Evolutionarily Divergent Type II Protein Arginine Methyltransferase in Trypanosoma brucei

doi:10.1128/EC.00133-07

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Evolutionarily Divergent Type II Protein Arginine Methyltransferase in Trypanosoma brucei

Deborah A. Pasternack,¹ Joyce Sayegh,² Steven Clarke,² and Laurie K. Read¹^*

Department of Microbiology and Immunology and Witebsky Center for Microbial Pathogenesis and Immunology, State University of New York School of Medicine, Buffalo, New York 14214,¹ Department of Chemistry and Biochemistry and Molecular Biology Institute, University of California at Los Angeles, Los Angeles, California 90095-1569²

Received 20 April 2007/ Accepted 22 June 2007

ABSTRACT

Top
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Protein arginine methylation is a posttranslational modificationthat impacts cellular functions, such as RNA processing, transcription,DNA repair, and signal transduction. The majority of our knowledgeregarding arginine methylation derives from studies of yeastand mammals. Here, we describe a protein arginine N-methyltransferase(PRMT), TbPRMT5, from the early-branching eukaryote Trypanosomabrucei. TbPRMT5 shares the greatest sequence similarity withPRMT5 and Skb1 type II enzymes from humans and Schizosaccharomycespombe, respectively, although it is significantly divergentat the amino acid level from its mammalian and yeast counterparts.Recombinant TbPRMT5 displays broad substrate specificity invitro, including methylation of a mitochondrial-gene-regulatoryprotein, RBP16. TbPRMT5 catalyzes the formation of ${omega}$ -N^G-monomethylarginineand symmetric ${omega}$ -N^G,N^G'-dimethylarginine and does not requiretrypanosome cofactors for this activity. These data establishthat type II PRMTs evolved early in the eukaryotic lineage.In vivo, TbPRMT5 is constitutively expressed in the bloodstreamform and procyclic-form (insect host) life stages of the parasiteand localizes to the cytoplasm. Genetic disruption via RNA interferencein procyclic-form trypanosomes indicates that TbPRMT5 is notessential for growth in this life cycle stage. TbPRMT5-TAP ectopicallyexpressed in procyclic-form trypanosomes is present in high-molecular-weightcomplexes and associates with an RG domain-containing DEAD boxprotein related to yeast Ded1 and two kinetoplastid-specificproteins. Thus, TbPRMT5 is likely to be involved in novel methylation-regulatedfunctions in trypanosomes, some of which may include RNA processingand/or translation.

INTRODUCTION

Top
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Protein arginine methylation is an irreversible posttranslationalmodification catalyzed by protein arginine methyltransferases(PRMTs). PRMTs transfer a methyl group from S-adenosyl-L-methionine(AdoMet) to the guanidino nitrogen atoms of substrate arginineresidues (34). Arginine residues found within RGG, RG, or RXRmotifs are common, but not exclusive, sites of methylation (reviewedin reference 60). Interestingly, a large percentage of PRMTsubstrates are RNA binding proteins, especially those containingRG-rich motifs (9, 57). Other common substrates include histonesand transcriptional coactivators (reviewed in references 7 and95). Arginine methylation regulates protein function by modulatingsubcellular localization (44, 65, 82), protein-protein interactions(6, 31), and, less frequently, protein-RNA interactions (27,28, 86). Through these mechanisms, protein arginine methylationexerts a range of effects on several cellular processes, includingtranscription (18, 96), signal transduction (1, 22), DNA repair(10), and RNA processing (12, 32, 82).

Arginine methyltransferases have been identified in animals,fungi, plants, and protozoa, and in total, four classes of enzymeshave been described. Type I PRMTs catalyze the formation of ${omega}$ -N^G-monomethylarginine (MMA) and asymmetric ${omega}$ -N^G,N^G-dimethylarginine(aDMA). Type II enzymes catalyze the formation of MMA and symmetric ${omega}$ -N^G,N^G'-dimethylarginine (sDMA). Type III and type IV PRMTscatalyze only MMA or ${delta}$ -N^G-monomethylarginine formation, respectively.Most of our knowledge about PRMTs derives from analysis of mammalsand yeasts. Of the 11 putative PRMTs identified in the genomeof Homo sapiens, five display clear type I activity (PRMT1,PRMT3, PRMT4/CARM1, PRMT6, and PRMT8), one displays clear typeII activity (PRMT5), and work is in progress on the others (reviewedin reference 50). In contrast to humans, only three PRMTs havebeen described in Saccharomyces cerevisiae. They are PRMT1 andPRMT5 homologs (called HMT1p and HSL7p), as well as a noveltype IV PRMT called RMT2p, which has been described only inbudding yeast, although homologs are present in a variety offungi and plants (20, 99). Genes homologous to PRMT1 and PRMT5have also been described in the yeast Schizosaccharomyces pombe,as well as an additional type I PRMT that is a homolog of PRMT3(4, 38, 75). Although genes encoding putative PRMTs are presentin the genomes of various plants and protozoa, analysis of argininemethylation in these groups has been limited. Type II PRMT activitymediated by SKB1 specific for histone H4 is reported to controlflowering time in Arabidopsis thaliana (92), whereas type IPRMT homologs have been characterized from the parasitic protozoaTrypanosoma brucei (TbPRMT1 [72]) and Toxoplasma gondii (TgCARM1and TgPRMT1 [81]). Phylogenetic analysis suggests that PRMTsoriginated early in the eukaryotic lineage, since no homologshave been identified in bacteria, archaea, or the basal eukaryoteGiardia lamblia (50).

T. brucei, the causative agent of African trypanosomiasis, isan early-branching eukaryote that lacks transcriptional controland displays complex mechanisms of gene expression. Transcriptionof protein-coding genes is polycistronic, yet the differentialexpression of steady-state RNA has been observed between bloodstreamform (BF) and procyclic-form (PF) life stages of the parasite(37). Trypanosomes exhibit unique biology, in which gene expressionis coordinated posttranscriptionally through mechanisms thatinclude trans splicing, RNA stability, RNA editing, and translation(23, 80, 89). A vast number of RNA binding proteins are presumablyrequired to coordinate these posttranscriptional regulatoryevents in T. brucei, and a few such proteins have been identified(25). Since a large percentage of PRMT substrates are RNA bindingproteins, arginine methylation may be of heightened importancein trypanosomes. Both type I and type II PRMT activities havebeen detected in T. brucei cellular extracts (74), and an enzymetermed TbPRMT1 was shown to constitute the major type I enzymein the organism (72). We demonstrated recently that TbPRMT1-catalyzedarginine methylation functions in mitochondrial-RNA stabilizationand ribonucleoprotein formation and/or stability (41, 42). Inaddition to TbPRMT1, analysis of the T. brucei genome revealedthe presence of four additional PRMT genes (reference 48 andthis study). The enzymes encoded by these genes and their potentialroles in trypanosome biology remain completely uncharacterized.

Here, we describe the identification and characterization ofan evolutionarily divergent PRMT5 homolog from T. brucei, whichwe term TbPRMT5. Recombinant TbPRMT5 displays intrinsic typeII PRMT activity, catalyzing the formation of MMA and sDMA onmyelin basic protein, core histones, and an RG peptide. TbPRMT5also methylates the mitochondrial-RNA binding protein RBP16(45, 73) in vitro, although it catalyzes primarily MMA on thissubstrate. TbPRMT5 purified from trypanosome cellular extractsdisplays PRMT activity with properties similar to the recombinantenzyme and is present in high-molecular-weight complexes. Analysisof trypanosome proteins associated with TAP-tagged TbPRMT5 revealedthe absence of proteins homologous to components of the human20S methylosome (32, 33, 61). Instead, TbPRMT5 associates witha DEAD box-containing protein, which is related to the Ded1pand Vasa translation initiation factors described in yeast andDrosophila. This putative RNA helicase harbors an RGG-rich Cterminus, suggesting it is likely an endogenous TbPRMT5 substrate.In addition, TbPRMT5 copurified with tryparedoxin peroxidaseand two high-molecular-weight proteins, for which homologs arepresent only in the related kinetoplastid protozoa Trypanosomacruzi and Leishmania major. Thus, TbPRMT5 apparently assemblesin kinetoplastid-specific complexes, suggesting novel functionsfor this divergent type II PRMT.

