Molecular identification and phylogenetic relationships of trichomonad isolates of galliform birds inferred from nuclear small subunit rRNA gene sequences.

Histomonas meleagridis is the etiological agent of histomonosis or blackhead disease. Recently, genotyping, based on polymerase chain reaction and sequencing of internal transcribed spacer-1 sequences was applied to various isolates originating from fowl. Three genotypes were described: types I and II isolates were associated with clinical disease and probably derived from H. meleagridis, whereas, type III isolates were not disease-associated and likely corresponded to Parahistomonas wenrichi according to morphological observations. However, this latter species has never been characterized at the molecular level and its phylogenetic relationships with other parabasalids remained hypothetical. To confirm the identification of these isolates, small subunit rRNA gene sequences were obtained from representatives of types I, II, and III and analyzed in a broad phylogeny including 64 other parabasalid sequences. From our phylogenetic trees, we confirmed that types I and II isolates were closely related, if not identical, to H. meleagridis, while type III isolates represented P. wenrichi. Both species clustered together with high support. This grouping suggested that speciation leading to these two species inhabiting the same hosts and ecological niche occurred recently in birds. In addition, speciation was likely followed by loss of pathogenicity in P. wenrichi.

The class I histone deacetylases of the platyhelminth parasite Schistosoma mansoni.

Histone deacetylases (HDAC) form a conserved enzyme family that control gene expression via the removal of acetyl residues from histones and other proteins and are under increasing investigation as therapeutic targets, notably in cancer and parasitic diseases. To investigate the conservation of these enzymes in the platyhelminth parasite Schistosoma mansoni, we cloned and characterized three class I HDACs, orthologues of mammalian HDAC1, 3 and 8, and confirmed their identities by phylogenetic analysis. The identification of an HDAC8 orthologue showed that it is not vertebrate-specific as previously thought and insertions in its catalytic domain suggest specific enzymatic properties. SmHDAC1, 3, and 8 mRNAs are expressed at all schistosome life-cycle stages. SmHDAC1 repressed transcriptional activity in a mammalian cell line and this activity was dependent on its catalytic activity since transcription was partially restored by treatment with trichostatin A and a catalytic site mutant failed to repress transcription.

Molecular cloning and characterization of Schistosoma mansoni Ftz-F1 interacting protein-1 (SmFIP-1), a novel corepressor of the nuclear receptor SmFtz-F1.

In order to characterize protein cofactors of the Schistosoma mansoni nuclear receptor SmFtz-F1, we have screened a yeast two-hybrid adult worm cDNA library using a construct expressing the D, E and F domains of SmFtz-F1 as bait. One of the selected clones encoded a sequence without homologues in any other species, apart from Schistosoma japonicum. The complete sequence was obtained by 5' and 3' rapid amplification of cDNA ends (RACE) and comprised 3660 nucleotides with an open reading frame of 788 amino acids. The gene is expressed at all schistosome life cycle stages at a 5-11-fold higher level than SmFtz-f1. The protein, named SmFIP-1, interacted with SmFtz-F1 in a GST pull-down assay and in a mammalian two-hybrid assay in CV-1 cells. Although SmFIP-1 contains a consensus NR box (LXXLL) this was not involved in the interaction with SmFtz-F1. However, interaction did depend on the AF2-AD motif in the nuclear receptor ligand binding domain. Deletion analysis showed that the C-terminal moiety of SmFIP-1 was involved in the binding, but this could not be localized to a particular motif, suggesting that the binding may be conformation-dependent. Finally, SmFIP-1 markedly repressed SmFtz-F1-mediated transcription in a dose-dependent manner from the SmFtz-f1 gene promoter demonstrating that SmFIP-1 is a schistosome-specific transcriptional corepressor.

Schistosoma mansoni CBP/p300 has a conserved domain structure and interacts functionally with the nuclear receptor SmFtz-F1.

Metazoan species diversification in general and the adaptation of parasites to their life-style in particular are due, not only to the evolution of different structural or metabolic proteins, but also to changes in the expression patterns of the corresponding genes. In order to explore the conservation/divergence of transcriptional regulation in the platyhelminth parasite Schistosoma mansoni, we are studying the structures and functions of transcriptional mediators. CREB-binding protein (CBP) and p300 are closely related transcriptional coactivators that possess histone acetyltransferase (HAT) activity that can modify chromatin to an active relaxed state. They are also thought to link transcription factors to the basic transcriptional machinery and to act as integrators for different regulatory pathways. Here we describe the cloning and functional characterization of S. mansoni CBP. SmCBP1 comprises 2093 amino acids and displays a conserved modular domain structure. The HAT domain was shown to acetylate histones with a marked activity toward H4. Functional studies showed that SmCBP1 could interact physically with the nuclear receptor SmFtz-F1 and also potentiated its transcriptional activity in the CV-1 cell line. Screening of the EST and genomic sequence databases with the SmCBP1 sequence allowed us to characterize a second CBP gene in S. mansoni. SmCBP2 shows a high degree of sequence identity to SmCBP1, particularly in the HAT domain. Phylogenetic studies show that these peptides are more closely related to each other than to either mammalian CBP or p300, suggesting that they derive from a platyhelminth-specific duplication event. Both genes are expressed at all life-cycle stages, but differences in their relative expression and structural variations suggest that they play distinct roles in schistosome gene regulation.

Evidence for a dispersed Hox gene cluster in the platyhelminth parasite Schistosoma mansoni.

