Meager genetic variability of the human malaria agent Plasmodium vivax.

Malaria is a major human parasitic disease caused by four species of Plasmodium protozoa. Plasmodium vivax, the most widespread, affects millions of people across Africa, Asia, the Middle East, and Central and South America. We have studied the genetic variability of 13 microsatellite loci in 108 samples from 8 localities in Asia, Africa, South America, and New Guinea. Only one locus is polymorphic; nine are completely monomorphic, and the remaining three are monomorphic in all but one or two populations, which have a rare second allele. In contrast, Plasmodium falciparum displays extensive microsatellite polymorphism within and among populations. We further have analyzed, in 96 samples from the same 8 localities, 8 tandem repeats (TRs) located on a 100-kb contiguous chromosome segment described as highly polymorphic. Each locus exhibits 2-10 alleles in the whole sample but little intrapopulation polymorphism (1-5 alleles with a prevailing allele in most cases). Eight microsatellite loci monomorphic in P. vivax are polymorphic in three of five Plasmodium species related to P. vivax (two to seven individuals sampled). Plasmodium simium, a parasite of New World monkeys, is genetically indistinguishable from P. vivax. At 13 microsatellite loci and at 7 of the 8 TRs, both species share the same (or most common) allele. Scarce microsatellite polymorphism may reflect selective sweeps or population bottlenecks in recent evolutionary history of P. vivax; the differential variability of the TRs may reflect selective processes acting on particular regions of the genome. We infer that the world expansion of P. vivax as a human parasite occurred recently, perhaps <10,000 years ago.

Evolutionary relationships between 15 Plasmodium species from new and old world primates (including humans): an 18S rDNA cladistic analysis.

We present a new phylogenetic analysis of 15 primate Plasmodium species based on 18S rDNA sequences including new sequences of Plasmodium coatneyi, P. fieldi, P. gonderi, P. hylobati and P. simium. The results are discussed in the context of the parasite host species and their geographical distribution. Contrary to other phylogenies constructed with this 18S rDNA molecule, we observed that the topology of phylogenetic trees was not affected either by the quality of the nucleotide matrices, or by the species present in the outgroup. This analysis showed the following. (1) The polyphyly of human Plasmodium is confirmed. (2) The monophyly of Plasmodium from Old World monkeys is confirmed by the new added sequences and P. gonderi, an African species, possibly could be at the root of this group. (3) The most parsimonious biogeographical hypothesis is that P. vivax originated in Asia; thus, its related species P. simium appears to be derived through a transfer from the human P. vivax to New World monkey species in South America. (4) Sampling efforts of non-human primate Plasmodium could permit improvement of the knowledge of primate Plasmodium phylogeny and also consideration of the risks of malaria emergence from monkey reservoirs.

Evidence for phylogenetic inheritance in pathogenicity of Mycobacterium.

In this study, we attempt to highlight part of the adaptive and phylogenetic constraints in mycobacterial pathogenicity. For this purpose, we first provide a phylogeny of Mycobacteria based on cladistic analyses of 64 different taxa. We then performed a comparative analysis, taking into account both ecological factors and phylogenetic relationships. The GLIM modelling analysis showed that different ecological and phylogenetic factors might be invoked to explain the variation in pathogenicity levels. Interestingly, the most harmful species were shown to be connected with the most diversified habitats. However, the independent contrast analysis revealed that once phylogeny was taken into account, none of the relationships between ecological factors and pathogenicity remained significant, and the pathogenicity appeared to be phylogenetically inherited among mycobacteria. The most pathogen were found in the slow-growing/long helix 18 group, and within this group in the most derived taxa.

Significant linkage disequilibrium and high genetic diversity in a population of Plasmodium falciparum from an area (Republic of the Congo) highly endemic for malaria.

A study based on 28 microsatellite loci was performed on 32 isolates of Plasmodium falciparum from Pointe Noire (Republic of the Congo) and compared with a cosmopolitan sample of 21 isolates collected from different countries in Africa, Latin America, and Asia. The Pointe Noire population exhibited very high genetic diversity (A = 7.8 +/- 2.6, He = 0.79 +/- 0.11). Significant linkage disequilibria were observed in 28 of 378 pairs of microsatellite loci. This result could be explained by two non-exclusive hypotheses: 1) uniparental propagation (i.e., selfing), leading to non-panmictic associations, and/or 2) a Wahlund effect (i.e., spatial population genetic heterogeneity). These observations are in agreement with data previously obtained from isozyme loci of the same isolates, but contrast with other population genetic analyses conducted in other hyperendemic zones.

Molecular characterization of environmental mycobacterium strains by PCR-restriction fragment length polymorphism of hsp65 and by sequencing of hsp65, and of 16S and ITS1 rDNA.

