Diverse microbial ecosystems underpin life in the sea. Among these microbes are many unicellular eukaryotes that span the diversity of the eukaryotic tree of life. However, genetic tractability has been limited to a few species, which do not represent eukaryotic diversity or environmentally relevant taxa. Here, we report on the development of genetic tools in a range of protists primarily from marine environments. We present evidence for foreign DNA delivery and expression in 13 species never before transformed and for advancement of tools for eight other species, as well as potential reasons for why transformation of yet another 17 species tested was not achieved. Our resource in genetic manipulation will provide insights into the ancestral eukaryotic lifeforms, general eukaryote cell biology, protein diversification and the evolution of cellular pathways.
The ciliate Tetrahymena thermophila incorporates sterols from its environment that desaturates at positions C5(6), C7(8), and C22(23). Phytosterols are additionally modified by removal of the ethyl group at carbon 24 (C24). The enzymes involved are oxygen-, NAD(P)H-, and cytochrome b5 dependent, reason why they were classified as members of the hydroxylases/desaturases superfamily. The ciliate's genome revealed the presence of seven putative sterol desaturases belonging to this family, two of which we have previously characterized as the C24-de-ethylase and C5(6)-desaturase. A Rieske oxygenase was also identified; this type of enzyme, with sterol C7(8)-desaturase activity, was observed only in animals, called Neverland in insects and DAF-36 in nematodes. They perform the conversion of cholesterol into 7-dehydrocholesterol, first step in the synthesis of the essential hormones ecdysteroids and dafachronic acids. By adapting an RNA interference-by-feeding protocol, we easily screened six of the eight genes described earlier, allowing the characterization of the Rieske-like oxygenase as the ciliate's C7(8)-desaturase (Des7p). This characterization was confirmed by obtaining the corresponding knockout mutant, making Des7p the first nonanimal Rieske-sterol desaturase described. To our knowledge, this is the first time that the feeding-RNAi technique was successfully applied in T. thermophila, enabling to consider such methodology for future reverse genetics high-throughput screenings in this ciliate. Bioinformatics analyses revealed the presence of Des7p orthologs in other Oligohymenophorean ciliates and in nonanimal Opisthokonts, like the protists Salpingoeca rosetta and Capsaspora owczarzaki. A horizontal gene transfer event from a unicellular Opisthokont to an ancient phagotrophic Oligohymenophorean could explain the acquisition of the Rieske oxygenase by Tetrahymena.
How animals emerged from their unicellular ancestor remains a major evolutionary question. New genome data from the closest unicellular relatives of animals have provided important insights into the evolution of animal multicellularity. We know that the unicellular ancestor of animals had an unexpectedly complex genetic repertoire, including many genes that are key to animal development and multicellularity. Thus, assessing the function of these genes among unicellular relatives of animals is key to understanding how they were co-opted at the onset of the Metazoa. However, such analyses have been hampered by the lack of genetic tools. Progress has been made in choanoflagellates and teretosporeans, two of the three lineages closely related to animals, whereas no tools are yet available for functional analysis in the third lineage: the filastereans. Importantly, filastereans have a striking repertoire of genes involved in transcriptional regulation and other developmental processes. Here, we describe a reliable transfection method for the filasterean Capsaspora owczarzaki. We also provide a set of constructs for visualising subcellular structures in live cells. These tools convert Capsaspora into a unique experimentally tractable organism to use to investigate the origin and evolution of animal multicellularity.
Opisthokonta represents a major lineage of eukaryotes and includes fungi and metazoans, as well as other less known unicellular groups. The latter are paraphyletic assemblages that branch in between the former two groups, and thus are important for understanding the origin and early diversification of opisthokonts. The full range of their diversity, however, has not yet been explored from diverse ecological habitats. Freshwater environments are crucial sources for new diversity; they are considered even more heterogeneous than marine ecosystems. This heterogeneity implies more ecological niches where local eukaryotic communities are located. However, knowledge of the unicellular opisthokont diversity is scarce from freshwater environments. Here, we performed an 18S rDNA metabarcoding study in the Middle Paraná River, Argentina, to characterize the molecular diversity of microbial eukaryotes, in particular unicellular members of Opisthokonta. We identified a potential novel clade branching as a sister-group to Fungi. We also detected in our data that more than 60% operational taxonomic units classified as unicellular holozoans (animals and relatives) represent new taxa at the species level. Of the remaining, the majority was assigned to the newly described holozoan species, Syssomonas multiformis. Together, our results show that a large hidden diversity of unicellular members of opisthokonts still remain to be uncovered. We also found that the geographical and ecological distribution of several taxa considered exclusive to marine environments is wider than previously thought.
