High prevalence, coinfection rate, and genetic diversity of retroviruses in wild red colobus monkeys (Piliocolobus badius badius) in Tai National Park, Cote d'Ivoire.

Simian retroviruses are precursors of all human retroviral pathogens. However, little is known about the prevalence and coinfection rates or the genetic diversity of major retroviruses-simian immunodeficiency virus (SIV), simian T-cell lymphotropic virus type 1 (STLV-1), and simian foamy virus (SFV)-in wild populations of nonhuman primates. Such information would contribute to the understanding of the natural history of retroviruses in various host species. Here, we estimate these parameters for wild West African red colobus monkeys (Piliocolobus badius badius) in the Taï National Park, Côte d'Ivoire. We collected samples from a total of 54 red colobus monkeys; samples consisted of blood and/or internal organs from 22 monkeys and additionally muscle and other tissue samples from another 32 monkeys. PCR analyses revealed a high prevalence of SIV, STLV-1, and SFV in this population, with rates of 82%, 50%, and 86%, respectively. Forty-five percent of the monkeys were coinfected with all three viruses while another 32% were coinfected with SIV in combination with either STLV or SFV. As expected, phylogenetic analyses showed a host-specific pattern for SIV and SFV strains. In contrast, STLV-1 strains appeared to be distributed in genetically distinct and distant clades, which are unique to the Taï forest and include strains previously described from wild chimpanzees in the same area. The high prevalence of all three retroviral infections in P. b. badius represents a source of infection to chimpanzees and possibly to humans, who hunt them.

[Human retrovirus HTLV-1: descriptive and molecular epidemiology, origin, evolution, diagnosis and associated diseases]. / Le rétrovirus humain oncogène HTLV-1 : épidémiologie descriptive et moléculaire, origine, évolution et aspects diagnostiques et maladies associées.

Human T-cell leukemia/lymphoma virus type 1 (HTLV-1) was the first oncogenic human retrovirus discovered in 1980. It is estimated that around 10-20 million people are infected with HTLV-1 worldwide. However, HTLV-1 is not a ubiquitous virus. Indeed, HTLV-1 is present throughout the world with clusters of high endemicity including mainly southern Japan, the Caribbean region, parts of South America and intertropical Africa, with foci in the Middle East and Australia. The origin of this puzzling geographical repartition is probably linked to a founder effect in certain human groups. In the high endemic areas, 0.5 to 50% of the people have antibodies against HTLV-1 antigens. HTLV-1 seroprevalence increases with age, especially in women. HTLV-1 has 3 modes of transmission: mother to child, mainly through prolonged breastfeeding (> 6 months); sexual, mainly but not exclusively occurring from male to female; and by blood products contaminated by infected lymphocytes. HTLV-1 is mainly the etiological agent of two very severe diseases: a malignant T CD4+ cell lymphoproliferation of very poor prognosis, named adult T-cell leukemia/lymphoma (ATLL), and a chronic neuro-myelopathy named tropical spastic paraparesis/HTLV-1-associated myelopathy (TSP/HAM). HTLV-1 is also associated with rare anterior uveitis, infective dermatitis and myositis in some high HTLV-1 endemic areas. The repartition of the different molecular subtypes or genotypes is mainly linked to the geographical origin of the infected persons but not to the associated pathology. HTLV-1 possesses a remarkable genetic stability probably linked to viral amplification via clonal expansion of infected cells rather than by reverse transcription. This stability can be used as a molecular tool to gain better insights into the origin, evolution and modes of dissemination of HTLV-1 and infected populations. HTLV-1 originated in humans through interspecies transmission from STLV-1, a very closely related retrovirus, highly endemic in several populations of apes and Old World monkeys.

Coinfection of Ugandan red colobus (Procolobus [Piliocolobus] rufomitratus tephrosceles) with novel, divergent delta-, lenti-, and spumaretroviruses.