MATERIALS AND METHODS

Top
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Plasmid constructs. To identify type II PRMT homologs in T. brucei, a BLAST searchwas performed against the sequenced and partially annotatedT. brucei genomic database (The Institute for Genomic Research)using the coding sequence for H. sapiens PRMT5 (GenBank accessionno. O14744 [GenBank] ). A putative methyltransferase that displayed homologyto human PRMT5 was identified on chromosome 10 (locus Tb10.70.7570)and was used to design oligonucleotide primers for the PCR amplificationof the full-length TbPRMT5 open reading frame (ORF) from cDNA.For cDNA synthesis, total RNA was isolated from PF T. bruceibrucei clone IsTaR1 stock EATRO 164, and the cDNA was reversetranscribed using oligonucleotide primer [dT]-RXS (5'-GAGAATTCTCGAGTCGACTTTTTTTTTTTTTTTTT-3')(restriction enzyme sites of all oligonucleotides used in thisstudy are underlined). To generate an N-terminal maltose-bindingprotein (MBP) fusion, the TbPRMT5 ORF was PCR amplified fromcDNA using PRMT5-5' (5'-GAGAATTCGCTAGCATGAAGCCATGTGTTTCCGCTGC-3')forward and pMAL-PRMT5-3' (5'-GCTCTAGACTACGTCAGCAGAGAAATGTGGCCC-3')reverse primers and cloned into the EcoRI/XbaI restriction enzymesites of pMAL-c2 (New England Biolabs), creating pMAL-PRMT5.The pBSC-PRMT5 plasmid construct was created for use as a templatefor full-length TbPRMT5 antisense riboprobe synthesis. For thegeneration of pBSC-PRMT5, the full-length TbPRMT5 ORF was PCRamplified from PF cDNA using PRMT5-5' (see above) forward andPRMT5-3' (5'-GCTCTAGACTCGAGCGTCAGCAGAGAAATGTGGCCC-3') reverseprimers, blunt ended with T4 DNA polymerase (Invitrogen), andcloned into the EcoRV site of pBluescriptII SK(–) (Stratagene).The pHD918-PRMT5 plasmid construct was created for the generationof a trypanosome stable cell line constitutively expressinga C-terminal TAP tag fusion protein. To create pHD918-PRMT5,TbPRMT5 was PCR amplified from pMAL-PRMT5 using TbPRMT5-1 (5'-CCCAAGCTTATGAAGCCATGTGTTTCCGCTGC-3')forward and TbPRMT5-2 (5'-CTAGCTAGCGTTAACCGTCAGCAGAGAAATGTGGCCC-3')reverse primers and cloned into the HindIII/HpaI sites of thepHD918 TAP vector (a generous gift from Christine Clayton, HeidelbergUniversity, Heidelberg, Germany) (30, 78). To generate the pZJM-PRMT5RNA interference (RNAi) construct, a 449-nucleotide fragmentof TbPRMT5 (nucleotides 361 to 810) was PCR amplified from PFcDNA using PRMT5-5'i (5'-GCCTCGAGACTGCTTGCGGTAGCGTGTCG-3') forwardand PRMT5-3'i (5'-GCAAGCTTTTCAGCGTTGGGAAGTTCAAACGC-3') reverseprimers and cloned into the XhoI/HindIII sites of the pZJM RNAivector (a generous gift from Paul T. England, Johns HopkinsSchool of Medicine) (93). All plasmid constructs were transformedinto Escherichia coli strain DH5 ${alpha}$ competent cells (Invitrogen).Positive clones were selected on LB agar plates containing 100µg/ml ampicillin and confirmed by sequencing them (RoswellPark Cancer Institute DNA Sequencing Laboratory, Buffalo, NY).

Trypanosome cell culture, transfection, and induction of RNAi. PF T. brucei brucei clone IsTaR1 stock EATRO 164 (88) was culturedin SDM-79 as described previously (15). PF T. brucei bruceistrain 29-13 (a generous gift from George A. M. Cross, RockefellerUniversity), which harbors integrated constructs for the expressionof T7 RNA polymerase and tetracycline repressor genes, was culturedin SDM-79 supplemented with 15 µg/ml G418 and 50 µg/mlhygromycin B, as described previously (15, 94). BF T. bruceibrucei strain Lister 427 (MITat 1.2) clone 221 (a generous giftfrom George A. M. Cross, Rockefeller University) (29, 47, 49)was cultured in HMI-9 medium as described previously (46).

Stable cell lines constitutively expressing a TbPRMT5 C-terminalTAP tag fusion protein were generated via electroporation. Fortransfection, log-phase PF T. brucei brucei clone IsTaR1 stockEATRO 164 was harvested by centrifugation (1,000 x g), washedin 150 ml cold EM buffer (51), and resuspended to 2 x 10⁸ cells/mlwith EM buffer. Five-hundred microliters of this cell suspension(1 x 10⁸ cells/transfection) was transferred to chilled 2-mm-gapelectroporation cuvettes containing either water (control) or20 µg of NotI-linearized pHD918-PRMT5 plasmid DNA. Thecells were pulsed twice in a Bio-Rad Gene Pulsor electroporatorset at 800 V, 25 mF, and 400 ${Omega}$ . After electroporation, the cellswere transferred to 9.5 ml of SDM-79 medium supplemented with15% fetal bovine serum and incubated at 27°C overnight.Antibiotic selection was applied the following day with theaddition of 50 µg/ml hygromycin B. Clonal cell lines weregenerated by limiting dilution and confirmed by immunoblot analysisusing TAP-specific antibodies. Analysis of TbPRMT5-TAP-expressingcells was performed using the clonal cell line p8.1.E8.

Stable cell lines engineered for the tetracycline-regulatableknockdown of TbPRMT5 using RNAi were generated via electroporation.For transfection, log-phase PF 29-13 cells (94) were harvestedby centrifugation, washed in 150 ml cold EM buffer, and resuspendedto 2.5 x 10⁷ cells/ml. Four hundred fifty microliters of thiscell suspension was aliquoted into chilled 2-mm-gap electroporationcuvettes (1.1 x 10⁷ cells/transfection) containing either water(control) or 20 µg of Not1-linearized pZJM-PRMT5 plasmidDNA and electroporated as described above. After electroporation,the cells were transferred to 4 ml of SDM-79 supplemented with15% fetal bovine serum, 15 µg/ml G418, and 50 µg/mlhygromycin B and incubated at 27°C overnight. Antibioticselection was applied the following day with the addition of2.5 µg/ml phleomycin. Clones were obtained by limitingdilution and confirmed by restriction enzyme digestion and Southernhybridization using a TbPRMT5-specific probe. TbPRMT5 RNAi (clonep1.3.E9) inductions were initiated with the addition of 1 µg/mltetracycline.

Expression and purification of recombinant proteins. For the expression of recombinant MBP-TbPRMT5, 4 liters of LBmedium containing 100 µg/ml ampicillin was inoculatedwith an overnight culture of E. coli DH5 ${alpha}$ transformed with pMAL-PRMT5and grown at 36°C and 225 rpm to an optical density (OD)of 0.4 to 0.6. The cultures were chilled on ice for 15 min to $~$ 20°C, and 2% (vol/vol) ethanol was added to enhance proteinsolubility. MBP-TbPRMT5 expression was induced with the additionof 0.3 mM isopropyl ß-D-thiolgalactopyranoside for24 h at 20°C and 225 rpm. The cells were harvested by centrifugationfor 20 min at 4,000 x g and 4°C and resuspended in 50 mllysis buffer (20 mM ethanolamine [pH 9.0], 1 M NaCl, 1 mM EDTA,0.2% NP-40, 4 mM benzamidine, 1 mM phenylmethylsulfonyl fluoride[PMSF], 1 µM leupeptin, and 300 µg/ml lysozyme [addedafter resuspension]) per 1-liter culture. To reduce the viscosity,the extract was incubated with 5 mM MgCl₂ and 25 µg/mlDNase I (Sigma) at 4°C for 30 min with agitation. Cell lysiswas completed by sonication on ice for 3 min (30-second intervals)at 50% duty cycle pulse mode. The supernatant was clarifiedby centrifugation at 14,000 x g for 20 min at 4°C and dialyzedovernight in 4 liters of dialysis buffer (20 mM bis-Tris [pH7.0], 50 mM NaCl, 0.05% NP-40, 1 mM EDTA, 1 mM benzamidine,0.5 mM PMSF, 1 µM leupeptin) at 4°C. An additional3-h incubation in 2 liters of fresh dialysis buffer was performedthe following day. The dialyzed crude extract was then incubatedwith 15 ml of preequilibrated amylose resin (New England Biolabs)for 2 h at 4°C with rocking. This slurry was poured througha column to pack the resin, and the supernatant was passed overthe column again at a flow rate of $~$ 1 ml/min. The column waswashed with 12 bed volumes of column buffer (dialysis bufferminus protease inhibitors) at a flow rate of $~$ 1 ml/min. The MBP-TbPRMT5fusion protein was then eluted at a flow rate of $~$ 0.5 ml/minwith 30 ml of elution buffer (20 mM bis-Tris [pH 7.0], 50 mMNaCl, 2 mM EDTA, 0.1% NP-40, 10 mM maltose, 10% [vol/vol] glycerol,1 mM benzamidine, 1 mM PMSF, and 1 µM leupeptin) and collectedin 1-ml fractions. The fractions were analyzed by sodium dodecylsulfate-polyacrylamide gel electrophoresis (SDS-PAGE), quantifiedusing a bovine serum albumin (BSA) standard curve, and assayedfor methyltransferase activity.

Rat PRMT1 was expressed as a glutathione S-transferase (GST)fusion protein in E. coli BL-21 transformed with the pGEX-PRMT1bacterial expression vector (a generous gift from Harvey R.Herschman, University of California at Los Angeles) (55). Cellswere grown in super broth containing 0.1 mM ampicillin at 36°Cand 225 rpm to an OD of 0.5 to 0.7. The expression of GST-PRMT1was induced for 4 h with the addition of 1 mM isopropyl-ß-D-thiogalactopyranoside.The cells were harvested by centrifugation at 4,000 x g for20 min at 4°C and resuspended in 25 ml lysis buffer (50mM Tris-HCl [pH 8.0], 50 mM NaCl, 5 mM EDTA, 0.5 mM benzamidine,0.15 mM PMSF, and 1 µM leupeptin) per 1-liter culture.The cells were lysed by sonication on ice for 3 min (30-secondintervals) at 50% duty cycle pulse mode. The crude extract wasclarified by centrifugation at 14 rpm for 20 min at 4°Cand loaded onto a column containing 5 ml of preequilibratedGlutathione-Sepharose 4 Fast Flow resin (Amersham Biosciences)at a flow rate of $~$ 0.5 ml/min. The column was washed with 10bed volumes phosphate-buffered saline (PBS)-EDTA-PMSF buffer(PBS [pH 7.4] containing 5 mM EDTA and 0.15 mM PMSF), followedby a second wash with 10 bed volumes of PBS-EDTA buffer (PBS[pH 7.4] containing 5 mM EDTA) at a flow rate of 1.5 ml/min.GST-PRMT1 fusion protein was eluted in 2 ml fractions with 5bed volumes glutathione buffer (50 mM Tri-HCl [pH 8.0], 10 mMreduced-form glutathione [Sigma], and 10% [vol/vol] glycerol).The peak fractions were pooled and dialyzed overnight at 4°Cin two 2-liter changes of methyltransferase assay buffer (80mM Tris-HCl [pH 8.0], 0.5 mM benzamidine, and 0.4 mM PMSF).GST-PRMT1 was then concentrated, analyzed by SDS-PAGE alongsidea BSA standard curve, and assayed for methyltransferase activity.His-RBP16, His-CSD (cold shock domain), and His-RGG (RGG domain)fusion proteins were previously expressed as described previously(63). The MBP-TBRGG1 fusion protein was previously expressedas described previously (72).

