Identification of Novel Porcine Endogenous Betaretrovirus Sequences in Miniature Swine

doi:10.1128/JVI.75.6.2765-2770.2001

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Journal of Virology, March 2001, p. 2765-2770, Vol. 75, No. 6
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.6.2765-2770.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Identification of Novel Porcine Endogenous Betaretrovirus Sequences in Miniature Swine

Thomas Ericsson,¹ Beth Oldmixon,¹ Jonas Blomberg,² Margaret Rosa,¹ Clive Patience,¹^,^* and Göran Andersson¹^,

BioTransplant, Inc., Charlestown, Massachusetts 02129,¹ and Department of Medical Sciences, Clinical Virology, Uppsala University, Uppsala, Sweden²

Received 28 August 2000/Accepted 6 December 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

PCR amplification of genomic DNA from miniature swine peripheral blood lymphocytes, using primers corresponding to highlyconserved regions of the polymerase (pol) gene, allowed the identificationof two novel porcine endogenous retrovirus (PERV) sequences, PMSN-1and PMSN-4. Phylogenetic analyses of the nucleotide sequencesof PMSN-1 and PMSN-4 revealed them to be most closely relatedto betaretroviruses. The identification of PERVs belonging tothe Betaretrovirus genus shows that endogenous retroviruses ofthis family are more broadly represented in mammalian speciesthan previously appreciated. Both sequences contained inactivatingmutations, implying that these particular loci are defective.However, Southern blot analysis showed additional copies of closelyrelated proviruses in the miniature swine genome. Analyses offetal and adult miniature swine tissues revealed a broad mRNAexpression pattern of both PMSN-1 and PMSN-4. The most abundantexpression was detected in whole bone marrow c-kit⁺ (CD117⁺) progenitor bone marrow cells, fetal liver, salivary gland, andthymus. It appears unlikely that functional loci encoding thesenovel PERV sequences exist, but this remains to be established.The betaretrovirus sequences described in this report will allowsuch investigations to be activelypursued.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The pig (Sus scrofa), in particular, the miniature swine, is considered to be the primary source of xenograft organs to beused in xenotransplantation (29). Because of the potential riskof zoonotic transmission of porcine endogenous retroviruses (PERVs)from pig to human recipients of xenotransplants, a major effortto characterize the potential transmission of PERV is warranted.ERVs are present in the genomes of all cells of an organism andare transmitted from parent to offspring as a provirus in thegerm line DNA (6, 15, 18, 24, 33, 38). In mammals,two main types of ERVs, designated beta- and gammaretroviruses,have been identified (37). Retroviruses have acquired efficientmechanisms for survival and persistence in a wide range of hostspecies. Some strains of retroviruses are endogenous in one speciesand exogenous in other species (38). Of particular importancefor the potential risks associated with retroviruses and xenotransplantationis the capacity of retroviruses to change their pathogenicityfollowing interspecies transmission, possibly resulting in emerginginfections. Thus, it is possible for ERVs that are symbiotic inone host to be parasitic inanother.

At least three distinct PERV gammaretrovirus sequences (PERV-A, -B, and -C) have been identified (1, 16). PERV-A and-B produced from PK-15 (porcine kidney-derived) cells (25),activated peripheral blood mononuclear cells (PBMCs) (39), orporcine aortic endothelial cells (19) are able to infect humanand porcine cell lines. PERV-C has only been shown to infect porcinecell lines (35). There has been no evidence of PERV infectionin clinical samples taken from patients exposed to pig tissuesor cells (12, 23, 26).

To determine whether the porcine genome harbors additional PERV loci, a PCR-based approach that utilizes the high conservationof the pol gene was employed (17). This approach resulted inthe identification of novel betaretrovirus pol sequences. Genomiccopy number and phylogenetic and RNA expression analyses of thesenovel PERV sequences arepresented.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Genomic DNA preparation. PBMCs were isolated from miniature swine (obtained from the Transplantation Biology Research Center, Massachusetts GeneralHospital, Charlestown) inbred for the major histocompatibilitycomplex swine leukocyte antigen (MHC/SLA) (27-29). Three linesof inbred animals, haplotypes SLA^a/a, SLA^c/c, and SLA^d/d, were analyzed. Genomic DNA was extracted with the Genomic-tip500/G (Qiagen, Inc.) or the PureGene DNA isolation kit (GentraSystems, Inc.) according to the manufacturer'sinstructions.

