In silico prediction of host-pathogen protein - protein interactions in the malaria parasite, Plasmodium falciparum

Odendaal, Christiaan Jacobus

23 June 2011

Malaria claims millions of lives annually. This global killer causes approximately 2.7 million annual deaths worldwide; addressing this problem has become more and more crucial. Due to pathogen evolution no efficient vaccine for treatment of malaria currently exists. As infection has developed as a field of study, it became ever more clear that infections could only be understood within the context of the host-pathogen community. This project aims to predict possible drug targets based on host-pathogen interactions rather than just protein-protein interactions within a single organism. Similar to Lee et al. (2008) pathogen-host interaction predictions are based on orthology, these interactions are then analysed to identify potential drug targets. This could potentially aid researchers in their continuous battle against malaria and the larger scale battle against pathogen evolution. To predict in vitro host-pathogen interactions DISCOVERY uses an ortholog clustering method called ORTHOMCL. ORTHOMCL is very suitable for ortholog clustering of malaria data for two reasons. Firstly, it is capable of distinguishing between recent paralogs and ancient paralogs, which enables the inclusion of recent paralogs together with orthologs. Secondly, ORTHOMCL was initially developed for the use of malaria data. Identification of in vitro interactions is followed by scoring methods to determine the possible in vivo interactions that might occur between the Plasmodium parasite and the human and mosquito hosts. Scoring measures and weights were applied to 5 different factors to calculate a final score. These final scores allow user input to define the preferred stringency when viewing possible interactions with a single protein. These different factors are sequence similarity, PEXEL/VTS motif presence, microarray expression, metabolic map sharing and sub-cellular locations boundaries. DISCOVERY’S results and results from two other (Dyer et al. and Lee et al.) in silico prediction methods were compared with Vignali et al’s experimental interactions which are based on a yeast two-hybrid approach. Similar to results shown by Doolittle and Gomez these comparisons had poor results. The next step was to compare the in silico results with each other. Dyer et al’s and Lee et al‘s results compared poorly with each other. Although DISCOVERY did not compare well with Dyer et al’s results, comparisons with Lee et al. showed more promise. Poor comparisons with Dyer et al. may be due to their unique approach to predict in vitro host-pathogen interactions. This project identified the lack of enough valid and reliable experimental data to evaluate in silico prediction methods as a definite challenge for host-pathogen interaction predictors. Although this is a major problem, DISCOVERY improved on older prediction methods with the use of a more applicable ortholog clustering technique and the use of more assessment methods during in vivo interaction predictions. DISCOVERY also used scoring methods rather than exclusion methods during the identification of in vivo interactions. This allows a user to specify a threshold of sensitivity when viewing interactions. The true potential of host-pathogen interaction predictions would only be realized when the gap between predictions and evaluation data is bridged. / Dissertation (MSc)--University of Pretoria, 2010. / Biochemistry / unrestricted

Malaria parasite

Vaccine

Malaria

Protein interactions

Plasmodium falciparum

UCTD

Evolutionary ecology of reproductive strategies in malaria parasites

Carter, Lucy Mary

January 2014

For vector-borne parasites such as malaria, how within- and between-host processes interact to shape transmission is poorly understood. In the host, malaria parasites replicate asexually but for transmission via mosquitoes to occur, specialized sexual stages (gametocytes) must be produced. Once inside the mosquito vector, gametocytes immediately differentiate into male and female gametes, and motile male gametes must swim through the hostile environment of the bloodmeal to find and fertilise female gametes. Despite the central role that gametocytes play in disease transmission, explanations of why parasites adjust gametocyte production in response to in-host factors remain controversial. Furthermore, surprisingly little is known about the mating behaviour of malaria parasites once inside the mosquito. Developing drugs and/or vaccines that prevent transmission by disrupting sexual stages are major goals of biomedicine, but understanding variation in gametocyte investment and male gamete behaviour is key to the success of any intervention. First, I propose that the evolutionary theory developed to explain variation in reproductive effort in multicellular organisms provides a framework to understand gametocyte investment strategies in malaria parasites. I then demonstrate that parasites appear to change their reproductive strategies in response to environmental cues and in a manner consistent with our predictions. Next, I show how digital holographic microscopy can be used to characterise the morphology and motility of male gametes. I then provide evidence for non-random movement of male gametes and that gamete interactions with red blood cells appear to hinder mating success in a bloodmeal. Finally, I discuss the variation in gametocyte differentiation and fertilisation success when exposed to a number of factors implicated in gametocyte activation. The data presented here provides important information on the basic biology of malaria parasite reproductive stages and demonstrates considerable variation in parasite traits and behaviours in response environmental changes; both in the host and in the mosquito vector.

577.8

Mathematical modelling on interaction between malaria parasites and the host immune system

Marijani, Theresia

12 1900

Thesis (PhD)--Stellenbosch University, 2012. / Please refer to full text for abstract.