Nonhuman primates host a plethora of potentially zoonotic microbes, with simian retroviruses receiving heightened attention due to their roles in the origins of human immunodeficiency viruses type 1 (HIV-1) and HIV-2. However, incomplete taxonomic and geographic sampling of potential hosts, especially the African colobines, has left the full range of primate retrovirus diversity unexplored. Blood samples collected from 31 wild-living red colobus monkeys (Procolobus [Piliocolobus] rufomitratus tephrosceles) from Kibale National Park, Uganda, were tested for antibodies to simian immunodeficiency virus (SIV), simian T-cell lymphotrophic virus (STLV), and simian foamy virus (SFV) and for nucleic acids of these same viruses using genus-specific PCRs. Of 31 red colobus tested, 22.6% were seroreactive to SIV, 6.4% were seroreactive to STLV, and 97% were seroreactive to SFV. Phylogenetic analyses of SIV polymerase (pol), STLV tax and long terminal repeat (LTR), and SFV pol and LTR sequences revealed unique SIV and SFV strains and a novel STLV lineage, each divergent from corresponding retroviral lineages previously described in Western red colobus (Procolobus badius badius) or black-and-white colobus (Colobus guereza). Phylogenetic analyses of host mitochondrial DNA sequences revealed that red colobus populations in East and West Africa diverged from one another approximately 4.25 million years ago. These results indicate that geographic subdivisions within the red colobus taxonomic complex exert a strong influence on retroviral phylogeny and that studying retroviral diversity in closely related primate taxa should be particularly informative for understanding host-virus coevolution.

Simian T-lymphotropic virus diversity among nonhuman primates, Cameroon.

Cross-species transmission of retroviruses is common in Cameroon. To determine risk for simian T-cell lymphotropic virus (STLV) transmission from nonhuman primates to hunters, we examined 170 hunter-collected dried blood spots (DBS) from 12 species for STLV. PCR with generic tax and group-specific long terminal repeat primers showed that 12 (7%) specimens from 4 nonhuman primate species were infected with STLV. Phylogenetic analyses showed broad diversity of STLV, including novel STLV-1 and STLV-3 sequences and a highly divergent STLV-3 subtype found in Cercopithecus mona and C. nictitans monkeys. Screening of peripheral blood mononuclear cell DNA from 63 HTLV-seroreactive, PCR-negative hunters did not identify human infections with this divergent STLV-3. Therefore, hunter-collected DBS can effectively capture STLV diversity at the point where pathogen spillover occurs. Broad screening using this relatively easy collection strategy has potential for large-scale monitoring of retrovirus cross-species transmission among highly exposed human populations.

Ancient DNA identification of early 20th century simian T-cell leukemia virus type 1.

The molecular identification of proviruses from ancient tissues (and particularly from bones) remains a contentious issue. It can be expected that the copy number of proviruses will be low, which magnifies the risk of contamination with retroviruses from exogenous sources. To assess the feasibility of paleoretrovirological studies, we attempted to identify proviruses from early 20th century bones of museum specimens while following a strict ancient DNA methodology. Simian T-cell leukemia virus type 1 sequences were successfully obtained and authenticated from a Chlorocebus pygerythrus specimen. This represents the first clear evidence that it will be possible to use museum specimens to better characterize simian and human T-tropic retrovirus genetic diversity and analyze their origin and evolution, in greater detail.

The natural history and evolution of human and simian T cell leukemia/lymphotropic viruses.

The past five years have seen significant advances in understanding the origin and evolution of human T-cell leukemia/lymphotropic virus types I and II. The highlights include the identification of human T-cell leukemia/lymphotropic virus types I and II genotypic variants in remote human populations and the discovery of widely divergent simian T-cell leukemia virus in African and Asian non-human primates.

Phylogeny of primate T lymphotropic virus type 1 (PTLV-1) including various new Asian and African non-human primate strains.

