Human endogenous retrovirus HC2 is a new member of the S71 retroviral subgroup with a full-length pol gene

We have isolated and characterized a new human endogenous provirus, which is closely related to the human retrovirus S71, but unlike S71 has a full-length pol gene. Two degenerate oligonucleotide primers based on highly conserved motifs within the active sites of two retroviral proteins (the protease and reverse transcriptase) were designed and used for PCR. An amplified product of 847 bp in length, which showed significant homology to protease and reverse transcriptase of several retroviruses, was used for high stringency hybridization with a human genomic library. The MuLV-related endogenous retrovirus sequence, designated HC2, was isolated and completely sequenced. HC2 is a provirus with complete gag and pol genes and a 3' LTR; the 5' LTR and env gene are missing. The gag and pol genes appear complete, since they contain sequences homologous to the matrix protein, capsid protein, and nucleocapsid protein of gag and to the protease, reverse transcriptase, tether, RNase H, and integrase of pol. Phylogenetic analysis suggests that although HC2 and S71 are MuLV-related retroviruses, their characters are quite distinct, being placed outside of a clade containing most of the previously characterized MuLV-related retroviruses such as GaLV, FeLV, BaEV, and SSV/SSAV.

Baboon endogenous virus evolution and ecology

Cross-species transmission of retroviruses among primates has recently been recognized as the source of the current epidemics of HIV-1, HIV-2 and human T cell leukemia virus type 1 (HTLV-1). The distribution of baboon endogenous virus among non-human primates resembles that of exogenous viruses and appears to be a consequence of different primate species sharing the same habitat.

Endogenous retroviral long terminal repeats of the HLA-DQ region are associated with susceptibility to insulin-dependent diabetes mellitus

HLA-DQ genes are the main inherited factors predisposing to IDDM. This gene region harbors long terminal repeat (DQ LTR) elements of the human endogenous retrovirus HER V-K, which we analyzed for a possible association with disease. We first investigated whether LTR segregate with DQ alleles in families. Members (n = 110) of 29 families with at least one diabetic child, unrelated patients with IDDM (n = 159), and healthy controls (n = 173) were analyzed. Genomic DNA was amplified for DQ LTR3 by a nested primer approach as well as for DQA1 and DQB1 second exons, to assign DQA1 and DQB1 alleles. DQ LTR segregated in 24 families along with DQ alleles. Of the 29 families, 20 index patients were positive for DQ LTR. The DQ LTR was in all patients on the haplotype carrying the DQA1 *0301 and DQB1 *0302 alleles. A majority of patients had DQ LTR (62%) compared with controls (38%) (p < 1.3 x 10(-5)), even after matching for the high-risk alleles DQA1 *0501, DQB1 *0201-DQA1 *0301, and DQB1 *0302 (79% of patients and 48% of controls; p < 0.02). Subtyping for DRB1 *04 alleles in all DQB1 *0302+ individuals showed 56% DRB1 *0401, DQB1 *0302 [LTR' patients vs. 29% controls with the same haplotype (p < 0.002)]. In conclusion, these data demonstrate the segregation of DQ LTR with DQA1, DQB1 alleles on HLA haplotypes. Furthermore their presence on DRB1 *0401-, DQA1 *0301-, and DQB1 *0302-positive haplotypes suggest that they contribute to DQ-related susceptibility for IDDM.

A reevaluation of the higher taxonomy of viruses based on RNA polymerases

In order to assess the validity of classifications of RNA viruses, published alignments and phylogenies of RNA-dependent RNA and DNA polymerase sequences were reevaluated by a Monte Carlo randomization procedure, bootstrap resampling, and phylogenetic signal analysis. Although clear relationships between some viral taxa were identified, overall the sequence similarities and phylogenetic signals were insufficient to support many of the proposed evolutionary groupings of RNA viruses. Likewise, no support for the common ancestry of RNA-dependent RNA polymerases and reverse transcriptases was found.

