Experimental Genetics of Plasmodium berghei NFU in the Apicoplast Iron-Sulfur Cluster Biogenesis Pathway

Eukaryotic pathogens of the phylum Apicomplexa contain a non-photosynthetic plastid, termed apicoplast. Within this organelle distinct iron-sulfur [Fe-S] cluster proteins are likely central to biosynthesis pathways, including generation of isoprenoids and lipoic acid. Here, we targeted a nuclear-encoded component of the apicoplast [Fe-S] cluster biosynthesis pathway by experimental genetics in the murine malaria parasite Plasmodium berghei. We show that ablation of the gene encoding a nitrogen fixation factor U (NifU)-like domain containing protein (NFUapi) resulted in parasites that were able to complete the entire life cycle indicating redundant or non-essential functions. nfu ^– parasites displayed reduced merosome formation in vitro, suggesting that apicoplast NFUapi plays an auxiliary role in establishing a blood stage infection. NFUapi fused to a combined fluorescent protein-epitope tag delineates the Plasmodium apicoplast and was tested to revisit inhibition of liver stage development by azithromycin and fosmidomycin. We show that the branched apicoplast signal is entirely abolished by azithromycin treatment, while fosmidomycin had no effect on apicoplast morphology. In conclusion, our experimental genetics analysis supports specialized and/or redundant role(s) for NFUapi in the [Fe-S] cluster biosynthesis pathway in the apicoplast of a malarial parasite.     

Plasmodium pyruvate dehydrogenase activity is only essential for the parasite's progression from liver infection to blood infection

Plasmodium parasites possess a single pyruvate dehydrogenase (PDH) enzyme complex that is localized to the plastid‐like organelle known as the apicoplast. Unlike most eukaryotes, Plasmodium parasites lack a mitochondrial PDH. The PDH complex catalyses the conversion of pyruvate to acetyl‐CoA, an important precursor for the tricarboxylic acid cycle and type II fatty acid synthesis (FAS II). In this study, using a rodent malaria model, we show that the PDH E1α and E3 subunits colocalize with the FAS II enzyme FabI in the apicoplast of liver stages but are not significantly expressed in blood stages. Deletion of the E1α or E3 subunit genes of Plasmodium yoelii PDH caused no defect in blood stage development, mosquito stage development or early liver stage development. However, the gene deletions completely blocked the ability of the e1α^‐ and e3^‐ parasites to form exo‐erythrocytic merozoites during late liver stage development, thus preventing the initiation of a blood stage infection. This phenotype is similar to that observed for deletions of genes involved in FAS II elongation. The data strongly support the hypothesis that the sole role of PDH is to provide acetyl‐CoA for FAS II.     

Enzymes involved in plastid‐targeted phosphatidic acid synthesis are essential for Plasmodium yoelii liver‐stage development

Malaria parasites scavenge nutrients from their host but also harbour enzymatic pathways for de novo macromolecule synthesis. One such pathway is apicoplast‐targeted type II fatty acid synthesis, which is essential for late liver‐stage development in rodent malaria. It is likely that fatty acids synthesized in the apicoplast are ultimately incorporated into membrane phospholipids necessary for exoerythrocytic merozoite formation. We hypothesized that these synthesized fatty acids are being utilized for apicoplast‐targeted phosphatidic acid synthesis, the phospholipid precursor. Phosphatidic acid is typically synthesized in a three‐step reaction utilizing three enzymes: glycerol 3‐phosphate dehydrogenase, glycerol 3‐phosphate acyltransferase and lysophosphatidic acid acyltransferase. The Plasmodium genome is predicted to harbour genes for both apicoplast‐ and cytosol/endoplasmic reticulum‐targeted phosphatidic acid synthesis. Our research shows that apicoplast‐targeted Plasmodium yoelii glycerol 3‐phosphate dehydrogenase and glycerol 3‐phosphate acyltransferase are expressed only during liver‐stage development and deletion of the encoding genes resulted in late liver‐stage growth arrest and lack of merozoite differentiation. However, the predicted apicoplast‐targeted lysophosphatidic acid acyltransferase gene was refractory to deletion and was expressed solely in the endoplasmic reticulum throughout the parasite life cycle. Our results suggest that P. yoelii has an incomplete apicoplast‐targeted phosphatidic acid synthesis pathway that is essential for liver‐stage maturation.     

