Molecular Characterization and Placental Expression of HERV-W, a New Human Endogenous Retrovirus Family

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Journal of Virology, February 1999, p. 1175-1185, Vol. 73, No. 2
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Molecular Characterization and Placental Expression of HERV-W, a New Human Endogenous Retrovirus Family

Jean-Luc Blond,¹ Frédéric Besème,¹ Laurent Duret,² Olivier Bouton,¹ Frédéric Bedin,¹ Hervé Perron,¹ Bernard Mandrand,¹ and François Mallet¹^,^*

Unité Mixte 103 CNRS-bioMérieux, Ecole Normale Supérieure de Lyon, 69364 Lyon, Cédex 07,¹ and Laboratoire de Biométrie Génétique et Biologie des Populations, UMR CNRS 5558, Université Claude Bernard-Lyon 1, 69622 Villeurbanne Cedex,² France

Received 15 July 1998/Accepted 10 November 1998

	ABSTRACT

Top Abstract Introduction Materials and methods Results Discussion References

The multiple sclerosis-associated retrovirus (MSRV) isolated from plasma of MS patients was found to be phylogenetically andexperimentally related to human endogenous retroviruses (HERVs).To characterize the MSRV-related HERV family and to test the hypothesisof a replication-competent HERV, we have investigated the expressionof MSRV-related sequences in healthy tissues. The expression ofMSRV-related transcripts restricted to the placenta led to theisolation of overlapping cDNA clones from a cDNA library. ThesecDNAs spanned a 7.6-kb region containing gag, pol, and env genes;RU5 and U3R flanking sequences; a polypurine tract; and a primerbinding site (PBS). As this PBS showed similarity to avian retrovirusPBSs used by tRNA^Trp, this new HERV family was named HERV-W. Several genomic elementswere identified, one of them containing a complete HERV-W unit,spanning all cDNA clones. Elements of this multicopy family werenot replication competent, as gag and pol open reading frames(ORFs) were interrupted by frameshifts and stop codons. A completeORF putatively coding for an envelope protein was found both onthe HERV-W DNA prototype and within an RU5-env-U3R polyadenylatedcDNA clone. Placental expression of 8-, 3.1-, and 1.3-kb transcriptswas observed, and a putative splicing strategy was described.The apparently tissue-restricted HERV-W long terminal repeat expressionis discussed with respect to physiological and pathologicalcontexts.

	INTRODUCTION

Top Abstract Introduction Materials and methods Results Discussion References

A few years ago, the presence of extracellular particles associated with reverse transcriptase (RT) activity was observedin leptomeningeal cells (LM7) (42) and monocyte cultures (44)from patients with multiple sclerosis (MS). Viral RT-associatedactivity plus electron microscopy examination and the presencein MS patients of antibodies cross-reacting with human immunodeficiencyvirus type 1 and type 2 RT and human T-cell leukemia virus type1 CA as well (41) led to the hypothesis of the retroviral natureof these viral particles. By mainly a PCR-based approach, a partialmolecular identification of a novel retrovirus isolated from cerebrospinalfluid, plasma, or cell culture supernatant of MS patients wasrecently obtained (40). Retroviral RNAs with strong similaritiesto MS-associated retrovirus (MSRV) were also found in plasma ofrheumatoid arthritis (RA) patients (17). Furthermore, expressionof related mRNA sequences (8) was found in both MS and controlbrain tissues (29).

All together, these observations might result from three different situations. The extracellular particles may be producedby a replication-competent endogenous provirus. Alternatively,MSRV could represent a virion-producing exogenous member of anendogenous family, as described for the mouse mammary tumor virusand murine leukemia virus retroviral families of mice (23) andin the Jaagsiekte retroviral family of sheep (37). Lastly, amore complicated process would involve separated defective retroviralentities cooperating via trans-complementation.

MSRV was found to be related to the endogenous retroviral sequence ERV-9 (26), and Southern blot analysis with an MSRV polprobe showed hybridization with a multicopy endogenous family(40). Therefore, we have studied the MSRV-related human endogenousretroviruses (HERVs), which could represent either distant membersof the ERV-9 family or an as yet undescribed HERV family. As (i)the HERV family was shown to be a multicopy family (40) and(ii) we focused on the hypothesis that MSRV could be a replication-competentHERV, we followed a strategy based on the characterization ofmRNA isolated from a healthy human tissue, by using MSRV- andERV-9-derived probes. We describe a new multicopy endogenous retroviralfamily tentatively named HERV-W. All members of the family areapparently not competent for replication. However, a functionalU3 promoter and an open reading frame (ORF) putatively codingfor an envelope protein were identified. HERV-W mRNA expressionis restricted to placental tissue in Northern blot analysis. Thestrategy of transcription is addressed, and the promoter tissuespecificity isdiscussed.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and methods Results Discussion References

Probe definition and labelling. The 678-bp Ppol-MSRV probe was RT-PCR amplified from RNA extracted from particles collected from the supernatant of synoviocytecultures of an RA patient. These particles were gradient concentratedas previously described (43), and RNA was extracted by the methodof Chomczynski and Sacchi (10) and DNase treated as previouslydescribed (54). A first round of RT-PCR amplification was performedwith primers AP2942 (5'-AGGAGTAAGGAAACCCAACGGAC-3') (forward)and AP2152 (5'-TAAGAGTTGCACAAGTGCG-3') (reverse). A nested PCRwas then performed with primers AP2522 (5'-TCAGGGATAGCCCCCATCTAT-3')(forward) and AP2510 (5'-AACCCTTTGCCACTACATCAATTTC-3') (reverse).The 649-bp Ppol-ERV-9 probe was PCR amplified from a B-lymphocytecDNA library of an MS patient with primers AP2522 and AP2510 mentionedabove. Discrimination between the Ppol-MSRV- and Ppol-ERV-9-clonedPCR fragments was performed with an enzyme-linked oligosorbentassay (ELOSA) (35). Capture and detection oligonucleotide probesused in this nonisotopic sandwich technique are depicted in Fig.1A.

The Pgag-LB19 (536 bp), Ppro-E (364 bp), and Penv-C15 (591 bp) probes corresponded to PCR fragments of the longest ORFs ofLB19, E, and C15 clones, respectively. LB19 and E clones (37a)were obtained from RNA extracted from gradient-concentrated particlesof B-lymphocyte cultures of an MS patient or from the plasma ofan MS patient, respectively. The C15 clone (22a) was obtainedfrom RNA extracted from the pellet of centrifuged supernatantsof synoviocyte cultures of an RApatient.

Fifty nanograms of each probe was radioactively labelled by random priming with the Ready-to-Go DNA labelling kit from PharmaciaBiotech, Inc., according to the manufacturer's protocol with [ $alpha$ -³²P]dCTP (3,000 Ci/mmol). The specific activity of probes was >5.0× 10⁸ cpm/µg.