The structure and phylogeny of a new family of human endogenous retroviruses

A novel endogenous retrovirus (ERV) designated XA34 was isolated from a human glioma cDNA library using low stringency hybridization with an ERV-9 env probe. Southern blot hybridizations with human genomic DNA revealed the presence of approximately 16 genomic copies closely related to XA34. Sequencing of a 2303 bp cDNA clone of XA34 showed that it belongs to a new ERV family. The XA34 ERV has recombined with an ERV-9-like retrovirus resulting in a truncated ERV-9-like env region that ends with an Alul-like 3' LTR. By using PCR, we isolated approximately 940 bp pol fragments from three additional members of this family, XA35, XA36 and XA37. A fifth member, XA38, was isolated and sequenced as a 4729 bp genomic clone. The genomic XA38 clone spans from pol towards the 3' flanking region. The XA38 virus contains a more cryptic env region. The XA38 env is truncated in the transmembrane region and the virus then ends with three Alu repeats. Southern blot studies with human, chimpanzee, orangutan and squirrel monkey DNA show the presence of the XA34 family in all these species. That both the New and Old World monkeys have this ERV family means that the integration and/or amplification in the primate germ-line of XA34 probably took place about 40-45 million years ago. The phylogeny and the closet relatives to ERV XA34 are discussed.

Differential expression of human endogenous retroviral sequences similar to mouse mammary tumor virus in normal peripheral blood mononuclear cells

Mouse mammary tumor virus (MMTV) is a retrovirus that causes breast cancer in certain strains of mice. In a previous study we identified, by sequencing clones from human lymphocytes, six groups with similarities to MMTV. Using a primer pair derived from pol sequences conserved within types A, B, and D retroviruses and probes from the six human MMTV-like (HML-1 to HML-6) groups in an internally controlled hybridization assay we investigated the normal variation of expression in PBMCs. Variations occurred within all groups but was most significant within group HML-1, where hybridization signals differed by more than 500-fold between individuals. Groups HML-2 and HML-3 showed consistently stronger hybridization signals than groups HML-1 and HML-5, while group HML-6 resulted in weak signals for all individuals. Stringent hybridization of the amplified cDNA to 20 individual HML clones also demonstrated a marked heterogeneity of expression. Hybridization signals from some groups and sequences were found to be correlated, either in a positive or negative fashion. RNA isolated from PBMCs collected from two donors at four different time points (in the morning and in the afternoon on the same day, repeated 1 week later) was also analyzed using the six hml probes. A small variation in hybridization signals was seen in samples collected on the same day, but a larger difference was observed in samples taken 1 week later. The correlations and the differences in the expression of HMLs between individuals implicate a complex transcriptional regulation system of these sequences.

Complete nucleotide sequence and transcriptional analysis of snakehead fish retrovirus

The complete genome of the snakehead fish retrovirus has been cloned and sequenced, and its transcriptional profile in cell culture has been determined. The 11.2-kb provirus displays a complex expression pattern capable of encoding accessory proteins and is unique in the predicted location of the env initiation codon and signal peptide upstream of gag and the common splice donor site. The virus is distinguishable from all known retrovirus groups by the presence of an arginine tRNA primer binding site. The coding regions are highly divergent and show a number of unusual characteristics, including a large Gag coiled-coil region, a Pol domain of unknown function, and a long, lentiviral-like, Env cytoplasmic domain. Phylogenetic analysis of the Pol sequence emphasizes the divergent nature of the virus from the avian and mammalian retroviruses. The snakehead virus is also distinct from a previously characterized complex fish retrovirus, suggesting that discrete groups of these viruses have yet to be identified in the lower vertebrates.

Unique long terminal repeat U3 sequences distinguish exogenous jaagsiekte sheep retroviruses associated with ovine pulmonary carcinoma from endogenous loci in the sheep genome

Ovine pulmonary carcinoma (OPC) is a contagious lung cancer of sheep that is presumed to be caused by an exogenous retrovirus of sheep, jaagsiekte sheep retrovirus (JSRV). The sheep genome carries 15 to 20 copies of endogenous sheep retrovirus (ESRV) loci that hybridize to JSRV DNA probes. In order to clarity the etiologic roles of ESRV and an exogenous JSRV-like retrovirus (exJSRV) in OPC, we assessed sequence differences between ESRV and JSRV. Molecular characterization of six ESRV loci revealed restriction sites specific for JSRV. Nucleotide sequences of ESRVs from sheep of different breeds were similar to those of JSRV in structural genes but divergent in U3. Therefore, primers specific for the U3 sequences of exJSRV were designed for use in the PCR. Of 13 tumor DNAs tested by PCR with these exogenous-virus U3 primers, 8 produced DNA fragments that hybridized with the JSRV gag probe, but neither lung DNAs from healthy sheep nor DNAs from nontumor tissues of diseased sheep produced similar DNA fragments. exJSRV PCR products from tumor DNAs of sheep with OPC from three continents had restriction profiles similar to each other but different from those of ESRVs upon digestion with EcoRI, HindIII, NdeI, KpnI, and ScaI. These exjSRVs could be classified into two genotypes according to U3 sequences and restriction profiles. U3 sequences of exJSRV proviruses in tumors strongly resembled those of JSRV but differed from those of ESRVs, suggesting that exJSRVs, rather than ESRVs, are primarily associated with oncogenesis in OPC.

