The action of falciparum malaria on the human and chimpanzee genomes compared: absence of evidence for a genomic signature of malaria at HBB and G6PD in three subspecies of chimpanzee.

The historical association between Plasmodium and primates has meant that many Plasmodium species have coevolved with specific primate hosts. However, unlike humans that are infected by species such as P. falciparum that cause severe malaria, many non-human primates are infected by Plasmodium species that only cause mild disease. Here we investigate whether the genomic signatures of plasmodial infection found in humans are also present in chimpanzees. We find no evidence of the major deleterious mutations at HBB (beta-globin) and G6PD in chimpanzees that confer resistance to malaria caused by P. falciparum nor evidence of long-term balancing selection at these loci. Our knowledge of malaria prevalence and pathogenesis in wild chimpanzees is severely limited, but it may be the case that beta-globin and G6PD variation are not adaptive in chimpanzees because malaria is rare and/or less detrimental in this species. Alternatively, chimpanzees may utilise mechanisms that are different from those of humans to protect against malaria.

Patterns of diversity in HIV-related loci among subspecies of chimpanzee: concordance at CCR5 and differences at CXCR4 and CX3CR1.

Human immunodeficiency virus type 1 (HIV-1) arose in humans via zoonotic transmissions of simian immunodeficiency viruses (SIV(cpz)) from common chimpanzees, Pan troglodytes. Despite the close relatedness of the two viruses and their hosts, we do not yet understand what causes SIV(cpz) to be nonpathogenic in chimpanzees, and HIV/AIDS to be one of the most devastating infectious diseases to have emerged in humans. There have been a number of genes identified in humans that confer disease resistance/susceptibility toward HIV-1, but little is known about the evolution and diversity of most of these chemokine receptor genes in chimpanzees. Here we show that genetic variation in chimpanzees differs across the various loci related to HIV-1, and that the pattern of variation differs among the chimpanzee subspecies. For all three subspecies, low diversity at CCR5 is confined to a small area of chromosome 3, suggesting that a selective sweep at this locus may have predated subspeciation. In contrast, diversity and neutrality tests suggest differing evolutionary forces among subspecies at CXCR4 and CX(3)CR1, with directional selection (in Pan troglodytes vellerosus) and demographic expansion (Pan troglodytes troglodytes) offering the most likely scenarios. These are some of the first data demonstrating differentiation in functional loci among chimpanzee subspecies.

Population pharmacokinetics of tenofovir in HIV-1-infected pregnant women and their neonates (ANRS 12109).

Thirty-eight human immunodeficiency virus-1 (HIV-1)-infected pregnant women were administered tenofovir disoproxil fumarate (TDF; 300 mg)-emtricitabine (FTC; 200 mg) tablets: two at labor initiation and one daily for 7 days postpartum. Maternal, umbilical, and neonatal plasma tenofovir concentrations were measured by high-performance liquid chromatography and analyzed using a population approach. Data were described using a two-compartment model for the mother, an effect compartment linked to maternal circulation for cord, and a neonatal compartment disconnected after delivery. Absorption was greater for women delivering by caesarian section than for those delivering vaginally. The maternal 600 mg TDF administration before delivery produces the same concentrations as 300 mg administration in other adults. If the time elapsed between maternal administration and delivery is >or=12 h, two tablets of TDF-FTC should be readministered. Tenofovir showed good placental transfer (60%). Administering 13 mg/kg of TDF as soon as possible after birth should produce neonatal concentrations comparable with those observed in adults.

A serological survey of Ebola virus infection in central African nonhuman primates.

We used an ELISA to determine the prevalence of IgG antibodies specific for the Zaire subtype of Ebola virus in 790 nonhuman primates, belonging to 20 species, studied between 1985 and 2000 in Cameroon, Gabon, and the Republic of Congo. The seroprevalence rate of Ebola antibody in wild-born chimpanzees was 12.9%, indicating that (1) Ebola virus circulates in the forests of a large region of central Africa, including countries such as Cameroon, where no human cases of Ebola infections have been reported; (2) Ebola virus was present in the area before recent outbreaks in humans; (3) chimpanzees are continuously in contact with the virus; and (4) nonlethal Ebola infection can occur in chimpanzees. These results, together with the unexpected detection of Ebola-specific IgG in other species (5 drills, 1 baboon, 1 mandrill, and 1 Cercopithecus), may help to narrow the search for the reservoir of Ebola virus. They also suggest that future Ebola outbreaks may occur anywhere in the central African forest region.