In vitro methyltransferase assays. In vitro methylation assays were performed at 36°C in thepresence of 0.9 to 1 µM S-adenosyl-L-[methyl-³H]methionine([methyl-³H]AdoMet) (Amersham; 66.0 to 80.0 Ci/mmol; 1 µCi/µl)in 80 mM Tris-HCl (pH 8.0) buffer containing 0.5 mM benzamidineand 0.4 mM PMSF protease inhibitors. Experimental details aredescribed in the figure legends. For MBP-TbPRMT5 time course,titration, and substrate specificity, reactions were stoppedby the addition of SDS-PAGE sample buffer. Samples were incubatedat 95°C for 5 min and analyzed by either 12.5% or 15% polyacrylamideSDS-PAGE. Gels were stained with 0.1% (wt/vol) Coomassie brilliantblue R250 (Sigma) in 50% methanol-10% acetic acid, destainedwith 5% methanol-10% acetic acid, and then treated by fluorographyto visualize tritiated substrates. For fluorography, gels weretreated with EN³HANCE (Perkin-Elmer Life Sciences), dried at60°C in vacuo, and exposed to Kodak X-Omat Blue XB-1 scientificimaging film at –80°C.

In vitro methylation assays performed for substrate amino acidanalysis are described in the figure legends. Reactions werestopped by the addition of 10% (wt/vol) trichloroacetic acid(TCA), followed by a 30-minute incubation on ice. TCA-precipitatedproteins were centrifuged at 13,000 x g for 10 min at room temperature.The supernatant was decanted, and the pellets were washed in500 µl of acetone. Samples were centrifuged as describedabove, the acetone was decanted, and the pellets were allowedto dry. The TCA-precipitated pellets were then subjected toacid hydrolysis for substrate amino acid analysis.

The recombinant substrates and enzymes used in this analysisare described above. Calf thymus core histones were purchasedfrom Roche (no. 223 565). Myelin basic protein from bovine brainwas purchased from Sigma (no. M 1891). The RG peptide substrate(H-CGRGRGRGRGRGRGRG-NH₂) was custom synthesized by Bachem.

Amino acid analysis. Substrate amino acid analysis was performed essentially as describedpreviously (32). In vitro methylation reaction mixtures wereacid hydrolyzed in 200 µl of constantly boiling 6 N HCl(Sigma) for 20 h at 110°C in vacuo. Acid hydrolysates weredried at room temperature in a Savant Speed Vac, resuspendedin 5 µl of water, and analyzed by thin-layer chromatography(TLC) alongside 30 nmol of MMA (acetic acid salt; Sigma), aDMA(dihydrochloride; Sigma), sDMA (dihydrochloride; Calbiochem),and AdoMet (iodide salt; MP Biochemical) standards. Sampleswere loaded on LK6DF silica gel 60 TLC plates (Whatman) andseparated using a 2:0.5:4.5:1 ammonium hydroxide-chloroform-methanol-watersolvent system. Amino acid standards were visualized with sprayninhydrin (Tokyo Chemical Industry Co., Ltd.), and methyl-³Hresidues were visualized by fluorography using EN³HANCE sprayreagent (Perkin-Elmer Life Sciences).

For the analysis of MBP-TbPRMT5 substrates by cation-exchangechromatography of methylated amino acids obtained after acidhydrolysis, in vitro methylation reactions were performed at36°C for 16 h in the presence of 0.35 µM MBP-TbPRMT5,1 µM [methyl-³H]AdoMet (66.0 to 80.0 Ci/mmol), and either20 µg calf thymus core histones or 3.5 µM His-RBP16substrates. The reactions were stopped by precipitation withTCA and were acid hydrolyzed with 100 µl of 6 N HCl at110°C for 20 h in vacuo in a Waters Pico-Tag Vapor Phaseapparatus. The dried hydrolyzed samples were resuspended in50 µl of water, 25 µl of which was added to 500µl of citrate buffer (0.2 M Na⁺, pH 2.2) with 1.0 µmoleach of unlabeled standards of MMA, aDMA, and sDMA (di-p-hydroxyazobenzene-p'-sulfonatesalt; Sigma). The sample was loaded onto a cation-exchange columnequilibrated with sodium citrate buffer (0.35 M Na⁺, pH 5.27)(the column resin was Beckman AA-15 sulfonated polystyrene beads;column length, 0.9-cm inner diameter by 7-cm column height)and eluted at 1 ml/min at 55°C.

RNA isolation and Northern blot analysis. Total RNA was isolated from log-phase cells using the PurescriptRNA Isolation Kit (Gentra Systems). A full-length [ ${alpha}$ -³²P]UTP-labeledTbPRMT5 riboprobe was generated by in vitro transcription (MaxiscriptT3 kit; Ambion) using NheI-linearized pBSC-PRMT5 as a template.An [ ${alpha}$ -³²P]UTP-labeled tubulin riboprobe, corresponding to a 650-nucleotidestuffer sequence of the pZJM RNAi expression vector, was generatedby in vitro transcription (Maxiscript T7 kit; Ambion) afterdigestion with XhoI and BamHI restriction endonucleases. The[ ${gamma}$ -³²P]ATP 5'-labeled tubulin oligonucleotide probe (TUB-RT;5'-GGGGGTCGCACTTTGTC-3'; melting temperature, 46°C) waslabeled by a T4 kinase forward reaction.

For the Northern blot analysis of TbPRMT5 BF versus PF expression,total RNA (20 µg) isolated from BF T. brucei strain Lister427 (MITat 1.2) clone 221 and PF T. brucei clone IsTaR1 stockEATRO 164 was resolved on a 1.5% formaldehyde-agarose gel andtransferred to Nytran (Schleicher & Schuell) by capillaryaction in 10x SSC (1x SSC is 0.15 M NaCl plus 0.015 M sodiumcitrate). The membrane was prehybridized for $≥$ 1 h at 65°Cin 0.15 ml hybridization solution (50% formamide, 1% SDS, 5xSSC, 1x Denhardt's solution, and 150 µg/ml denatured shearedsalmon sperm DNA) per 1-cm² blot, followed by an overnight hybridizationat 65°C with $≥$ 1 x 10⁶ cpm full-length TbPRMT5 antisense riboprobesper ml hybridization solution. Two low-stringency washes wereperformed at 65°C for 15 min in 2x SSC-0.1% SDS, followedby two high-stringency washes at 65°C for 15 min in 0.1xSSC-0.1% SDS. The membrane was stripped at 80°C in Northernblot stripping solution (40 mM Tris-HCl [pH 7.5], 1% SDS, and0.1x SSC) and reprobed for tubulin RNA as follows. Prehybridizationwas performed at 36°C for $≥$ 1 h in 0.2 ml hybridization solution(10x Denhardt's solution, 5x SSC, 1% SDS, and 200 µg/mldenatured salmon sperm DNA) per 1-cm² blot. The membrane washybridized overnight at 36°C with a 5'-labeled tubulin oligonucleotideprobe ( $≥$ 1 x 10⁶ cpm probe/ml hybridization solution). Five roomtemperature washes were performed in 6x SSC-1% Sarkosyl for5 min each, followed by a final 3-min wash in 1x SSC-0.1% SDS.RNA levels were analyzed on a Bio-Rad Personal FX phosphorimagerusing Quantity One software.

For the analysis of TbPRMT5 RNAi, total RNA (10 µg) isolatedfrom parental, uninduced, and induced RNAi cells on days 1,2, 4, 6, and 8 postinduction was analyzed by Northern blottingusing a full-length TbPRMT5 riboprobe as described above. Tocontrol for loading, the membrane was stripped and hybridizedas described above with a tubulin-specific riboprobe. Autoradiographywas performed using Kodak X-Omat AR scientific imaging film,and RNA levels were analyzed by densitometry using Bio-Rad QuantityOne software.

Preparation and fractionation of trypanosome cellular extracts. Fractionation of trypanosome cellular extracts was performedas described previously (79) with some modifications. Log-phaseTbPRMT5-TAP-expressing cells were harvested by centrifugationat 10,000 x g for 10 min at 4°C. The cell pellets were washedin cold PBS, weighed, and resuspended in 3 volumes of cell mass(ml/g cell mass) low-salt hypotonic lysis buffer (10 mM HEPES[pH 7.9], 10 mM KCl, 1.5 mM MgCl₂, 0.5 mM dithiothreitol, 1mM benzamidine, 0.5 mM PMSF, 1 µM leupeptin, and 1 µg/mlpepstatin) containing 0.2% NP-40. The lysates were incubatedon ice for 10 min, followed by the addition of 12 volumes low-salthypotonic lysis buffer containing 0.5% NP-40. Cell disruptionwas completed by homogenization in a glass Dounce homogenizer,followed by passage through a 26-gauge needle 10 times. Crudewhole-cell extracts were either quick-frozen in liquid nitrogenand stored at –80°C or further fractionated into cytosolicand nuclear extracts. To obtain a cytosolic extract, nucleiwere pelleted by centrifugation at 5,000 x g for 20 min at 4°C.The supernatant (cytosolic extract) was transferred to a cleantube, quick-frozen in liquid nitrogen, and stored at –80°C.The nuclear pellet was resuspended in 5 volumes 0.25 M sucrosebuffer (low-salt hypotonic lysis buffer containing 0.25 M sucrose)and centrifuged at 1,100 x g for 15 min at 4°C. The supernatantwas decanted, and the pellet was resuspended in 5 volumes 0.25M sucrose buffer. This lysate was then layered with an equalvolume of 0.35 M sucrose buffer (low-salt hypotonic lysis buffercontaining 0.35 M sucrose) and centrifuged at 1,100 x g for15 min at 4°C. The supernatant was decanted, and the nucleiwere resuspended in 5 volumes of 0.35 M sucrose buffer. To disruptthe nuclear membranes, the extract was sonicated on ice for3 min (at 30-second intervals) at 50% duty cycle pulse modeand micropipet limit setting 3. The nuclear extract was thenlayered with 5 volumes of 0.88 M sucrose buffer (low-salt hypotoniclysis buffer containing 0.88 M sucrose) and centrifuged at 1,100x g for 20 min at 4°C. The supernatant (nuclear extract)was transferred to a clean tube, quick-frozen in liquid nitrogen,and stored at –80°C.