Placental cDNA library screening, 5' rapid amplification of cDNA ends (RACE), and sequencing. A placental cDNA library constructed in the bacteriophage lambda vector was used (human placenta 5'-Stretch Plus cDNA libraryfrom Clontech Laboratories, Inc., Palo Alto, Calif.). Screeningof the library was performed according to the manufacturer's instructionswith the Ppol-MSRV probe for initial screening, and probes werederived from the resulting clones for additional screening. Briefly,for each screening the plating density was about 5 × 10⁵ PFU for two 220- by 220-mm plates. After growth, plaques weretransferred onto a nylon membrane (Hybond N⁺; Amersham) and hybridized with probes radioactively labelledas described above (10⁶ cpm/ml of hybridization solution). Prehybridization was performedovernight at 42°C in a freshly prepared solution: 50% formamide,5× SSPE (20× SSPE is 3 M NaCl, 0.2 M NaH₂PO₄, and 20 mM EDTA,pH 7.4), 5× Denhardt's solution (100× Denhardt's solution is 10g of Ficoll 400, 10 g of polyvinylpyrrolidone, and 10 g of bovineserum albumin for 500 ml), and 0.1% sodium dodecyl sulfate (SDS)with 100 µg of heat-denatured herring sperm DNA per ml. Hybridizationwas performed overnight at the same temperature, in a renewedsolution freshly prepared in the same way. After hybridization,filters were washed once for 20 min at room temperature with 2×SSC (20× SSC is 3 M NaCl and 0.3 M sodium citrate)-0.5% SDS followedby one wash for 25 min at 60°C with 1× SSC-0.1% SDS. Washed filterswere exposed to X-ray films (Kodak) for 72 h at $-$ 80°C. Isolatedpositive plaques were picked and eluted in the appropriatebuffer.

A rapid method was used for subcloning of the cDNA clones. A PCR amplification using a primer generated according to the bacteriophagelambda vector sequence and a specific primer designated accordingto the probe sequence was performed in a 9600 Perkin-Elmer machine.PCR was carried out with initial denaturation at 94°C for 5 minfollowed by 30 cycles of 94°C for 1 min, 54°C for 1 min, and 72°Cfor 4 min; terminal extension was performed at 72°C for 7 min.After 1% agarose gel analysis, the longest fragments were subclonedinto pCR 2.1 vector (TA cloning; Invitrogen, San Diego, Calif.)andsequenced.

A 5' RACE technique was used to obtain the 5' end of the retrovirus genome; the kit, used strictly according to the manufacturer'srecommendations, was provided by Life Technologies, Inc. (Bethesda,Md.). Reverse transcription, dC-tailing, and amplifications wereperformed on a commercially available placental mRNA [human placentalpoly(A)⁺ RNA; Clontech], and fragments were subcloned into pCR 2.1 vector(TAcloning).

Sequencing reactions were performed, in both directions for each clone, with the Prism Ready Reaction kit and Dye Deoxyterminatorcycle sequencing kit (Applied Biosystems). Automatic sequenceanalysis was performed on an automatic sequencer (AppliedBiosystems).

Hybridization of Northern blots and RNA dot blots. Several Northern blots of different registration lot numbers were used (multiple-tissue Northern blot, catalog no. 7760-1from Clontech Laboratories, Inc.). Prehybridization was performedovernight at 42°C in the following freshly prepared solution:50% formamide, 5× SSPE, 10× Denhardt's solution, 2% SDS, and heat-denaturedherring sperm DNA (100 µg/ml). Hybridization was performed overnightat 42°C in a renewed solution with a probe labelled as describedabove (10⁶ cpm/ml of hybridization solution). Filters were washed twicewith 1× SSC-0.1% SDS at room temperature for 5 min and once with0.1× SSC-0.1% SDS at 50°C for 10 min. Washed filters were exposedto X-ray films (Kodak) for 5 days at $-$ 80°C.

RNA dot blot (human RNA Master Blot from Clontech Laboratories, Inc.) was used according to the manufacturer's instructions.Briefly, prehybridization was performed at 65°C in the ExpressHybhybridization solution from Clontech for 30 min. Hybridizationof a probe labelled as described above was performed overnightat 65°C in a renewed solution. The membrane was washed twice at65°C with 2× SSC-1% SDS for 20 min and once at 55°C with 0.1×SSC-0.5% SDS and exposed to X-ray film (Kodak) for about 12h.

Hybridization of Southern blots and DNA dot blots. Human genomic DNA was digested with EcoRI, HindIII, and PstI. Ten micrograms of each reaction mixture was electrophoresedon a 0.8% agarose gel and transferred onto a charged nylon membrane(Hybond N⁺ [Amersham]). Prehybridization was performed overnight at 42°Cin a freshly prepared solution: 50% formamide, 5× SSPE, 1% (wt/vol)nonfat dried milk, 1% SDS, and 50 µg of heat-denatured herringsperm DNA per ml. Hybridization was performed overnight at 42°Cin a renewed solution, with a probe radioactively labelled asmentioned above (10⁶ cpm/ml of hybridization solution). Filters were washed once with1× SSC-0.1% SDS at room temperature for 5 min and once with 0.1×SSC-0.1% SDS at 50°C for 10 min. Washed filters were exposed toX-ray films (Kodak) for 5 days at $-$ 80°C.

For the DNA dot blot, successive dilutions of each probe (2.5, 5, 10, 25, 50, and 100 pg) and 0.5 µg of genomic DNA were blottedon a charged nylon membrane after denaturation. For each probe,the dot blot and the Southern blot were handled in the samevessel.

CAT assay. The putative promoter region was cloned into pCAT3 Enhancer reporter vector purchased from Promega Biotec (Madison, Wis.).HeLa 60% confluent cells cultured in Dulbecco modified Eagle medium-10%fetal calf serum (Life Technologies) were transfected with theSuperfect transfection kit (Qiagen GmbH) with 2 µg of purifiedrecombinant plasmid. After a 48-h incubation, the cells were harvestedin order to evaluate chloramphenicol acetyltransferase (CAT) activityby the use of the CAT enzyme assay system (Promega Biotec). Forthis purpose, the liquid scintillation counting protocol was followedas recommended by the manufacturer. Briefly, cell extracts wereobtained by several freezes-thaws and a subsequent heating at60°C for 10 min. Then, 10 µl of this extract was added to 0.25M Tris-HCl, pH 8.0 (125 µl, final volume), containing 0.15 µCiof [¹⁴C]chloramphenicol (NEN, Boston, Mass.) and 5 µg of n-butyryl coenzymeA, and incubated for 4 h at 37°C. Five hundred microliters ofa mix of xylene isomers was added, and the butyrylated chloramphenicolpresent in this organic phase was extracted twice with 100 µlof 0.25 M Tris-HCl. This 200 µl was mixed with 5 ml of scintillationfluid and counted in a liquid scintillationcounter.