PCR. PCR was performed with 500 ng of genomic DNA with standard reagents and 2.5 U of Amplitaq Gold (Perkin-Elmer Co.) for 40 cycles(94°C for 30 s, 45°C for 30 s, and 72°C for 30 s). The oligonucleotidesused were 5'-MOP-2 (5'-CCWTGGAATACTCCYRTWTT-3') and 3'-MOP-2 (5'-GTCKGAACCAATTWATATYYCC-3')(17), where R stands for A or G, Y stands for C or T, K standsfor G or T, and W stands for A orT.

Cloning and sorting of PCR products. The approximately 640-bp PCR products were purified and cloned into the pCR2.1-TOPO vector (Invitrogen). Bacterial colonyPCRs with 5'-MOP-2 and 3'-MOP-2 followed by restriction enzymedigestion were used to screen a total of 84 colonies. From therestriction enzyme digestion profile, colonies were assigned toone of seven differentgroups.

Nucleotide sequence and phylogenetic analyses. Representative clones were sequenced by Lark Technologies, Inc., with a model 373 automated sequencer (Applied Biosystems-Perkin-Elmer).A neighbor-joining phylogenetic tree (30) was constructed fromtranslated N-terminal sequences. The sequences used and theirGenBank accession numbers are listed in Table 1. Distances werecalculated by using a PAM250 similarity matrix. The programs PROTDISTand NEIGHBOR were used to deduce a tree that was then drawn byDRAWTREE. The last three programs are part of the PHYLIP package(37). Numbers denote the percentage of 600 bootstraps at whicha certain branch occurred. Values above 60% are not shown. A fewbranches in the HML cluster had values as low as 22% but are notshown because of space limitations.

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TABLE 1. ERV pol sequences used for phylogenetic tree construction

Southern blot analysis of porcine genomic DNA for PERV-MSN1 and PERV-MSN4 sequences. Genomic DNA (5 µg) from miniature swine and domestic pigs (Clontech) was digested with EcoRI (New England Biolabs), fractionatedon a 0.8% agarose gel, and transferred to nylon membranes (Schleicherand Schuell). A PCR product from a PMSN-1 or PMSN-4 clone with5'-MOP-2 and 3'-MOP-2 primers was used as a template for [ $alpha$ -³²P]dCTP random-primed probes (Amersham Pharmacia Biotech). Thehybridizations were performed at 60°C for PMSN-1 and at 57°C forPMSN-4 for 1.5 h with ExpressHyb solution (Clontech) and thenwashed under high-stringency conditions (0.03 M NaCl, 0.03 M sodiumcitrate, and 0.1% sodium dodecyl sulfate [SDS] at 60°C for PMSN-1and at 57°C for PMSN-4). The membranes were exposed for autoradiographyat $-$ 70°C for 10 days before development. A single membrane wasused and initially hybridized with the PMSN-1 probe as describedpreviously. After development, the PMSN-1 probe was removed byboiling for 15 min in a mixture of 15 mM NaCl, 15 mM sodium citrate,and 0.5% SDS. The membrane was then probed for PMSN-4sequences.

RNA preparation and cDNA synthesis. Total RNA was extracted from tissues or cells by using TRIzol reagent (Gibco Life Technologies) followed by cDNA synthesiswith random hexamers and 0.5 to 1 µg of RNA with the Superscriptpreamplification system (Gibco Life Technologies) according tothe manufacturer's instructions. The quality of the cDNA was testedby 18S rRNA PCR (data notshown).

PMSN-1- and PMSN-4-specific RT-PCR. One-tenth of the total cDNA reaction mixture was amplified with standard reagents and 2.5 U of Amplitaq Gold (Perkin-Elmer)for 35 cycles (96°C for 10 s, 59°C for 30 s, and 72°C for 30 s).PMSN-1 reverse transcriptase (RT)-PCR was performed with the forwardoligonucleotide PMSN1F (5'-GCATGGAACCTACGGGG-3') and reverse oligonucleotidePMSN1R (5'-GAAAGGCTCAGCATCTTGTG-3'). PMSN-4 RT-PCR was performedwith the forward oligonucleotide PMSN4F (5'-TGCAATTCCCTTAGACTGGG-3')and reverse oligonucleotide PMSN4R (5'-CGGCAACACTTTCCACTGA-3').PCRs were electrophoresed on 2% agarose gels stained with ethidiumbromide and analyzed for the presence of the expectedproducts.