To further unravel intra- and interspecies PTLV-1 evolution in Asia and Africa, we phylogenetically analysed 15 new STLV-1 LTR and env sequences discovered in eight different Asian and African non-human primate species. We show that orang-utan STLV-1s form a tight, deeply branching monophyletic cluster between Asian STLV-1 macaque species clades, suggesting natural cross-species transmission. Novel viruses of Macaca maura, Macaca nigra and siamang cluster with other Sulawesian STLV-1s, demonstrating close relatedness among the STLV-1s in these insular species and suggesting cross-species transmission to a siamang in captivity. Viruses from Western chimpanzees and a Western lowland gorilla cluster within the HTLV-lb/STLV-1 clade, the latter close to a human strain, indicative of zoonosis. A new STLV-1 from Cercopithecus ascanius differs from the published STLV-Cas57, explainable by the existence of five geographically separated subspecies. Barbary macaques, not yet described to be STLV-infected, carry a relatively recent acquired, typical African STLV-1, giving us no clue on the phylogeographical origin of PTLV-1.

Detailed phylogenetic analysis of primate T-lymphotropic virus type 1 (PTLV-1) sequences from orangutans (Pongo pygmaeus) reveals new insights into the evolutionary history of PTLV-1 in Asia.

While human T-lymphotropic virus type 1 (HTLV-1) originates from ancient cross-species transmission of simian T-lymphotropic virus type 1 (STLV-1) from infected nonhuman primates, much debate exists on whether the first HTLV-1 occurred in Africa, or in Asia during early human evolution and migration. This topic is complicated by a lack of representative Asian STLV-1 to infer PTLV-1 evolutionary histories. In this study we obtained new STLV-1 LTR and tax sequences from a wild-born Bornean orangutan (Pongo pygmaeus) and performed detailed phylogenetic analyses using both maximum likelihood and Bayesian inference of available Asian PTLV-1 and African STLV-1 sequences. Phylogenies, divergence dates and nucleotide substitution rates were co-inferred and compared using six different molecular clock calibrations in a Bayesian framework, including both archaeological and/or nucleotide substitution rate calibrations. We then combined our molecular results with paleobiogeographical and ecological data to infer the most likely evolutionary history of PTLV-1. Based on the preferred models our analyses robustly inferred an Asian source for PTLV-1 with cross-species transmission of STLV-1 likely from a macaque (Macaca sp.) to an orangutan about 37.9-48.9kya, and to humans between 20.3-25.5kya. An orangutan diversification of STLV-1 commenced approximately 6.4-7.3kya. Our analyses also inferred that HTLV-1 was first introduced into Australia ~3.1-3.7kya, corresponding to both genetic and archaeological changes occurring in Australia at that time. Finally, HTLV-1 appears in Melanesia at ~2.3-2.7kya corresponding to the migration of the Lapita peoples into the region. Our results also provide an important future reference for calibrating information essential for PTLV evolutionary timescale inference. Longer sequence data, or full genomes from a greater representation of Asian primates, including gibbons, leaf monkeys, and Sumatran orangutans are needed to fully elucidate these evolutionary dates and relationships using the model criteria suggested herein.

The simian origins of the pathogenic human T-cell lymphotropic virus type I.

At least four, and possibly six, molecular subtypes of human T-cell lymphotropic virus type I (HTLV-I) exist: one is confined to Melanesia/Australia, one is ubiquitous, and the others are found only in Africa. Molecular epidemiology suggests that all subtypes arose from separate interspecies transmissions from simians to humans.

Phylogenetic relationships of HTLV-I/STLV-I in the world.

In an effort to delineate the origin and evolution of HTLV-I/STLV-I, we have been conducting phylogenetic analyses on LTR sequences of this virus group. HTLV-I isolates newly analyzed in the present study were from Iran, South Africa, Cameroon, Sakhalin and Brazil where little is known concerning the genetic features of HTLV-I. In addition, STLV-I isolates were obtained from non-human primates in Africa and Asia including an isolate from orangutans in Indonesia. Proviral LTR sequences were amplified by nested PCR, and then sequenced. Phylogenetic trees were constructed by the neighbor joining method. The results obtained are: 1) African STLV-I isolates formed one large cluster together with the Central African group of HTLV-I in the tree; 2) Asian STLV-I isolates including that of an orangutan in Indonesia were highly divergent from African STLV-I and the Cosmopolitan group of HTLV-I, but not so closely related to each other and to the Melanesian group of HTLV-I; 3) An HTLV-I isolate of Cameroon Pygmy was related to African STLV-I isolates, but distinct from the Central African group of HTLV-I; 4) The majority of HTLV-I isolates belonged to subgroup A which is the most widespread subgroup of the Cosmopolitan group of HTLV-I, while some Brazilian isolates from descendants of Japanese immigrants belonged to subgroup B which mainly consists of HTLV-I isolates from Japan. 5) In the phylogenetic tree, several HTLV-I isolates of subgroup A from the same areas appear to form monophyletic clusters such as a subcluster of Brazilian and Colombian isolates and that of Iranian isolates.