In vitro transcription-translation. In vitro transcription-translation was performed with a kit from Promega Biotec (TNT coupled reticulocyte lysate systems).It was used strictly according to the manufacturer's instructions.Briefly, DNA templates were obtained by PCR with a 5' primer designedwith a T7 promoter (5'-CATAATACGACTCACTATAGGGAGACCATGGCCCTCCCTTATCAT-3').The radiolabelled amino acid was [³⁵S]methionine, provided by Amersham. Glycosylation was studiedby the translation in vitro in the presence of canine pancreaticmicrosomal membranes (also provided by Promega). Posttranslationalanalysis was performed by SDS-polyacrylamide gel electrophoresis,and the gel was exposed to X-ray films (Kodak), usually for 12h.

Sequence analysis. Individual cDNA clones were used for phylogenetic analysis. Sequences were filtered for low-complexity regions and repeatsequences (Alu-like and microsatellites) with XBLAST (12). ABLASTN (or BLASTX) (2) query for GenBank (release 101, June1997) was performed, and sequence matches with scores greaterthan 200 were retained. Homologous fragments were extracted fromGenBank and aligned with our cDNA clones. Alignments were performedsemimanually, with the SEAVIEW multiple alignment editor (16)and the Clustal W (52), Dialign (36), or MABIOS (1) multiplealignment program. Regions corresponding to putative coding regionswere determined with Blixem (51), a program allowing the visualizationof protein similarities on a nucleic acid sequence from the alignment.We selected in the alignment three regions from long terminalrepeat (LTR), Pol, and Env that are conserved in all members ofthe family of human endogenous viruses that we have identified.Phylogenetic trees were computed from these three regions withPhylo_win (16) with the neighbor-joining method (49). Fivehundred bootstrap replicates were performed to evaluate the robustnessof thetrees.

Promoter prediction was performed with PROSCAN v1.7 (47) and SIGSCAN v4.05 (46). A searching for protein sequence similaritieswas performed with LFASTA (39). The prediction of leader peptidewas made with GeneWorks 2.5.1 software. Prediction of the fusiondomain and the transmembrane region was performed with the PHDpackage (48).

Nucleotide sequence accession numbers. The sequences described in this paper have been submitted to GenBank under the following accession numbers. The probe numbersare as follows: Ppol-MSRV (AF072494), Ppol-ERV-9 (AF072495),Pgag-LB19 (AF072496), Ppro-E (AF072497), and Penv-C15 (AF072498).The placental cDNA clones numbers are as follows: cl.6A1 (AF072499),cl.6A2 (AF072500), cl.7A16 (AF072501), cl.Pi5T (AF072502),cl.Pi22 (AF072503), cl.44.4 (AF072504), cl24.4 (AF072505),cl.PH74 (AF072506), cl.PH7 (AF072507), and cl.C4C5 (AF072508).

	RESULTS

Top Abstract Introduction Materials and methods Results Discussion References

Design of probes. Pol probes were designed to evaluate the expression of MSRV-related sequences in healthy human tissues. The choice of Polprobes relied on the observations that (i) the previously describedPol region of MSRV was related to the ERV-9 HERV and (ii) ERV-9sequences were occasionally detected with MSRV in plasma or cellculture supernatants of MS patients (40). Because (i) the 2,304-bpMSRV Pol region (40) was a consensus sequence resulting fromoverlapping clones obtained from different sources and (ii) theMSRV and ERV-9 codetected sequences were only 120 bp long, wechose to amplify two continuous 650-bp MSRV- and ERV-9-relatedfragments, defined by the same borders and including the 120-bpcodetected region. MSRV- and ERV-9-related Pol regions were RT-PCRamplified as described in Materials and Methods, and mixed resultingfragments were cloned and checked (data not shown) with the ELOSAprocedure (Fig. 1A), which was previously shown to discriminatebetween the MSRV and ERV-9 Pol 120-bp coamplified fragments (40).The ELOSA MSRV-related probe, which was called Ppol-MSRV, has87 and 69% similarity with MSRV and ERV-9 reference sequences,respectively. The ELOSA ERV-9-related probe, which was calledPpol-ERV-9, has 70 and 87% similarity with MSRV and ERV-9, respectively.

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FIG. 1. (A) Capture and detection probes used in ELOSA to detect PCR-amplified ERV-9 and MSRV pol-related sequences. Discrimination between ERV-9 and MSRV cloned PCR fragments was performed at the capture step with CpV1A and CpV1B-D, respectively. Colorimetric detection was achieved with the DpV1A-D peroxidase-labelled probe located within the most conserved region of ERV-9 and MSRV pol genes. The selected PCR fragments were called Ppol-MSRV and Ppol-ERV-9 according to ELOSA characterization. The reference (ref) ERV-9 (gb X57147, gb M85205, and gb M37638) and MSRV (gb AF009668) sequences are indicated as well as the consensus (cons) sequences. These consensus sequences resulted from RT-PCR amplification of the conserved region of the pol gene present in all retroviruses (40, 50); the RNA material was obtained from MS patients. (B) Northern blot analysis of poly(A)⁺ cellular RNAs from eight human tissues with the Ppol-MSRV and Ppol-ERV-9 probes characterized by ELOSA.

In order to improve the likelihood of finding sequences containing ORFs, consistent with the hypothesis that MSRV could bea replication-competent HERV, three other probes were derivedfrom putatively packaged extracellular mRNAs detected in pathologicalcontexts. These mRNAs were RT-PCR amplified with primers designedaccording to the obtained placental cDNA clones (see below) and/orto the conserved region of retroviruses and/or to 5' and 3' RACEprotocols. Although no amplified fragments supported coding capacitiescompatible with a replication-competent retrovirus, Pgag-LB19,Ppro-E, and Penv-C15 probes were designed, corresponding to thelongest ORFs found in PCR products derived from gag, pro, andenv,respectively.

Expression of a novel HERV in placenta. Ppol-MSRV, Ppol-ERV-9, Pgag-LB19, and Penv-C15 probes were then used for hybridization of a multiple-tissue Northern blotunder stringent conditions. The Ppol-MSRV probe revealed an 8-kbtranscript that was expressed in placenta but not in heart, brain,lung, liver, skeletal muscle, kidney, or pancreas (Fig. 1B). Nosignal was detected with the Ppol-ERV-9 probe (Fig. 1B). The placenta-restrictedexpression was confirmed for Pgag-LB19 and Penv-C15 probes (datanot shown). Furthermore, 48 tissue samples including cerebral,muscular, endocrine, exocrine, lymphoid, visceral, and fetal tissueswere not revealed by Pgag-LB19 and Penv-C15 probes by RNA dotblot, but both placental and kidney mRNAs were found to be positive(data not shown). As the kidney mRNA expression was not revealedby Northern blotting, with four different commercial lots, weinterpreted the kidney mRNA positive signal as an artifact resultingfrom the method per se, including tissue-specific mRNA preparationor DNAcontamination.