The protein concentrations in subcellular fractions were quantifiedby Bradford assay. Cytosolic and nuclear fractionations wereanalyzed by Western blotting using rabbit anti-Hsp70.4 (a generousgift from J. D. Bangs, University of Wisconsin—Madison)and rabbit anti-CTD (RNAPII; a generous gift from Vivian Bellofatto,University of Medicine and Dentistry of New Jersey) antibodies,respectively. TbPRMT5-TAP localization was analyzed by immunoblottingusing peroxidase-anti-peroxidase (PAP) soluble-complex antibodyproduced in rabbits (Sigma), which recognizes the protein Amoiety of the TAP tag.

Glycerol gradient sedimentation. For the analysis of in vivo TbPRMT5 protein complexes, 500 µlof clarified whole-cell extract prepared from 1 x 10⁹ log-phaseTbPRMT5-TAP cells was fractionated in triplicate over a 5 to20% linear glycerol gradient. Glycerol gradients were preparedin gradient buffer (10 mM HEPES [pH 7.9], 1.5 mM MgCl₂, 10 mMKCl, 0.5 mM dithiothreitol, 1 µg/ml pepstatin A, 1 µg/mlleupeptin, 1 mM benzamidine, 0.5 mM PMSF), and samples werefractionated by centrifugation at 35,000 rpm for 20 h at 4°Cin a Beckman SW-41 rotor. Twenty-five 500-µl fractionswere collected from the top of each glycerol gradient, resolvedby denaturing (12.5 µl) and nondenaturing (10 µl)gel electrophoresis alongside 20 µg of TbPRMT5-TAP whole-cellextract, and analyzed by immunoblotting using the TAP-specificPAP reagent. The sedimentation of TbPRMT5-TAP-containing proteincomplexes was compared to the sedimentation of cytochrome c(1.9S), BSA (4.3S), yeast alcohol dehydrogenase (7.4S), catalase(11.3S), and thyroglobulin (19S) protein standards fractionatedin a parallel glycerol gradient (also performed in triplicate).

Native gel electrophoresis. Nondenaturing (native) electrophoresis was performed using Novex4 to 12% polyacrylamide gradient Tris-glycine gels (Invitrogen)as described by the manufacturer. For the analysis of glycerolgradient fractions, the addition of a buoyancy reagent was omittedfrom the native sample buffer. A High Molecular Weight CalibrationKit for Native Electrophoresis (Amersham Biosciences) was usedfor molecular weight standards.

Immunoblot analysis. For the immunoblot analysis of TbPRMT5-TAP subcellular localization,15 µg of whole-cell, cytoplasmic, or nuclear extract wasresolved by 12.5% SDS-PAGE and transferred to nitrocellulose(Bio-Rad) at 50 V for 75 min in 10 mM 3-[cyclohexylamino]-1-propanesulfonicacid buffer (pH 11.0) containing 10% methanol. The membraneswere blocked for 1 h in Tris-buffered saline containing 5% (wt/vol)dry milk. For the detection of TbPRMT5-TAP, membranes were incubatedwith 1:2,000 PAP soluble-complex antibody (Sigma) for 1 h, andPAP was detected by chemiluminescence using the SupersignalWest Pico Chemiluminescent Substrate Solution (Pierce). Themembrane was then stripped and incubated overnight with eitheranti-TbHsp70.4 (cytosolic marker) or anti-CTD (RNAPII nuclearmarker) primary antibody in Tris-buffered saline containing2% (wt/vol) dry milk and 0.05% Tween 20. Primary antibodieswere detected using horseradish peroxidase-conjugated goat anti-rabbitimmunoglobulin G (IgG) (Pierce) secondary antibody and detectedby chemiluminescence.

For the immunoblot analysis of native TbPRMT5-TAP-containingcomplexes, samples were resolved on Novex 4 to 12% Tris-glycinegels (Invitrogen) by nondenaturing electrophoresis and transferredto nitrocellulose for 2 h at 25 V, as described by the manufacturer.TAP-containing complexes were detected using PAP soluble-complexantibodies, as described above.

TbPRMT5-TAP tandem-affinity purification. Ectopically expressed TbPRMT5-TAP protein was purified by tandem-affinitypurification as described previously (78) with some modifications.For the analysis of native TbPRMT5-TAP-associated complexes,1.25 x 10¹⁰ cells were harvested from either wild-type or TbPRMT5-TAPlog-phase cultures. The cell pellets were washed with 100 mlof PBS-G (1x PBS containing 6 mM glucose), centrifuged at 6,090x g for 10 min, and resuspended in 9 ml of IPP150 buffer (10mM Tris-HCl [pH 8.0], 150 mM NaCl, 0.1% NP-40) containing 1%(wt/vol) BSA and 1 Complete Mini EDTA-free protease inhibitortablet (Roche Diagnostics). The cells were lysed on ice for20 min after the addition of 1% (vol/vol) Triton X-100, andthe crude extract was clarified by centrifugation at 10,000x g for 15 min at 4°C. TbPRMT5-TAP-associated complexeswere purified from whole-cell extract (10 ml) over tandem IgG-Sepharose6 Fast Flow (Amersham Biosciences) and calmodulin resin (Stratagene)columns as described previously (78). Native TbPRMT5-TAP-associatedcomplexes were eluted in 1-ml volumes. Ten percent of the finaleluate was TCA precipitated (10% final concentration) and analyzedby 12.5% SDS-PAGE, followed by silver staining. The remainingTbPRMT5-calmodulin-binding protein (CBP) final eluate was digestedwith trypsin and analyzed by liquid chromatography-tandem massspectrometry (LC-MS/MS).

For the analysis of TbPRMT5-CBP enzymatic activity, cytosolicextract prepared from 1 liter of TbPRMT5-TAP log-phase cellswas dialyzed overnight at 4°C in two 1-liter changes ofIPP150 buffer containing 1 mM benzamidine, 0.5 mM PMSF, 1 µMleupeptin, and 1 µg/ml pepstatin protease inhibitors.The dialyzed extract was divided into three equal volumes andseparately purified over tandem IgG-Sepharose 6 Fast Flow (AmershamBiosciences) and calmodulin resin (Stratagene) columns as describedpreviously (78). Before final elution, the three different calmodulincolumns were washed with buffer containing either 0.15 M, 0.5M, or 1 M NaCl. The resultant eluates were dialyzed in two 1-literchanges of methyltransferase assay buffer and assayed for activity.Protein composition was analyzed by 12.5% SDS-PAGE and silverstaining. The protein concentration was estimated by comparisonto a BSA standard curve run on the same gel.

RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

T. brucei harbors genes encoding at least two putative type II PRMTs. We previously reported biochemical evidence for both type Iand type II PRMT activities in T. brucei cellular extracts (74),and the gene encoding the major type I PRMT (TbPRMT1) has beenidentified (72). To elucidate the entire complement of PRMTsin this evolutionarily ancient organism and to identify thegene(s) responsible for type II activity, we performed a proteinBLAST search against the T. brucei genomic database using theH. sapiens PRMT1 (type I) and PRMT5 (type II) sequences as queries.A comparison of these BLAST results with all predicted methyltransferasesin The Institute for Genomic Research's T. brucei AnnotationDatabase identified five putative PRMTs in T. brucei. Figure1A presents the phylogenic analysis of the putative trypanosomePRMTs compared to the known PRMTs in H. sapiens. Two trypanosomeproteins (Tb10.70.7570 and Tb927.7.5490) cluster with the best-characterizedhuman type II enzyme, PRMT5, in which the methyltransferaseidentified on locus Tb10.70.7570 is most similar. The otherputative T. brucei type II PRMT (Tb927.7.5490) exhibits homologyto mammalian PRMT7, although the trypanosome protein lacks thesecond putative AdoMet binding domain found in human PRMT7.Two of the five trypanosome PRMTs (Tb927.1.4690 and Tb927.5.3960),including the previously characterized TbPRMT1 (72), share clearhomology with type I enzymes. Interestingly, the remaining PRMTidentified at locus Tb10.70.3860 exhibits characteristics ofboth type I and type II enzymes. This enzyme is most similarto PRMT3, which is a type I enzyme. However, Tb10.70.3860 lacksthe conserved THW loop that is found in all previously characterizedtype I PRMTs but which is frequently less conserved in typeII enzymes. Tb10.70.3860 also harbors a substitution at thesecond, normally invariant glutamate residue of the double-Eloop (E225D). Homologous genes that exhibit the same conservedchanges are also present in the genomes of the related organismsT. cruzi and L. major, suggesting a conserved role for thisenzyme in trypanosomatid biology. Taken together, our analysisindicates that the T. brucei genome encodes five putative PRMTs,including the previously characterized major type I enzyme,TbPRMT1 (72).

