Isolation and Characterization of Suv39h2, a Second Histone H3 Methyltransferase Gene That Displays Testis-Specific Expression

doi:10.1128/MCB.20.24.9423-9433.2000

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Molecular and Cellular Biology, December 2000, p. 9423-9433, Vol. 20, No. 24
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Isolation and Characterization of Suv39h2, a Second Histone H3 Methyltransferase Gene That Displays Testis-Specific Expression

Dónal O'Carroll,¹ Harry Scherthan,² Antoine H. F. M. Peters,¹ Susanne Opravil,¹ Andrew R. Haynes,³ Götz Laible,¹^, Stephen Rea,¹ Manfred Schmid,¹ Angelika Lebersorger,¹ Martin Jerratsch,² Lydia Sattler,⁴ Marie G. Mattei,⁵ Paul Denny,³ Stephen D. M. Brown,³ Dieter Schweizer,⁴ and Thomas Jenuwein¹^,^*

Research Institute of Molecular Pathology at The Vienna Biocenter,¹ and Institute of Botany, University of Vienna,⁴ A-1030 Vienna, Austria; Institute of Human Biology, University of Kaiserslautern, D-67663 Kaiserslautern, Germany²; Mouse Genome Centre and Mammalian Genetics Unit, Medical Research Council, Harwell, Oxon OX11 ORD, United Kingdom³; and INSERM U406, Génétique Médicale et Développement, 13385 Marseille Cedex 5, France⁵

Received 26 September 2000/Accepted 28 September 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Higher-order chromatin has been implicated in epigenetic gene control and in the functional organization of chromosomes. Wehave recently discovered mouse (Suv39h1) and human (SUV39H1) histoneH3 lysine 9-selective methyltransferases (Suv39h HMTases) andshown that they modulate chromatin dynamics in somatic cells.We describe here the isolation, chromosomal assignment, and characterizationof a second murine gene, Suv39h2. Like Suv39h1, Suv39h2 encodesan H3 HMTase that shares 59% identity with Suv39h1 but which differsby the presence of a highly basic N terminus. Using fluorescentin situ hybridization and haplotype analysis, the Suv39h2 locuswas mapped to the subcentromeric region of mouse chromosome 2,whereas the Suv39h1 locus resides at the tip of the mouse X chromosome.Notably, although both Suv39h loci display overlapping expressionprofiles during mouse embryogenesis, Suv39h2 transcripts remainspecifically expressed in adult testes. Immunolocalization ofSuv39h2 protein during spermatogenesis indicates enriched distributionat the heterochromatin from the leptotene to the round spermatidstage. Moreover, Suv39h2 specifically accumulates with chromatinof the sex chromosomes (XY body) which undergo transcriptionalsilencing during the first meiotic prophase. These data are consistentwith redundant enzymatic roles for Suv39h1 and Suv39h2 duringmouse development and suggest an additional function of the Suv39h2HMTase in organizing meiotic heterochromatin that may even impartan epigenetic imprint to the male germline.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

In eukaryotes, control of gene expression and the functional organization of chromosomes depends on higher-order chromatin,which has been proposed to be nucleated by the covalent modificationof histone amino termini (45). In addition to its role in somaticcells, dynamic transitions in the organization of higher-orderchromatin are also important during meiosis (15). Although condensationand pairing of meiotic chromosomes is evolutionarily highly conserved,meiosis in male mammals is exceptional because the heteromorphicX and Y chromosomes undergo facultative heterochromatinizationthat is accompanied by transcriptional silencing (21). Thisselective inactivation of the sex chromosomes, which is cytologicallydefined by the appearance of the so-called XY body or sex vesicle(44), has been suggested to restrict promiscuous pairing orrecombination between nonhomologous chromosomes, thereby reducingthe risk for aneuploidy (21).

Despite the apparent resemblance of the XY body to the Barr body (9) in female somatic cells, it is currently unresolvedwhether similar mechanism(s) operate in inducing chromosome-specificheterochromatinization in meiotic and somatic cells. For example,although Xist RNA also localizes to the XY body (5), spermatogenesisis unaffected in Xist-deficient mice (29). Moreover, only afew proteins that associate with the XY body have been described(12, 23, 26, 43) of which M31 (HP1 $beta$ ) represents the firstbona fide heterochromatic component (32, 49). Because M31(HP1 $beta$ ) is a mammalian member of the Su(var) gene family, thisresult suggested a possible link between heterochromatin-inducedgene repression in somatic tissues and transcriptional silencingof the sex chromosomes during malemeiosis.

Su(var) genes were initially identified by genetic screens on centromeric position effects in Drosophila melanogaster (37)and Schizosaccharomyces pombe (3). Since Su(var) genes suppressposition effect variegation (PEV), their gene products have beenimplicated in the organization of repressive chromatin domains.Indeed, characterized family members represent either chromosomalproteins or enzymes that can modify chromatin (47). Recently,we isolated mouse (Suv39h1) and human (SUV39H1) homologs (1)of the dominant Drosophila PEV modifier Su(var)3-9 (46) anddemonstrated that they encode histone methyltransferases whichselectively methylate lysine 9 (Lys9) in the histone H3 N terminus(36). Immunolocalization of endogenous Suv39h1 or SUV39H1 proteinsin mammalian cells indicated enriched distribution at heterochromaticfoci during interphase and transient accumulation at centromericpositions during mitosis (2). In addition, Suv39h1 or SUV39H1associate with M31 (HP1 $beta$ ), indicating the existence of a mammalianSU(VAR) protein complex (1). Moreover, deregulated SUV39H1can induce ectopic heterochromatin and redistribute endogeneousM31 (HP1 $beta$ ) (30). Together, our data defined Suv39h1 or SUV39H1as novel heterochromatin-associated HMTases that are intrinsicallyinvolved in the structural organization of mammalian higher-orderchromatin in somaticcells.