Fifteen mycobacterial strains from the environment, not clearly identifiable by biochemical properties, were analyzed with molecular markers: PCR-restriction enzyme analysis of hsp65 and sequencing of hsp65, and of the internal transcribed spacer 1 (ITS1) and 16S rDNA. The 16S rDNA sequencing closely related the strains to a slow-growing mycobacterial group including Mycobacterium simiae, Mycobacterium lentiflavum, Mycobacterium genavense, Mycobacterium triplex and Mycobacterium heidelbergense. A stretch of T bases at the level of 16S rDNA enabled the separation of M. simiae and M. lentifiavum from M. genavense, M. triplex and M. heidelbergense; hence the attribution of some environmental strains to the first or second group. But the distances between the two clades were very short and the relative positions of environmental strains and of reference strains were not resolved in terms of node robustness (low bootstrap values) in the distance tree. However, the hsp65 restriction profiles suggested assigning six strains to the M. lentiflavum species, although these strains had been found closely related to M. genavense and M. triplex from 16S rDNA nucleotide signatures. The clustering of environmental strains into the same three clusters was deduced from analysis of three sequence data (hsp65, and ITS1 and 16S rDNA), but the taxonomic affiliation of environmental strains to reference strains remained tentative. Among environmental strains and reference strains, the distances found from hsp65 sequences had the same amplitude as those found between different strains of Mycobacterium gordonae. From ITS1 rDNA sequences, the distances found between the strains of the Mycobacterium avium complex also had the same amplitude as those found between environmental strains and reference strains. From our results, it appears that the environmental strains and the reference strains could constitute a complex of subspecies or closely related species. Their taxonomic status must be confirmed by DNA/DNA hybridization experiments.

Taxonomic and phylogenetic analysis of Saprolegniaceae (Oomycetes) inferred from LSU rDNA and ITS sequence comparisons.

The aim of this study was to improve our knowledge about the taxonomy and phylogeny of the family Saprolegniaceae, a group of water molds including several pathogens of plants, fish and crustacea. ITS and LSU rDNA were sequenced for representatives of forty species corresponding to ten genera (Achlya, Aphanomyces, Brevilegnia, Dictyuchus, Leptolegenia, Plectospira, Pythiopsis, Saprolegnia, Thraustotheca). Phenetic and cladistic analyses were then carried out. The species Brevilegnia bispora does not appear to belong to the family Saprolegniaceae. Plectospira myrianda clusters with Aphanomyces spp. and they constitute an ancestral group. (Thraustotheca clavata is closely related to the eccentric species of the genus Achlya. The genus Achlya appears polyphyletic, corroborating more or less the three known subgroups, defined by their sexual spore type (eccentric, centric and subcentric). The achlyoid type of spore dehiscence, shared by Aphanomyces and Achlya genera, is shown to be an ancestral character. The saprolegnioid, dictyoid and thraustothecoid types of spore dehiscence are derived characters but their relative evolutionary positions are not resolved.

Identification, characterization, and immunolocalization of a nucleoside triphosphate diphosphohydrolase in pig liver.

Different isoforms of nucleoside triphosphate diphosphohydrolases (NTPDases; EC 3.6.1.5), also identified as ATP diphosphohydrolases, have been previously described in mammalian tissues. We report here the biochemical characterization of NTPDases in the pig liver. Optimum pH of catalysis is more acidic for this enzyme than for NTPDases (neutral or alkaline pH) found in other mammalian tissues. It is less sensitive to bile salts than the bovine spleen NTPDase. Calculated Km values for ATP and ADP (31 and 21 microM, respectively) are slightly higher than those reported for the latter enzyme. Electrophoretograms of these enzymes also show different migration patterns. Western blots with Ringo, an antibody that recognizes the different isoforms of mammalian NTPDases, show a small but reproducible difference in estimated molecular masses (75 kDa for liver vs 78 kDa for spleen NTPDase). A second antibody, generated against a different sequence of NTPDase I, does not recognize the liver enzyme, thereby indicating some differences in primary structure. Immunolocalization produced a strong signal on hepatocytes, epithelial cells of the bile duct system, and vascular cells. Immunoreactivity was variable among hepatocytes of different lobules and among hepatocytes within a given lobule. In general, those located in the perilobular zone were more reactive than those located in the central zone and in the periphery of the centrolobular vein.

Low divergence in rDNA ITS sequences among five species of Fucus (Phaeophyceae) suggests a very recent radiation.

Sequences from the two ribosomal DNA internal transcribed spacers (ITS1 and ITS2) were compared among five species of Fucus. Based on the present taxon sampling, parsimony analysis showed that Fucus serratus is the sister-group of the remaining Fucus species when Ascophyllum nodosum was used as an outgroup. The topology of the tree was (Fucus serratus (F. lutarius (F. vesiculosus (F. spiralis + F. ceranoides)))). The extremely low variation observed suggests a very recent radiation of the genus which supports the view widely accepted that the Fucales are among the most evolutionarily advanced of the brown algae. We further note that sequence differences between Fucus and Ascophyllum were 28%: this does not rule out the utility of ITS sequences within the Fucaceae. The very low number of informative positions allows to demonstrate empirically that distance matrix methods group on the basis of symplesiomorphies.