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FIG. 1. TbPRMT5 is a putative type II PRMT with a conserved methyltransferase domain. (A) Phylogenetic analysis of putative PRMTs identified in T. brucei with PRMT homologs from H. sapiens. Phylogenetic analysis was performed using the ClustalW multiple-sequence alignment tool. The GenBank accession numbers are as follows: HsPRMT1, NP_001527; HsPRMT2, NP_001526; HsPRMT3, NP_005779; HsPRMT4, NP_954592; HsPRMT5, O14744; HsPRMT6, Q96LA8; HsPRMT7, NP_061896; and HsPRMT8, Q9NR22. (B) Schematic representation of PRMT5 homologs from T. brucei (TbPRMT5), H. sapiens (PRMT5/JBP1; GenBank accession no. O14744), and S. pombe (Skb1; GenBank accession no. P78963) illustrating the presence of a conserved methyltransferase domain (motifs I, Post I, II, and III) and variable N termini. The percent amino acid identity/similarity over the core catalytic domain (278 amino acids in TbPRMT5) is shown. (C) A multiple-sequence alignment of core catalytic domains and flanking regions of the PRMTs shown in panel B was generated using ClustalW. Similar amino acids are shaded gray, while identical amino acids are shaded black. The conserved AdoMet binding domain (motifs I, Post I, II, and III) is indicated above the sequences. The double-E loop is denoted with asterisks. The THW domain is denoted with a bar and does not appear to be conserved in type II PRMTs. Tb, T. brucei; HS, H. sapiens; Sp, S. pombe.

To further characterize the putative PRMT5 homolog in T. brucei,the ORF of Tb10.70.7570 was amplified by reverse transcription-PCRfrom PF RNA, cloned into the pMAL-c2 bacterial expression vector,and sequenced. The 2,349-nucleotide ORF, which we term TbPRMT5,shares 99% nucleotide sequence identity with the T. brucei TRUE927genomic strain and encodes a 783-amino-acid protein with theexpected molecular mass and isoelectric point of 86.7 kDa and5.52, respectively. Sequence analysis of TbPRMT5 using BLASTand CLUSTALW proteomic tools indicated that TbPRMT5 containsa conserved methyltransferase domain (amino acids 432 to 710)that displays 30/44% and 29/44% identity/similarity with PRMT5homologs from H. sapiens (PRMT5/JBP1) and S. pombe (Skb1), respectively(Fig. 1B and C). The core catalytic domains of human (aminoacids 361 to 581) and yeast (amino acids 348 to 577) PRMT5 homologsshare 47/62% amino acid identity/similarity, consistent withthe closer evolutionary relationship of the kingdoms Animaliaand Fungi to each other than to Protista. Similar to other PRMT5homologs, TbPRMT5 has an N-terminal addition outside the catalyticcore (432 amino acids), in which no conserved domains or bindingmotifs have been detected. The N-terminal domain of TbPRMT5is extended compared to that in other PRMT5 homologs by approximately75 amino acids. The signature methyltransferase domain commonto all PRMTs, including TbPRMT5 (Fig. 1C), includes an AdoMetbinding domain (motifs I, Post I, II, and III), as well as adouble-E loop, whose glutamate residues make up part of thearginine-binding pocket (97, 98). The catalytic core of typeI PRMTs also contains a THW loop, in which the histidine residueis thought to participate in an active-site His-Asp proton relaysystem in the elimination of a proton from substrate arginineresidues (98). As stated above, this THW loop is not conservedin type II PRMTs (50, 98), and this holds true for TbPRMT5,as well. Collectively, phylogenetic and sequence analyses indicatethat TbPRMT5 represents the T. brucei homolog of mammalian PRMT5and yeast Skb1.

Recombinant TbPRMT5 exhibits methyltransferase activity in a concentration- and time-dependent manner. To confirm that TbPRMT5 possesses methyltransferase activity,we expressed TbPRMT5 in E. coli as an MBP fusion protein (Fig.2). An SDS-PAGE gel showing the partial purification of MBP-TbPRMT5by affinity chromatography on amylose resin (Fig. 2A) demonstratedthat the protein was expressed as a 128-kDa fusion protein (comparelanes PI and I) and that it constituted the major protein inthe column eluate (lane E). Minor contaminating proteins arenot expected to exhibit PRMT activity, since prokaryotes lackthis class of enzyme (50). The PRMT activity of MBP-TbPRMT5was assayed in the presence of [methyl-³H]AdoMet and recombinantRBP16, a trypanosome RNA binding protein with an RG-rich C terminusthat is methylated in vivo (74). Methylation assays were performedin the presence of either increasing (Fig. 2B) or fixed (Fig.2C) concentrations of MBP-TbPRMT5 to determine the concentrationand time dependence of the enzyme activity, respectively. Theseassays clearly demonstrated that RBP16 is methylated in vitroby MBP-TbPRMT5. Analysis of triplicate experiments showed thatMBP-TbPRMT5 exhibited methyltransferase activity in both a concentration-and time-dependent manner. Thus, we conclude that, as predictedby its sequence, TbPRMT5 is a PRMT.

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FIG. 2. Recombinant MBP-TbPRMT5 exhibits time- and concentration-dependent in vitro methyltransferase activity. (A) Coomassie-stained 10% SDS-PAGE gel showing the partial purification of recombinant TbPRMT5. TbPRMT5 was cloned and expressed as an N-terminal MBP fusion protein and partially purified by affinity chromatography over amylose resin. M, markers; PI, preinduced; I, induced; E, eluate from amylose column. (B) Recombinant MBP-TbPRMT5 exhibits concentration-dependent in vitro methyltransferase activity. In vitro methylation assays were performed in triplicate for 1 h at 36°C in the presence of 1 µM [methyl-³H]AdoMet, 5 µM His-RBP16, and increasing concentrations of MBP-TbPRMT5. The reactions were stopped with the addition of SDS sample buffer, resolved by 15% polyacrylamide SDS-PAGE, and analyzed by fluorography. Bands were quantified using Bio-Rad Quantity One imaging software. The background OD was subtracted and set to 0. The graph shows the mean ± standard deviation of triplicate experiments. A representative fluorograph and corresponding Coomassie-stained gel are shown above the graph. The positions of MBP-TbPRMT5 and His-RBP16 in the Coomassie-stained gel are indicated with arrows. (C) Time course of MBP-TbPRMT5 in vitro methyltransferase activity. In vitro methyltransferase assays were performed in triplicate at 36°C in the presence of 1 µM [methyl-³H]AdoMet, 3 µM His-RBP16, and 0.3 µM MBP-TbPRMT5. Aliquots were taken at the indicated time points, and the reactions were stopped with the addition of SDS sample buffer. The reactions were analyzed as described for panel B, except baseline OD values were normalized to the minimal value of triplicate experiments. Labels as in panel B.

Recombinant TbPRMT5 exhibits broad substrate specificity. We next wanted to examine the substrate specificity of TbPRMT5.Since TbPRMT5 was predicted to be a type II PRMT, we asked whetherits substrate specificity differs from that of a well-characterizedtype I PRMT, mammalian PRMT1 (55). To assess the substrate specificityof TbPRMT5, methylation assays were performed in the presenceof [methyl-³H]AdoMet, various PRMT substrates indicated in Fig.3, and equal molar MBP-TbPRMT5 or rat GST-PRMT1. Arginine residuesfound within the context of RGG, RG, or RXR motifs are commonsites of methylation (reviewed in reference 60). Thus, we firstdetermined whether TbPRMT5 methylates arginine residues in theRG context by assaying its activity toward a peptide consistingof seven RG repeats (22). TbPRMT5 robustly methylated the RGpeptide in vitro to an extent similar to that of PRMT1. We nextcompared the substrate specificities of TbPRMT5 and PRMT1 towardwell-characterized PRMT substrates that lack extensive RGG-richregions: calf thymus core histones and myelin basic protein.While PRMT1 is reported to methylate only histone H4 (85, 87),PRMT5 has been reported to methylate histones H2A (13, 52, 76),H3 (69, 70), and H4 (52, 76). Myelin basic protein harbors MMAor sDMA modifications in vivo (5, 14) and is an in vitro substratefor human PRMT5 (13, 76). Methylation of both histone H4 andmyelin basic protein reportedly occurs in the GRG context (14,87). In our in vitro methylation assays, we found that TbPRMT5and PRMT1 displayed very similar activities toward the corehistones, methylating both histones H4 and, to a lesser extent,H2A. Both TbPRMT5 and PRMT1 exhibited methylation activitiestoward myelin basic protein, with TbPRMT5 showing greater activity,as expected for a type II enzyme. These data demonstrate thatTbPRMT5 is highly active toward the RG peptide and suggest thatproteins harboring arginine residues found within this contextmay also be good substrates for this enzyme.

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FIG. 3. Recombinant MBP-TbPRMT5 exhibits broad substrate specificity. MBP-TbPRMT5 exhibits in vitro methyltransferase activity toward a synthetic RG peptide, core histones H4 and H2A (arrows), myelin basic protein, and the trypanosome RNA binding protein, His-RBP16. For the core histone substrates, in vitro methylation assays were performed at 36°C for 1 h in the presence of 1 µM [methyl-³H]AdoMet, 10 µg calf thymus core histones, and 0.1 µM of either rat GST-PRMT1 or MBP-TbPRMT5. For the remaining substrates, in vitro methylation assays were performed at 36°C for 1 h in the presence of 1 µM [methyl-³H]AdoMet, 30 µM RG peptide or 1.2 µM of the indicated substrates, and 0.3 µM of either rat GST-PRMT1 or MBP-TbPRMT5. The reaction mixtures were resolved on 10 or 15% SDS-PAGE gels, and tritiated substrates were visualized by fluorography. Representative fluorographs and corresponding Coomassie-stained SDS-PAGE gels of triplicate experiments are shown. The positions of enzymes and substrates are indicated with asterisks and arrows, respectively. Note that a breakdown product of MBP-TbPRMT5 comigrates with myelin basic protein. The fluorographs correspond to the regions of the gels indicated above with arrows.