We describe here the isolation and characterization of a second murine Suv39h gene, Suv39h2. Over the entire length of the477-amino-acid protein, Suv39h2 shares 59% identity with Suv39h1and also displays an H3-Lys9-selective HMTase activity. However,Suv39h2 differs from Suv39h1 by the presence of a very basic,histone H1-like N terminus. Moreover, whereas both murine Suv39hloci show overlapping expression profiles during embryogenesis,Suv39h2 transcripts are restricted to adult testes. Immunolocalizationof endogenous Suv39h2 protein reveals enriched distributions atheterochromatin during the first meiotic prophase and in the earlystages of spermiogenesis. During mid-pachytene, Suv39h2 specificallyaccumulates with chromatin of the silenced sex chromosomes presentin the XY body. These data are consistent with redundant genefunctions for both Suv39h loci during mouse development but, inaddition, suggest a role for the Suv39h2 HMTase in regulatinghigher-order chromatin dynamics during malemeiosis.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Molecular cloning of murine Suv39h2. A 210-bp EST DNA probe (encoding amino acids 219 to 289 of Suv39h2, see Fig. 1) was PCR amplified from murine B-cell-specific(J558L and S194) cDNA libraries and screened against a day 11.5mouse embryonic $lambda$ gt11 cDNA library (Clontech) and a $lambda$ 129/Sv genomiclibrary (Stratagene), resulting in the isolation of six cDNA andthree genomic clones. The longest cDNA (1 kb; $lambda$ 4-Suv39h2) andgenomic (14-kb) isolates were sequenced by primer walking on anautomated sequencer (Applied Biosystems). Sequence analysis indicatedthat the $lambda$ 4-Suv39h2 cDNA encoded amino acids 132 to 477 and thatthe genomic sequence comprised exons 1 to 3, as predicted by GENE-Finder.Missing 5' sequences of the Suv39h2 cDNA were extended by nestedrapid amplification of cDNA ends (RACE) (Marathon cDNA AmplificationKit; Clontech) from the J558L and S194 cDNA libraries using theexon 3 specific primers 5'-GCCCTCCAAGTCAACAGTG and 5'-GTGTTGAGGTAATCTTGCCATC.The RACE amplifications identified exon 2 (amino acids 83 to 131).Exon 1, including the starting ATG, was deduced from an EST (accessionno. AA959164) which correctly spliced into exon 2 and whosesequence information was confirmed by comparison with genomicsequences.

Chromosomal assignment and fine mapping of the Suv39h1 and Suv39h2 loci. To obtain genomic Suv39h1 sequences, we hybridized a Suv39h1-specific DNA probe encoding amino acids 19 to 223 of Suv39h1(1) against a $lambda$ 129/Sv genomic library (Stratagene). Among severalisolates, a 13-kb partial genomic Suv39h1 fragment comprisingexons 1 to 3 was sequenced by primer walking. Both Suv39h1 andSuv39h2 genomic sequences were subcloned into pBluescript (seeFig. 2, top) and used for fluorescence in situ hybridization (FISH)analysis on Robertsonian mouse chromosomes as described previously(28). Fine mapping by single-stranded conformation polymorphism(SSCP) was performed with a 170-bp exon 3-, intron 3-specificDNA probe for Suv39h1 (primers 5'-CACTAATGATGGCCGAGG and 5'-GCAGAAGAGTTTGAGGTACAG)and with the 210-bp exon 3-specific EST-Suv39h2 probe (primers5'-GGGGATGATATTTGTTGAAAACAC and 5'-GGTTGGATTTTAATTTGTTGCTTC).The SSCP analysis and calculation of genetic distances was asrecently reported (28).

RNA isolation and blot analysis. RNA isolation and analysis was done as described previously (1). Membranes were sequentially hybridized under stringentChurch conditions (41) with a 1.6-kb EcoRI cDNA fragment comprisingnearly full-length Suv39h1 (1) or with a 980-bp cDNA PCR ampliconwhich codes for amino acids 143 to 477 of Suv39h2. To controlfor the quality of the RNA preparations, blots were rehybridizedwith a DNA probe that is specific for Gadph sequences (17).

In situ hybridization for Suv39h1 and Suv39h2 expression. To obtain Suv39h1- and Suv39h2-specific riboprobes, PCR-converted SalI/BamHI DNA fragments were subcloned into the polylinkerof pGEM-3Zf (Promega). Similar to an internal 395-bp DNA fragmentencoding amino acids 113 to 237 of Suv39h1 (1), a 325-bp internalDNA fragment encoding amino acids 186 to 290 of Suv39h2 was used.Within this region, Suv39h1 and Suv39h2 nucleotide sequences areonly ~53% identical and do not cross-hybridize. In situ RNA probeswere internally labeled with DIG-UTP (Boehringer Mannheim) bytranscription with SP6 (antisense probes of EcoRI-linearized plasmid)or T7 RNA polymerase (sense probes of BamHI-linearizedplasmid).

In situ hybridizations of whole-mount embryos or of 5-µm sections of paraffin-embedded testes were performed at 65 to 70°Covernight, washed under high stringency, and processed for detectionafter incubation with $alpha$ -DIG alkaline phosphatase-conjugated antibodiesand BM purple as the chromogenic substrate (BoehringerMannheim).

Generation and purification of rabbit polyclonal $alpha$ -Suv39h2-specific antibodies. Suv39h2 coding sequences comprising amino acids 157 to 477 were converted into a BamHI-EcoRI DNA fragment by PCR amplificationand combined in-frame with N-terminal glutathione S-transferase(GST) in the bacterial expression vector pGEX-2T (Pharmacia).Purification of recombinant protein and immunization of rabbitswith the GST-Suv39h2 antigen was done as described elsewhere (1).An immunoglobulin G fraction was prepared from the crude serumof rabbit 2218, batch preabsorbed against GST-Suv39h1 glutathione-Sepharosebeads (1), and $alpha$ -Suv39h2 antibodies were affinity purifiedover a glutathione-Sepharose (Pharmacia) column that had beenloaded with GST-Suv39h2. After elution with 100 mM glycine (pH2.5), antibodies were neutralized with a 1/10 volume of 2 M HEPES(pH 7.9). These affinity-purified $alpha$ -Suv39h2 antibodies (concentration,~0.5 mg/ml) were used at 1:250 or 1:500 dilutions for proteinblot analysis or at 1:10 to 1:20 dilutions for indirectimmunofluorescence.

Epitope-tagged Suv39h2 protein in HeLa cells. To generate a (myc)₃-tagged Suv39h2 protein that would resemble the shorter Suv39h1 or SUV39H1 gene products, the portionof the Suv39h2 cDNA comprising amino acids 83 to 477 was convertedinto a NotI/XhoI DNA fragment by PCR amplification and transferredinto a NotI/XhoI-digested pKW2T-(myc)₃H₆SUV39H1 derivative whichcontains a unique in-frame NotI cloning site immediately followingthe N-terminal tag (1). The (myc)₃-Suv2(83-477) construct wasconfirmed by sequencing and "stably" cotransfected into HeLa cellsas described earlier (1). One clone (HeLa-S2/5) with significantoverexpression of the ectopic protein in ~65% of clonal cellswas characterized further and, together with HeLa-B55 cells whichoverexpress (myc)₃-SUV1(3-412) (30), used to analyze specificityof the $alpha$ -Suv39h2antibodies.