Molecular taxonomy and epidemiology of Blastomyces and Histoplasma species.

Cladistic analysis of partial 26S rRNA sequences was used to estimate evolutionary distances among species and varieties of the dimorphic onygenalean genera Blastomyces, Coccidioides, Emmonsia, Histoplasma and Paracoccidioides. With the exception of Coccidioides, all genera were closely related, with about 5% base differences and even less (1-2%) between Blastomyces and Emmonsia. These data were supported by a teleomorph in the same genus Ajellomyces. In a phylogenic study of a wide range of ascomycete orders and families, Coccidioides immitis was found to be closest to Aphanoascus fulvescens and Chrysosporium keratinophilum, and to have relative distances to the remaining dimorphic genera (family Onygenaceae) similar to those of the dermatophytes (family Arthrodermataceae). The sequencing data were confirmed by genomic comparisons. All dimorphic genera had a nuclear DNA base composition in the same range of 46.6-47.3% G + C. The DNA melting curves of Blastomyces and Histoplasma strains showed irregularities that were ascribed to the presence of AT-rich stretches in satellite DNA rather than in mitochondrial DNA. Derivative profiles proved to be highly reproducible within regional populations and coincided with differences in clinical behaviour of each species. Blastomyces dermatitidis generated two kinds of curves, corresponding to the geographically distinct serotypes 1 and 2. The African type (serotype 2) was characterized by a classical sigmoidal melting curve similar to that for all strains of Coccidioides, Emmonsia and Paracoccidioides. In contrast, the American type (serotype 1) contained satellite DNA (27% G + C). A rRNA base difference of 1.5% was observed between geographical types, a value slightly higher than that noted between Histoplasma capsulatum and its variety farciminosum (0.9%). All three H. capsulatum varieties presented irregularities in their DNA melting curves. The molecular data support the recognition of two of them as agents of blastomycosis and the assignment of more than one species and two varieties to the genus Emmonsia.

Phylogeny of dermatophytes and dimorphic fungi based on large subunit ribosomal RNA sequence comparisons.

The phylogeny of dermatophytes and dimorphic fungi was considered using the large-subunit of ribosomal RNA (25S rRNA). Aligned sequences of 595 nucleotides covering the two most divergent domains D1 and D2, permitted a comparison of phylogenetic relationships at different levels. The dimorphic species (Onygenaceae) were significantly separated from dermatophytes (Arthrodermataceae) and from a third group including geophilic or very weakly pathogenic species (Onygenaceae and Gymnoascaceae). On a species level, the varietal status of Histoplasma duboisii and Histoplasma farciminosum, as close relations of Histoplasma capsulatum, was confirmed. The dimorphic fungus Emmonsia parva, in spite of a completely different parasitic form (adiaspores instead of yeast-like cells), clustered with Blastomyces dermatitidis which has a perfect form resembling that of H. capsulatum. From our data, teleomorphs of E. parva, Paracoccidioides brasiliensis and H. farciminosum, three dimorphic fungi known only under their anamorphic states, should belong to the family of Onygenaceae and the genus Ajellomyces. Among Arthrodermataceae, and family containing the most keratinophilic species, it was not possible to establish a clear hierarchy of species. Only Ctenomyces serratus, the species adapted to degrade keratin of feathers, Trichophyton ajelloi and Trichophyton terrestre were significantly separated. The speciation of true dermatophytes resulted most likely from a very recent evolution by adaptation to parasitism. Among species used as outgroups, the two emerging pathogens Pseudallescheria boydii (Scedosporium apiospermum) and Scedosporium prolificans (Scedosporium inflatum) were shown to be closely related to each other.

Plasmids and phase variation in Xenorhabdus spp.

Three strains of Xenorhabdus nematophilus (A24, F1, NC116) and strain Dan of Xenorhabdus bovienii were tested to evaluate whether the phase variation observed in these bacteria was in any way connected with plasmids. The plasmid patterns of both phases of A24 and F1 strains were the same, whereas the two NC116 phases had only one band each. No difference was observed between the undigested or digested plasmid patterns of the two phases from the three strains. No plasmid was detected in either phase of strain Dan. The plasmid probes were prepared from the six bands of A24 phase 1. By hybridization studies, three plasmids in two forms (open circular and supercoiled) were detected in the strain A24. Two were estimated at 12 kb, and the smallest was about 4 kb. Attempts to hybridize plasmid probes with either undigested or digested chromosomal DNA of the two phases of strain A24 were unsuccessful. The results suggest that neither a difference in plasmid content nor a plasmid recombination with the chromosome is involved in phase variation. The hybridizations revealed homologous DNA sequences among the three plasmids of strain A24 and among the plasmids of strains such as A24 and NC116, which were isolated from geographically distant countries, suggesting that plasmids may encode similar proteins.