GST-hDcp1a and GST-hDcp2 (lanes 18 and 19; 10 and 100 ng each, respectively), and products were separated by thin-layer chromatography. The reaction mixture in lane 10 was treated with nucleoside diphosphate kinase (NDPK) and ATP. The migration of unlabeled GMP, GDP, ^m7GMP, ^m7GDP, and ^m7GTP (25 µg) is indicated on the left.

Purified, bacterially produced hDcp1a and hDcp2 proteins, fusedwith glutathione S-transferase (GST), were also tested for decappingactivity in vitro. As seen in Fig. 3, GST-hDcp2 exhibits decappingactivity (lanes 16 and 17). In contrast, GST-hDcp1a showed nodetectable activity (lanes 14 and 15) and was not capable ofstimulating the activity of GST-hDcp2 (compare lanes 18 and19 to lanes 16 and 17). Similar observations were originallyreported by E. van Dijk and coworkers (B. Séraphin, personalcommunication).

Critical mutations in hDcp1a and hDcp2 disrupt decapping activity. The decapping activity of immunopurified hDcp1a and hDcp2 couldoriginate from either the hDcps themselves or unknown associatedfactors. To render it likely that the hDcp proteins are responsiblefor the observed decapping activity, immunopurified hDcp1a andhDcp2 proteins mutated at residues previously shown to be criticalfor S. cerevisiae Dcp activity (16, 57) (Fig. 1) were testedfor decapping activity (Fig. 4). The hDcp1a D20A and R59A immunoprecipitateswere both impaired in decapping by 4- to 12-fold (lanes 4 and5). Interestingly, it was observed by Western blotting thatboth hDcp1a D20A and R59A proteins were expressed at 10- to20-fold-lower levels than wild-type hDcp1 (data not shown),but the amount of added immunoprecipitate was adjusted to usea similar amount of FLAG-hDcp in each decapping reaction (Fig.4, lower panel). Mutation of a conserved mutT domain glutamateresidue (E148Q) in hDcp2, which was previously demonstratedto be critical in other mutT domain proteins including S. cerevisiaeDcp2p (16, 35, 51), results in 20-fold-lower activity (Fig.4, lane 10). Unlike the hDcp1a mutants, hDcp2 E148Q is as stableas the wild-type protein (data not shown). Immunoprecipitatescontaining FLAG-tagged hDcp1a deletion mutants were also testedfor decapping activity. Although only the N-terminal 133-amino-acidregion of hDcp1a is similar to S. cerevisiae Dcp1p, each ofthe hDcp1a C-terminal deletion mutants tested were impairedin decapping (Fig. 4, lanes 6 to 8), even though they were allfound to copurify with Myc-hDcp2 (data not shown).

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FIG. 4. Mutation of critical residues in hDcp1a and hDcp2 disrupts decapping activity. The figure shows the results of decapping assays with immunopurified wild-type and mutant hDcp1a and hDcp2 proteins as indicated. The amount of protein corresponds to 5 x 10⁶, 0.5 x 10⁶, 5 x 10⁶, 5 x 10⁶, 1 x 10⁶, 0.5 x 10⁶, 0.5 x 10⁶, 5 x 10⁶, and 5 x 10⁶ cells in lanes 2 to 10, respectively. The relative amount of ^m7GDP generated by each hDcp mutant was quantified with a phosphorimager and is given below relative to that of wild-type hDcps, which was set to 100%. A fraction of each assay (lanes 3 to 10) was subjected to Western blotting with anti-FLAG antibodies, shown in the lower panel. wt, wild type.

Transiently expressed hDcp1a and hDcp2 localize primarily to the cytoplasm. If hDcp proteins are responsible for mRNA decapping in humancells, they would be expected to primarily localize to the cytoplasm,where most mRNA decay is believed to take place. It was thereforetested where transiently expressed FLAG-tagged hDcp1a and hDcp2proteins localize by indirect immunofluorescence. Human HeLacells were transiently transfected with plasmids expressingFLAG-hDcp1a or FLAG-hDcp2. Forty hours after transfection, thecells were fixed with paraformaldehyde and permeabilized, andthe localization of the FLAG-tagged proteins was assessed byindirect immunofluorescence (Fig. 5). Both FLAG-hDcp1a and FLAG-hDcp2are found primarily in localized dots in the cytoplasm. However,for both FLAG-hDcp1a and FLAG-hDcp2, some nuclear staining isevident.