In most bilaterian organisms so far studied, Hox genes are organized in genomic clusters and determine development along the anteroposterior axis. It has been suggested that this clustering, together with spatial and temporal colinearity of gene expression, represents the ancestral condition. However, in organisms with derived modes of embryogenesis and lineage-dependent mechanisms for the determination of cell fate, temporal colinearity of expression can be lost and Hox cluster organization disrupted, as is the case for the ecdysozoans Drosophila melanogaster and Caenorhabditis elegans and the urochordates Ciona intestinalis and Oikopleura dioica. We sought to determine whether a lophotrochozoan, the platyhelminth parasite Schistosoma mansoni, possesses a conserved or disrupted Hox cluster. Using a polymerase chain reaction (PCR)-based strategy, we have cloned and characterized three novel S. mansoni genes encoding orthologues of Drosophila labial (SmHox1), deformed (SmHox4), and abdominal A (SmHox8), as well as the full-length coding sequence of the previously described Smox1, which we identify as an orthologue of fushi tarazu. Quantitative reverse transcriptase-PCR showed that the four genes were expressed at all life-cycle stages but that levels of expression were differentially regulated. Phylogenetic analysis and the conservation of "parapeptide" sequences C-terminal to the homeodomains of SmHox8 and Smox1 support the grouping of platyhelminths within the lophotrochozoan clade. However, Bacterial Artificial Chromosome (BAC) library screening followed by genome walking failed to reconstitute a cluster. The BAC clones containing Hox genes were sequenced, and in no case were other Hox genes found on the same clone. Moreover, the SmHox4 and SmHox8 genes contained single very large introns (>40 kbp) further indicating that the schistosome Hox cluster is highly extended. Localization of the Hox genes to chromosomes using fluorescence in situ hybridization showed that SmHox4 and SmHox8 are on the long arm of chromosome 4, whereas SmHox1 and Smox1 are on chromosome 3. In silico screening of the available genome sequences corroborated results of Southern blotting and BAC library screening that indicate that there are no paralogues of SmHox1, SmHox4, or SmHox8. The schistosome Hox cluster is therefore not duplicated, but is both dispersed and disintegrated in the genome.

Unique functional properties of a member of the Fushi Tarazu-Factor 1 family from Schistosoma mansoni.

SmFtz-F1 (Schistosoma mansoni Fushi Tarazu-Factor 1) belongs to the Ftz-F1 subfamily of nuclear receptors, but displays marked structural differences compared with its mammalian homologues SF-1 (steroidogenic factor-1) or liver receptor homologue-1. These include a long F domain (104 amino acids), an unusually large hinge region (133 amino acids) and a poorly conserved E-domain. Here, using Gal4 constructs and a mammalian two-hybrid assay, we have characterized the roles of these specific regions both in the transcriptional activity of the receptor and in its interactions with cofactors. Our results have shown that, although the AF-2 (activation function-2) region is the major activation function of the receptor, both the F and D domains are essential for AF-2-dependent activity. Modelling of SmFtz-F1 LBD (ligand-binding domain) and structure-guided mutagenesis allowed us to show the important role of helix H1 in maintaining the structural conformation of the LBD, and suggested that its autonomous transactivation activity, also observed with SF-1, is fortuitous. This strategy also allowed us to study an eventual ligand-dependence for this orphan receptor, the predicted three-dimensional models suggesting that the SmFtz-F1 LBD contains a large and well-defined ligand-binding pocket sealed by two arginine residues orientated towards the interior of the cavity. Mutation of these two residues provoked a loss of transcriptional activity of the receptor, and strongly reduced its interaction with SRC1 (steroid receptor cofactor-1), suggesting a ligand-dependent activity for SmFtz-F1. Taken together, our results argue for original and specific functional activities for this platyhelminth nuclear receptor.

A functionally conserved member of the FTZ-F1 nuclear receptor family from Schistosoma mansoni.

The fushi tarazu factor 1 (FTZ-F1) nuclear receptor subfamily comprises orphan receptors with crucial roles in development and sexual differentiation in vertebrates and invertebrates. We describe the structure and functional properties of an FTZ-F1 from the platyhelminth parasite of humans, Schistosoma mansoni, the first receptor from this family to be characterized in a Lophotrochozoan. It contains a well conserved DNA-binding domain (55-63% identity to other family members) and a poorly conserved ligand-binding domain (20% identity to that of zebrafish FF1a). However, both the ligand domain signature sequence and the activation function 2-activation domain (AF2-AD) are perfectly conserved. Phylogenetic analysis confirmed that SmFTZ-F1 is a member of nuclear receptor subfamily 5, but that it clustered with the Drosophila receptor DHR39 and has consequently been named NR5B1. The gene showed a complex structure with 10 exons and an overall size of 18.4 kb. Two major transcripts were detected, involving alternative promoter usage and splicing of the two 5' exons, but which encoded identical proteins. SmFTZ-F1 mRNA is expressed at all life-cycle stages with the highest amounts in the larval forms (miracidia, sporocysts and cercariae). However, expression of the protein showed a different pattern; low in miracidia and higher in adult male worms. The protein bound the same monomeric response element as mammalian SF-1 (SF-1 response element, SFRE) and competition experiments with mutant SFREs showed that its specificity was identical. Moreover, SmFTZ-F1 transactivated reporter gene transcription from SFRE similarly to SF-1. This functional conservation argues for a conserved biological role of the FTZ-F1 nuclear receptor family throughout the metazoa.