Malaria -- Mathematical models

Malaria parasite

Immune system

Dissertations -- Mathematics

Theses -- Mathematics

Molecular characterisation of the ornithine decarboxylase gene of the human malaria parasite, plasmidium falciparum

Birkholtz, Lyn-Marie

January 1998

Malaria is one of the most serious tropical infectious diseases affecting mankind. The prevention of the disease is hampered by the increasing resistance of the parasite to existing chemotherapy and -prophylaxis drugs. The need for novel therapeutic targets and drugs is therefore enormous and the understanding of the biochemistry of the parasite is imperative. The aim of this study was the identification and molecular characterisation of the eDNA of one such metabolic target protein, ornithine decarboxylase (ODC), in the human malaria parasite P. falciparum. The P. falciparum ODC eDNA was isolated by means of a modified RT-PCR technique, RACE. No sequence data were available and the primers used were based on consensus areas identified in the protein sequences from other related organisms. The isolation and identification of the eDNA with degenerate primers was successful in 3' -RACE, but necessitated the optimisation of the eDNA synthesis protocol and the use of total RNA as starting material. The sequence obtained facilitated the application of 5' -RACE with ODC-specific primers based on the 3' -RACE sequence data. The full-length ODC eDNA sequence was obtained by overlap-alignment of various segments. A novel suppression PCR technology was applied during the 5' -RACE in order to create an uncloned eDNA library of amplified cDNAs representing only the mRNA population. The P. falciparum ODC eDNA contains an open reading frame of ---2847 bp and translates to a large 939 amino acid protein. The protein contained large internal insertions and was extended by '""273 N-terminal residues compared to ODCs from other organisms. Several possible signature motifs were identified for phosphorylation, glycosylation and transamidation. The P. falciparum ODC protein seems to contain more hydrophilic and a-helix forming residues. These characteristics should be further investigated after expression of the recombinant protein. The isolation of the P. falciparum ODC eDNA facilitates the validation of this protein as an antimalarial target. / Dissertation (MSc)--University of Pretoria, 1998. / gm2014 / Biochemistry / unrestricted

Malaria

Tropical infectious diseases

Molecular characterisation of the eDNA

Human malaria parasite P. falciparum

Ornithine decarboxylase (ODC)

UCTD

Biochemical And Molecular Insights Into β-Hydroxyacyl-Acyl Carrier Protein Dehydratase (FabZ) From Plasmodium Falciparum