Phylogenetic analysis of 49 newly derived HIV-1 group O strains: high viral diversity but no group M-like subtype structure.

We assess the genetic relationships between 49 HIV-1 group O strains from 24 and 25 patients living in Cameroon and France, respectively. Strains were sequenced in four genomic regions: gag (p24) and three env regions (C2-V3, gp41, and for 22 C2-gp41). In each of the genomic regions analyzed, the genetic diversity among the group O strains was higher than that exhibited by group M. We characterize three major group O phylogenetic clusters (O:A, O:B, and O:C) that comprised the same virus strains in each of the genomic regions analyzed. The majority of strains cluster in O:A, a cluster previously identified by analysis of pol and env sequences. Group O recombinants were also identified. Importantly, the distinction between these three major group O clades was weak compared to the strong clustering apparent in the global group M phylogenetic tree that led to the identification of subtypes. Thus, these clusters of group O viruses should not be considered as equivalent to the group M subtypes. This difference between the pattern of group O and the global group M diversity, both taking into account the pandemic status of the group M subtypes and the comparatively small number of group O-infected individuals (the majority being from Cameroon), indicates that the group O phylogeny primarily represents viral divergence in the Cameroon region, analogous to group M viral diversity present in the Democratic Republic of Congo.

Measles virus strains circulating in Central and West Africa: Geographical distribution of two B3 genotypes.

Africa remains one of the major reservoirs of measles infection. Molecular epidemiological studies have permitted different measles virus isolates to be grouped into clades and genotypes; the major group, which has been identified as indigenous to Africa, is clade B. The viruses from epidemics in the Gambia (1993) and in the Cameroon (2001) were examined. In both studies, the homogeneity of the virus isolates within the epidemic as shown by sequence analysis revealed less than 0.2% variation of nucleotides between isolates. The measles viruses isolated in 1983 in Yaoundé, Cameroon, were designated as the B1 genotype. However, in 2001 only viruses belonging to the B3 genotype were found in this city. The viruses in the Gambia (1993) were also of the B3 genotype. However, these viruses could be distinguished from each other at the antigenic level and by comparative sequence analysis. The B3 Cameroon (2001) viruses were related to the proposed B3.1 subgroup, whereas the Gambian (1993) isolates corresponded to the B3.2 subgroup. The geographical distribution for the period 1993-2001 of these two viruses shows that B3.1 is found from the Sudan to Nigeria and Ghana extending south to the Cameroon, whereas the B3.2 genotype is found in West Africa. In Nigeria and Ghana, the viruses co-circulate. The identification of these viruses will permit more meaningful epidemiological studies after the proposed increase in measles vaccination coverage.

SIVcpz from a naturally infected Cameroonian chimpanzee: biological and genetic comparison with HIV-1 N.

Thus far, simian immunodeficiency virus from chimpanzees (SIVcpz) genomes have been characterized as Pan troglodytes troglodytes and show a strong relation with human immunodeficiency virus (HIV)-1 N in their env genes. We fully characterized another SIVcpz from P. t. troglodytes. This chimpanzee (Cam5) was, as was also the host of SIVcpz-cam3, wild born in Cameroon, a region where all three groups of HIV-1 (M, N and O) co-occur. In contrast to other SIVcpz, SIVcpz-cam5 was isolated immediately after the rescue of the animal. Our data demonstrate that SIVcpz-cam5, like SIVcpz-cam3, grows easily on human peripheral blood mononuclear cells (PBMCs) and uses CCR5 as a co-receptor similar to HIV-1 N YBF30. Phylogenetic analysis based on the entire env gene shows that SIVcpz-cam5 falls into the same unique subcluster as HIV-1 N YBF30, SIVcpz-cam3 and SIVcpz-US. A phylogenetic relationship was also found with the vif gene of HIV-1 N. This study provides proof that HIV-1 N related viruses circulate in wild P. t. troglodytes.