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FIG. 5. Transiently expressed hDcp1a and hDcp2 proteins localize primarily in the cytoplasm. The figure shows the results of immunocytochemical staining of fixed, permeabilized HeLa cells, transiently expressing FLAG-tagged hDcp1a (panels 1 to 3) or hDcp2 (panels 4 to 6). Cells were stained with anti-FLAG M2 monoclonal antibody and visualized with Texas red-conjugated anti-mouse immunoglobulin G antibody (panels 1 and 4). Nuclei are visualized with 4',6'-diamidino-2-phenylindole (DAPI) (panels 2 and 5). Panels 1 to 6 show one cell, representative of at least 100 observed transfected cells.

hDcp1a and hDcp2 proteins interact with the NMD protein hUpf1. Decapping may play a role in several mRNA decay pathways inhuman cells. In S. cerevisiae, the process of NMD triggers decappingby an unknown mechanism (44). One possibility is that decappingenzymes are recruited to nonsense-containing mRNAs by the Upfproteins that are central players in the NMD pathway. Supportingthis view is the finding that S. cerevisiae Upf1p interactswith Dcp2p (also called NMD1) in a two-hybrid screen (22). Totest if hDcp1a and hDcp2 interact with hUpf1, HEK293 cells weretransiently cotransfected with plasmids expressing FLAG-taggedhUpf1 and Myc-tagged hDcp proteins. Myc-hnRNPA1 served as anegative control. In this experiment FLAG-tagged, as opposedto endogenous, hUpf1 was used for immunoprecipitations becauseof an observed low, but significant, cross-reaction betweenanti-hUpf1 antibodies and FLAG-hDcp1 (data not shown). Anti-FLAGimmunoprecipitates from RNase-treated cell extracts were testedfor the presence of Myc-tagged proteins by Western blotting.In contrast to Myc-hnRNPA1, which was undetectable in the precipitates, $~$ 2 to 4% of total Myc-hDcp1a and $~$ 50% of total Myc-hDcp2 copurifiedwith FLAG-hUpf1 (Fig. 6A; compare the precipitates in lane 3to 5% of total extract in lane 1). In this experiment, bothhUpf1 and hnRNPA1 were expressed at about twofold-higher levelsthan hDcp1a, which in turn was expressed at 10- to 15-fold-higherlevels than hDcp2 (data not shown). To confirm this result,Myc-hUpf1 was also tested for its ability to coimmunopurifywith FLAG-tagged hDcp1a and hDcp2. As seen in Fig. 6B, $~$ 10% oftotal Myc-hUpf1 copurified with FLAG-hDcp1a and FLAG-hDcp2.

hUpf1 interacts with the other hUpf proteins, hUpf2, hUpf3a,and hUpf3b. To test if the interaction between hUpf1 and hDcp1arequires the presence of the other hUpf proteins, the abilityof Myc-hDcp1a to coimmunoprecipitate with FLAG-hUpf1 was testedafter depletion of endogenous hUpf proteins. Passage of cellextracts over anti-hUpf1 or anti-hUpf2 antibody columns resultedin complete depletion of endogenous hUpf1 or hUpf2 proteins,respectively, whereas the other hUpf proteins were affectedtwofold or less (Fig. 6C, lanes 4 and 5, lower five panels).In contrast, anti-hUpf3b antibodies depleted both of the homologoushUpf3b and hUpf3a proteins as well as hUpf2 (Fig. 6C, lane 6,lower four panels). This is most likely a result of cross-reactionbetween anti-hUpf3b antibodies and hUpf3a (data not shown) andbecause the equally abundant hUpf2 protein interacts stronglywith the hUpf3 proteins (37, 40, 54). None of the antibodiessignificantly depleted Myc-hDcp1a from the extracts (Fig. 6C,third panel from top). As seen in Fig. 6C (upper panels) Myc-hDcp1a,but not Myc-hnRNPA1, coimmunoprecipitates with FLAG-hUpf1 evenin the absence of hUpf2 (lane 5) or hUpf2, hUpf3a, and hUpf3b(lane 6). As expected, no Myc-hDcp1a is observed in the immunoprecipitatewhen hUpf1 has first been depleted (lane 4). Interestingly,the amount of Myc-hDcp1a coprecipitating with FLAG-hUpf1 isreduced three- to fivefold after depletion with anti-hUpf2 oranti-hUpf3b antibodies, even though hUpf1, which is 10- to 20-foldmore abundant than hUpf2 and hUpf3 proteins (40), was not significantlyaffected by the depletions (compare lanes 5 and 6 with lane3). This suggests that, even though a maximum of 5 to 10% ofcellular hUpf1 can be complexed with hUpf2 and/or hUpf3 proteinsat any given time, the majority of hUpf1 protein that interactswith hDcp1a is in a complex with hUpf2 and/or hUpf3. These datasuggest a link between NMD and human decapping enzymes.