Isolation of PMEFs. Primary mouse fibroblasts (PMEFs) were derived from day E12.5 C57BL6/129SvJ fetuses after removing the head and inner organs.Trunk tissues were partially homogenized in 5 ml of medium byrepeated passage through a 20-gauge hypodermic needle, reseededonto a 10-cm-diameter dish, and cultivated in high-glucose Dulbeccomodified Eagle medium supplemented with 15% fetal calf serum-2mM glutamine-1% nonessential amino acids-0.1 mM $beta$ -mercaptoethanol-1%penicillin-streptomycin (all Gibco-BRL). This primary culturewas trypsinized after 3 days, and the floating single cell suspensionwas expanded into passage 1, which already contained a highlyenriched population ofPMEFs.

Nuclear extracts and protein blot analysis. Isolation of nuclei from mouse testes was performed according to described protocols (11, 32). Approximately 30 µg ofnuclear extracts from testes, the HeLa cell clones, or from PMEFswere analyzed on protein blots with $alpha$ -myc, $alpha$ -M31 (HP1 $beta$ ) (49), $alpha$ -Suv39h1, and $alpha$ -Suv39h2 antibodies as reported elsewhere (1).

HMTase assays with recombinant Suv39h2. Methyltransferase assays with free histones (Boehringer Mannheim) or histone H3, CENP-A, and macroH2A N-terminal peptidesand the recombinant GST-Suv2(157-477) product were done as recentlydescribed (36).

Immunofluorescence analysis of testes sections. Testes were surgically removed from adult C57BL6/129SvJ mice, embedded in O.C.T. 4853 (Tissue-Tek), and frozen in liquid nitrogenusing precooled isopentane. Then, 10-µm sections were fixed in2% paraformaldehyde in phosphate-buffered saline (PBS; pH 7.4)for 10 min on ice, washed in cold PBS, and treated with 0.1% sodiumcitrate buffer (pH 6.0) containing 0.1% Triton X-100 for 5 minon ice. Subsequently, the sections were washed and blocked withPBS-2.5% bovine serum albumin (BSA)-0.1% Tween 20-10% goat serumfor 30 min at roomtemperature.

For indirect immunofluorescence of M31 (HP1 $beta$ ) and Scp3 epitopes, sections were simultaneously incubated with rat monoclonal $alpha$ -M31 antibodies (49) and mouse monoclonal $alpha$ -Scp3 antibodies(22) overnight at 4°C. After several washes (PBS, 0.2% BSA,0.1% Tween 20), samples were incubated for 1 h at room temperaturewith secondary CY3-conjugated goat anti-rat and CY5-conjugatedgoat anti-mouse antibodies (both from Dianova). After three finalwashes with PBS containing 0.1% Tween 20, sections were mountedin Vectashield antifade solution (Vector Laboratories) containing4',6'-diamidino-2-phenylindole(DAPI).

For double labeling of Suv39h2 and Scp3 epitopes, sections were incubated with rabbit polyclonal $alpha$ -Suv39h2 antibodies andmouse monoclonal $alpha$ -Scp3 antibodies. Suv39h2 staining was visualizedby immunoamplification, using biotinylated goat anti-rabbit antibodies,Alexa488-conjugated avidin, biotinylated goat anti-avidin antibodies,and Alexa488-conjugated avidin (Vector Laboratories and MolecularProbes). Scp3 epitopes were visualized by secondary Alexa568-conjugatedgoat anti-mouse antibodies (Molecular Probes). Processed sampleswere evaluated using a Zeiss Axiophot epifluorescence microscope.Digital black-and-white images were recorded with a cooled charge-coupleddevice camera (Princeton Instruments), merged to RGB images usingthe Metamorph Imaging System (Universal Imaging Corporation),and processed in Adobe Photoshop 5.1.

Immunofluorescense analysis of testis suspension cells. Testes were minced with scalpel blades in cold minimal essential medium (Gibco) containing protease inhibitors (Roche Biochemicals).Structurally preserved suspension cells were prepared by cross-linkingfixation as described elsewhere (35). Testis suspension cellswere mixed with equal volumes of PBS-buffered (pH 7.2) 3.7% formaldehyde-0.1M sucrose, placed on silanized glass slides, and allowed to drydown until they were coated by a thin layer ofsucrose.

For indirect immunofluorescence of Suv39h2 epitopes, sucrose-embedded cells were briefly washed with PBS, extracted for 30min with 0.2% Triton X-100 in PBS, and incubated overnight at4°C with rabbit polyclonal $alpha$ -Suv39h2 antibodies. After three 3-minwashes in PBS-0.1% Tween 20-0.2% BSA-0.1% gelatin, samples wereeither incubated for 45 min at 37°C with secondary, CY3-conjugatedgoat anti-rabbit antibodies (Vector Laboratories) or with secondarygoat anti-rabbit biotinylated antibodies (Dianova) that were visualizedafter a third incubation by using avidin-fluorescein isothiocyanate(FITC) (Sigma). After three final washes in PBS-0.1% Tween 20,preparations were mounted in Antifade solution containing DAPI.Staging of individual mouse spermatogenic cells was determinedby the specific distribution of heterochromatin (42).

For double-labeling experiments, samples were first incubated with $alpha$ -Suv39h2 antibodies, followed by sandwich detection withanti-rabbit biotinylated antibodies and avidin-CY3. After a brieffixation with 1% formaldehyde in PBS, Xmr epitopes were then detectedwith mouse monoclonal $alpha$ -Xmr antibodies (12) that were visualizedwith secondary goat anti-mouse FITC-conjugated antibodies(Dianova).

GenBank accession numbers. The murine Suv39h2 cDNA (accession no. AF149205) and the murine genomic Suv39h2 (accession no. AF149204) and murinegenomic Suv39h1 (accession no. AF149203) sequences have beendeposited inGenBank.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Isolation of a second murine Suv39h gene: Suv39h2. Sequence similarity searches (4, 7) with the murine Suv39h1 or human SUV39H1 cDNAs (1) revealed the presence of related,yet distinct expressed sequence tags (ESTs) in the DDBJ, EMBL,and GenBank databases. In particular, the mouse ESTs fall intotwo categories that are either homologous to Suv39h1 or indicativeof a second gene. Using oligonucleotides specific for this secondclass of Suv39h ESTs, an internal (lacking the conserved chromoand SET domain sequences) DNA probe was PCR amplified from murinecDNAs and screened against a mouse embryonic day 11.5 (E11.5)cDNA library (see Materials and Methods). Of six positive isolates,the longest insert was subcloned and sequenced, revealing an openreading frame (ORF) which comprises the chromo and the C-terminalSET domain. RACE amplifications with cDNA templates from the murineB-cell-specific cell lines J558L and S194 extended the missing5' end; however, they did not detect a startingATG.

