Recent Advances in Molecular Genetic Tools for Babesia

Development of in vitro culture and completion of genome sequencing of several Babesia parasites promoted the efforts to establish transfection systems for these parasites to dissect the gene functions. It has been more than a decade since the establishment of first transfection for Babesia bovis, the causative agent of bovine babesiosis. However, the number of genes that were targeted by genetic tools in Babesia parasites is limited. This is partially due to the low efficiencies of these methods. The recent adaptation of CRISPR/Cas9 for genome editing of Babesia bovis can accelerate the efforts for dissecting this parasite’s genome and extend the knowledge on biological aspects of erythrocytic and tick stages of Babesia. Additionally, glmS ribozyme as a conditional knockdown system is available that could be used for the characterization of essential genes. The development of high throughput genetic tools is needed to dissect the function of multigene families, targeting several genes in a specific pathway, and finally genome-wide identification of essential genes to find novel drug targets. In this review, we summarized the current tools that are available for Babesia and the genes that are being targeted by these tools. This may draw a perspective for the future development of genetic tools and pave the way for the identification of novel drugs or vaccine targets.

Involvement of translocon complex in hemoglobin import from infected erythrocyte cytoplasm into the Plasmodium parasite

Haemoglobin degradation is crucial for the growth and survival of Plasmodium falciparum in human erythrocytes. Although the process of Hb degradation has been studied in great detail, the mechanisms of Hb uptake remain ambiguous to date. Here, we characterized Heme Detoxification Protein (PfHDP), a protein localized in the parasitophorous vacuole, parasite food vacuole and infected erythrocyte cytosol for its role in Hb uptake. Immunoprecipitation of PfHDP-GFP fusion protein from a transgenic line using anti-GFP antibody and of Plasmodium parasite extract using anti-human Hb antibodies respectively, showed the association of PfHDP/Hb with each other as well as with the members of PTEX translocon complex. Some of these associations such as PfHDP/Hb and PfHDP/Pfexp-2 interactions were confirmed by in vitro protein-protein interaction tools. To know the roles of PfHDP and translocon complex in Hb import into the parasites, we next studied the Hb uptake by the parasite in PfHDP knock-down line using the GlmS ribozyme strategy. PfHDP knock-down significantly reduced the Hb uptake in these parasites in comparison to the wild type parasites. Further, the transient knock-down of one of the members of the translocon complex; PfHSP101 showed considerable reduction in Hb uptake. Morphological analysis of PfHDP-HA-GlmS transgenic parasites in the presence of GlcN showed food vacuole abnormalities and parasite stress, thereby causing a growth defect in the development of these parasites. Together, we implicate the translocon complex in the trafficking of PfHDP/Hb complex in the parasite and suggest a role for PfHDP in the uptake of Hb and parasite development. The study thus reveals new insights into the function of PfHDP, making it an extremely important target for developing new antimalarials.

Protein abundance and folding rather than the redox state of Kelch13 determine the artemisinin susceptibility of Plasmodium falciparum

Decreased susceptibilities of Plasmodium falciparum towards the endoperoxide antimalarial artemisinin are linked to mutations of residue C580 of Kelch13, which is the homologue of the redox sensor Keap1 in vertebrates. Here, we addressed whether mutations alter the artemisinin susceptibility by modifying the redox properties of Kelch13 or by compromising its native fold or abundance. Using selection-linked integration and the glmS ribozyme, efficient down-regulation of Kelch13 resulted in ring-stage survival rates around 40%. While the loss of a potential disulfide bond between residues C580 and C532 had no effect on the artemisinin suceptibility, the thiol group of C473 could not be replaced. We also established a protocol for the production of recombinant Kelch13. In contrast to cysteine-to-serine replacements, common field mutations resulted in misfolded and insoluble protein. In summary, not the redox properties but impaired folding of Kelch13, resulting in a decreased Kelch13 abundance, is the central parameter for mutant selection.

Testing the CRISPR-Cas9 and glmS ribozyme systems in Leishmania tarentolae

Leishmania parasites include important pathogens and model organisms and are even used for the production of recombinant proteins. However, functional genomics and the characterization of essential genes are often limited in Leishmania because of low-throughput technologies for gene disruption or tagging and the absence of components for RNA interference. Here, we tested the T7 RNA polymerase-dependent CRISPR-Cas9 system by Beneke et al. and the glmS ribozyme-based knock-down system in the model parasite Leishmania tarentolae. We successfully deleted two reference genes encoding the flagellar motility factor Pf16 and the salvage-pathway enzyme adenine phosphoribosyltransferase, resulting in immotile and drug-resistant parasites, respectively. In contrast, we were unable to disrupt the gene encoding the mitochondrial flavoprotein Erv. Cultivation of L. tarentolae in standard BHI medium resulted in a constitutive down-regulation of an episomal mCherry-glmS reporter by 40 to 60%. For inducible knock-downs, we evaluated the growth of L. tarentolae in alternative media and identified supplemented MEM, IMDM and McCoy’s 5A medium as candidates. Cultivation in supplemented MEM allowed an inducible, glucosamine concentration-dependent down-regulation of the episomal mCherry-glmS reporter by more than 70%. However, chromosomal glmS-tagging of the genes encoding Pf16, adenine phosphoribosyltransferase or Erv did not reveal a knock-down phenotype. Our data demonstrate the suitability of the CRISPR-Cas9 system for the disruption and tagging of genes in L. tarentolae as well as the limitations of the glmS system, which was restricted to moderate efficiencies for episomal knock-downs and caused no detectable phenotype for chromosomal knock-downs.

Overexpression of the HECT ubiquitin ligase PfUT prolongs the intraerythrocytic cycle and reduces invasion efficiency of Plasmodium falciparum

The glms ribozyme system has been used as an amenable tool to conditionally control expression of genes of interest. It is generally assumed that insertion of the ribozyme sequence does not affect expression of the targeted gene in the absence of the inducer glucosamine-6-phosphate, although experimental support for this assumption is scarce. Here, we report the unexpected finding that integration of the glms ribozyme sequence in the 3′ untranslated region of a gene encoding a HECT E3 ubiquitin ligase, termed Plasmodium falciparum ubiquitin transferase (PfUT), increased steady state RNA and protein levels 2.5-fold in the human malaria parasite P. falciparum. Overexpression of pfut resulted in an S/M phase-associated lengthening of the parasite’s intraerythrocytic developmental cycle and a reduced merozoite invasion efficiency. The addition of glucosamine partially restored the wild type phenotype. Our study suggests a role of PfUT in controlling cell cycle progression and merozoite invasion. Our study further raises awareness regarding unexpected effects on gene expression when inserting the glms ribozyme sequence into a gene locus.