Since RNA binding proteins harboring RGG-rich motifs are preferredsubstrates for type I enzymes (reviewed in reference 60), wenext assessed the specificity of TbPRMT5 toward similar proteinsof trypanosome origin. We demonstrated (Fig. 2) that TbPRMT5could utilize the trypanosome RBP16 protein as a substrate.RBP16 is methylated in both RGG and non-RGG contexts in vivo(74). When we compared the activity of TbPRMT5 toward this substratewith that of PRMT1, we found that TbPRMT5 exhibited relativelyweak activity toward RBP16 compared to PRMT1. Analysis of theRBP16 cold shock domain (His-CSD) and RGG domain (His-RGG) (63)confirmed that both enzymes exclusively methylated residueswithin the RGG-containing C terminus of the protein. We nextexamined the activity of TbPRMT5 toward the RGG-rich T. bruceimitochondrial-RNA binding protein, TBRGG1 (Fig. 3, MBP-TBRGG1)(91). We previously demonstrated that the N-terminal RGG domainof TBRGG1 is methylated in vitro by the trypanosome type I enzyme,TbPRMT1 (72). Interestingly, TbPRMT5 is completely unable tomethylate MBP-TBRGG1, although the same protein was robustlymethylated by PRMT1 in a parallel assay. A control assay withthe MBP tag alone confirmed that methylation of MBP-TBRGG1 byPRMT1 occurred within the TBRGG1 portion of the protein. Takentogether, these results indicate that TbPRMT5 exhibits unexpectedlybroad substrate specificity. Based on the robust methylationof the RG peptide and the reported in vivo methylation of histoneH4 and myelin basic protein occurring on arginines in the contextof GRG (14, 87), these data suggest that TbPRMT5 has a preferencefor methylation of arginines within the context of GRG, as opposedto those within extensive RGG motifs.

Recombinant TbPRMT5 catalyzes the formation of monomethylarginine and symmetric dimethylarginine in proteins. TbPRMT5 is predicted by its sequence to be a type II enzymeand therefore is predicted to synthesize MMA and sDMA modifications.Since TbPRMT5 displays substrate specificity with many similaritiesto rat PRMT1, it was important to directly analyze the modificationscatalyzed by TbPRMT5 in vitro. To this end, we determined theidentity of [methyl-³H]arginine modifications in various TbPRMT5substrates after acid hydrolysis and fractionation of substrateamino acids by TLC alongside MMA, aDMA, sDMA, and AdoMet standards(Fig. 4). Methylation assays were performed in the presenceof [methyl-³H]AdoMet and either increasing concentrations ofMBP-TbPRMT5 (Fig. 4A) or the indicated substrates (Fig. 4B, C, and D).Control reactions for each substrate were performed in the presenceof GST-PRMT1 (Fig. 4A to D) and in the absence of either enzyme(Fig. 4A and B) or substrate (Fig. 4C and D). With all substrates,we observed that PRMT1 catalyzed the formation of MMA and aDMA,as previously demonstrated (55). The methylation profile forTbPRMT5-catalyzed reactions differed from that of PRMT1. Aminoacid analysis of all four substrates clearly demonstrated thatTbPRMT5 catalyzes the formation of MMA (Fig. 4A to D). In thepresence of RG peptide (Fig. 4A), core histones (Fig. 4B), ormyelin basic protein (Fig. 4C), TbPRMT5 also catalyzed the formationof a substantial amount of sDMA. A small amount of sDMA synthesiswas observed with the RBP16 substrate at the highest substrateconcentration, although MMA was clearly the most dominant modificationon this substrate and aDMA also appeared to be present (Fig.4D).

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FIG. 4. Recombinant MBP-TbPRMT5 catalyzes the formation of monomethylarginine and symmetric dimethylarginine in a substrate- and concentration-dependent manner. (A) Amino acid analysis of an RG peptide methylated in vitro by recombinant MBP-TbPRMT5. In vitro methylation assays were performed at 36°C for 1 or 24 h (far-right lane) in the presence of 1 µM [methyl-³H]AdoMet, 30 µM RG peptide substrate, and either 0.3 µM GST-PRMT1 or the indicated concentrations of MBP-TbPRMT5. Samples were acid hydrolyzed to free amino acids and resolved by TLC alongside 30 nmol of the indicated amino acid standards shown to the right, as described in Materials and Methods. (B) Amino acid analysis of methylated calf thymus core histones. Assays were performed for 16 h at 36°C in the presence of 1 µM [methyl-³H]AdoMet, 10 to 40 µg core histone substrate, and either 0.07 µM GST-PRMT1 or 0.13 µM MBP-TbPRMT5. The reactions were stopped and analyzed as described for panel A. (C) Amino acid analysis of methylated myelin basic protein. Assays were performed for 16 h at 36°C in the presence of 1 µM [methyl-³H]AdoMet, the indicated molar excess (X) of myelin basic protein substrate, and either 2.2 µM GST-PRMT1 or 0.5 µM MBP-TbPRMT5. The reactions were stopped and analyzed as described for panel A. (D) Amino acid analysis of methylated His-RBP16. Assays were performed for 16 h at 36°C in the presence of 1 µM [methyl-³H]AdoMet, the indicated molar excess (X) of His-RBP16 substrate, and either 0.05 µM GST-PRMT1 or 0.7 µM MBP-TbPRMT5. The reactions were stopped and analyzed as described for panel A.

In our TLC analyses, we frequently observed an unknown [³H]methylspecies that comigrated between the MMA and aDMA standards inthe presence of RG peptide and core histone substrates (Fig.4A and B). In addition, we suspected that the RBP16 [³H]methylspecies observed comigrating with or near aDMA by TLC (Fig.4D) might be the same or a similar unknown [³H]methyl species.Because of the possibility that [methyl-³H]AdoMet breakdownproducts might complicate the TLC analyses, especially in thepresence of substrate proteins, we decided to use high-resolutioncation ion-exchange amino acid analysis, in which larger amountsof hydrolyzed proteins can be fractionated, to confirm thatTbPRMT5 catalyzes the production of solely MMA and sDMA andno other novel products (Fig. 5). Amino acid analysis of corehistones (Fig. 5A) and His-RBP16 (Fig. 5B) substrates revealedonly MMA and sDMA and did not reveal the presence of a novel[³H]methyl species that exhibited a difference in comigrationcompared to MMA, aDMA, or sDMA standards. These results confirmedthat TbPRMT5 catalyzes the formation of MMA and sDMA in corehistones. Cation-exchange chromatography also indicated thatTbPRMT5 catalyzes primarily MMA, and a relatively small amountof sDMA, in the trypanosome RNA binding protein His-RBP16 (Fig.5B). The identities of the peak radioactive fractions 76 to79 for the His-RBP16 sample were further confirmed to be sDMA,after the samples were pooled, desalted, and analyzed by TLCalongside MMA, aDMA, and sDMA amino acid standards (data notshown). In conclusion, combined TLC and cation-exchange analysesindicate that TbPRMT5 catalyzes the formation of MMA and sDMAin proteins and is therefore a type II enzyme.

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FIG. 5. Amino acid analysis detects monomethylarginine and symmetric dimethylarginine in core histones and RBP16. Purified MBP-TbPRMT5 was incubated with the methyl-accepting substrate core histones (A) or His-RBP16 (B) and analyzed by amino acid analysis as described in Materials and Methods. TCA-precipitated and acid-hydrolyzed samples were applied to a cation-exchange column with unlabeled MMA, aDMA, and sDMA standards. To detect ³H radioactivity (open diamonds), 200 µl of each fraction was mixed with 400 µl water and 5 ml fluor. Radioactivity was determined using a Beckman LS6500 counter as an average of three 3-min counting cycles. Unlabeled standards (closed squares) were detected with a ninhydrin assay using 100 µl of each fraction (66). As expected, the ³H radiolabel for sDMA and MMA migrated slightly ahead of the nonisotopically labeled standards due to a tritium isotope effect in the ion-exchange chromatography, where three tritium atoms replace three hydrogen atoms on each methyl group (35, 40).

TbPRMT5 is constitutively expressed in BF and PF life stages of the parasite, and localizes to the cytoplasm. Having identified TbPRMT5 as a type II PRMT, we next wantedto determine the properties of the enzyme in vivo. To assesswhether TbPRMT5 is differentially expressed in BF and PF lifestages of the parasite, we analyzed RNA isolated from BF andPF trypanosomes by Northern blotting using a TbPRMT5-specificprobe (Fig. 6A). We detected one transcript of approximately3,200 nucleotides, indicating the presence of combined 5' and3' untranslated regions of approximately 850 nucleotides. Theabundances of this transcript were similar in BF and PF lifestages, indicating that TbPRMT5 is constitutively expressedthroughout the T. brucei life cycle.