To obtain more sequence information, a partial Suv39h2 genomic clone of approximately 14 kb was isolated (see Materials andMethods). In addition, we also identified a partial genomic cloneof approximately 13 kb for the mouse Suv39h1 locus. Overall, thegenomic organization, including the exon-intron structure andthe presence of a predicted CpG-island across the first exon,is very similar for both loci (see Fig. 2 and below). Comparisonof the available genomic, cDNA, and EST sequences for the Suv39h1-relatedgene allowed the definition of exon 1 (see Materials and Methods)that contains a consensus ATG preceded by in-frame stop codonsand which can correctly splice into exon 2. In analogy to Suv39h1,we designated this novel gene Suv39h2 [for Su(var)3-9 homolog2]. The nucleotide sequence (~1.5 kb) and conceptional readingframe (477 amino acids) of the composite coding Suv39h2 cDNA areshown in Fig. 1A.

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FIG. 1. Conceptional reading frame and domain conservation of the Suv39h2 protein. (A) The ~1.5-kb nucleotide sequence and conceptional reading frame of the coding part of the Suv39h2 cDNA is shown. Exon 1, including the starting ATG preceded by in-frame stop codons (asterisks), has been derived from genomic Suv39h2 sequences and from an EST that correctly spliced into exon 2. From the available genomic sequences, exons 1 to 3 could be identified, and their respective exon-intron boundaries are indicated by open arrowheads at nucleotide positions 278, 424, and 1083. The 477-amino-acid Suv39h2 protein contains several conserved sequence motifs, including a chromo domain (dashed box), the SET domain (light gray shading), and a C-terminal tail (dark gray shading). Basic amino acids in the N terminus are highlighted by gray circles. In addition, cysteine residues that are also conserved in Suv39h1 are circled. Putative nuclear localization signals are underlined. (B) Phylogenetic relationships of murine Suv39h1 (412 amino acids) (1), murine Suv39h2 (477 amino acids), Drosophila SU(VAR)3-9 (635 amino acids) (46), S. pombe CLR4 (490 amino acids) (25), and a C. elegans ORF C15H11.5 (503 amino acids) (accession no. Z81035). Over the entire length of the protein, Suv39h1 shares 59% identity with Suv39h2, 41% identity with SU(VAR)3-9, 35% identity with CLR4, and 18% identity with C15H11.5. Similarly, Suv39h2 shares 59% identity with Suv39h1, 39% identity with SU(VAR)3-9, 37% identity with CLR4, and 22% identity with C15H11.5. Highly conserved sequence motifs are indicated and comprise the chromo (stippled) and SET (black) domains and the SET-associated cysteine-rich clusters (gray), which are only in part present in C15H11.5. In addition, an N-terminal region (hatched) shared by the murine and fly proteins (1), a putative GTP-binding domain (light-shaded box) in SU(VAR)3-9 (46), and the basic N termini (basic) in Suv39h2 and C15H11.5 are also highlighted. (C) Amino acid identity and similarity (in brackets) between the Suv39h2 N terminus and the C-terminal portion of histone H1.

Sequence conservation of Suv39h2 within the SU(VAR)3-9 protein family. Over the length of the 477-amino-acid protein, Suv39h2 is 59% identical to Suv39h1 (412 amino acids) (1). Cross-speciescomparison of Suv39h1 or Suv39h2 with other representative membersof the SU(VAR)3-9 protein family, such as Drosophila SU(VAR)3-9(46), S. pombe CLR4 (25), and a putative ORF in Caenorhabditiselegans (C15H11.5; accession no. Z81035) indicate very similarsequence identities and phylogenetic relationships (Fig. 1B).

Interestingly, however, Suv39h2 contains a highly basic (20.7%) N-terminal extension of 82 amino acids that is not presentin Suv39h1, although a very basic, yet distinct N terminus isalso found in the C15H11.5 ORF. In addition to its resemblanceto arginine-rich protamines, the Suv39h2 N terminus shows moderatesequence identity (23.2%) with the C-terminal portion of the linkerhistone H1 that is not restricted to basic residues (Fig. 1C).With the exception of this extended N terminus, Suv39h2 maintainsall other conserved domains outlined previously for Suv39h1 (1).For example, both proteins display highest identity in the 130-amino-acidSET domain core (75.2%) and in the conspicuous C-terminal tail(69.6%) with its three conserved cysteine residues. The 60-amino-acidchromo domain (62.7%), the SET-associated cysteine-rich region(54.9%), and the SU(VAR)3-9-specific N-terminal region (45.0%)are also highly identical. Like Suv39h1, Suv39h2 is also significantlyshorter than the 635-amino-acid fly protein (46).

Chromosomal assignment of the murine Suv39h1 and Suv39h2 loci. To investigate the chromosomal assignment of the two Suv39h loci, metaphase spreads prepared from stimulated lymphocytes ofWMP mice, which are homozygous for metacentric Robertsonian (Rb)translocations in all autosomes except chromosome 19, were analyzedby FISH with genomic Suv39h1 and Suv39h2 DNA probes (Fig. 2, top,and Materials and Methods). The genomic Suv39h1 probe indicateda symmetrical, two-dotted signal at the tip of the mouse X chromosome,a localization consistent with the previous assignment of a SUV39H1homologous sequence (MG-44) to the Xp11.2 region on the humanX chromosome (20). In contrast, the genomic Suv39h2 probe specificallyhybridized with the A region of mouse chromosome 2 present inthe Rb(2;16) translocation (Fig. 2, bottom).

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FIG. 2. Genomic organization and chromosomal localization of the Suv39h1 and Suv39h2 loci. (Top) Organization of partial genomic clones comprising the 5' regions of murine Suv39h1 and Suv39h2. Exons are shown by black boxes, and numbers indicate the starting amino acid positions of the respective exons. Demarcated by the dashed lines are exon regions that encode the conserved chromo domain. Both loci are drawn to scale, and the respective Suv39h1 and Suv39h2 subclones (dashed lines above the loci) that were hybridized to metaphase spreads (below) are shown, as are the specific primer pairs (split arrows) used for the haplotype analysis (see Fig. 3). (Bottom) FISH analysis of Suv39h1 and Suv39h2 localization on metaphase chromosomes prepared from lymphocytes of WMP male mice. Chromosomes were counterstained and R banded with propidium iodide. Arrowheads indicate symmetrical signals on the X chromosome for Suv39h1 (left panel) and on the Rb(2;16) chromosome for Suv39h2 (right panel). Based on the R banding, localization of Suv39h1 is assigned to regions A1 and A2 of chromosome X and that of Suv39h2 to region A of chromosome 2.