Background The opportunistic pathogen Naegleria fowleri establishes infection in the human brain, killing almost invariably within 2 weeks. The amoeba performs piece-meal ingestion, or trogocytosis, of brain material causing direct tissue damage and massive inflammation. The cellular basis distinguishing N. fowleri from other Naegleria species, which are all non-pathogenic, is not known. Yet, with the geographic range of N. fowleri advancing, potentially due to climate change, understanding how this pathogen invades and kills is both important and timely. Results Here, we report an -omics approach to understanding N. fowleri biology and infection at the system level. We sequenced two new strains of N. fowleri and performed a transcriptomic analysis of low- versus high-pathogenicity N. fowleri cultured in a mouse infection model. Comparative analysis provides an in-depth assessment of encoded protein complement between strains, finding high conservation. Molecular evolutionary analyses of multiple diverse cellular systems demonstrate that the N. fowleri genome encodes a similarly complete cellular repertoire to that found in free-living N. gruberi. From transcriptomics, neither stress responses nor traits conferred from lateral gene transfer are suggested as critical for pathogenicity. By contrast, cellular systems such as proteases, lysosomal machinery, and motility, together with metabolic reprogramming and novel N. fowleri proteins, are all implicated in facilitating pathogenicity within the host. Upregulation in mouse-passaged N. fowleri of genes associated with glutamate metabolism and ammonia transport suggests adaptation to available carbon sources in the central nervous system. Conclusions In-depth analysis of Naegleria genomes and transcriptomes provides a model of cellular systems involved in opportunistic pathogenicity, uncovering new angles to understanding the biology of a rare but highly fatal pathogen.
The gene coding for a C-5(6) sterol desaturase in Tetrahymena thermophila, DES5A, has been identified by the knockout of the TTHERM_01194720 sequence. Macronucleus transformation was achieved by biolistic bombardment and gene replacement through phenotypic assortment, using paromomycin as the selective agent. A knockout cell line (KO270) showed a phenotype consistent with that of the DES5A deletion mutant. KO270 converted only 6% of the added sterol into the C-5 unsaturated derivative, while the wild type accumulated 10-fold larger amounts under similar conditions. The decreased desaturation activity is specific for the C-5(6) position of lathosterol and cholestanol; other desaturations, namely C-7(8) and C-22(23), were not affected. Analysis by reverse transcription-PCR reveals that DES5A is transcribed both in the presence and absence of cholestanol in wild-type cells, whereas the transcribed gene was not detected in KO270. The growth of KO270 was undistinguishable from that of the wild-type strain. Des5Ap resembles known C-5(6) sterol desaturases, displaying the three typical histidine motifs, four hydrophobic transmembrane regions, and two other highly conserved domains of unknown function. A phylogenetic analysis placed T. thermophila's enzyme and Paramecium orthologues in a cluster together with functionally characterized C-5 sterol desaturases from vertebrates, fungi, and plants, although in a different branch.Tetrahymena thermophila is a fresh-water protozoan that has been used successfully as a model system in cell biology (8). The advanced molecular and genetic tools developed for Tetrahymena have facilitated fundamental discoveries, such as the first descriptions of ribozymes, telomeres, and telomerases, thereby maintaining this organism at the forefront of fundamental research (2,11,30).Conner et al. (5, 6) described the peculiar sterol metabolism in Tetrahymena that leads to the accumulation of provitamin D analogs due to the C-5(6), C-7(8), and C-22(23) sterol-desaturating activities present in the organism (Fig. 1). The transformation of cholesterol to the C-7 unsaturated derivative (provitamin D 3 [cholest-5,7-dien-3-ol]) particularly has attracted attention because of pharmaceutical and food-related applications (28, 29) to decrease the cholesterol content in foodstuffs and the coupled production of provitamin D 3 in a single step (27). Despite the potential societal impact, progress on the isolation and purification of desaturases has been modest, mainly due to the loss of enzyme activity upon the dissociation of microsomal complexes (13).The preliminary characterization of sterol-desaturating activities in T. thermophila indicated that the corresponding enzymes are located in the microsomal fraction and require cytochrome (Cyt) b 5 , Cyt b 5 reductase, oxygen, and a reduced cofactor (NADH) (17). These biochemical requirements are characteristic of sterol C-5(6) desaturases and C-4 methyl oxidases (14). By using amino acid sequences of known C-5 desaturases as queries, eight putative desaturas...
