A key role for lipoic acid synthesis during Plasmodium liver stage development

The successful navigation of malaria parasites through their life cycle, which alternates between vertebrate hosts and mosquito vectors, requires a complex interplay of metabolite synthesis and salvage pathways. Using the rodent parasite Plasmodium berghei, we have explored the synthesis and scavenging pathways for lipoic acid, a short‐chain fatty acid derivative that regulates the activity of α‐ketoacid dehydrogenases including pyruvate dehydrogenase. In Plasmodium, lipoic acid is either synthesized de novo in the apicoplast or is scavenged from the host into the mitochondrion. Our data show that sporozoites lacking the apicoplast lipoic acid protein ligase LipB are markedly attenuated in their infectivity for mice, and in vitro studies document a very late liver stage arrest shortly before the final phase of intra‐hepaticparasite maturation. LipB‐deficient asexual blood stage parasites show unimpaired rates of growth in normal in vitro or in vivo conditions. However, these parasites showed reduced growth in lipid‐restricted conditions induced by treatment with the lipoic acid analogue 8‐bromo‐octanoate or with the lipid‐reducing agent clofibrate. This finding has implications for understanding Plasmodium pathogenesis in malnourished children that bear the brunt of malarial disease. This study also highlights the potential of exploiting lipid metabolism pathways for the design of genetically attenuated sporozoite vaccines.     

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.     

Endogenous production of lipoic acid is essential for mouse development

alpha-Lipoic acid (LA) is a cofactor for mitochondrial alpha-ketoacid dehydrogenase complexes and is one of the most potent, natural antioxidants. Reduction of oxidative stress by LA supplementation has been demonstrated in patients with diabetic neuropathy and in animal models. To determine how normal development or pathological conditions are affected by genetic alterations in the ability of mammalian cells to synthesize LA and whether dietary LA can circumvent its endogenous absence, we have generated mice deficient in lipoic acid synthase (Lias). Mice heterozygous for disruption of the Lias gene develop normally, and their plasma levels of thiobarbituric acid-reactive substances do not differ from those of wild-type mice. However, the heterozygotes have significantly reduced erythrocyte glutathione levels, indicating that their endogenous antioxidant capacity is lower than those of wild-type mice. Homozygous embryos lacking Lias appear healthy at the blastocyst stage, but their development is retarded globally by 7.5 days postcoitum (dpc), and all the null embryos die before 9.5 dpc. Supplementing the diet of heterozygous mothers with LA (1.65 g/kg of body weight) during pregnancy fails to prevent the prenatal deaths of homozygous embryos. Thus, endogenous LA synthesis is essential for developmental survival and cannot be replaced by LA in maternal tissues and blood.     

Type II fatty acid synthesis is essential only for malaria parasite late liver stage development

Intracellular malaria parasites require lipids for growth and replication. They possess a prokaryotic type II fatty acid synthesis (FAS II) pathway that localizes to the apicoplast plastid organelle and is assumed to be necessary for pathogenic blood stage replication. However, the importance of FAS II throughout the complex parasite life cycle remains unknown. We show in a rodent malaria model that FAS II enzymes localize to the sporozoite and liver stage apicoplast. Targeted deletion of FabB/F , a critical enzyme in fatty acid synthesis, did not affect parasite blood stage replication, mosquito stage development and initial infection in the liver. This was confirmed by knockout of FabZ , another critical FAS II enzyme. However, FAS II-deficient Plasmodium yoelii liver stages failed to form exo-erythrocytic merozoites, the invasive stage that first initiates blood stage infection. Furthermore, deletion of FabI in the human malaria parasite Plasmodium falciparum did not show a reduction in asexual blood stage replication in vitro . Malaria parasites therefore depend on the intrinsic FAS II pathway only at one specific life cycle transition point, from liver to blood.     