Characterization of a new simian T-lymphocyte virus type 1 (STLV-1) in a wild living chimpanzee (Pan troglodytes verus) from Ivory Coast: evidence of a new STLV-1 group?

A new strain of simian T-lymphotropic virus type 1 in blood samples from a chimpanzee that lived in the tropical rainforest of Ivory Coast is described. The sequence obtained from the long terminal repeat region of the genome is significantly divergent from all known human and nonhuman primate T-lymphotropic virus type 1 strains (963% homology to the closest related strains from Central African subtype B) and clusters with none of the established clades. The tax sequences reveal two sequence differences that seem to be unique as they are not found in any of the HTLV-1 or STLV-1 tax sequences from the public databases.

Two distinct STLV-1 subtypes infecting Mandrillus sphinx follow the geographic distribution of their hosts.

The mandrill (Mandrillus sphinx) has been shown to be infected with an STLV-1 closely related to HTLV-1. Two distinct STLV-1 subtypes (D and F) infect wild mandrills with high overall prevalence (27.0%) but are different with respect to their phylogenetic relationship and parallel to the mandrills' geographic range. The clustering of these new STLV-1mnd sequences with HTLV-1 subtype D and F suggests first, past simian-to-human transmissions in Central Africa and second, that species barriers are easier to cross over than geographic barriers.

Molecular characterization and phylogenetic analyses of a new simian T cell lymphotropic virus type 1 in a wild-caught african baboon (Papio anubis) with an indeterminate STLV type 2-like serology.

STLV-1 viruses are closely related to HTLV-1 and infect many African monkey species. Seroreactivities of monkeys infected by STLV-1 are nearly identical to those of HTLV-1-infected individuals. In some cases, STLV-1 are, sequence-wise, indistinguishable from HTLV-1, and cannot be separated from them on the basis of phylogenetic analyses. HTLV-2-related simian viruses have been rarely reported. Such STLV-2 viruses, present in African bonobo (Pan paniscus), possess a genomic organization related to but different from all known HTLV-2 subtypes. We report here the molecular characterization and the subtyping of a new STLV-1 in a wild-caught baboon (Papio anubis) whose serum exhibited an indeterminate STLV-2-like serology (p24, GD21, MTA-1 with no p19). In the env and LTR regions, this virus is phylogenetically related to the large African STLV-1 group, but does not cluster with any STLV-1 baboon sequence. The complete p19 sequence reveals amino acid changes at critical positions. This is the first report of an African STLV-1 virus leading to an STLV-2-like serological profile in its host.

A New STLV-1 in a household pet Cercopithecus nictitans from Gabon.

A recent serological survey of wild-born captive monkeys from Gabon, Central Africa, revealed that 1 of 20 Cercopithecus nictitans tested was infected with a new simian T cell lymphotropic virus type 1 (STLV-1). We investigated the molecular relationship between the STLV-1 strain present in this C. nictitans (CN01) and the other available HTLV/STLV strains. Phylogenetic analysis of the env (gp46 and gp21) region showed that the new STLV(nict) clusters with the HTLV-1/STLV-1 group and not with the other nictitans STLVs belonging to the STLV-3 group. Moreover, our new STLV(nict) is closely related to the molecular subtype D, which presently includes five HTLV-1 and three mandrill STLV-1 strains from Gabon and two from Cameroon. These data show that C. nictitans may be the natural carrier of two different molecular types of STLV, one related to STLV-3 and the other possibly one of the simian STLV type 1 counterparts of HTLV-1 subtype D.