A BLASTN query on the EST (expressed sequence tag) database, with placental cDNA clones (see below) derived from the aboveprobes, showed hundreds of related transcripts in the human tissues,most in the opposite direction. With a search criterion of 90%identity over 100 nucleotides (nt) or more, these sequences werefound predominantly expressed in the placenta (53%), but alsoin fetal liver-spleen (28%). The relative abundance of HERV-Wsequences among placenta ESTs was found to be three times higherthan that among fetal liver-spleenESTs.

Isolation and sequencing of overlapping cDNA fragments. A placental cDNA library was screened with Ppol-MSRV, Pgag-LB19, and Penv-C15 probes. Probes derived from the resulting cloneswere then used for additional screening. The clones obtained withall three screenings exhibited the same characteristics. All together,the overlapping cDNA clones covered 7.6 kb. Nine overlapping clonesobtained with the Ppol-MSRV screening are shown in Fig. 2A. Thepercentages of similarity among the overlapping parts of thesePpol-MSRV-derived cDNA clones, a polyadenylated clone (cl.C4C5)probed with Penv-C15, and the probes used for the screening aswell are presented in Fig. 2B. The similarity between cDNA clonesranged from 97 to 100% with the exception of the cl.7A16 clone,which was about 90%. The similarity between the cDNA clones andprobes derived from MSRV-related extracellular RNA sequences rangedfrom 85 to 94%. Similarly, this percentage was near 90% with theMSRV Pol region previously described (40) but was lower than70% with the ERV-9 Pol probe.

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FIG. 2. (A) Clones isolated from a placental cDNA library first with the Ppol-MSRV probe and probes derived from the resulting clones for additional screening. The length of the clone is indicated in parentheses. Black, white, and grey boxes represent regions showing extensive homology with gag, pol, and env genes, respectively; AAAAAAAA indicates poly(A) tail; flanking striped boxes represent UTRs; and repeats are indicated by black arrowheads. (B) Percentages of similarity between the overlapping regions of placental cDNA clones and between the cDNA clones and the probes used in this study. For the cDNA clone analysis, percentages are indicated in boldface and italics for overlapping fragments larger than 1 kb and 490 bp, respectively. The smallest overlapping fragment is 205 bp long. For the comparison between cDNA clones and probes, percentages labelled with asterisks indicate a partial overlap. Probes used for the placental cDNA library screening are underlined.

With BLASTX, sequences of the different fragments showed extensive homology with Gag, Pol, and Env retroviral proteins. Howevergag and pol genes did not support ORFs corresponding to functionalproteins. An ORF putatively coding for a retroviral envelope proteinwas observed on the 3' cDNA clones (cl.24.4, cl.C4C5, and cl.PH74).This Env ORF was totally contained in the cl.PH74 cDNA clone.Flanking untranslated regions (UTRs) were observed upstream anddownstream from gag and env genes, respectively, containing repeatedsequences (R) as described for LTRs. The length of R was estimatedas about 120 bp by comparison of the 5' end of the 5' most cDNAclone (cl.6A2) and the 3' end of a polyadenylated clone (cl.PH74),both clones showing 98% similarity in their 5' UTR overlap. Threeclones contained 3' UTRs followed by a poly(A) tail (cl.Pi5T,cl.PH74, and cl.C4C5).

Phylogenetic analysis. A phylogenetic analysis was performed at the nucleic acid level on 11 different subregions of the region spanned by the cDNAsand at the protein level on two different Env subregions, as describedin Materials and Methods. All the trees had the same topologyregardless of the region addressed. Notably, the human BAC cloneRG083M05 was represented in all trees. These results were illustratedat the nucleic acid level within the most conserved regions ofthe LTR (R-U5) and the pol gene (RT catalytic domain) betweenthe obtained sequences and ERV-9 and RTVL-H (Fig. 3). The treesclearly showed that those sequences described a new family relatedto, but distinct from, ERV-9 and even more distant from RTVL-Has highlighted by the bootstrap analysis. Those sequences werefound on several chromosomes, including 5, 7, 14, 16, 21, 22,and X, with an apparent high concentration of LTR in chromosomeX.

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FIG. 3. Phylogenetic analyses were performed at the nucleic acid level for LTR and pol regions and at the protein level for Env. The included sequences were selected as described in Materials and Methods. Experimental clones are indicated in shaded boxes, and MSRV sequences are underlined. LTR, POL, and ENV neighbor-joining trees based upon 123-nt LTR (nt 6 to 143 of clone cl.6A2), 575-nt pol (nt 2309 to 2933 of clone cl.6A1), and 113-aa Env (translation of nt 1852 to 2211 of clone cl.PH74) fragments are presented from left to right. Pairwise gap removal was used for the LTR tree, and all-gap removal was used for POL and ENV trees. Bootstrap values for 500 replicated trees are indicated. "c-" means that the sequence is presented in reverse orientation. Chromosomal assignments are indicated in brackets. Upstream (5) and downstream (3) LTRs are indicated when required. Sequences used in the LTR tree are as follows: clone RG083M05 (AC000064); IMMDL, DNA sequence of the human immunoglobulin D segment locus (X97051 S64822); cosmid U221F2 (Z75893); cosmid cU96H11 (Z70042); PAC 107N3 (Z75741); cosmid E110C7 (Z68223); P135H5C8, H. sapiens DNA sequence on chromosome 21 (L35660); cosmid cN74G7 (Z69715); cosmid U101D3 (Z85998); BAC clone CIT987SK-29B12 (U95738); PAC clone H74 (AC000352); cosmid 315B17 (Z73967); cosmid U61F10 (Z75895); cosmid U85B5 (Z69724); cosmid U116E9 (Z95333); human DNA sequence from clone J428A131 (Z82209); PAC 49C23 (Z93019); PAC 162C6 containing endogenous retrovirus pHE.1 (ERV-9) (Z84475); ERV-9LTR3 (M92648); ERV-9LTR2 (M92647); and ERV-9LTR-ZNF80, H. sapiens DNA for ZNF80-linked ERV-9 LTR (X83497). Additional sequences included in the POL tree are as follows: MSRV-pol reconstructed consensus (AF009668); Ppol-MSRV probe; ERV-9, HERV pHE.1 mRNA sequence (X57147, M85205, and M37638); Ppol-ERV-9 probe; PAC pDJ239b22 (AC003969 and U90583); and RTVL-H, HERV type H (D11078). Sequences appearing in the ENV tree are as follows: SNV, spleen necrosis virus (EMBL M87666); REV-A, reticuloendotheliosis virus strain A (X01455 K02537); SMRV-H, simian sarcoma virus (M23385); SRV-1 (L47.1), simian SRV-1 type D retrovirus (M11841); MPMV, simian Mason-Pfizer type D retrovirus (M12349); SRV-2, simian SRV-2 type D retrovirus (M16605); SRV-1, simian type D virus 1 (U85505); RD114, cat endogenous retrovirus RD114 env gene (X87829); BaEV, baboon endogenous virus virion (M16550); GALV, gibbon ape leukemia virus (M26927); MERV-Fv4, mouse endogenous retrovirus in Fv4 locus (M33884); Cas Br E MuLV, murine leukemia virus (Cas-Br-E MuLV) (M14702); MoMLV, Moloney murine leukemia virus (J02255, J02256, J02257, and M76668); MuLV, murine leukemia virus (M93052); and human sequences RTVL-H (NBRF B44282), ERV-9 (M85205 and M37638), and RAB7 (H. sapiens mRNA) (X93499).