Nucleotide sequence accession number. The nucleotide sequences of PMSN-1.1 and -1.2 have been submitted to GenBank under accession no. AF277320 and AF277321,respectively. The nucleotide sequence of PMSN-4 has been submittedto GenBank under accession no. AF277322.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Identification of PERV pol genes. Pan-pol PCR with degenerate primers corresponding to conserved regions of known retrovirus pol genes was performed and yieldedproducts of the expected size of approximately 640 bp. The PCRproducts were grouped by restriction enzyme digestion, which identifiedseven different groups of amplicons (Materials and Methods). Themajority of the clones fell into two groups of 61 and 14 clonesout of a total of 84. The first group was designated PERV miniatureswine new-1 (PMSN-1), and the second group was designated PMSN-4.Partial nucleotide sequence analysis established that these twomain groups contained sequences that were of retroviral origin.The remaining five groups contained sequences corresponding tononinfectious, nonretroviral porcine retroelements (e.g., porcineLINEs) and will not be discussed further. Representative clonesfrom each main group were subjected to complete nucleotide sequenceanalyses (describedbelow).

The nucleotide sequences of a total of three PMSN-1 clones obtained from different miniature swine were determined. Alignmentof nucleotide sequences derived from these PMSN-1 clones showedthat two were identical (PMSN-1.1) and that the third clone (PMSN-1.2)displayed differences at 11 positions (seven nucleotide substitutionsand two 2-bp insertions). Restriction analysis of a small numberof PMSN-1 clones showed approximately equal numbers of PMSN-1.1and PMSN-1.2 varieties (data not shown). The nucleotide sequencesof PMSN-1.1 clones were used for phylogenetic analysis. Both varietiesof PMSN-1 have single frameshift mutations and four prematurestop codons. The nucleotide sequences of three PMSN-4 clones obtainedfrom different miniature swine were determined. The clones werederived from three different miniature swine. The nucleotide sequencesof all three clones were identical and possessed three frameshiftmutations and four premature stopcodons.

The pol genes of PMSN-1 and PMSN-4 are related to betaretroviruses. Phylogenetic alignments were performed based on translated sequences from the amino terminus of available pol sequences inthe databases, as well as a recently identified pig betaretrovirussequence denoted PERV-B3 (26a), by using a stretch from the motifAINA and its analogs to two amino acids before the superconservedmotif YVDD. The alignment had 129 columns. The complete alignmentsare available at http://www.kvir.uu.se at the Uppsala Universitysubdirectory. The phylogenetic tree obtained is presented in Fig.1. The abbreviations and identities of all viruses included inthe tree are listed in Table 1. In this analysis, PMSN-1 clusteredbetween PMSN-4 and HML-6, while PMSN-4 was between JSRV and PMSN-1,and PERV-B3 was most similar to HML-1 (Fig. 1). These three novelPERV sequences branched together with the HML sequences, withonly HRV-5 and the intracisternal A particles (IAPs) being clearlymore ancestral relative to the rest of the family Retroviridae(Fig. 1). We conclude that the three novel PERV sequences belongto genus Betaretrovirus, and although they are unique, they arerelated to several human MMTV-like (HML) sequences.

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FIG. 1. Phylogenetic tree analysis. The tree is based on an alignment and calculations of N-terminal protein sequences from ERV pol sequences listed in Table 1. Numbers denote the percentage of 600 bootstraps in which a certain branch occurred. Values above 60% are not shown. A few branches in the HML cluster had values as low as 22% but are not shown because of limited space. Four sequences in the betaretrovirus cluster are indicated to the right of the tree due to space limitation. Exogenous retroviruses, some of which are also known to be endogenous, are shown in italics.