[Epidemiology, origin and genetic diversity of HTLV-1 retrovirus and STLV-1 simian affiliated retrovirus]. / Epidémiologie, origine et diversité génétique du rétrovirus HTLV-1 et des rétrovirus simiens apparentés à STLV-1.

Human T Cell leukemia/lymphoma virus type I, the first human oncogenic retrovirus, is the aetiological factor of Adult T cell leukemia (ATL), a CD4+ malignant lymphoproliferative disease and of a chronic neuromyelopathy, the tropical spastic paraparesis or HTLV-1 associated myelopathy (TSP/HAM). HTLV-1, which infects from 15 to 25 million individuals world-wide, is highly endemic in certain areas such as south-western Japan, Central Africa, the Caribbean basin and some regions of South America, Melanesia and of the middle East (for example the Mashhad area of Iran). The three major modes of transmission for HTLV-1 infection are perinatal, sexual and by blood transfusion. Recent molecular studies on HTLV-1 have shown the existence of several molecular subtypes (genotypes). These are related to the geographical origin of the infected populations and not to the associated diseases. The virus has a very high genetic stability. Viral amplification via clonal expansion of infected cells, rather than by use of reverse transcription could explain this remarkable phenomenon which can be used as a molecular tool for gaining new insights into the origin, evolution and modes of dissemination of HTLV-1. Analyses of HTLV-1 and STLV-1 (the simian counterpart) viral strains from throughout the world suggest that four events are responsible for this pattern of dissemination: 1) the transmission in the wild of STLV-1 between simian species, 2) the transmission of STLV-1 to humans as exemplified by the high percentage of identity between STLV-1 strains from chimpanzees or from mandrills with some HTLV-1 strains present in inhabitants of Central Africa, 3) persistence of HTLV-1 over a long period of time (by sexual and perinatal transmissions) in remote populations, as seen in the Australo-Melanesian region and 4) a global distribution of HTLV-1 via large scale human migrations, e.g., the slave trade from Africa to the New World.

Identification and molecular characterization of new simian T cell lymphotropic viruses in nonhuman primates bushmeat from the Democratic Republic of Congo.

Four types of human T cell lymphotropic viruses (HTLV) have been described (HTLV-1 to HTLV-4) with three of them having closely related simian virus analogues named STLV-1, -2, and -3. To assess the risk of cross-species transmissions of STLVs from nonhuman primates to humans in the Democratic Republic of Congo, a total of 330 samples, derived from primate bushmeat, were collected at remote forest sites where people rely on bushmeat for subsistence. STLV prevalences and genetic diversity were estimated by PCR and sequence analysis of tax-rex and LTR fragments. Overall, 7.9% of nonhuman primate bushmeat is infected with STLVs. We documented new STLV-1 and STLV-3 variants in six out of the seven species tested and showed for the first time STLV infection in C. mona wolfi, C. ascanius whitesidei, L. aterrimus aterrimus, C. angolensis, and P. tholloni. Our results provide increasing evidence that the diversity and geographic distribution of PTLVs are much greater than previously thought.

Diversity of STLV-1 strains in wild chimpanzees (Pan troglodytes verus) from Côte d'Ivoire.

Simian T-lymphotropic viruses type 1 (STLV-1) are regarded as a highly conserved group of viruses with genotypes clustering according to geographic regions rather than to infected species. In free living West African chimpanzees we have described a variety of STLV-1 strains and suggested that this diversity results from interspecies transmissions. Here we present new data on STLV-1 infections in these chimpanzees with the presence of two new distinct clades, proposing the establishing of two new STLV-1 subtypes. Moreover, in one of the chimpanzees, the Central African STLV-1 subtype B was detected. The STLV-1 strains detected here display a much wider diversity than heretofore reported for STLV-1 with presence of three distinct subtypes in chimpanzees from one distinct geographic region. In conclusion, the hypothesis of primate T-lymphotropic virus type 1 (PTLV-1) clustering by geography rather than host should be reconsidered, at least regarding STLV-1 infections in chimpanzees.