Characterization of the Plasmodium falciparum and P. berghei glycerol 3‐phosphate acyltransferase involved in FASII fatty acid utilization in the malaria parasite apicoplast

Malaria parasites can synthesize fatty acids via a type II fatty acid synthesis (FASII) pathway located in their apicoplast. The FASII pathway has been pursued as an anti‐malarial drug target, but surprisingly little is known about its role in lipid metabolism. Here we characterize the apicoplast glycerol 3‐phosphate acyltransferase that acts immediately downstream of FASII in human (Plasmodium falciparum) and rodent (Plasmodium berghei) malaria parasites and investigate how this enzyme contributes to incorporating FASII fatty acids into precursors for membrane lipid synthesis. Apicoplast targeting of the P. falciparum and P. berghei enzymes are confirmed by fusion of the N‐terminal targeting sequence to GFP and 3′ tagging of the full length protein. Activity of the P. falciparum enzyme is demonstrated by complementation in mutant bacteria, and critical residues in the putative active site identified by site‐directed mutagenesis. Genetic disruption of the P. falciparum enzyme demonstrates it is dispensable in blood stage parasites, even in conditions known to induce FASII activity. Disruption of the P. berghei enzyme demonstrates it is dispensable in blood and mosquito stage parasites, and only essential for development in the late liver stage, consistent with the requirement for FASII in rodent malaria models. However, the P. berghei mutant liver stage phenotype is found to only partially phenocopy loss of FASII, suggesting newly made fatty acids can take multiple pathways out of the apicoplast and so giving new insight into the role of FASII and apicoplast glycerol 3‐phosphate acyltransferase in malaria parasites.     

Mitochondrial lipoic acid scavenging is essential for Plasmodium berghei liver stage development

Lipoic acid is an essential cofactor for enzymes that participate in key metabolic pathways in most organisms. While in mammalian cells lipoylated proteins reside exclusively in the mitochondria, apicomplexan parasites of the genus Plasmodium harbour two independent lipoylation pathways in the mitochondrion and the apicoplast, a second organelle of endosymbiotic origin. Protein lipoylation in the apicoplast relies on de novo lipoic acid synthesis while lipoylation of proteins in the mitochondrion depends on scavenging of lipoic acid from the host cell. Here, we analyse the impact of lipoic acid scavenging on the development of Plasmodium berghei liver stage parasites. Treatment of P. berghei-infected HepG2 cells with the lipoic acid analogue 8-bromo-octanoic acid (8-BOA) abolished lipoylation of mitochondrial enzyme complexes in the parasite while lipoylation of apicoplast proteins was not affected. Parasite growth as well as the ability of the parasites to successfully complete liver stage development by merosome formation were severely impaired but not completely blocked by 8-BOA. Liver stage parasites were most sensitive to 8-BOA treatment during schizogony, the phase of development when the parasite grows and undergoes extensive nuclear division to form a multinucleated syncytium. Live cell imaging as well as immunofluorescence analysis and electronmicroscopy studies revealed a close association of both host cell and parasite mitochondria with the parasitophorous vacuole membrane suggesting that host cell mitochondria might be involved in lipoic acid uptake by the parasite from the host cell.     