Southern blot analysis of PMSN-1 and PMSN-4 in the miniature swine genome. To estimate the number of PMSN-1 and PMSN-4 loci in the miniature swine genome, Southern blot analysis of EcoRI-digested genomicDNA prepared from 11 different miniature swine and from a singledomestic pig was performed (Fig. 2). Initially the filter washybridized with a PMSN-1 probe. In one animal, the apparent lackof hybridizing bands was due to the small amount of DNA loadedin each lane, because weak signals were evident upon prolongedexposure (not shown). This blot indicates that at least two copiesof PMSN-1 are present within the miniature swine as well as domesticswine genomes. Some variation was evident, with some animals havingsingly or doubly hybridizing bands of 4, 6, and/or 7 kb.

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FIG. 2. Genomic DNA prepared from miniature swine was analyzed by Southern blotting of PMSN-1 (A) and PMSN-4 (B). Lane 1 contains partially EcoRI-digested SLA^d/d miniature swine genomic DNA, followed by nine distinct SLA^d/d miniature swine genomic DNA samples (lanes 2 and 3 and 5 to 11; lane 10 is extremely faint). In lane 4, genomic DNA from an SLA^c/c haplotype miniature swine was analyzed. Lane 12 contains domestic pig genomic DNA. All samples were digested with EcoRI. Sizes in kilobase pairs of the hybridizing bands are indicated to the right. The filter was exposed for 10 days in both cases.

The same filter was used for hybridization with the PMSN-4 probe after the PMSN-1 probe was removed (Materials and Methods).One major hybridizing band of 11 kb was found in all swine (Fig.2B, lanes 2 to 9, 11, and 12) along with additional weak bands,indicating at least a single copy of PMSN-4. The fainter bandsmay represent divergent copies of PMSN-4 loci or cross-hybridizationto related PERVsequences.

Expression of PMSN-1 and PMSN-4 mRNA. The mRNA expression of PMSN-1 and PMSN-4 pol was analyzed by RT-PCR with RNA prepared from several porcine tissues. The 13different cell types and tissues that were used for RNA preparationand the MHC haplotype and animal designations are listed togetherwith the results obtained (Table 2). Two MHC homozygous animals(SLA^a/a), one MHC heterozygous animal (SLA^a/d), one SLA^g/g homozygous animal, and fetal tissues from one SLA^d/d homozygous animal were analyzed.

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TABLE 2. Expression of PMSN-1 and PMSN-4 mRNA in miniature swine tissues

Representative results are shown in Fig. 3. The PMSN-1 PCR produces a 422-bp product for PMSN-1.1 and a 426-bp product forPMSN-1.2 that could not be separated by the agarose gel electrophoresisemployed (Fig. 3A). The PMSN-4 PCR produced a 155-bp product (Fig.3B). The mRNA expression of both PMSN-1 and PMSN-4 showed individualvariation between different miniature swine, with PMSN-1 showinga broader range of tissues and cell types. The highest mRNA expressionof PMSN-1 was detected in salivary glands, in one fetal liversample, and in c-kit⁺ (CD117⁺) hematopoietic progenitor cells (Table 2 and Fig. 3). All sevenfetal tissues were found to be positive for expression. PMSN-4expression appeared to be greatest in c-kit⁺ enriched bone marrow cells.

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FIG. 3. RT-PCR analysis of PMSN-1 and PMSN-4. Agarose gel electrophoresis was performed with PMSN-1 (A) and PMSN-4 (B) RT-PCR products obtained from RNA prepared from the following cell and tissue types: lanes 1 and 8, c-kit⁺ cells; lanes 2 and 9, whole bone marrow (RNAs were prepared from an SLA^a/d heterozygous miniature swine). The remaining samples (lanes 3 to 7 and 10 to 14) were prepared from cells obtained from an SLA^a/a homozygous miniature swine. Lanes 3 and 10, spleen; lanes 4 and 11, liver; lanes 5 and 12, thymus; lanes 6 and 13, peripheral blood lymphocytes; lanes 7 and 14, lung. Lanes 8 to 14 represent negative controls without the presence of RT. In panel A, control amplifications with a PMSN-1 PCR product (lane 15), a negative control (lane 16), and miniature swine genomic DNA (lane 17) are shown. In panel B, heart +/ $-$ RT (lanes 15 and 16), control amplifications with a PMSN-4 PCR product (lane 17), miniature swine genomic DNA (lane 18), and a negative control (lane 19) are shown. The sizes of the products obtained are indicated to the left.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Transmission of human-tropic gammaretrovirus PERVs constitutes a potential risk in pig-to-human xenotransplantation (9,34). To better understand such risks, further molecular andfunctional characterization of PERVs is warranted. Therefore,we employed a pan-pol PCR approach using degenerate retroviralpol primers to identify PERVs that belong to other retroviralgenera. In this study, two novel PERV pol elements denoted PMSN-1and PMSN-4 wereidentified.