DISCUSSION

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Discussion

Several lines of evidence indicate that hDcp1a and hDcp2 areinvolved in mRNA decapping in human cells and that they maybe implicated in NMD. First, hDcp1a and hDcp2 are interactingproteins, similar to their S. cerevisiae homologs (Fig. 2).Second, hDcp1a and hDcp2 copurify with decapping activity fromhuman cells, and point mutations in critical hDcp1a and hDcp2residues impair the decapping activity (Fig. 3 and 4). Third,recombinant GST-hDcp2 exhibits decapping activity (Fig. 3) (E.van Dijk and B. Séraphin, personal communication). Fourth,transiently expressed hDcp1a and hDcp2 proteins localize primarilyin the cytoplasm, as would be expected for proteins involvedin general mRNA decay (Fig. 5). Fifth, both hDcp1a and hDcp2interact with hUpf1, a protein central to the NMD pathway (Fig.6). Sequential depletion and immunoprecipitation experimentsdemonstrated that, although hUpf1 does not require the presenceof hUpf2 and hUpf3 proteins for interaction with hDcp1a, mostof hUpf1 complexed with hDcp1a is also in complex with hUpf2and hUpf3 (Fig. 6C). Unfortunately, an attempt to directly implicatehDcps in NMD was unsuccessful, because expression of inactivehDcp mutants described for Fig. 4, as well as hDcp2 mutantswith C-terminal deletions of 60, 120, or 180 amino acids, inHEK293 or HeLa cells had no dominant negative effects on a coexpressedß-globin NMD substrate (data not shown). Therefore,there is currently no direct evidence for the significance ofthe strong interaction between hUpf1 and the hDcp proteins.

Characteristics of hDcp proteins. Two human homologs of S. cerevisiae Dcp1p were identified, hDcp1aand hDcp1b. It is possible that they function redundantly indecapping in human cells, although there is so far no evidencethat hDcp1b is involved in decapping other than the global similarityto hDcp1a. Point mutations of the conserved D20 and R59 residuesof hDcp1a led to impaired decapping activity (Fig. 4). Importantly,both of these residues are conserved in hDcp1b (Fig. 1A). Theobservation that hDcp1a D20A and R59A proteins were expressedat 10- to 20-fold-lower levels than wild-type hDcp1a indicatesthat they are unstable. Perhaps the poor decapping activityof the hDcp1a mutants is a result of impaired folding or ofa loss of interaction with an important protein partner thatwould also lead to protein instability. The corresponding S.cerevisiae Dcp1p mutants do not appear to be unstable (57).Interestingly, hDcp1a (also called SMIF) may play a role inSmad-mediated transforming growth factor ß signaltransduction, because it was reported earlier to interact withSmad4 and to partially translocate to the nucleus in responseto transforming growth factor ß stimulation (2).

hDcp2 contains a mutT domain which is found in proteins thatcatalyze pyrophosphatase reactions (7). Since decapping involvescleavage of a pyrophosphate, the observation that mutation ofa critical glutamate residue in the mutT domain of Dcp2 stronglyimpairs decapping activity (Fig. 4) (16) suggests that the Dcp2protein is the enzyme responsible for catalysis. Moreover, recombinantGST-hDcp2, but not GST-hDcp1a, shows decapping activity (Fig.3). However, purified S. cerevisiae Dcp1p exhibits decappingactivity after separation from Dcp2p (17, 30), and immunopurifiedhDcp1a deletion mutants that maintain their ability to copurifywith hDcp2 are impaired in decapping activity (Fig. 4, lanes6 to 8). Most likely Dcp1 and Dcp2 form a complex required fordecapping.