Kumar, Shailendra

10 1900

Malaria, caused by Plasmodium, is one of the most devastating infectious diseases of the world in terms of mortality as well as morbidity (WHO, 2002). The development of resistance in the Plasmodium falciparum against the present antimalarials has made the situation very alarming (Trape et al., 2000). To combat this situation, new antimalarials as well as identification of new drug targets are urgently required. The discovery of the presence of type II fatty acid biosynthesis system in the malarial parasite has offered several promising new targets for this mission. This thesis describes the successful cloning of fabZ from Plasmodium falciparum, its expression in E. coli, single step affinity purification, kinetic characterization and most importantly discovery of two small molecule inhibitors (Sharma et al., 2003). The study was executed to gain insights into the structure and function of PfFabZ to get better understanding of the interactions with its substrate analogs, novel inhibitors and also acyl carrier protein (PfACP). The molecular details of the interactions of the two novel inhibitors were also determined. Lastly, the residues of PfFabZ important for the interaction with PfACP were successfully elucidated. Chapter 1 presents a brief review of the literature about the disease as well as the life cycle, biology and the metabolic pathways operational in malarial parasite, Plasmodium falciaparum. The discovery of type II FAS in P. falciparum and the aims and the scope of the thesis are also discussed. The quest of developing new antimalarials, study of the mechanism of actions of antimalarials such as quinine and its derivatives along with the major metabolic pathways (Purine, pyrimidine, phospholipids, carbohydrate metabolism, folate and heme biosynthesis pathways etc.) existing in P. falciparum are described in detail in this chapter. Origin and importance of apicoplast in P. falciaprum is also described in brief. For long, it was believed that Plasmodium spp. are incapable of de novo fatty acid synthesis but this view has undergone substantial revision due to the recent discovery of plant and bacterial type of fatty acid biosynthesis pathway in them (Surolia and Surolia, 2001). As this pathway is distinct from that of the human host it has accelerated the momentum for the discovery of new antimalarials (Surolia and Surolia, 2001). The Chapter also surveys the details of type II FAS in bacteria, particularly that of E. coli (Rock and Cronan, 1996). The dehydratase step which is the third step of fatty acid elongation cycle has been covered in considerable detail. Lastly, it focuses on the recent advancement in the understanding of fatty acid biosynthesis system in Plasmodium falciparum along with some inhibitors targeting the malarial FAS. As each enzyme of the Plasmodium FAS can serve as good antimalarial targets, my work focuses on the dehydratase step catalyzed by β-hydroxyacyl-ACP dehydratase (PfFabZ). Cloning, expression and kinetic characterization of PfFabZ forms the major content of Chapter 2. The PlasmoDB data base was searched for this gene and the mined out open reading frame contained sequence of the putative FabZ together with the bipartite leader polypeptide. Our aim was to clone the mature PfFabZ without the bipartite leader sequence. Amplification of the mature pffabZ using Plasmodium falciparum genomic DNA revealed the presence of an intron in the ORF and the gene was finally cloned by RT-PCR in pET-28a(+) vector. It was expressed with an N-terminal hexahistidine tag in BL-21(DE3) cells and purified to near homogeneity but the protein was insoluble and unstable. Truncation of 12 residues from the N-terminal end improved the stability and solubility of the protein by 3-5 fold. Truncated PfFabZ was used for all future experiments. FabZs from other sources are reported to be hexamer in solution but PfFabZ showed homodimeric arrangement in the conditions used for gel filtration as well as dynamic light scattering studies. Kinetics of PfFabZ was characterized using substrate analogs, β-hydroxybutryl-CoA (forward substrate) and Crotonoyl-CoA (reverse substrate). Both the forward and reverse reaction were thoroughly characterized by spectrophotometry and HPLC and the reverse reaction was found to be 7 times faster than the forward reaction. Km οf crotonoyl-CoA was calculated to be 86 µM and kcat/Km of 220 M-1s-1 whereas the Kmfor β-hydroxybutryl-CoA was found to be 199 µM and kcat/Kmof 80.2 M-1s-1. The kinetic data clearly indicates the higher affinity of PfFabZ for the reverse substrate. Chapter 3 describes the discovery of two small molecules inhibitors, NAS-21 and NAS-91 for PfFabZ, their detailed inhibition kinetics and their effect on the growth of Plasmodium falciparum in culture. These inhibitors were the first inhibitors to be reported for FabZ class of enzymes with an IC50 ranging below 15 µM. Both of them inhibited PfFabZ following competitive kinetics with respect to the substrates utilized for both the forward and reverse reactions. The inhibition data were analyzed by Lineweaver-Burk and Dixon plots and both inhibitors showed competitive inhibition kinetics with dissociation constant in submicromolar range. Binding constants for both the inhibitors were also determined by fluorescence titration method and were calculated to be 1.6 (± 0.04) X 106 M-1 for NAS-91 and 1.2 (± 0.03) X 106 M-1 for NAS-21. These inhibitors were checked on Plasmodium falciparum culture and both inhibited parasite growth with IC50 values of 7 µM and 100 µM for NAS-21 and NAS-91, respectively. They also inhibited the incorporation of [1,2-14C]-acetate in the fatty acids of the P. falciparum conforming the inhibition of fatty acid biosynthesis. FabZ class of enzymes are thought to contain His-Glu as a catalytic dyad. Based on the disparity in the arrangement of residues at the active