The chromosomal position of the two murine Suv39h loci was further defined by haplotype analysis of recombinant progeny (Musspretus × C57BL/6) from the European collaborative interspecificbackcross (EUCIB) (8, 38). Allelic variants were identifiedon a series of PCR-amplified DNA fragments by SSCP (see Materialsand Methods). SSCP polymorphisms were detected with an exon 3-intron3 primer pair for Suv39h1 and with an exon 3-specific primer pairfor Suv39h2 (see Fig. 3, top). Each of these specific primer pairswas scored through a random panel of EUCIB backcross mice, indicatinglinkage of Suv39h1 to mouse chromosome X markers and of Suv39h2to mouse chromosome 2 markers (data not shown). Haplotype analysislocalized Suv39h1 to map position 1.8 cM of the mouse chromosomeX, in an interval that also harbors the mouse mutations tattered(Td) (13) and scurfy (Sf) (39) (Fig. 3, left panel). In theparallel fine mapping of Suv39h2, haplotype analysis of a panelof 89 mice carrying recombinants in the D2Mit1/D2Mit6 region localizedSuv39h2 to this interval. The Suv39h2 locus lies 0.7 ± 0.4 centimorgans(cM) distal of D2Mit355. Genetic distances taken from the MouseGenome Database (http://www.jax.org) would indicate that Suv39h2resides at map position 2.5 cM of mouse chromosome 2 (Fig. 3,right panel).

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FIG. 3. Linkage mapping of Suv39h1 and Suv39h2 on mouse chromosomes X and 2. (Top) Haplotype analysis. The segregation of C57BL/6 or M. spretus parental alleles for Suv39h1 (left panel), Suv39h2 (right panel), and for the respective flanking microsatellite markers that are specific for chromosome X or chromosome 2 are shown. Each backcross progeny has inherited the indicated allele from the F₁ female parent. A white box indicates an M. spretus allele, and a black box indicates a C57BL/6 allele. Gray boxes represent markers that have not been scored. Numerals inside boxes reflect the number of selected recombinant progeny for which typings are missing in the EUCIB database. The numbers above each column indicate the number of progeny inheriting each type of chromosome. The calculation of genetic distances and standard error, correcting for recombinants not typed, was done as described previously (28). (Bottom) Consensus maps for Suv39h1 and Suv39h2 loci. Since genetic distances are calculated from multiple crosses, they reflect the relative rather than the precise order of markers. All distances (in centimorgans) are according to MGD chromosome committee maps. The position of the corresponding SUV39H1 locus (Xp11.2) on the human X chromosome (20) is also indicated.

Temporal and spatial expression of Suv39h1 and Suv39h2 during mouse development. To determine the expression and size of Suv39h2 mRNAs, RNA blots containing total RNA from embryonic stem (ES) cells and mousefetuses from various embryonic stages (days E10.5 to E17.5) andon postnatal days 1 to 4 (P1 to P4) were hybridized with a 980-bpcDNA probe comprising Suv39h2 coding sequences (amino acids 143to 477). Within this region, the Suv39h2 cDNA is approximately60% identical to the Suv39h1 nucleotide sequence and does notcross-hybridize with Suv39h1 transcripts (see Fig. 5A; also datanot shown). This Suv39h2-specific cDNA probe recognized a prominentmRNA of approximately 2.7 kb in most RNA preparations of the analyzedstages (Fig. 4A, middle panel), whereas at day E10.5, smaller-sized(1.7-kb) transcripts were also detected. Abundant Suv39h2-specifictranscripts are present in ES cells, in in vitro-differentiatedembryoid bodies (EB), and appear to peak at ca. day E10.5. Incontrast, Suv39h2-specific transcripts are substantially downregulatedat day E17.5 and are nearly absent during postnatal development.A very similar dynamic expression profile was also observed forSuv39h1, except that the relative abundance of Suv39h1 transcriptsin ES cells and EB is reduced compared to Suv39h2 transcripts(Fig. 4A, top panel). With a more sensitive RNase protection assay,however, Suv39h1 has been shown to be expressed in ES cells (1).

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FIG. 4. Temporal and spatial expression of Suv39h1 and Suv39h2 during mouse development. (A) RNA blot analysis to detect Suv39h1 and Suv39h2 transcripts in 15 µg of total RNA prepared from undifferentiated CCE ES cells, EB derived after retinoic-acid-induced in vitro differentiation of CCE cells, and whole fetuses at various stages of embryonic (E10.5 to E17.5) and postnatal (P1 to P4) development. As a control for the quality of the RNA, the RNA blot was rehybridized with a probe that is specific for Gapdh sequences. (B) Whole-mount RNA in situ hybridizations of E8.5 and E9.5 mouse fetuses with Suv39h1- and Suv39h2-specific riboprobes. The arrow indicates the presence of Suv39h1 transcripts in the allantois. As a control, fetuses were also hybridized with a Suv39h2-specific sense probe.

To investigate the spatial expression profiles of Suv39h2 and Suv39h1, we performed whole-mount in situ hybridizations withSuv39h2- and Suv39h1-specific riboprobes (see Materials and Methods)on day E8.5 and day E9.5 mouse fetuses. Whereas only residualstaining is observed with a Suv39h2 control sense probe, the Suv39h2antisense probe reveals a rather uniform expression throughoutthe entire fetus (Fig. 4B, middle panel). Similarly, the Suv39h1antisense probe detects a broad distribution of transcripts, afinding consistent with the ubiquitous expression of Suv39h1 inprevious in situ hybridizations on sagittal sections of day E12.5fetuses (1). In addition to embryonic tissues, the mesenchyme-derivedallantois is also prominently stained by the Suv39h1 antisenseprobe (Fig. 4B, arrow in left panel). Together with the RNA blotshown above, this comparative analysis indicates significant coexpressionof Suv39h1 and Suv39h2 during mousedevelopment.

Suv39h2 transcripts are highly expressed in mouse testes. In contrast to embryonic expression profiles, the abundance of Suv39h1 and Suv39h2 transcripts greatly differs in adult tissues.Whereas Suv39h1 displays broad expression in a panel of RNA preparationscomprising 14 adult tissues, the expression of Suv39h2 remainslargely restricted to the testes, with mRNAs being present as2.7- and 1.7-kb transcripts (Fig. 5A, middle panel). In additionto other tissues, Suv39h2 transcripts are also significantly downregulatedin ovaries.