Comparison at the protein level between the most conserved regions of Env retroviral proteins (immunosuppressive to transmembrane[TM] domain) resulted in trees showing a sequence distributionsimilar to the one observed at the nucleic acid level (Fig. 3).The two proximal coding sequences corresponded to the translatedenv ORF of RG083M05 and a truncated ORF located downstream fromthe GTP-binding protein RAB7 on the same mRNA. This group of sequenceswas more closely related to simian type D and reticuloendotheliosisavian retroviruses than to type C mammalianretroviruses.

Genomic complexity of the family. In order to characterize the complexity of this new endogenous retroviral family, we used several probes spanning the entiregenome. Southern blot analysis of human DNA digested with threedifferent restriction enzymes showed complex patterns with anapparent increase of complexity from env to gag and protease regions(Fig. 4A). A more precise determination of the copy number ofeach region was done by a dot blot analysis of serial dilutionsof the plasmids that contained the corresponding probes (datanot shown). The calculated number of copies per haploid genome(Fig. 4A) emphasized the heterogeneous distribution of the retroviralsubregions. A 6- and 20-fold increase of Gag and protease signals,respectively, versus the Env signal confirmed the gradation suspectedin Southern blot analysis.

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FIG. 4. (A) Southern blot analysis of human genomic DNA digested separately with EcoRI (E), HindIII (H), and PstI (P) and probed with Pgag-LB19, Ppro-E, and Penv-C15. The number of bands detected on the blot is indicated at the bottom for each restriction enzyme. The absolute copy numbers deduced from dot blot analysis, as well as confidence intervals, are also indicated at the bottom. Un., undigested. (B) Alignment of the placental cDNA clones (cDNAs; schematic representation of the 7.6-kb region defined with the overlapping cDNA clones) with the four sequences showing the higher scores with BLASTN query. Shown are human BAC clone RG083M05 (gb AC000064), human BAC378 (gb U85196 and gb AE000660), H. sapiens cosmid Q11M15 (gb AF045450), and human DNA sequence from cosmid U134E6 (EMBL Z83850). Locations of the aligned region of each clone are indicated. Chromosomal assignments are indicated in brackets. The percentages of similarity (without gaps) between the four sequences and the consensus sequence (cDNAs) are given (values for individual clones are indicated in the text). The presence of repeats at both ends of the genome is stated.

To characterize some genomic sequences at the molecular level, a BLASTN query on several databases was performed, with theplacental cDNA clones. The four most significant sequence hitsare depicted in Fig. 4B. They consisted of the human BAC cloneRG083M05 from 7q21-7q22, the human BAC378 corresponding to Homosapiens T-cell receptor alpha delta locus whose chromosomal locationis 14q11-12, the H. sapiens chromosome 21q22.3 cosmid Q11M15,and the human DNA sequence from cosmid U134E6 on chromosome Xq22containing NIK-like and thyroxin-binding globulin precursor. Repeatedsequences were found located at both ends of three of these clones.All the cDNA sequences fell entirely within the clone RG083M05(10.2 kb) with a similarity of about 98 to 99%, except the clonecl.7A16 (90%). However, in addition to gag, pol, and env genes,RG083M05 exhibited a 2-kb insert located just downstream fromthe 5' UTR, this insert being found also in clones BAC378 andQ11M15. These two clones and a third one (U134E6) presented astrictly conserved 2.3-kb deletion just upstream from the 3' UTR.No clone contained all three gag, pol, and env ORFs. The cloneRG083M05 exhibited a 538-amino-acid ORF corresponding to a full-lengthenvelope. The cosmid Q11M15 contained two large contiguous ORFsof 413 (frame 0) and 305 (frame +1) aa corresponding to a truncatedPol polyprotein. All together, these data suggested a quite complexfamily from which the RG083M05 clone could represent a genomicprototype.

RNA elements: LTR, polypurine tract, and primer binding site (PBS) characterization. In order to identify a potential promoter downstream from the cl.PH74 putative env ORF, a predictive analysis was performed.Proscan 1.7 did not predict any obvious promoter, but Signalscan4.05 indicated the presence of putative transcription factor bindingsites, including a CCAAT box and a TATA box. The 2,364- to 2,720-ntcorresponding region of the cl.PH74 clone (2,764 bp) was PCR amplifiedand subcloned into pCAT3 reporter vector. The CAT assay showeda significant expression level (Fig. 5A). A promoter activitywas also found in BeWo human choriocarcinoma cells and Jurkathuman T cells (data not shown).

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FIG. 5. Definition of a putative LTR. (A) The 2,364- to 2,720-nt region of the cl.PH74 clone, identified as a putative promoter region with Signalscan 4.05, was PCR amplified and subcloned into pCAT3 reporter vector. The resulting pCAT3-3'LTR plasmid and pCAT3 control plasmid were used to transfect HeLa cells prior to CAT activity determination. Cells, HeLa cell extract; pCAT3 and pCAT3-3'LTR, extract of HeLa cells transfected with control plasmid and promoter plasmid, respectively. (B) Alignment of 5' and 3' UTRs of placental experimental clones with the 5' (5-RG-28000-28872) and 3' (3-RG-37500-38314) repeated sequences of the 28,000- to 38,314-nt fragment of human DNA sequence RG083M05. The end of the 3'-most ORF is indicated (env orf). The tandemly repeated CAAC flanking sequences are doubly underlined on DNA sequences. The 783-bp LTR consensus sequence is positioned at the bottom. The polypurine tract (PPT) upstream from the 5' end of the LTR and the tRNA^Trp PBS downstream from the 3' end of LTR are indicated. U3, R, and U5 subparts are indicated, except for the U3-R junction. Transcription factor sites determined with Signalscan 4.05 are underlined and labelled from I to VI. The sites V and VI may correspond to CCAAT box and TATA box, respectively. The 3' region of clone cl.PH74 used in the CAT assay is underlined on the cl.PH74 sequence. * and $black-triangle$ , potential cap sites obtained in 5' RACE experiments with human placental poly(A)⁺ RNA and total RNA extracted from pCAT-3'LTR-transfected HeLa cells, respectively. [polyA], polyadenylation signal.