Phylogenetic analyses revealed that both PMSN-1 and PMSN-4 cluster with betaretroviruses. Together with PERV-B3 (26a), thesesequences represent the first described PERVs belonging to thisgenus. Furthermore, these sequences diverged close to the Betaretrovirusroot, suggesting a relatively distant relationship to previouslyknown mammalian betaretroviruses. This is also reflected by theoverall low nucleotide sequence similarities of approximately60% between PMSN-1 and other betaretrovirus sequences (not shown).PMSN-1 was found to be most similar to HML-6 (21). A descriptionof the HML groups was recently published (3). PMSN-4 appearedmore distantly related to betaretrovirus sequences, branched offcloser to the root, and was closely related to Jaagsiekte sheepretrovirus (JSRV), MMTV, and Mason-Pfizer monkey virus (MPMV).PERV-B3 was more similar to PMSN-1 than to PMSN-4 and clusteredwith HML-5. As seen in Fig. 1, PERVs span a sequence spectrumsimilar to that of human ERVs (HERVs). This may indicate a poolof common ERVs in vertebrates created by interspecies transfersduring vertebrate evolution. An alternative explanation is thatthe pol sequences originated from a common ancestor of modernhostspecies.

Endogenous betaretroviruses may be biologically active, and some HERV-K loci show conservation of complete and intact retroviralgenes with open reading frames (ORFs) encoding Gag, Pol, and Envproteins (4, 20, 22). Enzymatic activities for the HERV-KdUTPase, protease, and endonuclease have been reported (10,14, 31). Recently, it was shown that several HERV-K membersalso encode functional RT polymerase and an RNase H domain (4).

As discussed above, while the pol genes of betaretroviruses are highly similar (22, 42), the viruses diverge into twocategories, with env genes resembling either betaretrovirusesor the murine leukemia virus (MLV)-like group of gammaretroviruses.This feature implies that a recombination event involving theenv gene from an MLV-like virus into one resembling MMTV at somepoint occurred during evolution (7). MMTVs exist in both endogenousand infectious exogenous forms. Moreover, the role of MMTV integrationand the development of mammary carcinoma are well-establishedfeatures (36). Betaretrovirus particles have been identifiedfrom several mammalian species (11, 13, 32). Their establishedrole in pathogenesis in other species is an additional cause ofconcern for pig-to-human xenotransplantation. However, based onour results, a role for pig betaretroviruses in transmitted diseaseappears unlikely. Southern blot analysis showed that only a relativelyfew copies of these PERVs are present in the porcine genome. Inboth the PMSN-1 and -4 pol sequences described here, as well asin the PERV-B3 pol sequence, mutations disrupting the ORFs werepresent, which suggests that the few copies present are most likelydefective.

Transcription of these novel pol sequences was shown in several different cell types by RT-PCR. Individual variation of PMSN-1expression between different animals was evident. Differencesin expression of human betaretrovirus sequences between individualsand between different tissues were reported earlier (2, 41).The expression of PMSN-1 mimics the expression pattern of HERV-K(HML-2), to which PMSN-1 is relatively closely related (Fig. 1)(4). In contrast, PMSN-4 mRNA expression had a more limitedtissue distribution. Among the different cell types analyzed,the highest PMSN-4 mRNA expression was detected in hematopoieticallyderived cells, like bone marrow cells enriched for the expressionof c-kit⁺ (CD117⁺), and in fetal liver. However, due to the highly mutated anddefective nature of the clones sequenced, it appears unlikelythat these PERVs will pose risks inxenotransplantation.