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FIG. 6. TbPRMT5 is constitutively expressed in PF and BF life stages and localizes to the cytoplasm. (A) Northern blot analysis of TbPRMT5 expression in PF and BF life stages. Twenty micrograms of total RNA isolated from log-phase PF and BF parasites was resolved on a 1.5% formaldehyde-agarose gel, transferred to a nylon membrane, and hybridized with a full-length TbPRMT5 antisense riboprobe. To normalize for loading, the membrane was stripped and hybridized with a 5' end-labeled oligonucleotide probe complementary to tubulin mRNA. (B) TbPRMT5 localizes to the cytoplasm. To determine the subcellular localization of TbPRMT5, a PF cell line expressing TbPRMT5-TAP was subjected to subcellular fractionation, followed by immunoblot analysis. Fifteen micrograms of wild-type (WT) or TbPRMT5-TAP (WC) whole-cell extract was resolved by SDS-PAGE alongside equivalent microgram amounts of TbPRMT5-TAP cytoplasmic (Cyt) and nuclear (Nuc) extracts. The proteins were electroblotted to nitrocellulose, and the fractionation of TbPRMT5-TAP was analyzed using the TAP-specific PAP soluble-complex reagent. The efficiency of subcellular fractionation was assessed by Western blotting using antibodies against cytoplasmic (TbHsp70.4) and nuclear (RNAP CTD) proteins.

To determine the subcellular localization of TbPRMT5, we engineereda PF cell line constitutively expressing a C-terminal TAP-taggedfusion protein. Topology prediction programs did not detecta signal peptide or localization signal for TbPRMT5, and theprotein was therefore predicted to localize to the cytoplasm.Whole-cell extracts were prepared from log-phase TbPRMT5-TAP-expressingcells and fractionated into cytoplasmic and nuclear subcellularfractions. The subcellular fractionation of TbPRMT5-TAP wasanalyzed by immunoblotting using the PAP reagent, which detectsthe protein A moiety of the TAP tag (Fig. 6B). As a controlto assess the efficiency of cytoplasmic and nuclear fractionations,the membrane was stripped and analyzed by Western blotting usinganti-TbHsp70.4 and anti-CTD antibodies, respectively. As shownin Fig. 6B, the expected 107-kDa fusion protein was expressedonly in TbPRMT5-TAP-expressing cells and was absent from wild-typecells. Analysis of subcellular fractions indicated that TbPRMT5-TAPwas present almost exclusively in the cytoplasmic fraction andwas essentially absent from the nucleus. Therefore, similarto the localization reported for human PRMT5 (77), TbPRMT5 ispredominantly localized to the cytoplasm.

TbPRMT5 associates with a homolog of the DEAD box RNA helicase, Ded1p, and novel trypanosome proteins. To investigate the possible biological processes in which TbPRMT5may play a role, we utilized our PF TbPRMT5-TAP-expressing cellline to analyze the compositions of native TbPRMT5 protein complexes(Fig. 7). To address whether TbPRMT5 is present in macromolecularcomplexes, we subjected whole-cell extract prepared from TbPRMT5-TAP-expressingcells to glycerol gradient fractionation (Fig. 7A). Fractionsfrom a 5 to 20% glycerol gradient were first resolved by SDS-PAGEand analyzed by immunoblotting using the TAP-specific PAP reagent(Fig. 7A, top). TbPRMT5-TAP-containing complexes sedimentedpredominantly at 8 to 10S, with minor complexes exhibiting sedimentationvalues up to 19S. Monomeric TbPRMT5-TAP was expected to exhibitsedimentation values of less than 7.4S. Therefore, the sedimentationpattern of TbPRMT5-TAP suggested the presence of both monomersand higher-order complexes. To further characterize higher-orderTbPRMT5-TAP-containing complexes, we then fractionated bothwhole-cell extract and glycerol gradient fractions by nondenaturingPAGE (Fig. 7A, bottom). These analyses demonstrated that inwhole-cell extract TbPRMT5-TAP is a component of protein complexesapproximately 250 kDa and 700 kDa in mass (Fig. 7A, bottom,lane WC). The larger of these complexes is less stable, as itdoes not withstand glycerol gradient fractionation (Fig. 7A,bottom, fractions 1 to 25). Upon native gel analysis of 5 to20% glycerol gradient fractionation, we observed primarily twobands with apparent molecular masses of approximately 140 kDaand 250 kDa, suggesting that monomeric and dimeric forms ofthe enzyme may be in equilibrium during the gradient sedimentationand native PAGE. Taken together, these results suggest thatTbPRMT5 is present in relatively unstable macromolecular complexes,which may be either homo- or heteromultimers.

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FIG. 7. Analysis of in vivo TbPRMT5 protein complexes. (A) Glycerol gradient fractionation of TbPRMT5-TAP-containing complexes. Whole-cell extract prepared from PF trypanosomes ectopically expressing a TbPRMT5-TAP fusion protein was fractionated by centrifugation on a 5 to 20% glycerol gradient. The fractions were resolved by either denaturing polyacrylamide gel electrophoesis (SDS PAGE; top) or nondenaturing PAGE (native PAGE; bottom), and TbPRMT5-TAP-containing complexes were analyzed by immunoblotting using the TAP-specific PAP reagent. Twenty micrograms of whole-cell extract (WC) was analyzed by both methods for comparison. The sedimentation values and molecular masses of protein standards are indicated. (B) Tandem-affinity purification of native TbPRMT5 protein complexes. Wild type (W) or TbPRMT5-TAP (T) whole-cell extracts were fractionated by tandem-affinity purification over consecutive IgG-Sepharose and calmodulin resin columns. A silver-stained SDS-PAGE gel of TbPRMT5-CBP purification and complex composition is shown. TbPRMT5-CBP (arrow; 91.5 kDa) was eluted from IgG-Sepharose resin after TEV protease cleavage (TEV eluate), purified over calmodulin resin (Calm), and eluted under native conditions with EGTA (EGTA eluate). Major copurifying proteins present only in eluates of TAP-expressing cells (EGTA eluate; cf. lanes W and T) are indicated (asterisks). WC Supe, whole-cell supernatant; IgG FT, IgG-Sepharose resin flowthrough; TEV, TEV protease; Calm FT, calmodulin resin flowthrough.

To identify native TbPRMT5-associated proteins, we purifiedTbPRMT5-TAP by tandem-affinity chromatography over consecutiveIgG-Sepharose and calmodulin resin columns (Fig. 7B). Tobaccoetch virus (TEV) protease cleavage of the TbPRMT5-TAP chimeraexposed a C-terminal CBP moiety that could then be purifiedover calmodulin resin and eluted under native conditions withEGTA. The composition of TbPRMT5-TAP protein complexes wereanalyzed by SDS-PAGE and silver staining (Fig. 7B), or the complexeswere digested with trypsin and analyzed by LC-MS/MS (Table 1).The SDS-PAGE gel in Fig. 7B shows the composition of IgG-Sepharoseand calmodulin resin eluates from wild-type or TbPRMT5-TAP whole-cellextracts. As expected, TEV protease (27-kDa protein) cleavageresulted in the elution of a prominent 91.5-kDa protein thatwas present in TAP eluates and not in wild-type eluates. Thisprotein was not present in the calmodulin resin flowthroughbut was eluted with EGTA from calmodulin resin, indicating thatit was TbPRMT5-CBP. Three TbPRMT5-copurifying proteins withapparent molecular weights of 40, 75, and 85 were visible onlyin the TAP EGTA eluates, where they were present in approximatelyequivalent ratios. Mass spectrometry analysis (Table 1) didnot detect TbPRMT5-interacting proteins with the predicted molecularmasses of 40 and 85 kDa. Since PRMT5 homologs are reported tointeract with themselves (32) and to homo-oligomerize (77),we suspect that the copurifying 85-kDa band was endogenous TbPRMT5(the theoretical mass is 86.7 kDa). Mass spectrometry analysisof final TAP eluates did reveal the presence of a predicted71.3-kDa protein, which may represent the 75-kDa protein observedby silver staining. This protein (Tb10.61.2130) contains anRGG-rich C terminus and a DEAD box motif, and the latter definesit as a putative RNA helicase. BLAST search analyses performedagainst human, yeast, and fruitfly genomes indicated that thisputative RNA helicase is related to the translation initiationfactors Ded1p from S. pombe (43) and S. cerevisiae (21, 26)and Drosophila melanogaster Vasa (16, 36). This protein, whichwe refer to as TbDED1, displays 49/64% and 41/61% amino acididentity/similarity to Ded1p and Vasa, respectively. The presenceof an RGG-rich C terminus suggests that TbDED1 is a substratefor arginine methylation and further substantiates the interactionobserved between this protein and TbPRMT5.

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TABLE 1. TbPRMT5-TAP-associated proteins identified by mass spectrometry

Mass spectrometry analysis also identified two hypotheticalconserved proteins (Tb10.389.1040 and Tb09.160.1400) in TbPRMT5-TAPeluates. These hypothetical T. brucei proteins have predictedmolecular masses of 121.2 and 147.2 kDa, respectively, and haveno homologs outside the kinetoplastid protozoa. While they donot contain RG-rich or conserved domains, the methylation siteprediction program MeMo (19; http://www.bioinfo.tsinghua.edu.cn/ $~$ tigerchen/memo.html),identified several potential sites of arginine methylation inboth proteins. In addition, Tb10.389.1040 was inferred by electronicannotation to possess nucleic acid binding activity, suggestingthat this protein may play a role in nucleic acid metabolism.Another novel protein that was identified in TbPRMT5-TAP eluateswas the cytosolic tryparedoxin peroxidase, which is involvedin the detoxification of hydrogen peroxides produced from aerobicmetabolism (90). Interestingly, no obvious homologs of the humanPRMT5-containing 20S methylosome (MEP50/pICln/p37) were identifiedin either the T. brucei genomic database or TbPRMT5-TAP eluates.Taken together, our results suggest that TbPRMT5 is presentin novel kinetoplastid-specific complexes.