In order to characterize the retroviral LTR, the 5' and 3' UTRs of cDNA experimental clones were aligned with the 5' and 3'repeated sequences of the most proximal human DNA sequence, RG083M05.Nonretroviral flanking cellular sequences allowed us to delineatea 783-bp putative LTR (Fig. 5B). A duplicated 4-bp sequence (CAAC)was found flanking 5' and 3' LTRs. The characteristic TG-CA basepairs were found juxtaposed with nonretroviral sequences at eachend of the integrated provirus. The 5' end of U3 was confirmedby the presence, on the cl.PH74 and cl.C4C5 clones, of a polypurinetract located immediately upstream from U3 and 46 bp downstreamfrom the env stop codon. Determination of the U3-R junction wasquite complex. Several possible cap sites were found by 5' RACEexperiments on placental mRNA (data not shown), but surprisingly,all these sites were found included within the cl.6A2 clone (Fig.5B). More surprisingly, the predicted TATA box fell within theR sequence defined according to the cl.6A2 clone. To simplifythe analysis, a similar procedure was applied to a single U3-Rregion, with total RNA extracted from pCAT3-3'LTR-transfectedHeLa cells (data not shown). It indicated a potential cap sitedownstream from the TATA box (Fig. 5B). The 3' end of R was preciselydefined according to the presence of a poly(A) tail on cl.PH74and cl.C4C5 clones. The polyadenylation signal was found withinthe R region, 13 bp upstream of U5. The U5 LTR remaining sequencewas found to be 455 bp long. The 3' end of U5 was confirmed bythe presence, on the cl.6A2 (gag), cl.PH74, and cl.24.4 (env)clones, of a putative PBS located 4 bp downstream. This PBS showedextensive homology with the avian retrovirus PBS (53) used bytRNA^Trp for minus-strand DNA synthesis (34). As the tRNA^Trp was not described for humans and this PBS sequence did not correspondto any other tRNA, we tentatively named this new family HERV-W.

Transcription and putative splicing strategy. The expression of the HERV-W family in placenta was analyzed by Northern blotting (Fig. 6A) with a set of probes spread overthe 7.6-kb region containing the cDNA clones (Fig. 6B) and consistingof two U5 probes, U5(g) and U5(e), derived from an RU5-gag cDNAclone (cl.6A2) and a U5-env cDNA clone (cl.24.4), respectively,as well as gag, pro, pol, and env probes as described in Materialsand Methods, and a U3-R probe, U3(e), derived from an env-U3-R-poly(A)⁺ clone (cl.C4C5). A simple pattern consisting of three bands at8, 3.1, and 1.3 kb was observed. Probes from the gag, pro, andpol genes hybridized only to the 8-kb transcript which was alsorevealed by env, U5, and U3 probes and thus may correspond toa putative full-length transcript. Probe from the env gene detectedboth the full-length transcript and an abundant 3.1-kb transcriptwhich also hybridized to the U5 and U3 probes. Thus, this 3.1-kbtranscript exhibited the characteristic features of a singly splicedsubgenomic retroviral env mRNA. The U5 and U3-R probes revealedan additional transcript of 1.3 kb, lacking detectable gag, pro,pol, and env sequences, which may result from alternative splicingor transcription from defective HERV-W provirus.

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FIG. 6. (A) Northern blot analysis of poly(A)⁺ RNAs from placental tissues with the U5(g) (nt 115 to 717 of cl.6A2) and U5(e) (nt 1 to 491 of cl.24.4) probe, gag (Pgag-LB19), pro (Ppro-E), pol (Ppol-MSRV), and env (Penv-C15) probes as described in Materials and Methods and the U3(e) (nt 732 to 1116 of cl.C4C5) probe. (B) Hypothetical splicing strategy. The RG083M05 prototype DNA clone as well as six experimental clones (cl.6A2 and cl.44.4, cl.24.4 and cl.PH74, cl.PH7, and cl.Pi5T) isolated from the cDNA library is depicted. The nucleotide sequences of regions overlapping putative splice sites are boxed. Nucleic acid sequences of RG083M05 and all placental cDNA clones are indicated with lowercase and capital letters, respectively. AG and GT bordering splice sites are in boldface. Splice donor (DS) and acceptor (AS) sites are indicated by rightward and leftward arrows, respectively. U3 (hatched from lower left to upper right), R (light grey), U5 (hatched from upper left to lower right), 2-kb insert (vertically striped), Gag (black), Pol (white), and Env (dark grey) are shown as boxes. The positioning of the seven probes used in the Northern blot analysis and the placental region spanned by the cDNAs (cDNAs) are illustrated at the bottom of the figure.

No trivial correspondence between the observed transcripts and the isolated cDNA clones could be found, as the 5' end of Rwas not unambiguously defined. However, the cl.PH74 clone containingan env ORF and repeats at both ends was a good candidate for the3.1-kb subgenomic mRNA. Likewise, the cl.PH7 clone which containedU5 and U3 sequences at the 5' and 3' ends, respectively, but nostructural gene, might represent a large spliced subgenomic mRNA.In addition, if we assumed (i) that the cap site location wasas defined by the 3' LTR transfection experiment and (ii) theregion spanned by the cDNAs reflects a genomic RNA organizationas suggested by the Northern blot analysis, the lengths of genomic,subgenomic, and small mRNAs deduced from the cDNA clones wouldbe 7,541, 2,812, and 1,148 nt, consistent with the 8-, 3.1-, and1.3-kb observed transcripts,respectively.

Although no band larger than 8 kb was observed in the Northern blot, the alignment of the experimental clones with the 10.2-kbDNA sequence of the RG083M05 clone was performed in order to understandwhether these RNA transcripts result from splicing events or indicateexpression of defective HERV-W proviruses. This strategy permittedus to identify several apparently well-conserved splice donorand acceptor sites (Fig. 6B). The comparison of the 5' cDNA clonescl.44.4 and cl.6A2 with the RG083M05 sequence identified a splicedonor (DS1) and a splice acceptor (AS1) site, strictly flankingthe 2,075-bp insertion previously observed (Fig. 4). They werefound on RG083M05, just 564 and 2,640 nt, respectively, downstreamfrom R, as defined above. The absence of a major splice donorsite in the 5' cDNA clones cl.44.4 and cl.6A2 suggested that the8-kb apparent genomic RNA could result from a splicing strategy.The comparison of cl.PH74 and cl.PH7 clones with the RG083M05sequence identified two putative splice acceptor sites, AS2 andAS3, located 7,338 and 9,001 bp downstream from R, respectively(Fig. 6B). AS3 was also found in the cl.Pi5T clone, which contained,in addition, a second putative donor site (DS2), 7,545 bp downstreamfrom R and 207 bp downstream from the env acceptor site but upstreamfrom the env ATG codon. The occurrence of DS1/AS1, DS1/AS2, andDS1/AS3 splicing events on a putative RG083M05 precursor RNA wouldlead to 7,491-, 2,793-, and 1,130-nt transcripts whose sizes areremarkably close to those of genomic, subgenomic, and small mRNAsdeduced from the cDNAclones.