Recruitment of decapping enzymes to nonsense-containing mRNAs? Although it remains to be established if NMD in mammals, asin S. cerevisiae, triggers decapping, a link between human Upfproteins and decapping enzymes has now been identified (Fig.6). The data presented here suggest that hDcp1 and hDcp2 maybe recruited to mRNAs by hUpf1 in complex with hUpf2 and hUpf3.Perhaps selective recruitment of decapping enzymes to PTC-containingmRNAs triggers NMD. This model is depicted in Fig. 7.

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FIG. 7. Model for how the interaction between hUpf1 and hDcp proteins may play a role in NMD. The EJC is deposited onto the mRNA upstream of exon-exon junctions after pre-mRNA splicing. hUpf3 associates with the EJC, followed by hUpf2 and hUpf1. A translation termination event upstream of the EJC/hUpf complex may allow hUpf1 to recruit the hDcp proteins to trigger mRNA decapping. RF, translation release factor.

How could recruitment of hDcp proteins lead to decapping? Severallines of evidence indicate that decapping does not occur onan mRNA without prior dissociation of the cap-binding complexeIF4F. For example, decapping by S. cerevisiae Dcp1p is inhibitedby the cap-binding protein eIF4E in vitro (53), and mutationsin eIF4F components that inhibit translation initiation leadto an increased rate of decapping in S. cerevisiae (3, 8, 52).Therefore, decapping may not be triggered by simply recruitinghDcps to the mRNA. In S. cerevisiae, the RNA helicase Dhh1pis implicated in decapping of deadenylated mRNAs, and it wasproposed that Dhh1p may function by dissociating the cap-bindingcomplex from the mRNA (11, 18). Importantly, it was demonstratedearlier that an RNA helicase can dissociate an RNA-protein complex(28). In the case of NMD, perhaps the conserved RNA helicasefunction of Upf1, which is critical for NMD (55, 64), couldplay a similar role. Interestingly, Upf2 contains three eIF4G-likerepeats (37, 41, 49, 54), and hUpf2 can interact with eIF4A(41). Therefore, it is possible that Upf2 assists in breakingup the eIF4F complex by interacting with individual components(41).

If the model in Fig. 7 is correct, some mechanism must ensurethat decapping enzymes are only recruited and/or activated onmRNAs containing PTCs, because hUpf proteins are believed toassociate with all intron-containing mRNAs (31, 33, 37). Perhapsphosphorylation of hUpf1, which has been shown elsewhere tobe crucial for NMD (15, 47, 66), is the trigger to recruit hDcps.Alternatively, phosphorylation of hDcps themselves may be necessaryfor activation. Note that hDcp1a produces a doublet in SDS-polyacrylamidegels (Fig. 2 and 6) and that S. cerevisiae Dcp1p is a phosphoprotein(30). These events may be triggered only if a complex of EJC,hUpf proteins, and eRFs is formed on an mRNA by a translationtermination event upstream of an exon-exon junction (Fig. 7).The details of the possible significance of the interactionbetween hUpf1 and hDcp proteins for NMD of PTC-containing mRNAsare an important problem for future studies.

ACKNOWLEDGMENTS

Norm Pace, Elsebet Lund, Morgan Tucker, and Eileen Wagner arethanked for advice on the manuscript. Morgan Tucker is alsothanked for advice on in vitro decapping assays. Stewart Shumanis thanked for a vaccinia virus capping enzyme expression plasmid.Robert M. Ross is thanked for technical assistance.

FOOTNOTES

* Mailing address: Molecular, Cellular and Developmental Biology, University of Colorado, CB 347, Boulder, CO 80309. Phone: (303) 735-4886. Fax: (303) 492-7744. E-mail: Jens.Lykke-Andersen{at}colorado.edu.

REFERENCES

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