The gene TTHERM_00438800 (DES24) from the ciliate Tetrahymena thermophila encodes a protein with three conserved histidine clusters, typical of the fatty acid hydroxylase superfamily. Despite its high similarity to sterol desaturase-like enzymes, the phylogenetic analysis groups Des24p in a separate cluster more related to bacterial than to eukaryotic proteins, suggesting a possible horizontal gene transfer event. A somatic knockout of DES24 revealed that the gene encodes a protein, Des24p, which is involved in the dealkylation of phytosterols. Knocked-out mutants were unable to eliminate the C-24 ethyl group from C 29 sterols, whereas the ability to introduce other modifications, such as desaturations at positions C-5(6), C-7(8), and C-22(23), were not altered. Although C-24 dealkylations have been described in other organisms, such as insects, neither the enzymes nor the corresponding genes have been identified to date. Therefore, this is the first identification of a gene involved in sterol dealkylation. Moreover, the knockout mutant and wild-type strain differed significantly in growth and morphology only when cultivated with C 29 sterols; under this culture condition, a change from the typical pear-like shape to a round shape and an alteration in the regulation of tetrahymanol biosynthesis were observed. Sterol analysis upon culture with various substrates and inhibitors indicate that the removal of the C-24 ethyl group in Tetrahymena may proceed by a mechanism different from the one currently known.Sterols are lipophilic membrane components essential for the structural integrity of most eukaryotic cells. Together with phospholipids, they regulate the fluidity of the lipid bilayers and permeability barrier properties (4); they also serve as precursors of bile salts and a number of different steroid hormones in mammals, brassinosteroids in plants and fungi (2), and ecdysteroids in arthropods (14). Sterols are also actively involved in the modulation of cell signaling, in the transport and distribution of lipophilic molecules, and in the formation of lipid rafts (22).For most organisms in which sterols are de novo synthesized, such as vertebrates (cholesterol), plants (stigmasterol, -sitosterol, and campesterol), and fungi (ergosterol), the enzymes involved have been well identified and characterized. Most of them can be grouped into four families of proteins: (i) the cytochrome b 5 (Cytb 5 )-dependent fatty acid hydroxylase superfamily, composed of C-5 sterol desaturases (erg3), C-4 sterol methyl oxidases (erg25), and cholesterol 25-hydroxylases; (ii) the S-adenosyl-L-methionine sterol methyltransferase (SMT) family, composed of the SMT1 and SMT2 types, which are typical in plants, and C-24 sterol methyltransferase, which has been described for fungi (erg6); (iii) the highly hydrophobic reductases, which include C-7, C-14, and C-24 sterol reductases; and (iv) the cytochrome P450 family, with C-22 sterol desaturases (erg5) and C-14 sterol demethylases (erg11) as its main representatives. Other eukaryotic org...
Genes and genomes can evolve through interchanging genetic material, this leading to reticular evolutionary patterns. However, the importance of reticulate evolution in eukaryotes, and in particular of horizontal gene transfer (HGT), remains controversial. Given that metabolic pathways with taxonomically-patchy distributions can be indicative of HGT events, the eukaryotic nitrate assimilation pathway is an ideal object of investigation, as previous results revealed a patchy distribution and suggested that the nitrate assimilation cluster of dikaryotic fungi (Opisthokonta) could have been originated and transferred from a lineage leading to Oomycota (Stramenopiles). We studied the origin and evolution of this pathway through both multi-scale bioinformatic and experimental approaches. Our taxon-rich genomic screening shows that nitrate assimilation is present in more lineages than previously reported, although being restricted to autotrophs and osmotrophs. The phylogenies indicate a pervasive role of HGT, with three bacterial transfers contributing to the pathway origin, and at least seven well-supported transfers between eukaryotes. In particular, we propose a distinct and more complex HGT path between Opisthokonta and Stramenopiles than the one previously suggested, involving at least two transfers of a nitrate assimilation gene cluster. We also found that gene fusion played an essential role in this evolutionary history, underlying the origin of the canonical eukaryotic nitrate reductase, and of a chimeric nitrate reductase in Ichthyosporea (Opisthokonta). We show that the ichthyosporean pathway, including this novel nitrate reductase, is physiologically active and transcriptionally co-regulated, responding to different nitrogen sources; similarly to distant eukaryotes with independent HGT-acquisitions of the pathway. This indicates that this pattern of transcriptional control evolved convergently in eukaryotes, favoring the proper integration of the pathway in the metabolic landscape. Our results highlight the importance of reticulate evolution in eukaryotes, by showing the crucial contribution of HGT and gene fusion in the evolutionary history of the nitrate assimilation pathway.
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