Knockout Studies Reveal an Important Role of Plasmodium Lipoic Acid Protein Ligase A1 for Asexual Blood Stage Parasite Survival

Lipoic acid (LA) is a dithiol-containing cofactor that is essential for the function of α-keto acid dehydrogenase complexes. LA acts as a reversible acyl group acceptor and ‘swinging arm’ during acyl-coenzyme A formation. The cofactor is post-translationally attached to the acyl-transferase subunits of the multienzyme complexes through the action of octanoyl (lipoyl): N-octanoyl (lipoyl) transferase (LipB) or lipoic acid protein ligases (LplA). Remarkably, apicomplexan parasites possess LA biosynthesis as well as scavenging pathways and the two pathways are distributed between mitochondrion and a vestigial organelle, the apicoplast. The apicoplast-specific LipB is dispensable for parasite growth due to functional redundancy of the parasite''s lipoic acid/octanoic acid ligases/transferases. In this study, we show that LplA1 plays a pivotal role during the development of the erythrocytic stages of the malaria parasite. Gene disruptions in the human malaria parasite P. falciparum consistently were unsuccessful while in the rodent malaria model parasite P. berghei the LplA1 gene locus was targeted by knock-in and knockout constructs. However, the LplA1⁽⁻⁾ mutant could not be cloned suggesting a critical role of LplA1 for asexual parasite growth in vitro and in vivo. These experimental genetics data suggest that lipoylation during expansion in red blood cells largely occurs through salvage from the host erythrocytes and subsequent ligation of LA to the target proteins of the malaria parasite.     

GFP‐targeting allows visualization of the apicoplast throughout the life cycle of live malaria parasites

Background information. The Plasmodium parasite, during its life cycle, undergoes three phases of asexual reproduction, these being repeated rounds of erythrocytic schizogony, sporogony within oocysts on the mosquito midgut wall and exo‐erythrocytic schizogony within the hepatocyte. During each phase of asexual reproduction, the parasite must ensure that every new daughter cell contains an apicoplast, as this organelle cannot be formed de novo and is essential for parasite survival. To date, studies visualizing the apicoplast in live Plasmodium parasites have been restricted to the blood stages of Plasmodium falciparum. Results. In the present study, we have generated Plasmodium berghei parasites in which GFP (green fluorescent protein) is targeted to the apicoplast using the specific targeting sequence of ACP (acyl carrier protein), which has allowed us to visualize this organelle in live Plasmodium parasites. During each phase of asexual reproduction, the apicoplast becomes highly branched, but remains as a single organelle until the completion of nuclear division, whereupon it divides and is rapidly segregated into newly forming daughter cells. We have shown that the antimicrobial agents azithromycin, clindamycin and doxycycline block development of the apicoplast during exo‐erythrocytic schizogony in vitro, leading to impaired parasite maturation. Conclusions. Using a range of powerful live microscopy techniques, we show for the first time the development of a Plasmodium organelle through the entire life cycle of the parasite. Evidence is provided that interference with the development of the Plasmodium apicoplast results in the failure to produce red‐blood‐cell‐infective merozoites.     

Plasmodium falciparum LipB mutants display altered redox and carbon metabolism in asexual stages and cannot complete sporogony in Anopheles mosquitoes

Malaria is still one of the most important global infectious diseases. Emergence of drug resistance and a shortage of new efficient antimalarials continue to hamper a malaria eradication agenda. Malaria parasites are highly sensitive to changes in the redox environment. Understanding the mechanisms regulating parasite redox could contribute to the design of new drugs. Malaria parasites have a complex network of redox regulatory systems housed in their cytosol, in their mitochondrion and in their plastid (apicoplast). While the roles of enzymes of the thioredoxin and glutathione pathways in parasite survival have been explored, the antioxidant role of α-lipoic acid (LA) produced in the apicoplast has not been tested. To take a first step in teasing a putative role of LA in redox regulation, we analysed a mutant Plasmodium falciparum (3D7 strain) lacking the apicoplast lipoic acid protein ligase B (lipB) known to be depleted of LA. Our results showed a change in expression of redox regulators in the apicoplast and the cytosol. We further detected a change in parasite central carbon metabolism, with lipB deletion resulting in changes to glycolysis and tricarboxylic acid cycle activity. Further, in another Plasmodium cell line (NF54), deletion of lipB impacted development in the mosquito, preventing the detection of infectious sporozoite stages. While it is not clear at this point if the observed phenotypes are linked, these findings flag LA biosynthesis as an important subject for further study in the context of redox regulation in asexual stages, and point to LipB as a potential target for the development of new transmission drugs.     