Retrovirus classification and cell interactions

Retroviruses cause a variety of diseases such as cancer, AIDS, autoimmunity and diseases of central nervous system, bone and joints. Some retroviruses are apparently harmless and some retroviral genomes are even inherited as host mendelian traits. Whereas oncoviruses generally have a low virus load, so that antiviral therapy would not greatly affect disease progression, lentiviruses like HIV have high load and turnover. The cell interactions of retroviruses largely determine their pathogenesis. Finally, retroviruses are being exploited therapeutically as vectors for gene therapy.

Retroviral vectors. From laboratory tools to molecular medicine

The majority of clinical trials for gene therapy currently employ retroviral-mediated gene delivery. This is because the life cycle of the retrovirus is well understood and can be effectively manipulated to generate vectors that can be efficiently and safely packaged. Here, we review the molecular technology behind the generation of recombinant retroviral vectors. We also highlight the problems associated with the use of these viruses as gene therapy vehicles and discuss future developments that will be necessary to maintain retroviral vectors at the forefront of gene transfer technology.

A novel murine retrovirus identified during testing for helper virus in human gene transfer trials

An important requirement for the use of retroviral vectors in human gene transfer experiments is the avoidance of human exposure to replication-competent (helper) retroviruses. To meet this requirement, we used a sensitive marker rescue assay for helper virus to screen vector-transduced cells prior to reinfusion into patients. This assay utilized Mus dunni cells harboring a retroviral vector that can be rescued by helper retroviruses. The assay indicated the presence of helper virus in medium exposed to hematopoietic cells from all patients tested, including six patients with various cancers and one patient with Gaucher's disease, whether or not the patient cells had been exposed to retroviral vectors. All of the helper viruses were in a single interference group. We have now shown that treatment of the M. dunni marker rescue assay cells with 5-iodo-2'-deoxyuridine or hydrocortisone can activate production of an apparently identical helper virus, which we have named M. dunni endogenous virus (MDEV). Thus, production of virus in the assays of patient materials was likely due to exposure of the marker rescue assay cells to the hydrocortisone present in the hematopoietic cell growth medium. MDEV does not belong to any of the known murine leukemia virus groups by interference analysis, and we have called the new group multitropic because of the wide range of cells from different species that MDEV can infect.

Three allelic forms of the human endogenous retrovirus, ERV3, and their frequencies in multiple sclerosis patients and healthy individuals

A possible association between the endogenous retrovirus, ERV3, and multiple sclerosis (MS) was examined. Samples of DNA from 74 MS patients and 159 healthy blood donors were subjected to enzymatic amplification followed by single strand conformational analysis to detect polymorphisms in the long terminal repeats of ERV3. Using this approach we detected six single base pair variations and a drop-out of a nucleotide. The linkage pattern of these base pair variations enabled us to define three allelic forms of ERV3. Polymorphisms exclusively present in the group of patients were not found and the distribution of the three allelic forms did not differ significantly between the group of controls and the MS group. Neither was there a significant difference in the distribution of the three alleles between MS patients with the progressive form and patients with relapsing/remitting MS. Our results are not in support of an association between ERV3 and MS.

Human endogenous retroviruses: nature, occurrence, and clinical implications in human disease

Retroviral diagnostics have become standard in human laboratory medicine. While current emphasis is placed on the human exogenous viruses (human immunodeficiency virus and human T-cell leukemia virus), evidence implicating human endogenous retroviruses (HERVs) in various human disease entities continues to mount. Literature on the occurrence of HERVs in human tissues and cells was analyzed. Substantial evidence documents that retrovirus particles were clearly demonstrable in various tissues and cells in both health and disease and were abundant in the placenta and that their occurrence could be implicated in some of the reproductive diseases. The characteristics of HERVs are summarized, mechanisms of replication and regulation are outlined, and the consistent hormonal responsiveness of HERVs is noted. Clear evidence implicating HERV gene products as participants in glomerulonephritis in some cases of systemic lupus erythematosus is adduced. Data implicating HERVs as etiologic factors in reproductive diseases, in some of the autoimmune diseases, in some forms of rheumatoid arthritis and connective tissue disease, in psoriasis, and in some of the inflammatory neurologic diseases are reviewed. The current major needs are to improve methods for HERV detection, to identify the most appropriate HERV prototypes, and to develop diagnostic reagents so that the putative biologic and pathologic roles of HERVs can be better evaluated.

