Primates are regularly infected by fungal organisms identified as Pneumocystis carinii. They constitute a valuable population for the confirmation of P. carinii host specificity. In this study, the presence of P. carinii was assessed by direct examination and nested PCR at mitochondrial large subunit (mtLSU) rRNA and dihydropteroate synthetase (DHPS) genes in 98 lung tissue samples from captive or wild nonhuman primates. Fifty-nine air samples corresponding to the environment of different primate species in zoological parks were also examined. Cystic forms of P. carinii were detected in smears from 7 lung tissue samples corresponding to 5 New World primate species. Amplifications at the mtLSU rRNA gene were positive for 29 lung tissue samples representing 18 different primate species or subspecies and 2 air samples corresponding to the environment of two simian colonies. Amplifications at the DHPS gene were positive for 8 lung tissue samples representing 6 different primate species. Direct sequencing of nested PCR products demonstrated that a specific mtLSU rRNA and DHPS sequence could be attributed to each primate species or subspecies. No nonhuman primate harbored the human type of P. carinii (P. carinii f. sp. hominis). Genetic divergence in primate-derived P. carinii organisms varied in terms of the phylogenetic divergence existing among the corresponding host species, suggesting coevolution.
Previous studies have demonstrated that the agent of Pneumocystis pneumonia (PcP), Pneumocystis carinii, is actually a complex of eukaryotic organisms, and cophylogeny could explain the distribution of the hosts and parasites. In the present work, we tested the hypothesis of cophylogeny between the primate-derived Pneumocystis group and their hosts. Specific strains isolated from 20 primate species, including humans, were used to produce a phylogeny of the parasites. Aligned sequences corresponding to DNA sequences of three genes (DHPS, mtSSU-rRNA, and mtLSU-rRNA) were separately analyzed and then combined in a single data set. The resulting parasite phylogeny was compared with different controversial phylogenies for the hosts. This comparison demonstrated that, depending upon which topology is accepted for the hosts, at least 61% and perhaps 77% of the homologous nodes of the respective cladograms of the hosts and parasites may be interpreted as resulting from codivergence events. This finding and the high specificity of these parasites suggests that cophylogeny may be considered the dominant pattern of evolution for Pneumocystis organisms, representing a new example of parallel evolution between primates and their specific parasites. Because the phylogeny of Pneumocystis followed very closely the differentiation of their hosts at the species level, the study of the parasites could provide valuable information on the phylogeny of their hosts. We used this information to explore controversial hypotheses of the phylogeny of the Platyrrhini by comparison with the phylogeny of their specific Pneumocystis parasites. If these organisms were closely associated as lung parasites with primates through the ages, the hypothesis of the Pneumocystis spp. being new pathogenic agents could be refuted. However, these organisms are opportunistic symbionts, becoming pathogenic whenever the immunological defences of their hosts decline. This study also provides support for the hypothesis that the different Pneumocystis species are genetically independent organisms, helping to clarify their taxonomic status.
The single name Pneumocystis carinii consists of an heterogeneous group of specific fungal organisms that colonize a very wide range of mammalian hosts. In the present study, mitochondrial large subunit (mtLSU) and small subunit (mtSSU) rRNA sequences of P. carinii organisms from 24 different mammalian species were compared. The mammals were included in six major groups: Primates (12 species), Rodents (5 species), Carnivores (3 species), Bats (1 species), Lagomorphs (1 species), Marsupials (1 species) and Ungulates (1 species). Direct sequencing of PCR products demonstrated that specific mtSSU and mtLSU rRNA Pneumocystis sequence could be attributed to each mammalian species. No animal harbored P. carinii f. sp. hominis. Comparison of combined mtLSU and mtSSU aligned sequences confirmed cospeciation of P. carinii and corresponding mammalian hosts. P. carinii organisms isolated from mammals of the same zoological group systematically clustered together. Within each cluster, the genetic divergence between P. carinii organisms varied in terms of the phylogenetic divergence existing among the corresponding host species. However, the relative position of P. carinii groups (rodent, camivore or primate-derived P. carinii) could not be clearly determined. Further resolution will require the integration of additional sequence data.
Bats belong to a wide variety of species and occupy diversified habitats, from cities to the countryside. Their different diets (i.e., nectarivore, frugivore, insectivore, hematophage) lead Chiroptera to colonize a range of ecological niches. These flying mammals exert an undisputable impact on both ecosystems and circulation of pathogens that they harbor. Pneumocystis species are recognized as major opportunistic fungal pathogens which cause life-threatening pneumonia in severely immunocompromised or weakened mammals. Pneumocystis consists of a heterogeneous group of highly adapted host-specific fungal parasites that colonize a wide range of mammalian hosts. In the present study, 216 lungs of 19 bat species, sampled from diverse biotopes in the New and Old Worlds, were examined. Each bat species may be harboring a specific Pneumocystis species. We report 32.9% of Pneumocystis carriage in wild bats (41.9% in Microchiroptera). Ecological and behavioral factors (elevation, crowding, migration) seemed to influence the Pneumocystis carriage. This study suggests that Pneumocystis-host association may yield much information on Pneumocystis transmission, phylogeny, and biology in mammals. Moreover, the link between genetic variability of Pneumocystis isolated from populations of the same bat species and their geographic area could be exploited in terms of phylogeography.
Two strains of bacteria isolated from the blood of French domestic cows were found to be similar to Bartonella species on the basis of phenotypic characteristics. Genotypic analysis based on sequence comparison of the 16S rRNA and citrate synthase (gltA) genes and on DNA-DNA hybridization showed that the two isolates represent a distinct and new species of Bartonella. Moreover, the phylogenetic analysis inferred from comparison of 16S rRNA and gltA sequences demonstrated that the new Bartonella species is related to other ruminant-derived Bartonella species. The name Bartonella chomelii is proposed for the new species. The type strain of Bartonella chomelii sp. nov. is A828 T (=CIP 107869 T =CCUG47497 T ).
Simian populations represent valuable models for understanding the epidemiology of human pneumocystosis. The present study aims to describe the circulation of Pneumocystis organisms within a social organization of healthy crab-eating macaques (Macaca fascicularis) living in a natural setting in France. Animals were followed for up to 2 years. Deep nasal swab and blood samples were collected monthly from each animal under general anaesthesia. Environmental air was sampled for a 1 week period every month in the park where the macaques dwelt. Pneumocystis DNA was detected by nested-PCR of mitochondrial large subunit rRNA (mtLSU) gene in nasal swab and air samples. Anti-Pneumocystis IgG antibodies were detected in serum samples by indirect immuno-fluorescence assay. Pneumocystis DNA was detected in 168 of 500 swab samples examined (33?6 %). The number of macaques with detectable Pneumocystis DNA was highly variable from one month to another. Positive detection of Pneumocystis DNA was not related to the detection of serum anti-Pneumocystis antibody. During the second year of the study, Pneumocystis DNA was amplified more frequently from unweaned macaques than from adults or subadults. The mtLSU sequence showed marked polymorphism with eight Pneumocystis sequence types representing two distinct groups. On the whole, a constant and intensive circulation of Pneumocystis organisms within the community was observed. However, the implication of the various members of the colony was probably different and several levels of colonization by Pneumocystis may occur in immunocompetent macaques.
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