Plasmodium falciparum OTU‐like cysteine protease (PfOTU) is essential for apicoplast homeostasis and associates with noncanonical role of Atg8

The metabolic pathways associated with the mitochondrion and the apicoplast in Plasmodium, 2 parasite organelles of prokaryotic origin, are considered as suitable drug targets. In the present study, we have identified functional role of a novel ovarian tumour unit (OTU) domain‐containing cysteine protease of Plasmodium falciparum (PfOTU). A C‐terminal regulatable fluorescent affinity tag on native protein was utilised for its localization and functional characterization. Detailed studies showed vesicular localization of PfOTU and its association with the apicoplast. Degradation‐tag mediated knockdown of PfOTU resulted in abnormal apicoplast development and blocked development of parasites beyond early‐schizont stages in subsequent cell cycle; downregulation of PfOTU hindered apicoplast protein import. Further, the isoprenoid precursor‐mediated parasite growth‐rescue experiments confirmed that PfOTU knockdown specifically effect development of functional apicoplast. We also provide evidence for a possible biological function of PfOTU in membrane deconjugation of Atg8, which may be linked with the apicoplast protein import. Overall, our results show that the PfOTU is involved in apicoplast homeostasis and associates with the noncanonical function of Atg8 in maintenance of parasite apicoplast.     

Apicomplexan parasites contain a single lipoic acid synthase located in the plastid

Apicomplexan parasites contain a vestigial plastid called apicoplast which has been suggested to be a site of [Fe-S] cluster biogenesis. Here we report the cloning of lipoic acid synthase (LipA) from Toxoplasma gondii, a well known [Fe-S] protein. It is able to complement a LipA-deficient Escherichia coli strain, clearly demonstrating that the parasite protein is a functional LipA. The N-terminus of T. gondii LipA is unusual with respect to an internal signal peptide preceding an apicoplast targeting domain. Nevertheless, it efficiently targets a reporter protein to the apicoplast of T. gondii whereas co-localization with the fluorescently labeled mitochondrion was not detected. In silico analysis of several apicomplexan genomes indicates that the parasites, in addition to the presumably apicoplast-resident pyruvate dehydrogenase complex, contain three other mitochondrion-localized target proteins for lipoic acid attachment. We also identified single genes for lipoyl (octanoyl)-acyl carrier protein:protein transferase (LipB) and lipoate protein ligase (LplA) in these genomes. It thus appears that unlike plants, which have only two LipA and LipB isoenzymes in both the chloroplasts and the mitochondria, Apicomplexa seem to use the second known lipoylating activity, LplA, for lipoylation in their mitochondrion.     

A novel amidotransferase required for lipoic acid cofactor assembly in Bacillus subtilis

In the companion paper we reported that Bacillus subtilis requires three proteins for lipoic acid metabolism, all of which are members of the lipoate protein ligase family. Two of the proteins, LipM and LplJ, have been shown to be an octanoyltransferase and a lipoate : protein ligase respectively. The third protein, LipL, is essential for lipoic acid synthesis, but had no detectable octanoyltransferase or ligase activity either in vitro or in vivo. We report that LipM specifically modifies the glycine cleavage system protein, GcvH, and therefore another mechanism must exist for modification of other lipoic acid requiring enzymes (e.g. pyruvate dehydrogenase). We show that this function is provided by LipL, which catalyses the amidotransfer (transamidation) of the octanoyl moiety from octanoyl‐GcvH to the E2 subunit of pyruvate dehydrogenase. LipL activity was demonstrated in vitro with purified components and proceeds via a thioester‐linked acyl‐enzyme intermediate. As predicted, ΔgcvH strains are lipoate auxotrophs. LipL represents a new enzyme activity. It is a GcvH:[lipoyl domain] amidotransferase that probably uses a Cys‐Lys catalytic dyad. Although the active site cysteine residues of LipL and LipB are located in different positions within the polypeptide chains, alignment of their structures show these residues occupy similar positions. Thus, these two homologous enzymes have convergent architectures.     