Distribution of baboon endogenous virus among species of African monkeys suggests multiple ancient cross-species transmissions in shared habitats

PCR amplification of baboon endogenous virus (BaEV) long terminal repeat, reverse transcriptase gene, and env fragments from 24 different species of African monkeys indicates that BaEV is less widespread than was formerly thought. Instead of being present in every species of African primates, BaEV can be found only in baboons, geladas, and mangabeys (all belonging to the Papionini tribe) and in African green monkey (Cercopithecus aethiops)subspecies. BaEV, which can be activated from baboon and gelada tissues, was most likely introduced in the germ line only recently (less than a few million years ago) and has not been inherited from a common ancestor of all extant African monkeys. Neighbor-joining and maximum-likelihood analyses of the sequences obtained showed that two distinct virus clusters can be distinguished: the first containing baboon, gelada, and African green monkey BaEV sequences and the second consisting of mandrill and mangabey BaEV sequences. This viral evolutionary tree does not follow host phylogeny, indicating the cross-species transmissions and multiple germ line fixations of the virus must have occurred in the past. BaEV sequences are found in monkeys inhabiting savannas (baboons, geladas, and African green monkeys) as well as forests (managabeys and mandrills) and cluster according to the habitats of their hosts, providing evidence for cross-species transmission in shared habitats.

Phylogeny reconstruction for protein sequences based on amino acid properties

This paper presents an essentially new method used to construct phylogenetic trees from related amino acid sequences. The method is based on a new distance measure which describes sequence relationships by means of typical steric and physicochemical properties of the amino acids and is advantageous in some essential points. The method was applied to different sets of protein sequences and the results were compared with other well-established methods.

Retrovirus-like particles released from the human breast cancer cell line T47-D display type B- and C-related endogenous retroviral sequences

The human mammary carcinoma cell line T47-D releases retrovirus-like particles of type B morphology in a steroid-dependent manner (I. Keydar, T. Ohno, R. Nayak, R. Sweet, F. Simoni, F. Weiss, S. Karby, R. Mesa-Tejada, and S. Spiegelman, Proc. Natl. Acad. Sci. USA 81:4188-4192, 1984). Furthermore, reverse transcriptase (RT) activity is found to be associated with particle preparations. Using a set of degenerate primers derived from a conserved region of retroviral pol genes, we repeatedly amplified three different retroviral sequences (MLN, FRD, and FTD) from purified T47-D particles in several RT-PCR experiments. Screening of a human genomic library and Southern blot analysis revealed that these sequences are of endogenous origin. ERV-MLN represents a multicopy family of human endogenous retroviral elements (HERVs) with two closely related copies and up to 20 more distantly related members. In contrast, ERV-FRD and ERV-FTD comprise only one copy and five to seven related elements per haploid human genome. DNA sequence analysis of the proviral pol region of ERV-MLN revealed an uninterrupted stretch of 241 amino acids that shows 65% identity with the RT of the type B-related HERV designated HERV-K10. ERV-FRD and ERV-FTD are defective type C-related HERVs. The pol gene of ERV-FRD displays a nucleotide homology of 54% to the gibbon ape leukemia virus, and the pol gene of ERV-FTD is about 67% homologous to members of the RTVL-I family of HERVs. Our results thus indicate that the retroviral particles released by the breast cancer cell line T47-D are probably generated by complementation of several endogenous proviruses and can package retroviral transcripts of different origins.

The Y chromosome: a graveyard for endogenous retroviruses

We have isolated 20 different human endogenous retroviruses (ERV) related to ERV3, Hsrirt and Humer 4-1. Phylogeny and the presence of these ERV among different primates were determined by computer and Southern blot analyses. Preferential localization of ERV to the human, chimpanzee and orangutan Y chromosomes among the low-copy-number ERV is demonstrated. The reason for this accumulation of ERV on the strongly heterochromatic Y chromosome is probably mediated by (i) the absence of recombination of the Y chromosome that makes it more difficult for sequences to be lost, and (ii) integration of retroviruses in heterochromatic regions is less harmful to the organism. If ERV located on the Y chromosome are transcribed and translated to peptides, such peptides could be potential HY-antigens.