Coding capacities. On the cl.PH74 clone, the initiation codon of the long ORF putatively encoding the envelope protein was found 227 bp downstreamfrom the putative DS1/AS2 splice junction. It was the first ATGdownstream from this junction, although not the first from the5' end of the subgenomic RNA as five ATGs preceding five smallORFs (less than 27 aa) were situated ahead. Nevertheless, thisATG was in a relatively favorable context (CCCATGG) although slightlydifferent from the known (A/G)CCATGG favorable context for translation(24, 25). Figure 7A presents the amino acid sequence of aputatively functional envelope protein. This sequence was derivedfrom three clones: cl.PH74 presented a 5' LTR, a splice junction,a coding sequence of 538 aa, and a 3' LTR poly(A)⁺; cl.24.4 presented a 5' LTR, a splice junction, and a codingsequence of 410 aa; and cl.C4C5 presented a coding sequence of242 aa, a 3' LTR, and poly(A)⁺. This ORF exhibited the characteristic features of the precursorpolypeptide of retroviral envelope proteins. It presented a leaderpeptide at the amino terminus and a carboxy-terminal hydrophobicsegment which could anchor the protein in the membrane. A furincleavage site (RNKR) separated the two characteristic subdomainsconsisting of the surface protein (SU) and the transmembrane protein(TM). The TM contained, in addition to the membrane-spanning segment,a hydrophobic fusion domain and a putative immunosuppressive regionhomologous to the immunosuppressive p15E retroviral peptide conservedamong murine, feline, and human retroviruses (11). The SU andTM regions contained seven and one potential glycosylation site,respectively. Furthermore, these potential glycolysation sitesare conserved among the three considered clones and in the RG083M05clone, which might code for the same protein too. An in vitrotranscription-translation assay has been performed on this envgene. The results are shown in Fig. 7B. The measured molecularmass of the precursor is 60 kDa, in agreement with the calculatedmolecular mass of 59,565 Da of the Env ORF based on its aminoacid composition. Glycosylation of the Env precursor was observed,consistent with the prediction of carbohydrate addition sites.The measured molecular mass of the glycosylated protein is 80kDa.

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FIG. 7. (A) Sequence of the putative HERV-W envelope polypeptide derived from three different placental cDNA clones. The leader peptide (L), the surface protein (SU), and the transmembrane protein (TM) are indicated between arrows. The hydrophobic fusion peptide and the carboxy-transmembrane region are singly and doubly underlined, respectively. The immunosuppressive region is indicated by italics. Potential glycosylation sites are indicated by dots. Divergent amino acids are indicated on the lower line. (B) In vitro transcription-translation assay for HERV-W envelope gene product, without (RR $-$ ) or with (RR+) canine microsomes, and control (Cont) without template.

Two initiation codons potentially directing the synthesis of 52-aa (ORF1) and 48-aa (ORF2) peptides were found 22 and 95 bpdownstream from the putative AS3 splice acceptor site, respectively.Both ATGs were not in a favorable context. ORF1 consisted of thecarboxy-terminal part of Env, and ORF2 was translated in a differentbut overlapping frame. No obvious homology was found by usingBLAST query. However, with an LFASTA query on the restricted Retroviridaesubdatabase, ORF1 and ORF2 showed about 35% identity with Rexfrom primate and human T-lymphotropic virus and Tat from simianimmunodeficiency virus, respectively (data not shown). Althoughunusual, the presence of such regulatory proteins in HERVs hasbeen described elsewhere for HERV-K10 (33).

	DISCUSSION

Top Abstract Introduction Materials and methods Results Discussion References

Here we report the molecular characterization of HERV-W, a new multicopy family of HERVs whose expression in healthy tissuesseemed restricted to the placenta. The phylogenetic trees withinthe Pol region showed that the HERV-W family is related to ERV-9and RTVL-H families and thus belongs to the class I endogenousretroviruses (5). Phylogenetic analysis of the env ORF showedthat it was closer to simian type D and avian reticuloendotheliosisretroviruses than to murine type C retroviruses. The homologieswithin the pol and env genes with the murine type C and simiantype D retroviruses, respectively, suggest a chimeric genome structureas described for baboon endogenous virus (22). Based on thesize criteria, such a chimerism seemed to exist within the LTR:the 247-nt U3 and the 79- to 81-nt R elements were comparableto avian or type D retrovirus U3 and mammalian type C R elements,respectively, although the 410- to 455-nt U5 element remainedunclassified as unusually long (57). The bush-like topologythat is observed in the phylogenetic trees for the HERV-W andERV-9 sequences suggests that in both families most elements werefixed in the germ line during a relatively short period of evolutionand probably derive from one or a few active elements. The phylogenetictree, supported by high bootstrap values, shows that ERV-9 andHERV-W families derive from two independent bursts of insertions.Thus, the active element(s) at the origin of the HERV-W familyis distinct from the one(s) from which the ERV-9 family is derived.Moreover, HERV-W PBS is predicted to use tRNA^Trp, whereas ERV-9 probably uses tRNA^Arg. Finally, members of the HERV-W family are expressed in the placenta,whereas we have not detected ERV-9 RNAs in this tissue. However,by RNase protection assay, the detection of protected fragmentssmaller than the expected one suggested that ERV-9-related sequencescould be expressed at a low level in placenta (26).

The persistence of flanking duplicated sequences generated during the integration process suggests either that a selectionprocess persists within the LTR or that the integration occurredrecently. The 5' and 3' LTRs of RG083M05 HERV-W DNA prototypeshowed 4% divergence and 6% gaps. This is comparable to the 0.2to 4.3% divergence described for HERV-K, but smaller than the5 to 12% divergence described for a number of cloned proviruses(5). Given an evolution rate of 3.5 × 10⁹ per site per year (30), the 4% divergence corresponds to arelatively recent integration event 6 million years ago. The HERV-Wdistribution in different primates will be studied to determinethe first introduction into the germline.

Like other HERVs, most (if not all) current members of the HERV-W family are defective for replication, due to mutations thatdisrupt one or more of the gag, pol, and env ORFs (38, 58).The observation of more gag-pro than env sequences in the humangenome may reflect the loss of the env gene. Several genomic clonesseemed to reflect such a loss, which appears to be a common featureamong endogenous elements (5). However, a complete env ORFwas observed on the cl.PH74 placental cDNA clone and the genomicRG083M05 clone which was nevertheless defective for replication.These results are not compatible with the hypothesis that particlesin cell culture supernatants of MS patients (42, 44) or thepresence of specifically packaged mRNA in plasma of MS and RApatients (17, 40) may result from a replication-competentHERV. However, although no replication-competent genome has beenobserved in the databases, it cannot be excluded that a nonidentifiedone exists. Furthermore, no HERV single genetic unit has yet beenshown experimentally to be a source of retroviral particles (58),even in the HERV-K family, which corresponds to the HTDV particles(6, 32). On the other hand, a trans-complementation processbetween distinct but individually defective loci cannot be excluded.Indeed, queries on nucleic acid databases showed that some largeregions were conserved and confirmed a widespread distributionon numerous chromosomes. To address these two hypotheses, a newapproach will be developed to detect potential coding sequences,irrespective of the existence of a putative single genetic element.A procedure based on probe hybridization coupled with in vitrotranscription-translation will be applied to isolated human chromosomesin heterokaryon somatic hybridcells.