Apicoplast lipoic acid protein ligase B is not essential for Plasmodium falciparum

Lipoic acid (LA) is an essential cofactor of alpha-keto acid dehydrogenase complexes (KADHs) and the glycine cleavage system. In Plasmodium, LA is attached to the KADHs by organelle-specific lipoylation pathways. Biosynthesis of LA exclusively occurs in the apicoplast, comprising octanoyl-[acyl carrier protein]: protein N-octanoyltransferase (LipB) and LA synthase. Salvage of LA is mitochondrial and scavenged LA is ligated to the KADHs by LA protein ligase 1 (LplA1). Both pathways are entirely independent, suggesting that both are likely to be essential for parasite survival. However, disruption of the LipB gene did not negatively affect parasite growth despite a drastic loss of LA (>90%). Surprisingly, the sole, apicoplast-located pyruvate dehydrogenase still showed lipoylation, suggesting that an alternative lipoylation pathway exists in this organelle. We provide evidence that this residual lipoylation is attributable to the dual targeted, functional lipoate protein ligase 2 (LplA2). Localisation studies show that LplA2 is present in both mitochondrion and apicoplast suggesting redundancy between the lipoic acid protein ligases in the erythrocytic stages of P. falciparum.     

A Nondiscriminating Glutamyl-tRNA Synthetase in the Plasmodium Apicoplast: THE FIRST ENZYME IN AN INDIRECT AMINOACYLATION PATHWAY*

The malaria parasite Plasmodium falciparum and related organisms possess a relict plastid known as the apicoplast. Apicoplast protein synthesis is a validated drug target in malaria because antibiotics that inhibit translation in prokaryotes also inhibit apicoplast protein synthesis and are sometimes used for malaria prophylaxis or treatment. We identified components of an indirect aminoacylation pathway for Gln-tRNA^Gln biosynthesis in Plasmodium that we hypothesized would be essential for apicoplast protein synthesis. Here, we report our characterization of the first enzyme in this pathway, the apicoplast glutamyl-tRNA synthetase (GluRS). We expressed the recombinant P. falciparum enzyme in Escherichia coli, showed that it is nondiscriminating because it glutamylates both apicoplast tRNA^Glu and tRNA^Gln, determined its kinetic parameters, and demonstrated its inhibition by a known bacterial GluRS inhibitor. We also localized the Plasmodium berghei ortholog to the apicoplast in blood stage parasites but could not delete the PbGluRS gene. These data show that Gln-tRNA^Gln biosynthesis in the Plasmodium apicoplast proceeds via an essential indirect aminoacylation pathway that is reminiscent of bacteria and plastids.     

Characterization of the ATG8-conjugation system in 2 Plasmodium species with special focus on the liver stage

Plasmodium parasites successfully colonize different habitats within mammals and mosquitoes, and adaptation to various environments is accompanied by changes in their organelle composition and size. Previously, we observed that during hepatocyte infection, Plasmodium discards organelles involved in invasion and expands those implicated in biosynthetic pathways. We hypothesized that this process is regulated by autophagy. Plasmodium spp. possess a rudimentary set of known autophagy-related proteins that includes the ortholog of yeast Atg8. In this study, we analyzed the activity of the ATG8-conjugation pathway over the course of the lifecycle of Plasmodium falciparum and during the liver stage of Plasmodium berghei. We engineered a transgenic P. falciparum strain expressing mCherry-PfATG8. These transgenic parasites expressed mCherry-PfATG8 in human hepatocytes and erythrocytes, and in the midgut and salivary glands of Anopheles mosquitoes. In all observed stages, mCherry-PfATG8 was localized to tubular structures. Our EM and colocalization studies done in P. berghei showed the association of PbATG8 on the limiting membranes of the endosymbiont-derived plastid-like organelle known as the apicoplast. Interestingly, during parasite replication in hepatocytes, the association of PbATG8 with the apicoplast increases as this organelle expands in size. PbATG3, PbATG7 and PbATG8 are cotranscribed in all parasitic stages. Molecular analysis of PbATG8 and PbATG3 revealed a novel mechanism of interaction compared with that observed for other orthologs. This is further supported by the inability of Plasmodium ATG8 to functionally complement atg8Δ yeast or localize to autophagosomes in starved mammalian cells. Altogether, these data suggests a unique role for the ATG8-conjugation system in Plasmodium parasites.     