site of the dimeric (Swarnamukhi et al., 2006) and hexameric forms of PfFabZ in the crystal structures (Kosteriva et al., 2005), we set out to elucidate the active site residues in PfFabZ which is described in Chapter 4. The role of each of the presumed active site residues His-133 and Glu-147 along with Arg-99 and His-98 were analyzed by chemical modification studies and site directed mutagenesis. Single and double mutants were prepared and the activity of the mutants was monitored by spectrophotometry and isothermal titration calorimetry (ITC). It was concluded that in PfFabZ, His-133 and Glu-147 makes the catalytic dyad, His-98 might be important in directing the substrate in correct orientation while Arg-99 is involved in maintaining the active site loop in proper orientation rather than taking direct part in catalysis. Chapter 4 also concludes that dimeric form of PfFabZ is inactive species and turns into active hexameric form in the presence of substrate. Chapter 5 describes the molecular details of NAS-21 and NAS-91 interactions with PfFabZ. The fact that both these compounds inhibited PfFabZ in competitive manner, prompted me to examine their interaction with the residues in the active site tunnel. Apart from the His-133 and Glu-147 catalytic dyad the only polar residue is His-98 and chemical modification and site directed mutagenesis studies were done to elucidate the interactions of these residues with NAS-21 and NAS-91. Both the inhibitors were able to protect the modification of histidines by DEPC in wild type PfFabZ, His-98-Ala mutant and His-133-Ala mutant but with differential strength, indicating that they do interact with histidines. The interaction of these inhibitors was further confirmed by determining the dissociation constants of wPfFabZ, His-98-Ala, His-133-Ala, His-98-Ala/His-133-Ala double mutant, Glu-147-Ala mutant by fluorescence titration method. The results obtained from chemical modification and fluorescence titration studies confirmed that NAS-21 interacts strongly with histidines, His-98 and His-133 but not with Glu-147. On the other hand NAS-91 interacts loosely with His-98 and His-133 but strongly with Glu-147. Chapter 5 concludes with the observation that both the inhibitors (NAS-21 and NAS-91) interact with the active site residues of PfFabZ, preventing the substrate to enter the active site tunnel. Acyl carrier protein (ACP) is a small acidic protein to which the acyl chain intermediates are tethered and shuttled from one enzyme to another for the completion of fatty acid elongation cycle. Whenever acyl carrier proteins are expressed in E. coli, they are present in three forms apo, holo and acyl-ACPs. Chapter 6 describes a novel method for the expression of histidine tagged PfACP in pure holo form, protocol for the cleavage of his-tag from PfACP by thrombin preparation of homogenous singly enriched ie PfACP [15N]-labeled or [13C]-labeled PfACP as well as doubly enriched [15N]-[13C] PfACP samples for its structure elucidation by NMR (Sharma et al., 2005). These studies also constituted reporting of a holo-ACP structure from any of the sources for the first time (Sharma, et. al. 2006). The purified pure holo-PfACP was further used for the interaction studies with PfFabZ. Earlier studies have shown that ACP interacts with FAS enzymes via helix II with conserved set of residues but the molecular details of the interactions are poorly known (Zhang, et. al., 2003). We have recently solved the NMR structure (Sharma, et. al., 2006) of PfACP and crystal structure of PfFabZ (Swarnamukhi, et. al., 2006). So, both the structures were docked using Cluspro server. Chapter 7 elucidates the roles of important residues on PfFabZ surface near the active site entry which are responsible for interacting with PfACP. The residues lining the active site entry were identified and mutated. The residues lining the active site tunnel of PfFabZ are Arg102, Lys104, Lys105, Lys123, Leu94, Phe95, Ala96, Gly97, Ile128, Ile145, Phe150 and Ala151. Charged residues were mutated to alanine and also to oppositely charged residues while the neutral residues were changed to charged residues. The interaction of PfFabZ mutants with PfACP was studied by ACP independent enzymatic assay and surface plasmon resonance (SPR) spectroscopy. It was concluded that PfFabZ and PfACP interaction is mainly governed by electrostatic interaction made by the charged residues (Lys104 being the most important residue) and is fine tuned by hydrophobic interactions. Chapter 8 summarizes the findings of the thesis. FabZ from Plasmodium falciparum was cloned and biochemically characterized. Two inhibitors for this enzyme were discovered and their molecular details of binding to PfFabZ were elucidated. The presence of catalytic dyad was confirmed and finally the residues of PfFabZ important for interaction with PfACP were elucidated. Appendix I describes the inhibition of PfENR (enoyl ACP reductase), the rate limiting and the fourth enzyme of the fatty acid elongation pathway by green tea extracts. Three tea catechins (EGCG, EGC and ECG) and two plant polyphenols (quercetin and buteine) were selected for the inhibition study. All the catechins inhibited PfENR potently with Ki values in nanomolar range. Among the five compounds studied, EGCG was found to be the best inhibitor. All of them blocked the NADH binding site showing competitive kinetics with respect to NADH and uncompetitive kinetics with crotonoyl-CoA, the substrate analog. Most importantly, the catechins potentiated the inhibition of PfENR by triclosan, a well known PfENR inhibitor. We also report that in the presence of tea catechins triclosan behaves as a slow-tight binding inhibitor of PfENR. The overall inhibition constant of triclosan in the presence of EGCG was calculated to be 2pM which is 50 times better than the earlier reported values with NAD+ (Kapoor, et. al., 2004).