Phylogenetic analysis of SIV and STLV type I in mandrills (Mandrillus sphinx): indications that intracolony transmissions are predominantly the result of male-to-male aggressive contacts.

Natural SIVmnd and STLVmnd infections of mandrills in a colony at the Centre International de Recherches Médicales de Franceville (CIRMF) in Gabon were investigated by genetic analysis to determine the extent of intracolony transmission. SIVmnd pol sequence analysis indicates that the six strains present in the colony belong to the SIVmnd lentivirus subgroup previously defined according to the only available prototype sequence (SIVmndGB1), which originated from the same colony. The intraanimal nucleotide diversity (1.1-3.1%) was similar in range to that reported in individuals infected by other HIV/SIVs. The interanimal diversity (0.5-4.3%) was not significantly different from that observed in each individual mandrill, indicating an epidemiological link among the SIVmnd isolates of distinct animals within the colony. Phylogenetic analysis of these isolates, together with seroepidemiological and behavior surveillance within the colony, indicates a predominant male-to-male transmission of SIVmnd that probably occurred during bouts of interanimal aggression. Moreover, our results suggest one case of vertical transmission of SIVmnd from a naturally infected founder female to one of her six offspring. The first genetic analysis of STLV isolates from mandrills is also reported here. Partial tax/rex sequences were used to evaluate the diversity between seven STLVmnd isolates and their phylogenetic relationships with other known strains of human and nonhuman primate T cell leukemia virus, types I and II (PTLV-I/II). They all belong to the PTLV-I subtype, but two genetically distinct STLVmnd groups were evidenced within the mandrill colony. The phylogenetic analyses of the STLVmnd isolates, together with seroepidemiological and behavior surveillance of the mandrills, indicate that intracolony transmissions of STLVmnd are also predominantly the result of male-to-male aggressive contacts.

Detection of Loa loa-specific DNA in blood from occult-infected individuals.

Accurate and specific diagnosis of human loiasis is of crucial importance in an endemic area where two-thirds of infected individuals are without circulating microfilariae (occult loiasis). By using the polymerase chain reaction (PCR) and specific primers to the repeat 3 region (15r3) of the gene coding for Loa loa 15-kDa polyprotein antigen, DNA was amplified from total blood lysate of occult-infected subjects. A 396-bp DNA fragment was specifically detected. We tested the specificity of this method by qualitative hybridization to PCR products using blood lysates of the following subjects: (1) from Gabon (80 individuals residing in L. loa endemic area where loiasis exists sympatrically with Mansonella perstans); (2) from Togo (12 individuals infected with Onchocerca volvulus and M. perstans); (3) from Tahiti (12 individuals infected with Wuchereria bancrofti); and (4) from Mali (12 individuals infected with O. volvulus and M. perstans). Samples from Gabon included 60 L. loa amicrofilaremics and 20 L. loa occult-infected subjects. Qualitative hybridization carried out at 50 degrees C on PCR products, using a 15r3-specific oligonucleotide probe, revealed hybridization with L. loa-infected samples from Gabon and four samples from Togo after 2 days exposure to the film. The positive samples from Togo were characterized by the use of nested PCR. Three nested PCR products have been sequenced. No differences were observed between the three sequences and they are 99.72% identical to L. loa 15r3. None of bancroftian-infected individuals from Tahiti, nor O. volvulus- and M. perstans-infected individuals from Mali reacted after 1 week's exposure (overexposure) to the film. This allows us to conclude first that our 15r3 PCR assay is specific for L. loa and secondly that L. loa infections occur in Togo. The sensitivity of this 15r3 PCR assay was further investigated with occult patients and field-collected amicrofilaremic samples. We found that 19 of the 20 occult-infected individuals were positive on Southern hybridization, whereas 35/60 amicrofilaremics were positive. These results have shown that the sensitivity of this assay in detecting unequivocal, parasitologically proven occult loiasis was 95%, while the specificity with regard to the sympatric M. perstans was 100%.