Although HERV-W is a quite complex family at the genomic level, a relatively simple pattern of mRNA expression was observedby Northern blot analysis, consisting of three major bands of8, 3.1, and 1.3 kb. This pattern resembles the one of lentivirusesor oncoviruses such as mouse mammary tumor virus and human T-cellleukemia virus (45). It is also similar to the one describedfor ERV-9 in undifferentiated embryonal carcinoma cells (28)and the HTDV/HERV-K family in teratocarcinoma cell lines (32),in which three to four transcripts were derived from a singlelocus by alternative usage of splicing signals. Whether the observedtranscripts resulted from a splicing strategy of one or severalgenetic entities or originated from different defective entitiesremains unresolved. Due to (i) the overall behavior of U5, gag,pro, pol, env, and U3 probes in Northern blot analysis and (ii)the identification of conserved splice sites on the RG083M05 DNAprototype and the cDNA clones, it is probable that the three observedbands represent genomic, subgenomic, and large spliced mRNAs.The situation resulting from the proposed splicing strategy wasquite unusual as the genomic mRNA would result from a splicingevent. Furthermore, no 9.6-kb precursor mRNA was detectable byNorthern blotting, which may reflect a very short half-life ofsuch a transcript. A query of the EST database with the 2-kb insertof the RG083M05 clone showed only smaller internal fragments,suggesting either a complex splicing strategy or the presenceof shorter unidentified genomes. The existence of an alternativesplicing strategy was confirmed by the isolation of clone cl.Pi5T,for which no trivial corresponding transcript was revealed onthe Northern blot; thus, this clone may represent a poorly expressedmRNA. Nevertheless, we cannot exclude that some if not most ofthe placental cDNA clones, although highly homologous, were obtainedfrom different genetic entities. The most divergent clone, Polcl.7A16, may reflect such a situation. The contradiction betweenthe 5' end of the cl.6A2 clone and the positioning of the predictedTATA box may also result from such a context. This clone may bederived from transcription driven by a nonretroviral promoterupstream from a complete or altered LTR and an extension throughthe R polyadenylation site as described for HERV-R (ERV-3) (20).Taken as a whole, this suggests that the complex HERV-W familyobserved at the DNA level could include well-conserved genomicelements (subset) coexpressed in theplacenta.

According to the results of the Northern blot and the RNA dot blot analyses, a significant LTR functionality among healthytissues seemed restricted to the placenta. Thus, the expressionof HERV-W could be regulated in a hormone-dependent manner assuggested for ERV-9 with the ZNF80 zinc finger gene (15) orfor HERV-R with the H-plk gene (21). However, by more sensitivetechniques, it may be possible to find much lower expression ofHERV-W in nonplacental tissue. Such related mRNA sequences werefound in brains of healthy and MS individuals (8, 29), byan RT-PCR-based method, and a complex mRNA expression was observedin various tissues by Northern blotting with the amplified productas a probe (29). This discrepancy with our experimental data,obtained with six probes spanning all the regions of a retroviralgenome, may result from different experimental conditions, includingthe length of the probe and the hybridization stringency. Furthermore,the EST query showed a significant concentration of HERV-W expressionin fetal liver-spleen, in addition to placenta. As the RNA dotblots were negative for both fetal liver and fetal spleen, onemay suspect the influence of the differentiation stage or a lowlevel of expression. Partial LTR tags were found in other fetal,adult, and tumoral tissues, most in the opposite direction. Thismay reflect expression driven by solitary LTRs or nonretroviralpromoters. Interestingly, the 85 to 94% similarities observedbetween the placental cDNA clones and the probes derived fromextracellular RNA isolated in a pathological context comparedwith the 90 to 100% similarities obtained between overlappingplacental cDNAs indicate that at least some of the probes werederived from transcriptional units distinct from those expressedin the placenta. This interpretation was supported by the reproducibleisolation of env interrupted ORFs from extracellular mRNA in MSand RA patients (22b) versus an env-containing ORF from the placentalcDNA library screening. This suggests a placenta-restricted expressionof an HERV-W subset versus a different or probably broader HERV-Wexpression in a pathological context (or in other tissues). Inagreement with this, the expression in different tissues at differenttimes of different subsets of one given family of elements wasdescribed, e.g., the expression of HTDV/HERV-K (27), ERV-9 (31),and HERV-R (13, 19) mRNAs differs quantitatively and qualitativelywith respect to the tissue considered. In pathological situations,silent LTRs could be reactivated by several factors such as virus,e.g., members of the herpesvirus family (3, 9, 18), orby local immuneactivation.

The finding in placental cDNA clones of a large ORF coding for a putatively functional envelope protein suggests some physiologicalfunctions related to pregnancy, such as a role in the creationof the syncytiotrophoblast layer of the placenta (7, 55)and a role in suppressing the maternal immune response againstthe fetal allograft (7, 55, 56) as suggested for the envelopeprotein of HERV-R. In pathological situations, an HERV Env mightprotect against exogenous retroviral infections by a receptorinterference mechanism (4) or alter the local cellular immunityvia, for example, a superantigen-encoded region, as was recentlyproposed for type I diabetes (insulin-dependent diabetes mellitus)(14). Conversely, HERV-W expression may represent only a consequenceof physiological or pathological events. Whatever the situationis, the finding of HERV-W sequences both in a physiological tolerogenicimmune context such as pregnancy and in autoimmune diseases suchas MS and RA deserves furtherinvestigations.

	ACKNOWLEDGMENTS

We thank F. L. Cosset (UCB-Lyon I, Lyon, France), C. Guillon (Erasmus University, Rotterdam, The Netherlands), and Doran Spencerfor critical reading of the manuscript. We also thank C. Gautierand all the staff of the Biometry Laboratory (UCB-Lyon I, Lyon,France) for helpful discussions and assistance with nucleic acidanalysis and F. Penin and C. Gourgeon (IBCP, Lyon, France) andF. Horn (EMBL, Heidelberg, Germany) for helpful assistance inprotein analysis. Most of the sequence analyses were performedin the PBIL (Pôle Bio-Informatique Lyonnais) facilities (http://pbil.univ-lyon1.fr).We are grateful to Florence Komurian-Pradel and Glaucia Parhanos-Baccalafor providing C15 and LB19 and E clones,respectively.

J.-L.B. was supported by a doctoral fellowship from the Ministère de l'Enseignement Supérieur et de la Recherche and bioMérieux.

	FOOTNOTES

^* Corresponding author. Mailing address: Unité Mixte 103 CNRS-bioMérieux, Ecole Normale Supérieure de Lyon, 46 allée d'Italie,69364 Lyon, Cédex 07, France. Phone: 33 472 728 358. Fax: 33472 728 533. E-mail: fmallet{at}ens-bma.cnrs.fr.

REFERENCES

Top
Abstract
Introduction
Materials and methods
Results
Discussion
References

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