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FIG. 5. Testis-specific expression of Suv39h2. (A) RNA blot analysis to detect Suv39h1 and Suv39h2 transcripts in 15 µg of total RNA prepared from adult 129/Sv tissues, including kidney (KI), skeletal muscle (SM), heart (HA), liver (LI), stomach (ST), intestine (IN), lung (LU), brain (BR), spleen (SP), thymus (TH), testis (TE), ovaries (OV), uterus (UT), and placenta (PL). As a loading control, the RNA blot was rehybridized with a probe that is specific for Gapdh sequences. (B) RNA in situ hybridizations on 5-µm sections of adult testis with Suv39h1- and Suv39h2-specific riboprobes. As a control, sections were also hybridized with the corresponding Suv39h1- and Suv39h2-specific riboprobes. Enlarged insets show specific staining of type B spermatogonia and preleptotene spermatocytes (indicated by arrows).

To analyze this testis-specific expression in more detail, we performed in situ hybridizations on sagittal sections of adulttestes. The Suv39h2 and Suv39h1 antisense probes revealed specificexpression in the outermost cell layer of the seminiferous tubules(Fig. 5B, right panels), whereas the corresponding control senseprobes proved negative. Suv39h2-specific transcripts appear atelevated levels compared to Suv39h1. Higher magnification (seeinsets in Fig. 5B) shows predominant staining of type B spermatogoniaand preleptotene spermatocytes. Suv39h2-specific transcripts arealso detected at reduced levels in several pachytene-stage cellsand in mitotically inactive Sertoli cells (data not shown). Together,these data indicate prominent expression of Suv39h2 transcriptsin male germ cells during the early stages ofspermatogenesis.

Detection and size of the endogenous Suv39h2 protein. To characterize the Suv39h2 protein at a biochemical level, we generated a Suv39h2-specific polyclonal rabbit antiserum (seeMaterials and Methods) and probed protein blots containing nuclearextracts from PMEFs and from adult testes with affinity-purified $alpha$ -Suv39h2 antibodies. As a specificity and size control, we includednuclear extracts from HeLa cell lines that "stably" overexpress(myc)₃-SUV39H1 (HeLa-B55) (30) or a corresponding (myc)₃-Suv39h2construct which encodes amino acids 83 to 477 of the Suv39h2 cDNA(HeLa-S2/5) (see Materials and Methods). Immunoblotting with $alpha$ -Suv39h1antibodies indicated the presence of ectopic (myc)₃-SUV39H1 (55kDa) and of endogenous SUV39H1 (48 kDa) in HeLa-B55 nuclear extracts.However, endogenous Suv39h1 was undetectable in PMEFs and detectableonly at low-abundant levels in testes (Fig. 6, middle panel).By contrast, the $alpha$ -Suv39h2 antibodies recognize an endogenousprotein of ~53 kDa in both PMEFs and testes (Fig. 6, lower panel),which comigrates with ectopic (myc)₃-Suv2(83-477) in HeLa-S2/5nuclear extracts. We conclude that Suv39h2 is more highly expressedin PMEFs and in testes than is Suv39h1 and that the size of theendogenous Suv39h2 protein is in good agreement with the geneproduct predicted from the coding sequence of the Suv39h2 cDNA(see Fig. 1).

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FIG. 6. Detection and size of endogenous Suv39h2 protein. Approximately 30 µg of nuclear extracts from HeLa-B55, HeLa-S2/5, PMEFs, and adult testis (TE) were immunoblotted with $alpha$ -myc, $alpha$ -Suv39h1, $alpha$ -Suv39h2, and $alpha$ -M31 (as a loading control) antibodies. HeLa-B55 cells overexpress (myc)₃-SUV1(3-412), and HeLa-S2/5 cells overexpress (myc)₃-Suv2(83-477). Ectopic proteins are indicated by arrowheads. Endogenous Suv39h2 (53 kDa) almost comigrates with (myc)₃-Suv2(83-477).

Suv39h2 is a second H3 Lys9 HMTase. SU(VAR)3-9 related proteins were recently shown to be novel histone H3 methyltransferases. Although Suv39h1 selectively methylatesLys9 of the histone H3 N terminus, a weak signal was also detectedif histone H1 was used as a substrate (36). To compare the HMTasespecificity of Suv39h2, we performed in vitro methylation assayswith free histones and a recombinant GST-Suv39h2 product thatcomprises amino acids 157 to 477. Purified GST-Suv2(157-477) onlymethylated histone H3, but not H2A, H2B, or H4 (Fig. 7A). Notably,histone H1 was also not a substrate. To investigate the methylationsite profile of Suv39h2, we extended the in vitro methylationassays with unmodified, modified, or mutated H3 N-terminal peptides.Whereas the unmodified H3 peptide was strongly methylated, mutationof Lys9 (K9L) abolished substrate specificity (Fig. 7B). Further,preexisting acetylation of Lys9 (K9-Ac) or phosphorylation ofserine 10 (S10-phos) prevented Suv39h2-dependent methylation,and acetylation of lysine 14 (K14-Ac), like mutation of lysine4 (K4L), significantly reduced the H3 substrate quality. The H3variant CENP-A has been shown to be retained in sperm chromatin(34), and macroH2A is a new component of the XY body (24).However, the Suv39h2 HMTase did not react with the CENP-A andmacroH2A N-terminal peptides (Fig. 7B). Together, these data defineSuv39h2 as a second H3 (Lys9) selective HMTase, whose substratespecificity and sensitivity to preexisting H3 tail modificationsappears even more stringent than that of Suv39h1.

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FIG. 7. Recombinant Suv39h2 is an H3 Lys9-selective HMTase. (A) In vitro HMTase assays with 10 µg of GST-Suv2(157-477) (murine Suv39h2) and free histones, using S-adenosyl-[methyl-¹⁴C]-L-methionine as a methyl donor. Coomassie blue staining (top panel) shows purified proteins (arrowhead) and free histones (dots). Fluorography (bottom panel) indicates H3 HMTase activity of GST-Suv2(157-477). (B) In vitro methylation assays using GST-Suv2(157-477) as enzyme and the indicated N-terminal peptides of H3, CENP-A, and macroH2A as substrates.