Endogenous cofactors do not appear to modulate the enzymatic properties of TbPRMT5. We demonstrated that bacterially expressed TbPRMT5 is competentto catalyze the formation of both MMA and sDMA in the absenceof trypanosome cofactors (Fig. 2 to 5). To determine if endogenouscofactors modulate the enzymatic properties of TbPRMT5, we nextexamined the activity of TbPRMT5 isolated from its native context(Fig. 8). Since TbPRMT5 localizes to the cytoplasm (Fig. 6),we isolated TbPRMT5-CBP by tandem-affinity chromatography fromPF cytosolic extract and assessed its substrate specificitiestoward RBP16 and TBRGG1 trypanosome proteins. We first assessedthe affinity of TbPRMT5-associated proteins by running threeseparate calmodulin columns that were washed with increasingconcentrations of NaCl (0.15, 0.5, or 1 M). Figure 8A showsa silver-stained SDS-PAGE gel of the final calmodulin resineluates. A large number of proteins copurify with TbPRMT5-CBPunder the two lower-salt wash conditions. However, when washeswere performed with 1 M NaCl, the majority of these proteinswere removed, with the exception of four major salt-resistantcopurifying proteins. These salt-resistant proteins were mostlikely contaminating CBPs, since several were detected by massspectrometry in native TbPRMT5-TAP eluates (data not shown).We did not observe a copurifying protein corresponding to themolecular mass of endogenous TbPRMT5 (86.7 kDa) in these eluates,although we cannot rule out the possibility that it was presentbelow the level of detection. To determine if endogenous trypanosomecytosolic factors act to modulate the substrate specificityof TbPRMT5, we compared the activities of TbPRMT5 prepared underdifferent salt washes to those of recombinant enzyme (Fig. 8B).Identical to the bacterially produced TbPRMT5 protein, TbPRMT5-CBPmethylated RBP16 but did not display any activity toward theTBRGG1 substrate. The complete absence of TBRGG1 methylation,even with preparations washed at relatively low salt (0.15 M),indicated that the previously characterized type I enzyme, TbPRMT1,did not copurify with TbPRMT5. In the presence of the RBP16substrate, we observed similar levels of activity with TbPRMT5-CBPprepared under all salt concentrations. Thus, TbPRMT5-associatedproteins do not appear to regulate either the substrate specificityor activity of the enzyme.

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FIG. 8. The enzymatic properties of TbPRMT5-CBP purified from T. brucei are equivalent to those of recombinant enzyme. (A) Silver-stained SDS-PAGE gel showing the final eluates of TbPRMT5-CBP purified by tandem-affinity purification over IgG-Sepharose and calmodulin resins. Three separate purifications were performed. Prior to final elution, the eluates were washed with either 0.15, 0.5, or 1 M NaCl. The asterisks denote salt-resistant TbPRMT5-CBP-copurifying proteins. (B) TbPRMT5-CBP methylates His-RBP16, but not MBP-TBRGG1, in vitro. In vitro methylation assays were performed at 36°C for 1 h in the presence of 1 µM [methyl-³H]AdoMet, 1.4 µM substrate, and either 0.1 µM recombinant MBP-TbPRMT5 or 0.6 nM TbPRMT5-CBP washed with 0.15, 0.5, or 1 M NaCl prior to elution. The reaction mixtures were analyzed by SDS-PAGE (top) and fluorography (bottom). (C) Amino acid analysis of His-RBP16 methylated in vitro by TbPRMT5-CBP. In vitro methylation assays were performed at 36°C for 16 h in the presence of 0.9 µM [methyl-3H]AdoMet, 2 µM His-RBP16, and either 0.02 µM rat GST-PRMT1, 0.2 µM recombinant MBP-TbPRMT5, or 1.1 nM TbPRMT5-CBP washed prior to elution with 0.15, 0.5, or 1 M NaCl. The reactions were stopped by TCA precipitation, acid hydrolyzed to free amino acids, and analyzed by TLC, as described in Materials and Methods. All abbreviations are as in Fig. 4.

Since recombinant TbPRMT5 catalyzed predominantly MMA modificationsof His-RBP16 (Fig. 4 and 5), we wanted to determine if the presenceof endogenous factors would modulate the ratio of TbPRMT5-catalyzedMMA to DMA modifications (Fig. 8C). To assess this, we performedmethylation assays in the presence of [³H]AdoMet, His-RBP16,and TbPRMT5-CBP washed at either 0.15, 0.5, or 1 M NaCl priorto final elution. Control reactions were performed in the absenceor presence of either recombinant TbPRMT5 or rat PRMT1. Thereaction mixtures were acid hydrolyzed and analyzed by TLC,as described in the legend to Fig. 4. The results presentedin Fig. 8C demonstrate that recombinant TbPRMT5 and TbPRMT5-TAPcatalyze similar ratios of MMA and sDMA modifications. The productof unknown identity, migrating between MMA and aDMA, that wasdescribed previously (Fig. 4) was also present in TbPRMT5 andPRMT1 reactions. Overall, these data demonstrate that TbPRMT5ectopically expressed in PF T. brucei is present in high-molecular-weightcomplexes with methyltransferase activity indistinguishablefrom that exhibited by recombinant TbPRMT5.

TbPRMT5 is not essential for growth in PF trypanosomes. To determine if TbPRMT5 is essential for growth, we disruptedits expression via tetracycline-inducible RNAi and monitoredcell growth daily for 22 days (Fig. 9A). Comparison of parental29-13 cells with uninduced and induced RNAi cells indicatedthat TbPRMT5 was not essential for growth. To confirm that TbPRMT5expression was disrupted, RNA was isolated on days 1, 2, 4,6, and 8 postinduction and analyzed by Northern blotting usinga TbPRMT5-specific riboprobe (Fig. 9B). After normalizationto a tubulin loading control, we observed a maximum 85% reductionin TbPRMT5 mRNA by day 6 postinduction. These results indicatethat TbPRMT5 is not essential for growth under normal log-phaseconditions in PF trypanosomes or, alternatively, that an 85%reduction in TbPRMT5 mRNA is not great enough to confer a growthdefect.

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FIG. 9. TbPRMT5 is not essential for growth in PF trypanosomes. (A) Growth curve of TbPRMT5-disrupted cells. TbPRMT5 expression in PF trypanosomes was disrupted via tetracycline-inducible RNAi. The cumulative cell density of wild-type (29-13), and tetracycline-induced (RNAi +Tet) and uninduced (RNAi –Tet) RNAi cells was monitored daily for 22 days. (B) Northern blot analysis of TbPRMT5 RNAi-disrupted cells. For the analysis of TbPRMT5 expression in RNAi-expressing cells, total RNA (10 µg) isolated on days 1, 2, 4, 6, and 8 postinduction (p.i.) from wild-type, uninduced, and induced RNAi cells was analyzed using a full-length TbPRMT5 riboprobe. As a control for loading, the membrane was stripped and rehybridized with a tubulin riboprobe. TbPRMT5 mRNA levels were analyzed by densitometry and are expressed as percentages of the wild type on each day after normalization to tubulin mRNA levels.

	DISCUSSION

Top ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

In this report, we characterized an evolutionarily divergentPRMT5 ortholog in T. brucei, termed TbPRMT5. TbPRMT5 is constitutivelyexpressed in the BF and PF life stages of the parasite (Fig.6A) and is not essential for growth in PF trypanosomes (Fig.9). Primary sequence analysis revealed that TbPRMT5 containsa conserved methyltransferase domain, lacks the THW loop thatis present in type I PRMTs but frequently absent from type IIenzymes, and has an extended N terminus compared to PRMT5 homologsin higher eukaryotes (Fig. 1). Recombinant TbPRMT5 exhibitsmethyltransferase activity (Fig. 2) with substrate specificitytoward a synthetic RG peptide, calf thymus core histone H4 andH2A, myelin basic protein, and RBP16 substrates and apparentlyprefers to methylate arginine residues found within the contextof GRG- as opposed to RGG-rich regions (Fig. 3). Substrate aminoacid analysis indicated that TbPRMT5 catalyzes the formationof MMA and sDMA, demonstrating that it is a type II enzyme,as predicted by its primary sequence (Fig. 4 and 5). Like humanPRMT5 (77), TbPRMT5 localizes almost exclusively to the cytoplasm(Fig. 6B) and is present in high-molecular-weight complexes(Fig. 7A). In PF trypanosomes, TbPRMT5-TAP copurifies with aDEAD box containing putative RNA helicase, which is relatedto a family of DEAD box proteins that includes yeast Ded1p andDrosophila Vasa (reviewed in references 56 and 67). In addition,TbPRMT5 associates with novel proteins, including tryparedoxinperoxidase (90) and two hypothetical conserved proteins thatare present only in kinetoplastids (Table 1).

TbPRMT5 displays intrinsic type II PRMT activity (Fig. 4 and5) and does not appear to be dependent on additional cofactorsfor the modulation of this activity (Fig. 8). This report constitutesthe first demonstration of sDMA synthesis by a bacterially expressedPRMT5 homolog. Moreover, the ability of recombinant TbPRMT5to robustly methylate numerous substrates in vitro is in contrastto what has been observed for PRMT5 from higher eukaryotes.Several groups have reported that bacterially expressed mammalianPRMT5 is inactive (32, 50, 70), although low levels of activityhave been demonstrated in some cases (77, 83). In vivo in highereukaryotes, PRMT5 homo-oligomerizes (76, 77) and complexes withMEP50, pICln, and p37 to form the 20S methylosome, which isresponsible for spliceosomal UsnRNP assembly and subsequentpre-mRNA splicing (8, 32, 33, 61). FLAG-tagged PRMT5 in thecontext of the methylosome efficiently methylates a varietyof substrates (32), and gel filtration chromatography indicatedthat active forms of PRMT5 in metazoans are present only inmultimeric complexes (54). It has been suggested that dimerizationof PRMT5 and subsequent association with MEP50 is required topromote biological activity (50). Moreover, genetic experimentsrecently demonstrated that the Drosophila MEP50 homolog is requiredfor activity and/or stability of the PRMT5 homolog in vivo (3,39). While we did observe higher-order TbPR