The liver stage of Plasmodium berghei inhibits host cell apoptosis

Plasmodium berghei is the causative agent of rodent malaria and is widely used as a model system to study the liver stage of Plasmodium parasites. The entry of P. berghei sporozoites into hepatocytes has extensively been studied, but little is known about parasite-host interaction during later developmental stages of the intracellular parasite. Growth of the parasite far beyond the normal size of the host cell is an important stress factor for the infected cell. Cell stress is known to trigger programmed cell death (apoptosis) and we examined several apoptotic markers in P. berghei-infected cells and compared their level of expression and their distribution to that of non-infected cells. As none of the apoptotic markers investigated were found altered in infected cells, we hypothesized that parasite infection might confer resistance to apoptosis of the host cell. Treatment with peroxide or serum deprivation induced apoptosis in non-infected HepG2 cells, whereas P. berghei-infected cells appeared protected, indicating that the parasite interferes indeed with the apoptotic machinery of the host cell. To prove the physiological relevance of these results, mice were infected with high numbers of P. berghei sporozoites and treated with tumour necrosis factor (TNF)-alpha/D-galactosamine to induce massive liver apoptosis. Liver sections of these mice, stained for degraded DNA, confirmed that infected cells containing viable parasites were protected from programmed cell death. However, in non-treated control mice as well as in TNF-alpha-treated mice a small proportion of dead intracellular parasites with degraded DNA were detected. Most hepatocytes containing dead parasites provoked an infiltration of immunocompetent cells, indicating that these cells are no longer protected from cell death.     

Mitochondrial NADH dehydrogenase from Plasmodium falciparum and Plasmodium berghei

The mitochondrial electron transport system is necessary for growth and survival of malarial parasites in mammalian host cells. NADH dehydrogenase of respiratory complex I was demonstrated in isolated mitochondrial organelles of the human parasite Plasmodium falciparum and the mouse parasite Plasmodium berghei by using the specific inhibitor rotenone on oxygen consumption and enzyme activity. It was partially purified by two sequential steps of fast protein liquid chromatographic techniques from n-octyl glucoside solubilization of the isolated mitochondria of both parasites. In addition, physical and kinetic properties of the malarial enzymes were compared to the host mouse liver mitochondrial respiratory complex I either as intact or as partially purified forms. The malarial enzyme required both NADH and ubiquinone for maximal catalysis. Furthermore, rotenone and plumbagin (ubiquinone analog) showed strong inhibitory effect against the purified malarial enzymes and had antimalarial activity against in vitro growth of P. falciparum. Some unique properties suggest that the enzyme could be exploited as chemotherapeutic target for drug development, and it may have physiological significance in the mitochondrial metabolism of the parasite.     

LISP1 is important for the egress of Plasmodium berghei parasites from liver cells

Most Apicomplexa are obligatory intracellular parasites that multiply inside a so-called parasitophorous vacuole (PV) formed upon parasite entry into the host cell. Plasmodium , the agent of malaria and the Apicomplexa most deadly to humans, multiplies in both hepatocytes and erythrocytes in the mammalian host. Although much has been learned on how Apicomplexa parasites invade host cells inside a PV, little is known of how they rupture the PV membrane and egress host cells. Here, we characterize a Plasmodium protein, called LISP1 ( li ver- s pecific p rotein 1), which is specifically involved in parasite egress from hepatocytes. LISP1 is expressed late during parasite development inside hepatocytes and locates at the PV membrane. Intracellular parasites deficient in LISP1 develop into hepatic merozoites, which display normal infectivity to erythrocytes. However, LISP1-deficient liver-stage parasites do not rupture the membrane of the PV and remain trapped inside hepatocytes. LISP1 is the first Plasmodium protein shown by gene targeting to be involved in the lysis of the PV membrane.     

Gene expression analysis during liver stage development of Plasmodium

The complex life cycle of malaria parasites requires significant changes in gene expression as the parasites move from vector to host and back to the vector. Although recognised as an important vaccine and drug target, the liver stage parasite has remained difficult to study. One of the major impediments in identifying parasite gene expression at the liver stage has remained the large number of uninfected hepatocytes relative to the number of infected hepatocytes in the liver after sporozoite inoculation. This article describes several of the approaches that have been utilised to overcome this difficulty in rodent models of malaria. While significant progress has been made to identify genes that are expressed during liver stage parasite development, a great deal more work remains to be done.     

Plasmodium falciparum: Organelle-specific acquisition of lipoic acid

Lipoic acid is an essential cofactor of multienzyme complexes that are integral to energy metabolism, amino acid degradation and folate metabolism. In recent years it has been shown that the malaria parasite Plasmodium falciparum possesses organelle-specific pathways that guarantee the lipoylation of their multienzyme complexes which occur in the mitochondrion (LA salvage) and in a plastid-like organelle, the apicoplast (LA biosynthesis). The unique distribution of the lipoylation machineries and the unique metabolic requirements of the parasites present a situation that is potentially exploitable for new ways to improve malaria control.     

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.     