A cyanobacterial serine protease of Plasmodium falciparum is targeted to the apicoplast and plays an important role in its growth and development

The prokaryotic ATP‐dependent protease machineries such as ClpQY and ClpAP in the malaria parasite may represent potential drug targets. In the present study, we show that the orthologue of cyanobacterial ClpP protease in Plasmodium falciparum (PfClpP) is expressed in the asexual blood stages and possesses serine protease activity. The PfClpP was localized in the apicoplast using a GFP‐targeting approach, immunoelectron microscopy and by immunofluorescence assays. A set of cell permeable β‐lactones, which specifically bind with the active site of prokaryotic ClpP, were screened using an in vitro protease assay of PfClpP. A PfClpP‐specific protease inhibitor was identified in the screen, labelled as U1‐lactone. In vitro growth of the asexual stage parasites was significantly inhibited by U1‐lactone treatment. The U1‐treated parasites showed developmental arrest at the late‐schizont stage. We further show that the U1‐lactone treatment resulted in formation of abnormal apicoplasts which were not able to grow and segregate in the parasite progeny; these effects were also evident by blockage in the replication of the apicoplast genome. Overall, our data show that the PfClpP protease has confirmed localization in the apicoplast and it plays important role in development of functional apicoplasts.     

Dephospho‐CoA kinase,a nuclear‐encoded apicoplast protein,remains active and essential after Plasmodium falciparum apicoplast disruption

Malaria parasites contain an essential organelle called the apicoplast that houses metabolic pathways for fatty acid, heme, isoprenoid, and iron–sulfur cluster synthesis. Surprisingly, malaria parasites can survive without the apicoplast as long as the isoprenoid precursor isopentenyl pyrophosphate (IPP) is supplemented in the growth medium, making it appear that isoprenoid synthesis is the only essential function of the organelle in blood‐stage parasites. In the work described here, we localized an enzyme responsible for coenzyme A synthesis, DPCK, to the apicoplast, but we were unable to delete DPCK, even in the presence of IPP. However, once the endogenous DPCK was complemented with the E. coli DPCK (EcDPCK), we were successful in deleting it. We were then able to show that DPCK activity is required for parasite survival through knockdown of the complemented EcDPCK. Additionally, we showed that DPCK enzyme activity remains functional and essential within the vesicles present after apicoplast disruption. These results demonstrate that while the apicoplast of blood‐stage P. falciparum parasites can be disrupted, the resulting vesicles remain biochemically active and are capable of fulfilling essential functions.     

Lipid synthesis in protozoan parasites: A comparison between kinetoplastids and apicomplexans

Lipid metabolism is of crucial importance for pathogens. Lipids serve as cellular building blocks, signalling molecules, energy stores, posttranslational modifiers, and pathogenesis factors. Parasites rely on a complex system of uptake and synthesis mechanisms to satisfy their lipid needs. The parameters of this system change dramatically as the parasite transits through the various stages of its life cycle. Here we discuss the tremendous recent advances that have been made in the understanding of the synthesis and uptake pathways for fatty acids and phospholipids in apicomplexan and kinetoplastid parasites, including Plasmodium, Toxoplasma, Cryptosporidium, Trypanosoma and Leishmania. Lipid synthesis differs in significant ways between parasites from both phyla and the human host. Parasites have acquired novel pathways through endosymbiosis, as in the case of the apicoplast, have dramatically reshaped substrate and product profiles, and have evolved specialized lipids to interact with or manipulate the host. These differences potentially provide opportunities for drug development. We outline the lipid pathways for key species in detail as they progress through the developmental cycle and highlight those that are of particular importance to the biology of the pathogens and/or are the most promising targets for parasite-specific treatment.     