Occurrence and frequency of transmission of naturally occurring simian retroviral infections (SIV, STLV, and SRV) at the CIRMF Primate Center, Gabon.

Among the primates held at the CIRMF Primate Center, Gabon, no serological sign of SIV infection could be demonstrated in 68 cynomolgus monkeys, 60 chimpanzees, nine gorillas, and 12 sun-tailed monkeys, while seven of 102 mandrills and six of 24 vervets were infected with SIV. Six mandrills, seven vervets and ten cynomolgus monkeys exhibited a full HTLV type 1 Western blot profile. The sera of two gorillas and one chimpanzee presented with a positive but not typical HTLV Western blot profile. The sera of the gorillas lacked p24 antibodies, and the chimpanzee had a Western blot profile evocative of HTLV-II. All attempts to amplify viruses from these animals by PCR were unsuccessful. Two other chimpanzees and seven gorillas presented with indeterminate HTLV Western blot profiles. In the mandrill colony, only male animals were STLV seropositive and no sexual transmission to females was observed. SIV infection was also more frequent in male than female mandrills and sexual transmission appeared to be a rare event. No SRV infection was observed in macaques.

The evolutionary rate of nonpathogenic simian immunodeficiency virus (SIVagm) is in agreement with a rapid and continuous replication in vivo.

African green monkeys (AGMs) are divided into four species (Cercopithecus aethiops, C. pygerythrus, C. sabaeus, C. tantalus), each harboring a species-specific simian immunodeficiency virus (SIVagm). Little is known about the host and/or viral factors that are responsible for the apathogenicity of SIVagm infections in their natural hosts. In order to analyze the specific selective pressures exerted by the host on the virus in vivo, we compared the genetic evolution of SIVagm.tan in its natural host (C. tantalus) and in a foreign host species (Erythrocebus patas), in which we could obtain a reproducible and persistent infection by SIVagm.tan. As in AGMs, patas monkeys do not develop any disease following SIVagm infection. Our longitudinal study in env (V3-C3-V4-C4-V5) of SIVagm.tan from three AGMs and three patas monkeys revealed a high ratio of synonymous to nonsynonymous mutation frequencies (1.5-6.2). These data indicate that the selective pressures for stability exerted by AGMs and patas monkeys on SIVagm override positive selection for change reported in pathogenic HIV-1 infections. The rapid accumulation of mutations observed in AGMs and patas monkeys (0.4-7.2 x 10(-2) nucleotide substitutions per site per year) suggests a continuous replication of SIVagm viruses in vivo. We thus propose that nonpathogenic SIVagm infections are the result of a long-term selection of SIVagm variants whose dissemination can be controlled in the host, rather than being explained by a low ability of the virus to replicate in vivo.

Simian immunodeficiency viruses from central and western Africa: evidence for a new species-specific lentivirus in tantalus monkeys.

Although up to 50% of African green monkeys (AGMs) are infected by simian immunodeficiency viruses (SIV) in their natural habitat, they remain asymptomatic carriers of these lentiviruses. They provide an attractive model to study not only the origin but also the link among genetic variation, host-virus adaptation, and pathogenicity of primate lentiviruses. SIVagm have been isolated from three species of AGM: the vervet (Cercopithecus pygerythrus), the grivet (Cercopithecus aethiops), and the sabaeus (Cercopithecus sabaeus) monkey. We studied four new SIVagm isolates from a fourth AGM species, the tantalus monkey (Cercopithecus tantalus), caught in the Central African Republic, and four new isolates from feral sabaeus monkeys from Senegal. Antigenic properties and partial env sequences were used to evaluate the diversity among these isolates. Alignment of env sequences in SIVagm isolated from tantalus and sabaeus monkeys permitted detailed mapping of the variable and conserved domains in the external glycoprotein. Genetic distances indicated that SIVagm isolates from tantalus monkeys are the most divergent among SIVagm in feral AGMs in Africa. The fact that AGMs are infected by four distinct lentiviruses, each specific for a single AGM species, supports the hypothesis of a coevolution of these viruses and their natural hosts and suggests that SIV transmission is a rare event among separated AGM species in the wild.