In situ localization of Suv39h2 and M31 (HP1 $beta$ ) in testes sections. To analyze the distribution and nuclear localization of the Suv39h2 HMTase during spermatogenesis, we performed double-labelingimmunofluorescence for Suv39h2 and Scp3 epitopes in testes sections.Scp3 is a major component of the lateral elements of the synaptonemalcomplex which is formed between homologous chromosomes duringmeiotic prophase (22). Prominent Suv39h2 signals were visualizedin late, but not early, spermatocytes in a subnuclear region thatdisplays a characteristic DAPI staining, reminiscent of the XYbody (arrowheads in Fig. 8C). This staining indicated that Suv39h2has a preference to localize to the sex chromosomes (see below).In addition, Suv39h2 is present at DAPI-dense blocks of heterochromatin(clustered centromeres) in round spermatids but was no longerdetectable in elongating spermatids (Fig. 8A and C). To evaluatethis staining pattern, we repeated the immunofluorescence with $alpha$ -Scp3 and $alpha$ -M31 antibodies (49) that are specific for HP1 $beta$ ,a known interacting partner for SUV39H1 or Suv39h1 proteins insomatic cells (1). As recently described (32), HP1 $beta$ was detectedat the XY body and at clustered centromeres in the nuclear peripheryof mid and late spermatocytes (arrows in Fig. 8D). Moreover, HP1 $beta$ also decorated the heterochromatic blocks of round spermatids.Thus, this comparative analysis indicates significant overlapin meiotic chromatin association between Suv39h2 and HP1 $beta$ in differentstages of mouse spermato- and spermiogenesis.

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FIG. 8. In situ localization of Suv39h2 and M31 (HP1 $beta$ ) in testis sections. Double-labeling indirect immunofluorescence for Suv39h2 (pink) and Scp3 (green) (A and C) or for M31 (pink) and Scp3 (green) (B and D) in testis sections representing different stages of spermatogenesis. DNA was counterstained with DAPI. The positions of early and late spermatocytes (eSP and lSP), round spermatids (rST), and elongating spermatids (eST) are shown. Staining of the XY body in lSP is indicated by arrowheads. Also highlighted by arrows in panel D is the concentration of M31 around clustered centromeres in the nuclear periphery of lSP and rST.

Dynamic heterochromatin association of Suv39h2 in male germ cells. To investigate chromosomal associations of Suv39h2 in more detail, we analyzed its distribution in structurally preservedtestis suspension cells (see Materials and Methods). EndogenousSuv39h2 is found in a dispersed distribution in some premeioticnuclei (data not shown) and as a granular stain in all preleptotenenuclei (Fig. 9A, PL). During the development of leptotene to diplotenespermatocytes (eSP to dSP), Suv39h2 staining is weakly but distinctlyapparent at blocks of heterochromatin, as visualized by the brightDAPI counterstaining. Prominent Suv39h2 signals accumulate atthe sex chromosomes present in the XY body during the mid to latepachytene stage (lSP, arrowhead). After the meiotic divisions,Suv39h2 remains enriched at the condensing heterochromatic fociand chromocenters of haploid spermatids (rSTs) but is no longerdetectable in mature sperm (data not shown).

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FIG. 9. Dynamic heterochromatin association of Suv39h2 in male germ cells. (A) Indirect immunofluorescence of testis suspension cells with $alpha$ -Suv39h2 antibodies (red). DNA was counterstained with DAPI (blue). Staging of individual mouse spermatogenic cells was determined as described in Materials and Methods and comprised preleptotene spermatogonia (PL); early, middle, and late spermatocytes (eSP, mSP, and lSP); diplotene spermatocytes (dSP); and round spermatids (rST). Merged images are artificially colored yellow. (B) Double-labeling indirect immunofluorescence for Suv39h2 (red) and Xmr (green) in late-pachytene spermatocytes of adult testis suspension cells. DNA was counterstained with DAPI (blue). The XY body (sex vesicle) in panel A is indicated by an arrowhead.

To demonstrate the specific accumulation of Suv39h2 with the XY body, we performed double immunofluorescence analyses forSuv39h2 and Xmr, which selectively associates with the axes andchromatin of sex chromosomes (12). The results of these analysesshow that Suv39h2 colocalizes with Xmr at the XY body in 48% ofevaluated spermatocytes (n = 194) containing a prominent Xmr stainingof the sex chromosomes (Fig. 9B). Whereas immunolocalization ofSuv39h2 at the XY body and at the chromocenters of haploid spermatidscan be observed by several staining techniques, the visualizationof Suv39h2 at heterochromatin in developing spermatocytes requirestriple labeling (see Materials and Methods). Despite these variationsin the detection sensitivity, our data indicate a dynamic heterochromatindistribution for Suv39h2 during most stages of spermato- and spermiogenesis.By contrast, in parallel analyses of testes swab preparationswith $alpha$ -Suv39h1 antibodies, immunolocalization of Suv39h1 onlyrevealed very weak labeling that did not show a preference forheterochromatin (data notshown).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Murine Suv39h genes are encoded by two loci. Using sequence information from isolated cDNAs, ESTs, and genomic sequences, we defined Suv39h2 as a novel gene encoding aprotein of 477 amino acids (Fig. 1). The size and authenticityof the Suv39h2 gene product has been confirmed by immunodetectionof a 53-kDa endogenous protein in nuclear extracts of PMEFs andtestis (see Fig. 6). RNA blot analyses (see Fig. 4A and data notshown) indicate that the most abundant Suv39h2 transcripts are2.7 kb, suggesting that the Suv39h2 mRNA is composed of 1.5-kbcoding and 1.2-kb 3'-untranslated sequences. In addition, smaller-sizedtranscripts of 1.7 kb are also present at day E10.5 of mouse embryogenesisand in adult testis. Although an alternative short exon (precedingthe starting ATG by ~260 bp and encoding the amino acids MASDLRT-)can be predicted from the genomic sequence, both the 1.7- andthe 2.7-kb transcripts hybridize with exon 1 sequences (data notshown). Since we failed to detect endogenous proteins distinctfrom the 53-kDa Suv39h2 gene product, the smaller-sized transcriptsdo not appear to give rise to a largely different Suv39h2isoform.

From all available sequence information, similarity searches against EST databases and reduced stringency hybridizations (datanot shown), murine Suv39h proteins appear to be encoded by nomore than two gene loci. Using FISH and haplotype analysis, wemapped the Suv39h2 locus to the subcentromeric region of mousechromosome 2 (Fig. 2 and 3). Our localization data characterizesSuv39h2 as one of the most proximal gene markers on mouse chromosome2 and would predict a syntenic position for SUV39H2 on human chromosome10p13-p15. Within this region, loss of heterozygosity has beencorrelated with human gliomas (26). In contrast, Suv39h1 residesat the tip of the X chromosome in the immediate vicinity of themouse mutations Td (13) and Sf (39). However, the recent correlationof mutations in a gene encoding a sterol isomerase with the Tdphenotype (16) and the absence of apparent alterations for Suv39h1in Sf/Y mice (10) would indicate that Suv39h1 is nonallelicto Td or Sf.