Phylogenetic analyses of 55 retroelements on the basis of the nucleotide and product amino acid sequences of the pol gene

Comparisons of pol gene nucleotide and reverse transcriptase (RT) amino acid sequences of 47 retroviruses, 3 caulimoviruses, and 5 hepadnaviruses showed that approximately one-third of the gene at the 5' end is much more conserved than other pol regions. The most conserved regions on both the nucleotide and amino acid sequences were chosen for construction of phylogenetic trees. The maximum-parsimony and distance-matrix methods were used for analyses of aligned amino acid sequences; these two methods, and the compatibility method, were used to analyze the aligned nucleotide sequences. Essentially identical majority-rule consensus trees were produced by these different methods from both the pol gene nucleotide and RT amino acid sequences, which divided the 55 retroelements into six major groups. The reliability of the phylogenetic trees was probed with the bootstrapping of 100 replicates of the original sequence alignments. The grouping results were shown to be statistically significant by multiple comparisons with the least-significant-difference procedure.

A highly divergent retroviral sequence in the tuatara (Sphenodon)

Vertebrate retroviruses have been classified into a number of different genera, and although many mammalian and avian examples have been characterized, less information exists about the retroviruses present within other vertebrate classes. We designed oligonucleotide primers against two highly conserved motifs within retroviral protease and reverse transcriptase genes and used them to isolate a retroviral fragment from the reptile tuatara (Sphenodon). Sequence analysis of this element, termed SpeV, demonstrated that it is substantially different from previously reported viruses, and that it cannot easily be placed into any known retroviral genus. Furthermore SpeV suggests that there may be some major differences between the retroviral populations found in reptiles and those present in mammals and birds.

Haematological disorders associated with feline retrovirus infections

Feline oncornavirus and lentivirus infections have provided useful models to characterize the virus and host cell factors involved in a variety of marrow suppressive disorders and haematological malignancies. Exciting recent progress has been made in the characterization of the viral genotypic features involved in FeLV-associated diseases. Molecular studies have clearly defined the causal role of variant FeLV env gene determinants in two disorders: the T-lymphocyte cytopathicity and the clinical acute immunosuppression induced by the FeLV-FAIDS variant and the pure red cell aplasia induced by FeLV-C/Sarma. Variant or enFeLV env sequences also appear to play a role in FeLV-associated lymphomas. Additional studies are required to determine the host cell processes that are perturbed by these variant env gene products. In the case of the FeLV-FAIDS variant, the aberrant env gene products appear to impair superinfection interference, resulting in accumulation of unintegrated viral DNA and cell death. In other cases it is likely that the viral env proteins interact with host products that are important in cell viability and/or proliferation. Understanding of these mechanisms will therefore provide insights to factors involved in normal lymphohaematopoiesis. Similarly, studies of FeLV-induced haematological neoplasms should reveal recombination or rearrangement events involving as yet unidentified host gene sequences that encode products involved in normal cell growth regulation. These sequences may include novel protoncogenes or sequences homologous to genes implicated in human haematological malignancies. The haematological consequences of FIV are quite similar to those associated with HIV. As with HIV, FIV does not appear to directly infect myeloid or erythroid precursors, and the mechanisms of marrow suppression likely involve virus, viral antigen, and/or infected accessory cells in the marrow microenvironment. Studies using in vitro experimental models are required to define the effects of each of these microenvironmental elements on haematopoietic progenitors. As little is known about the molecular mechanisms of FIV pathogenesis, additional studies of disease-inducing FIV strains are needed to identify the genotypic features that correlate with virulent phenotypic features. Finally, experimental FIV infection in cats provides the opportunity to correlate in vivo virological and haematological changes with in vitro observations in a large animal model that closely mimics HIV infection in man.