Malaria

Plasmodium Falciparum

FabZ Enzymes - Cloning

Plasmodium Falciparum Fabz (PfFabZ)

Antimalarials

Fatty Acid Biosynthesis

Apicoplast

Malaria Parasite

Microbiology

Computational And Biochemical Studies On The Enzymes Of Type II Fatty Acid Biosynthesis Pathway : Towards Antimalarial And Antibacterial Drug Discovery

Kumar, Gyanendra

02 1900

Malaria, caused by the parasite Plasmodium, continues to exact high global morbidity and mortality rate next only to tuberculosis. It causes 300-500 million clinical infections out of which more than a million people succumb to death annually. Worst affected are the children below 5 years of age in sub-Saharan Africa. Plasmodium is a protozoan parasite classified under the phylum Apicomplexa that also includes parasites such as Toxoplasma, Lankestrella, Eimeria and Cryptosporidium. Of the four species of Plasmodium affecting man viz., P. falciparum, P. vivax, P. ovale and P. malariae, Plasmodium falciparum is the deadliest as it causes cerebral malaria. The situation has worsened recently with the emergence of drug resistance in the parasite. Therefore, deciphering new pathways in the parasite for developing lead antimalarial compounds is the need of the hour. The discovery of the type II fatty acid biosynthesis pathway in Plasmodium falciparum has opened up new avenues for the design of new antimalarials as this pathway is different from the one in human hosts. Although many biochemical pathways such as the purine, pyrimidine and carbohydrate metabolic pathways, and the phospholipid, folate and heme biosynthetic pathways operate in the malaria parasite and are being investigated for their amenability as antimalarial therapeutic targets, no antimalarial of commercial use based on the direct intervention of these biochemical pathways has emerged so far. This is due to the fact that the structure and function of the targets of these drugs overlaps with that of the human host. A description of the parasite, its metabolic pathways, efforts to use these pathways for antimalarial drug discovery, inhibitors targeting these pathways, introduction to fatty acid biosynthesis pathway, discovery of type II fatty acid biosynthesis pathway in Plasmodium falciparum and prospects of developing lead compounds towards antimalarial drug discovery is given in Chapter 1 of the thesis. In the exploration of newly discovered type II fatty acid biosynthesis pathway of P. falciparum as a drug target for antimalarial drug discovery, one of the enzymes; β-hydroxyacyl- acyl carrier protein dehydratase (PfFabZ) was cloned and being characterized in the lab. The atomic structure of PfFabZ was not known till that point of time. Chapter 2 describes the homology modeled structure of PfFabZ and docking of the discovered inhibitors with this structure to provide a rationale for their inhibitory activity. Despite low sequence identity of ~ 21% with the closest available atomic structure then, E. coli FabA, a good model of PfFabZ could be built. A comparison of the modeled structure with recently determined crystal structure of PfFabZ is provided and design of new potential inhibitors is described. This study provides insights to further improve the inhibition of this enzyme. Enoyl acyl carrier protein reductase (ENR) is the most important enzyme in the type II fatty acid biosynthesis pathway. It has been proved as an important target for antibacterial as well as antimalarial drug discovery. The most effective drug against tuberculosis – Isoniazid targets this enzyme in M. tuberculosis. The well known antibacterial compound – Triclosan, a diphenyl ether, also targets this enzyme in P. falciparum. I designed a number of novel diphenyl ether compounds. Some of these compounds could be synthesized in the laboratory. Chapter 3 describes the design, docking studies and inhibitory activity of these novel diphenyl ether compounds against PfENR and E. coli ENR. Some of these compounds inhibit PfENR in nanomolar concentrations and EcENR in low micromolar concentrations, and many of them inhibit the growth of parasites in culture also. The structure activity relationship of these compounds is discussed that provides important insights into the activity of this class of compounds which is a step towards developing this class of compounds into an antimalarial and antibacterial candidate drugs. Components of the green tea extract and polyphenols are well known for their medicinal properties since ages. Recently they have been shown to inhibit components of the bacterial fatty acid biosynthesis pathway. Some selected tea catechins and polyphenols were tested in the laboratory for their inhibitory activity against PfENR. I conducted docking studies to find their probable binding sites in PfENR. On kinetic analysis of their inhibition, these compounds were found to be competitive with respect to the cofactor NADH. This has an implication that they could potentiate inhibition of PfENR by Triclosan in a fashion similar to that of NADH. As a model case, one of the tea catechins; EGCG ((-) Epigalocatechin gallate) was tested for this property. Indeed, in the presence of EGCG, the inhibition of PfENR improved from nanomolar to picomolar concentration of Triclosan.conducted molecular modeling studies and propose a model for the formation of a ternary complex consisting of EGCG, Triclosan and PfENR. Docking studies of these inhibitors and a model for the ternary complex is described in Chapter 4. Docking simulations show that these compounds indeed occupy NADH binding site. This study provides insights for further improvements in the usage of diphenyl ethers in conjugation or combination with tea catechins as possible antimalarial therapeutics. In search for new lead compounds against deadly diseases, in silico virtual screening and high throughput screening strategies are being adopted worldwide. While virtual screening needs a large amount of computation time and hardware, high throughput screening proves to be quite expensive. I adopted an intermediate approach, a combination of both these strategies and discovered compounds with a 2-thioxothiazolidin-4-one core moiety, commonly known as rhodanines as a novel class of inhibitors of PfENR with antimalarial properties. Chapter 5 describes the discovery of this class of compounds as inhibitors of PfENR. A small but diverse set of 382 compounds from a library of ~2,00,000 compounds was chosen for high throughput screening. The best compound gave an IC50 of 6.0 µM with many more in the higher micromolar range. The compound library was searched again for the compounds similar in structure with this best compound, virtual screening was conducted and 32 new compounds with better binding energies compared to the first lead and reasonable binding modes were tested. As a result, a new compound with an IC50 of 240 nM was discovered. Many more compounds gave IC50 values in 3-15 µM range. The best inhibitor was tested in red blood cell cultures of Plasmodium, it was found to inhibit the growth of the malaria parasite at an IC50 value of 0.75 µM. This study provides a new scaffold and lead compounds for further exploration towards antimalarial drug discovery. The summary of the results and conclusions of studies described in various chapters is given in Chapter 6. This chapter concludes the work described in the thesis. Cloning, over-expression and purification of PanD from M. tuberculosis, FabA and FabZ from E. coli are described in the Appendix.