Chromatin association of Suv39h2 in somatic versus meiotic cells. In our previous studies, we identified Suv39h1 and SUV39H1 as heterochromatic proteins that associate with centromeric positionsof metaphase chromosomes (1, 2). Although Suv39h2 can bedetected in some mammalian cell lines (data not shown) and inPMEFs (see Fig. 6), we failed to visualize endogenous Suv39h2at heterochromatic foci or at mitotic chromosomes in these cells.By contrast, transient expression of (myc)₃-Suv2(83-477) in murineCop8 cells results in preferred heterochromatic localizationsat a low abundance of ectopic protein (data not shown). This observationsuggests that the highly basic N terminus is not required forthe intrinsic chromatin affinity of Suv39h2 but may modulate chromosomalassociations in somatic versus meiotic chromatin. This interpretationis supported by the apparent preference of Suv39h2 for heterochromatinin pachytene spermatocytes and round spermatids (see Fig. 9),whereas Suv39h2 displays a rather broad nuclear staining in Sertolicells (data not shown). Because SUV39H1 has been shown to be aphosphoprotein with mitosis-specific isoforms (2) which appearsfurther regulated by the anti-phosphatase Sbf1 (18), it is likelythat phosphorylation-dependent modifications could also contributeto the distinct distributions of Suv39h2 in mitotic and meioticchromatin.

Suv39h HMTases and histone H3 tail modifications. Suv39h-dependent methylation of Lys9 in the histone H3 N terminus has been shown to modulate chromatin dynamics in somaticcells, in part by interfering with the phosphorylation of adjacentserine 10 (phosH3) (36), a modification required for the condensationand segregation of chromosomes (48). Moreover, heterochromatinassociation of HP1 is perturbed upon forced expression of SUV39H1in HeLa cells (30), and methylation of Lys9 in H3 generatesa high-affinity binding site for HP1 proteins in native chromatinof PMEFs (M. Lachner, D. O'Carroll, S. Rea, K. Mechtler, and T.Jenuwein, submitted for publication). Similarly, overexpressionof (myc)₃-Suv2(83-477) in HeLa cells also redistributes endogenousHP1 $beta$ (data not shown). Suv39h2 is an H3 Lys9-selective HMTase,whose substrate specificity and sensitivity to preexisting H3tail modifications appears to be even more stringent than thatof Suv39h1 (see Fig. 7). These findings indicate that both Suv39hHMTases can transduce the H3 Lys9 methylation mark into an importantepigenetic signal for the induction and assembly of mammalianheterochromatin in somaticcells.

A role for the Suv39h2 HMTase in the male germ line? Dynamic transitions in chromatin structure are particularly important during male meiosis (see the introduction), where heterochromatinizationhas been proposed to be involved in the progressive centromereclustering of chromosomes (31). Because phosH3 also definescentromeric heterochromatin in meiosis (14), Suv39h2 could modulatethe timing and/or degree of H3 phosphorylation, thereby influencingchromosome alignments during the meiotic divisions. In additionto such a centromeric model, meiotic chromatin associations ofthe Suv39h2 HMTase extend to the spermatid stage and significantlyoverlap with Hp1 $beta$ (see Fig. 8), suggesting that Suv39h2-inducedalterations could further contribute to the dense packaging ofchromatin in elongating spermatids. HP1 $beta$ has recently been shownto be retained in mature spermatozoa by protein blot analysis(23). Similarly, ~15% of human sperm chromatin remains complexedwith histones (19). Although the presence of Suv39h2 in maturesperm is currently undefined, its highly basic N terminus couldfacilitate associations with condensing chromatin in elongatingand elongated spermatids, when histones are replaced by protamines(6).

Most interestingly, Suv39h2 and HP1 $beta$ (32) accumulate with the silenced sex chromosomes present in the XY body (Fig. 8 and9). This finding is particularly intriguing, since SUV39H1 (18)and HP1 $beta$ (33, 40) have been shown to repress gene activityin somatic cells (18). Because of the high conservation betweenmammalian Suv39h proteins (Fig. 1), these data imply that Suv39h2would represent an important regulator to induce silenced chromatindomains at selective chromosomes during spermatogenesis. Basedon the results presented here, we even propose that the Suv39h2HMTase could impart an epigenetic imprint to the male germline.

	ACKNOWLEDGMENTS

We thank Gotthold Schaffner, Robert Kurzbauer, and Ivan Botto for sequence analysis and oligonucleotide synthesis; AlexanderSchleiffer for database searches on the C. elegans C15H11.5 ORF;Meinrad Busslinger for advice on the exon/intron organizationof the genomic Suv39h2 clone; Jean-Louis Guénet (Pasteur Institute,Paris, France) for his gift of WMP mice; Cécile Mignon-Ravixfor help in the FISH analysis; Prim B. Singh (The Roslin Institute,Roslin, Midlothian, United Kingdom) for $alpha$ -M31 (HP1 $beta$ ) antibodies;Christa Heyting (Wageningen, The Netherlands) for $alpha$ -Scp3 antibodies;H.-J. Garchon (Hopital Necker, Paris, France) for $alpha$ -Xmr antibodies;and Karl Mechtler for Suv39h2 antiserumpurification.

This work was supported by the IMP through Boehringer Ingelheim and by grants from by the Austrian Research Promotion Fundto T.J., the Deutsche Forschungsgemeinschaft (grant number DFG#350/8-2) to H.S., the Medical Research Council (United Kingdom)to S.D.M.B., and the ARC (Association pour la Recherche sur leCancer) to M.G.M.

	FOOTNOTES

^* Corresponding author. Mailing address: Research Institute of Molecular Pathology at the Vienna Biocenter, Dr. Bohrgasse 7,A-1030 Vienna, Austria. Phone: (43/1) 797-30-474. Fax: (43/1)798-7153. E-mail: jenuwein{at}nt.imp.univie.ac.at.

Present address: Dairy Science Group, AgResearch, Hamilton, NewZealand.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
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36. Rea, S., F. Eisenhaber, D. O'Carroll, B. D. Strahl, Z.-W. Sun, M. Schmid, S. Opravil, K. Mechtler, C. P. Ponting, C. D. Allis, and T. Jenuwein. 2000. Regulation of chromatin structure by site-specific histone H3 methyltransferases. Nature 406:593-599[CrossRef][Medline].

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40. Ryan, F. R., D. C. Schultz, K. Ayyanathan, P. B. Singh, J. R. Friedman, W. J. Fredericks, and F. J. Rauscher, III. 1999. KAP-1 corepressor protein interacts and colocalizes with heterochromatic and euchromatic HP1 proteins: a potential role for Krüppel-associated box-zinc finger proteins in heterochromatin-mediated gene silencing. Mol. Cell. Biol. 19:4366-4378[Abstract/Free Full Text].

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