Identification of a novel family of human endogenous retroviruses and characterization of one family member, HERV-K(C4), located in the complement C4 gene cluster

We have identified a novel family of about 10-50 human endogenous retrovirus elements (HERVs) and have characterized one family member (HERV-KC4). This retrovirus element is integrated within intron 9 of and complement C4A genes and also in some C4B genes, and is a principal contribution to interlocus and interallelic length heterogeneity of C4 genes. The HERV-K(C4) sequence has a typical retrovirus structure with elements of gag, pol and env domains, flanked by two long terminal repeats (LTRs) and is similar to type A, B and D retroviruses. Multiple termination codons preclude the existence of long open reading frames, suggesting that the HERV-K(C4) sequence is no longer functional. Zoo blot hybridization reveals that New World monkeys appear to lack sequences similar to HERV-K(C4), suggesting that integration has occurred after the divergence of Old and New World monkeys. Retrotransposition of prototype viruses is presumed to have led to the amplification and integration of the members of the family in different loci, which in humans, appear to be dispersed over several chromosomes. The absence of the HERV-K(C4) element in some C4B genes in both humans and orangutangs indicate that the retrovirus inserted into the C4A gene after the duplication of the cluster. Subsequent spread of the HERV-K(C4) sequence to C4B genes presumably occurred by interlocus sequence exchange mechanisms, such as unequal crossover and gene conversion-like mechanisms.

Phylogenesis and genetic complexity of the nonhuman primate retroviridae

The three known groups of nonhuman primate retroviruses (simian immunodeficiency virus, simian T cell lymphotropic/leukemic virus type I, and simian foamy virus) are thought to have equivalent human counterparts. This is clearly the case with human immunodeficiency virus types 1 and 2, the causative agents of acquired immunodeficiency syndrome, and with human T cell lymphotropic/leukemia virus type I (HTLV-I), which causes T cell leukemia and a progressive form of myelopathy (tropical spastic paraparesis/HTLV-I-associated myelopathy), and HTLV-II. However, the presence of spumaviruses (foamy viruses) in humans remains uncertain. Data accumulated in the last 5 years suggest the possibility that the human retroviruses are indeed the result of transmission of simian retroviruses to humans. In this article we attempt to parallel the genetic features of the simian retroviridae with their human counterparts and argue for the possibility of horizontal transmission of these viruses from monkeys to humans.

Primate T-lymphotropic virus type I LTR sequence variation and its phylogenetic analysis: compatibility with an African origin of PTLV-I

Due to the low evolutionary rate and the limited horizontal transmission of human T-lymphotrophic virus type I (HTLV-I), its phylogenetic analysis reveals the movements and contacts of ancient populations. Since simian strains cannot be distinguished from human strains by phylogenetic criteria, this virus has appropriately been called primate T-lymphotropic virus type I (PTLV-I). We sequenced the LTR of six PTLV-I strains: three HTLV-I strains from African patients with tropical spastic paraparesis (TSP) (Equateur, Zaire), two laboratory HTLV-I strains of Japanese origin, MT-2 and MT-4, and one STLV-I from a baboon of the primate center in Sukhumi, Georgia. We applied four phylogenetic inference methods: neighbor-joining (NJ), unweighted pair group method using arithmetic averages (UPGMA), Fitch and Wagner parsimony (pars), and maximum likelihood (ML), to these 6 LTR sequences and 18 published LTR sequences (cosmopolitan, African, and Melanesian HTLV-I strains and African and Asian STLV-I strains). Three major HTLV-I subtypes can be identified with all four methods: the cosmopolitan HTLV-Ia, the central African HTLV-Ib, clearly descendant from a STLV-I CH-like African ancestral simian strain, and the Melanesian HTLV-Ic, probably descendant from an Asian STLV-I strain. We observe a segregation of PTLV-I sequences according to their geographical origin and not according to host species. The Zairean strains form a cluster closely related to an STLV-I strain isolated from a chimpanzee (STLV-I CH) and distinct from western African strains, which belong to the cosmopolitan subtype of HTLV-I. The Sukhumi STLV-I strain found in a captive-born baboon was of Asian descent. We experienced rooting problems with UPGMA when using HTLV-II as an outgroup. Concordant results with all four methods were obtained by eliminating HTLV-II LTR sequence fragments with bad alignment to HTLV-I. This resulted in a HTLV-II root node on the African STLV-I TAN90 terminal branch (with bootstrap values above 92% for the NJ and pars methods) and not on the Asian STLV-I PtM3 branch, as has been derived by others based on their use of UPGMA. The results of the analyses also support a higher evolutionary rate of PTLV-I in Asia, implying that the trees obtained with the NJ and ML methods have a higher reliability. These results are more compatible with an ancient African origin of PTLV-I than with an Asian origin.