In vitro studies have shown transmission of gammaretrovirus PERVs to human cells (25, 39, 40). However, no evidenceof PERV transmission to human recipients of xenografted cellshas been documented, and productive in vivo PERV transmissionto human recipients of pig cells appears to be unlikely (5,12, 23, 26). Recombination between defective porcine andhuman retroviral sequences that would generate a pathogenic retrovirusseems only a remote possibility. The identification of the betaretrovirusPERV sequences described here will allow further assessment ofthe potential risks associated with PERV transmission followingxenotransplantation of miniature swineorgans.

	FOOTNOTES

^* Corresponding author. Mailing address: Immerge BioTherapeutics, Building 75, 3rd Ave., Charlestown Navy Yard, Charlestown,MA 02129. Phone: (617) 241-5200. Fax: (617) 241-8780. E-mail:clive.patience{at}immergebt.com.

Present address: Department of Animal Breeding and Genetics, Swedish University of Agricultural Sciences, Uppsala BioMedicalCenter, Uppsala,Sweden.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
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34. Stoye, J. P., P. Le Tissier, Y. Takeuchi, C. Patience, and R. A. Weiss. 1998. Endogenous retroviruses: a potential problem for xenotransplantation. Ann. N. Y. Acad. Sci. 862:67-74[CrossRef][Medline].

35. Takeuchi, Y., C. Patience, S. Magre, R. A. Weiss, P. T. Banerjee, P. Le Tissier, and J. P. Stoye. 1998. Host range and interference studies of three classes of pig endogenous retrovirus. J. Virol. 72:9986-9991[Abstract/Free Full Text].

36. Tekmal, R. R., and N. Keshava. 1997. Role of MMTV integration locus cellular genes in breast cancer. Front. Biosci. 2:519-526.

37. van Regenmortel, M. H. V., C. M. Fauquet, D. H. L. Bishop, E. B. Carsten, M. K. Estes, S. M. Lemon, J. Maniloff, M. A. Mayo, D. J. McGeoch, C. R. Pringle, and R. B. Wickner. 2000. Virus taxonomy: seventh report of the International Committee on Taxonomy of Viruses, p. 1104. Academic Press, San Diego, Calif.

38. Wilkinson, D. A., D. L. Mager, and J. A. Leong. 1994. Endogenous human retroviruses, p. 465-535. In J. Levy (ed.), The Retroviridae. Plenum Press, New York, N.Y.

39. Wilson, C. A., S. Wong, J. Muller, C. E. Davidson, T. M. Rose, and P. Burd. 1998. Type C retrovirus released from porcine primary peripheral blood mononuclear cells infects human cells. J. Virol. 72:3082-3087[Abstract/Free Full Text].

40. Wilson, C. A., S. Wong, M. VanBrocklin, and M. J. Federspiel. 2000. Extended analysis of the in vitro tropism of porcine endogenous retrovirus. J. Virol. 74:49-56[Abstract/Free Full Text].

41. Yin, H., P. Medstrand, M. L. Andersson, A. Borg, H. Olsson, and J. Blomberg. 1997. Transcription of human endogenous retroviral sequences related to mouse mammary tumor virus in human breast and placenta: similar pattern in most malignant and nonmalignant breast tissues. AIDS Res. Hum. Retrovir. 13:507-516[Medline].

42. Zsiros, J., M. F. Jebbink, V. V. Lukashov, P. A. Voute, and B. Berkhout. 1998. Evolutionary relationships within a subgroup of HERV-K-related human endogenous retroviruses. J. Gen. Virol. 79:61-70[Abstract].

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39.	Wilson, C. A., S. Wong, J. Muller, C. E. Davidson, T. M. Rose, and P. Burd. 1998. Type C retrovirus released from porcine primary peripheral blood mononuclear cells infects human cells. J. Virol. 72:3082-3087[Abstract/Free Full Text].
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41.	Yin, H., P. Medstrand, M. L. Andersson, A. Borg, H. Olsson, and J. Blomberg. 1997. Transcription of human endogenous retroviral sequences related to mouse mammary tumor virus in human breast and placenta: similar pattern in most malignant and nonmalignant breast tissues. AIDS Res. Hum. Retrovir. 13:507-516[Medline].
42.	Zsiros, J., M. F. Jebbink, V. V. Lukashov, P. A. Voute, and B. Berkhout. 1998. Evolutionary relationships within a subgroup of HERV-K-related human endogenous retroviruses. J. Gen. Virol. 79:61-70[Abstract].