Anti-Malarial Drugs

Anti-Bacterial Drugs

Fatty Acids - Biosynthesis

Malaria - Drugs

Bacteria - Drugs

Plasmodium Falciparum

Groundnuts - Vitamin B1

Enoyl ACP Reductase

Malaria Parasite

Antimalarials

Malaria Vaccine

FabZ

PfFabZ

Biochemistry

Unfolded Protein Response in Malaria Parasite

Chaubey, Shwetha

January 2014

Plasmodium falciparum is responsible for the most virulent form of human malaria. The biology of the intra-erythrocytic stage of P. falciparum is the most well studied as it is this stage that marks the clinical manifestation of malaria. To establish a successful infection, P. falciparum brings about extensive remodeling of erythrocytes, its host compartment. The infected erythrocytes harbor several parasite induced membranous structures. Most importantly, pathogenesis related structures termed knobs, which impart cytoadherence, appear on the cell surface of the infected erythrocytes. For bringing about such eccentric renovations in its host compartment, the parasite exports 8% of its genome (~400 proteins) to various destinations in the host cell. Studies from our lab have shown that proteins belonging to heat shock protein40 (Hsp40) and heat shock protein70 (Hsp70) group of chaperones are also exported to the host compartment. We and others have implicated these chaperones in important processes such as protein trafficking and chaperoning assembly of parasitic proteins into the cytoadherent knobs. As detailed above, malaria parasite invests a lot of energy in exporting a large number of proteins including chaperones in the red blood cell to meet its pathogenic demands. In order to do so, it heavily relies on its secretory pathway. However, it is known that the parasite experiences a significant amount of oxidative stress on account of heme detoxification, its own metabolism and the immune system of the host. The parasite also effluxes large quantities of reduced thiols such as glutathione and homocysteine into the extracellular milieu indicative of redox perturbation. Additionally, the parasite lacks Peroxiredoxin IV, which otherwise localizes in the ER and carries out detoxification of peroxide generated as a result of oxidative protein folding. Together, these factors indicate that maintaining redox homeostasis is a challenging task for the parasite. It also implies that the ER, where the redox balance is even more critical as it requires oxidising environment for protein folding, is predisposed to stress. In light of this fact and the importance of secretory pathway in malaria pathogenesis, we decided to address the ways and mechanisms used by the parasite to tackle perturbations in its secretory pathway. Examination of a canonical unfolded protein response pathway in P. falciparum ER-stress is a condition arising whenever the load of unfolded proteins increases the folding capacity of the ER. However, eukaryotes have evolved a fairly well conserved homeostatic response pathway known as unfolded protein response (UPR) to tackle ER-stress. This signal transduction pathway is composed of three arms involving three ER-transmembrane signal transducers namely; IRE1, ATF6 and PERK. IRE1 brings about splicing of a bZIP transcription factor, XBP1/Hac1 and ATF6 becomes activated upon getting proteolytically cleaved in the Golgi. These transcription factors then migrate to the nucleus where they bind onto the ER-stress elements thereby, leading to the transcriptional up-regulation of the UPR targets such as ER chaperones and components of ER associated degradation (ERAD) pathway which rescue the function of the ER. PERK on the other hand brings about translational attenuation by phosphorylating eIF2α, thereby providing parasite the benefit of time to recover. We started our examination on UPR in Plasmodium by carrying out in silico analysis of the major components of UPR in the parasite by using Homo sapiens protein sequences as the query. We found that the parasite lacks the homologues of all the transcriptional regulators of canonical UPR. Only PERK component of the UPR was found to be present in the parasite. To rule out the existence of the canonical UPR in P. falciparum, we examined the status of UPR targets by subjecting the parasites to treatment with DTT. DTT perturbs the disulfide oxidation in the ER and thereby inhibits protein folding leading to ER-stress. Owing to the missing components of a canonical UPR, we did not find up-regulation of known UPR targets such as ER-chaperones including PfBiP, PfGrp94, PfPDI and ERAD marker Derlin1 at transcript as well as protein level. Owing to the presence of a PERK homologue, phosphorylation of eIF2α followed by attenuation of protein synthesis was observed upon subjecting the parasites to DTT mediated ER-stress. In the absence of a canonical UPR, the parasites were found to be hypersensitive to ER-stress in comparison to the mammalian counterpart. In the presence of DTT, the parasites showed perturbation in the redox homeostasis as indicated by increase in the levels of ROS. Next, we sought to examine if the parasites resorted to any alternate means of increasing the availability of chaperones in the ER. For this, we analysed the involvement of another Hsp70 family member, Hsp70-x which is homologous to BiP and which is known to traverse the ER while getting exported to the erythrocyte compartment. Interestingly, we found that upon exposure to ER-stress, the export of this protein is partially blocked and around 30% of the protein is retained in the ER. On the other hand, there was no effect on the trafficking of another exported chaperone KAHsp40. This indicates that the parasite possibly recruits this pool of retained Hsp70-x for the chaperoning of unfolded proteins in the ER. Global response to ER-stress in P. falciparum To dig deeper into the parasite specific strategies