Plasmodium berghei berghei: ectopic development of the ANKA strain in Anopheles stephensi

Sporogonic development of Plasmodium berghei berghei is frequently ectopic, occurring deep within the tissue of the midgut with oocysts expelling sporozoites into its lumen. Inocula containing oocysts and sporozoites defecated with blood during the mosquito blood meal produced infections when introduced into mice. The fine structures and pellicle of luminal parasites appeared normal in all respects.     

G-strand binding protein 2 is involved in asexual and sexual development of Plasmodium berghei

G-strand binding protein 2 (GBP2) is a Ser/Arg-rich (SR) protein involved in mRNA surveillance and nuclear mRNA quality control in yeast. However, the roles of GBP2 in virulence and sexual development in Plasmodium parasites are unclear, although GBP2 is involved in the asexual development of Plasmodium berghei, the rodent malaria parasite. In this study, we investigated the role of GBP2 in virulence and sexual development of P. berghei using gbp2-deleted P. berghei (Δgbp2 parasites). Then, to identify factors affected by gbp2 deletion, we performed a comparative proteomic analysis of the Δgbp2 parasites. We found that GBP2 was not associated with the development of experimental cerebral malaria during infection with P. berghei, but asexual development of the parasite was delayed with deletion of gbp2. However, the development of P. berghei gametocytes was significantly reduced with deletion of gbp2. Comparative proteomic analysis revealed that the levels of adenosine deaminase (ADA), purine nucleoside phosphorylase (PNP), and hypoxanthine-guanine phosphoribosyltransferase (HGPRT) in Δgbp2 parasites were significantly higher than those in wild-type (WT) parasites, suggesting that biosynthesis of purine nucleotides may be involved in function of GBP2. Therefore, we investigated the effect of purine starvation on the sexual development and proteome. In nt1-deleted P. berghei (Δnt1 parasites), the production of male and female gametocytes was significantly reduced compared to that in WT parasites. Moreover, we found that protein levels of GBP2 in Δnt1 parasites were markedly lower than in WT parasites. These findings suggest that GBP2 is primarily involved in the sexual development of malaria parasites, and its function may be suppressed by purine starvation.     

A role for linoleic acid in erythrocytes infected with Plasmodium berghei

Unesterified fatty acids were measured in mouse erythrocytes infected either with chloroquine-susceptible (CS) or with chloroquine-resistant (CR) lines of Plasmodium berghei. This work was undertaken to identify candidates for the lipid involved in ferriprotoporphyrin IX (FP) polymerization. Linoleic, oleic, palmitic, and stearic acids were quantified by gas chromatography/mass spectrometry. In total, they increased 4-fold with CS infections and 6-fold with CR infections. Treating infected mice with chloroquine did not affect the amounts of unesterified fatty acids in erythrocytes. Of the four fatty acids, only linoleic acid increased disproportionately to the total. It increased 16-fold for the CS line and 35-fold for the CR line. The method could detect monoglycerides but they were below the limit of detection. It could not detect diglycerides, triglycerides or phospholipids. Triglycerides and phospholipids have been tested previously, however, and found to be ineffective at promoting FP polymerization. Therefore, other than linoleic acid, the lipids most likely to be involved in FP polymerization are diglycerides. We tested dilinoleolyglycerol in the present work and found it to be an effective promoter of FP polymerization. These results suggest that linoleic acid or a diglyceride containing it has the critical role of promoting FP polymerization in malaria parasites.     

Mitochondrial delivery is essential for synaptic potentiation

Mitochondria, as portable generators that power synaptic function, regulate the ATP supply and calcium homeostasis in the neuron. As molecular interactions within the synapses before and after the potentiation are beginning to be elucidated, the deciding moment during the tetanic stimulation that gives rise to the strengthening of the synapse remains a mystery. Here, I recorded electrically from an intact Drosophila nervous system, while simultaneously using time-lapse confocal microscopy to visualize mitochondria labeled with green fluorescent protein. I show that tetanic stimulation triggers a fast delivery of mitochondria to the synapse, which facilitates synaptic potentiation. Rotenone, an inhibitor of mitochondrial electron transport chain complex I, suppresses mitochondrial transport and abolishes the potentiation of the synapse. Expression of neurofibromin, which improves mitochondrial ATP synthesis in the neuron, enhances the movements of mitochondria to the synapse and promotes post-tetanic potentiation. These findings provide unprecedented evidence that the mitochondrial delivery to the synapse is critical for cellular learning.