Glycerophospholipid acquisition in Plasmodium - A puzzling assembly of biosynthetic pathways

Throughout the Plasmodium life cycle, malaria parasites repeatedly undergo rapid cellular growth and prolific divisions, necessitating intense membrane neogenesis and, in particular, the acquisition of high amounts of phospholipids. At the intraerythrocytic stage, glycerophospholipids are the main parasite membrane constituents, which mostly originate from the Plasmodium-encoded enzymatic machinery. Several proteins and entire pathways have been characterized and their features reported, thereby generating a global view of glycerophospholipid synthesis across Plasmodium spp. The malaria parasite displays a panoply of pathways that are seldom found together in a single organism. The major glycerophospholipids are synthesized via ancestral prokaryotic CDP-diacylglycerol-dependent pathways and eukaryotic-type de novo pathways. The parasite exhibits additional reactions that bridge some of these routes and are otherwise restricted to some organisms, such as plants, while base-exchange mechanisms are largely unexplored in Plasmodium. Marked differences between Plasmodium spp. have also been reported in phosphatidylcholine and phosphatidylethanolamine synthesis. Little is currently known about glycerophospholipid acquisition at non-erythrocytic stages, but recent data reveal that intrahepatocytic parasites, oocysts and sporozoites import various host lipids, and that de novo fatty acid synthesis is only crucial at the late liver stage. More studies on the different Plasmodium developmental stages are needed, to further assemble the different pieces of this glycerophospholipid synthesis puzzle, which contains highly promising therapeutic targets.     

Imaging liver‐stage malaria parasites

Plasmodium parasites, the causative agents of malaria, first invade and develop within hepatocytes before infecting red blood cells and causing symptomatic disease. Because of the low infection rates in vitro and in vivo, the liver stage of Plasmodium infection is not very amenable to biochemical assays, but the large size of the parasite at this stage in comparison with Plasmodium blood stages makes it accessible to microscopic analysis. A variety of imaging techniques has been used to this aim, ranging from electron microscopy to widefield epifluorescence and laser scanning confocal microscopy. High‐speed live video microscopy of fluorescent parasites in particular has radically changed our view on key events in Plasmodium liver‐stage development. This includes the fate of motile sporozoites inoculated by Anopheles mosquitoes as well as the transport of merozoites within merosomes from the liver tissue into the blood vessel. It is safe to predict that in the near future the application of the latest microscopy techniques in Plasmodium research will bring important insights and allow us spectacular views of parasites during their development in the liver.     

A genetic screen in rodent malaria parasites identifies five new apicoplast putative membrane transporters,one of which is essential in human malaria parasites

The malaria‐causing parasite, Plasmodium, contains a unique non‐photosynthetic plastid known as the apicoplast. The apicoplast is an essential organelle bound by four membranes. Although membrane transporters are attractive drug targets, only two transporters have been characterised in the malaria parasite apicoplast membranes. We selected 27 candidate apicoplast membrane proteins, 20 of which are annotated as putative membrane transporters, and performed a genetic screen in Plasmodium berghei to determine blood stage essentiality and subcellular localisation. Eight apparently essential blood stage genes were identified, three of which were apicoplast‐localised: PbANKA_0614600 (DMT2), PbANKA_0401200 (ABCB4), and PbANKA_0505500. Nineteen candidates could be deleted at the blood stage, four of which were apicoplast‐localised. Interestingly, three apicoplast‐localised candidates lack a canonical apicoplast targeting signal but do contain conserved N‐terminal tyrosines with likely roles in targeting. An inducible knockdown of an essential apicoplast putative membrane transporter, PfDMT2, was only viable when supplemented with isopentenyl diphosphate. Knockdown of PfDMT2 resulted in loss of the apicoplast, identifying PfDMT2 as a crucial apicoplast putative membrane transporter and a candidate for therapeutic intervention.