employed for dealing with ER-stress at a global level, we carried out high throughput transcriptomic and proteomic analysis upon subjecting the parasites to DTT mediated ER-stress. Microarray based gene expression profiling was carried out upon subjecting the parasites to DTT mediated ER-stress. We found that the parasite mounts a transcriptional response as indicated by up-regulation of 155 transcripts. In congruence with our biochemical analysis, we did not find up-regulation of ER chaperones as well as ERAD proteins. Functional grouping of the up-regulated genes revealed large number of hypothetical proteins in our list of differentially expressed genes. The genes encoding exported proteins represent yet another abundant class. In the course of examining the involvement of Plasmodium specific transcriptional regulators mediating response to DTT induced ER-stress, we identified 4 genes belonging to the family of AP2 transcription factors. AP2 (Apetela-2) are specific transcription factors which are possessed by apicomplexa and bring about regulation of developmental processes and stress response in plants. On comparing our list of up-regulated genes with the previously known targets of AP2 factors, we found that an entire cascade of AP2 factors is up-regulated upon DTT-mediated ER stress. Thus, AP2 factors appear to be the major stress response mediators as they are together responsible for the up-regulation of 60% of genes identified in this study. In addition, another striking observation made, was the up-regulation of a few sexual stage specific transcripts. 2D Gel electrophoresis and 2D-DIGE based Proteomic analysis indicated an up-regulation of secretory proteins and some components of vesicular trafficking and secretory machinery possibly to overcome the block in the functions of the secretory pathway. ER-stress triggers stage transition in P. falciparum Intrigued by the up-regulation of a few sexual stage specific genes, we were curious to examine if there was a functional significance of this observation. To this end, we decided to investigate the effect of ER-stress on induction of gametocytes, the only sexual stage found in humans. Indeed, we found a two fold induction in the numbers of gametocytes formed upon challenging the parasite with DTT mediated ER-stress. The induction of gametocytogenesis was also observed by using a clinical isolate of P. falciparum for the assay. The DTT treated cultures progressed through the gametocytogenesis pathway normally forming all the five morphologically distinct stages. Then we sought to examine if this phenomenon could be simulated in the physiological scenario as well. For this, we made use of a rodent model of malaria, P. berghei. Two different treatment regimes involving 1) direct injection of increasing concentration of DTT into P. berghei infected mice and 2) injection of DTT pretreated P. berghei infected erythrocytes into healthy mice were followed. In both cases, a significant increase in the gametocyte induction was observed. Having seen that Plasmodium undergoes gametocytogenesis upon exposure to ER-stress not only in in vitro cultures but also in in vivo scenario, we wanted to identify the players involved in the commitment to sexual stage. Recently, a transcription factor belonging to AP2 class of transcription factors, referred to as AP2-G has been implicated in committing the asexual parasites for transition to gametocyte stage. To examine the role of this factor in the phenotype observed by us, we looked at the effect of DTT on AP2-G. Interestingly, we found around 6 folds up-regulation in the expression of AP2-G levels under ER-stress. The downstream targets of AP2-G, many of which are the markers of gametocyte were also found to be up-regulated upon being exposed to DTT mediated ER-stress indicating the launch of a transcriptional program which together works in the direction of transition to gametocytes. Having seen that P. falciparum undergoes ametocytogenesis in response to DTT treatment both under in vitro and in vivo conditions, we sought to look for probable physiological analogue of DTT. Since glutathione is the major cellular redox buffer, critical for redox homeostasis, we quantitated the levels of both oxidized and reduced forms of this non protein thiol using Mass Spectrometric approach. We found that the levels of reduced forms of glutathione significantly increased upon treating the parasites with DTT. This indicates that the levels of glutathione could be one of the physiological triggers of gametocytogenesis. Conclusion In conclusion, our study analyses the ways and mechanisms employed by malaria parasite to cope with perturbations to its secretory pathway. We have established the absence of a canonical UPR in this parasite and our results suggest that Plasmodium has developed a three stage response to cope with ER stress: 1) an early adaptation to increase the local concentration of chaperones in the ER by partially blocking the export of a Hsp70 family member, 2) activation of gene expression cascade involving AP2 transcription factors and 3) a consequent switch to the transmissible sexual stage. Hence, our study throws light on a novel physiological adaptation utilised by malaria parasite to tackle stress to its secretory pathway. Gametocytogenesis, which can be transmitted to the mosquito vector, could hence serve as an effective means to escape ER-stress altogether. Importantly, while it is widely known that stress brings about switch towards sexual stages in P. falciparum, the molecular triggers involved in this process remain obscure in the field of malaria biology. Therefore, our findings also address this long standing question by providing the evidence of ER-stress being one such trigger required for switching to the transmissible sexual stages.

Malaria Parasite

Plasmodium falciparum

Protein Export in Plasmodium falciparum

Unfolded Protein Response (UPR)

Endoplasmic Reticulum (ER) Stress

Gametocytogenesis

Cellular Stress Response

Host Cell Remodelling

Heat Shock Proteins

Virulence

Malaria Pathogenesis

P. falciparum

Heat Shock Protein

Heat Shock Factor

Biochemistry

Understanding the Heat Shock Response Pathway in Plasmodium Falciparum and Identification of a Novel Exported Heat Shock Protein

Grover, Manish

January 2014

Infections or diseases are not just stressful for the one who encounters it. The pathogens causing the same also have to deal with the hostile environment present in the host. The maintenance of physiological homeostatic balance is must for survival of all organisms. This becomes a challenging task for the protozoan parasites which often alternate between two different hosts during their life cycle and thereby encounter several environmental insults which they need to acclimatize against, in order to establish a productive infection. Since their discovery as proteins up-regulated upon heat shock, heat shock proteins have emerged as main mediators of cellular stress responses and are now also known to chaperone normal cellular functions. Parasites like Plasmodium falciparum have fully utilized the potential of these molecular chaperones. This is evident from the fact that parasite has dedicated about 2% of its genome for this purpose. During transmission from the insect vector to humans, the malaria parasite Plasmodium falciparum experiences a temperature rise of about 10oC, and the febrile episodes associated with asexual cycle further add to the heat shock which the parasite has to bear with. The exact mechanism by which the parasite responds to temperature stress remains unclear; however, the induction of chaperones such as PfHsp90 and PfHsp70 has been reported earlier. In other eukaryotes, there are three main factors which regulate heat shock response (HSR): heat shock factor (HSF), heat shock element (HSE) and HSF binding protein (HSBP). Bioinformatics analysis revealed presence of HSE and HSBP in P. falciparum genome; however, no obvious homolog of HSF could be identified. Either the HSF homologue in P. falciparum is highly divergent or the parasite has evolved alternate means to tackle temperature stress. Therefore, we decided to biochemically characterize HSBP and understand the heat shock response pathway in the parasite using transcriptomics and proteomics. The expression for PfHSBP was confirmed at both mRNA and protein level and it was found to translocate into the nucleus during heat shock. As previously reported for HSBP in other organisms, PfHSBP also exists predominantly in trimeric and hexameric form and it interacts with PfHsp70-1. Nearly 900 genes, which represent almost 17% of the parasite genome, were found to have HSE in their promoter region. HSE are represented by three repeating units of nGAAn pentamer and its inverted repeat nCTTn; however, the most abundant class of genes in P. falciparum possessed an atypical HSE which had only 2 continuous repeat units. Next, we were interested to find out if these HSE could actually bind to any parasite protein. Therefore, we performed EMSA analysis with the parasite nuclear extracts using HSE sequence as the oligonucleotide. We observed retarded mobility of the oligonucleotide suggesting that it was indeed able to recruit some protein from the nuclear extract. The importance of transcriptional regulation during heat shock was further confirmed when parasite culture subjected to heat shock in the presence of transcription inhibitor did not show induction in the levels of PfHsp70. These evidences suggest that parasite indeed possesses all the components of heat shock response pathway with either a divergent homologue of HSF or an alternate transcription factor which would have taken its role. Next, we performed global profiling of heat shock response using transcriptomic analysis and 2DDIGE based proteomic profiling. Overall, the parasite’s response to heat shock can be classified under 5 functional categories which aim at increasing the folding capacity of the cell, prevent protein aggregation, increase cytoadhesion, increase host cell remodelling and increase erythrocyte membrane rigidity. Out of the 201 genes found to be up-regulated upon heat shock, 36 were found to have HSE in their promoter region. This suggested that HSE-mediated protein up-regulation could be responsible for the induction of only 18% of total number of genes up-regulated upon heat shock. How would the parasite bring about up-regulation of rest of the heat shock responsive genes? It has been previously reported that genes for some of the heat shock proteins in P. falciparum possess G-box regulatory elements in their promoters and recently, it was shown that these elements served as the binding site for one of the transcription factors (PF13_0235) of AP2 family. Therefore, we looked for the status of this AP2 factor and its targets in our transcriptome data. Although, PF13_0235 was itself not up-regulated, we found up-regulation of its target genes which included another AP2 factor gene PF11_0404. The target genes of PF11_0404 were also up-regulated upon heat shock, thereby suggesting the functioning of an AP2 factor mediated response to heat shock. The next major challenge which the malaria parasite has to deal with is the remodelling of the erythrocyte as these cells do not have a cellular machinery which the parasite can take control of. The parasite remodels the erythrocyte with the help of its large repertoire of exported proteins and develops protrusions known as “knobs” on the erythrocyte surface. These protrusions are cytoadherent in nature and constitute the main virulence determinants of malaria. They also represent variable antigens that allow immune escape. Our lab has previously demonstrated an exported PfHsp40, termed as KAHsp40, to be involved in knob biogenesis. Apart from KAHsp40, there are 19 other PfHsp40s which possess the PEXEL motif required for protein export to erythrocytes. Although, Hsp40s work with an Hsp70 partner, none of the parasitic Hsp70s were known to be exported and was always a missing link in the field of malaria chaperone biology. A genomic re-annotation event could fill this gap by re-annotating the sequence for a pseudogene, PfHsp70-x and described it to contain a functional ORF. According to the re-annotated ORF sequence, PfHsp70-x possessed an ER signal peptide and thus could be targeted to the secretory pathway. Following validation of the re-annotation using a PCR-based approach, we confirmed the expression of this protein at the protein level by immunoblot analysis. Using various subcellular fractionation approaches and immunolocalization studies we established that PfHsp70-x indeed gets exported to the erythrocyte compartment; however, it did not contain the PEXEL motif required for protein export. It gets secreted into the vacuole around the parasite via the canonical ER-Golgi secretory pathway. Its trafficking from vacuole into the erythrocyte was mediated by a hexameric sequence which was present just after the signal peptide cleavage site and before the beginning of ATP-binding domain. In the erythrocyte compartment, it was found to interact with KAHsp40 and MAHRP1, proteins previously implicated in knob biogenesis. Most importantly, PfHsp70-x interacted with the major knob component PfEMP1; however, itself did not become part of knobs. Instead, it localized to the Maurer’s clefts in the erythrocyte compartment. Inside the parasite, PfHsp70-x was present in a complex with Plasmepsin V and PfHsp101. These proteins have been shown to be essential for host cell remodelling process. Plasmepsin V recognizes the PEXEL motif and brings about its cleavage and PfHsp101 specifically targets these PEXEL-cleaved exported proteins to the translocon in vacuolar membrane thereby facilitating their export into the erythrocyte. Thus, PfHsp70-x could also be involved in directing the export of knob constituents apart from just facilitating their assembly. Since, we found out that heat shock or the febrile episodes encountered during the asexual cycling of the parasite promote host cell remodelling; we wanted to find out if PfHsp70-x has any specific role under conditions of temperature stress. PfHsp70-x gene expression was not influenced upon heat shock, however, its export into the erythrocyte was inhibited and the protein got accumulated within the parasite compartment. Surprisingly, immunolocalization studies revealed that the accumulated pool of PfHsp70-x localized into the nucleus instead of ER thus suggesting an alternate role to be associated with PfHsp70-x under stress. Overall, our study addresses two major aspects of malaria pathogenesis. First, response to heat shock and second, remodelling of the host cell. We, for the first time describe global profiling of the parasite’s heat shock response and identify a novel P. falciparum specific heat shock protein member to be involved in malaria pathogenesis.

Plasmodium Falciparum

Heat Shock Proteins

Malaria Pathogenesis

Molecular Chaperones

Malaria Heat Shock Proteins

Heat Shock Factor Binding Proteins

Pathogen Virulence

Transcription Regulation

Transcriptomics

Proteomics

Genomics

Hsp90

Hsp70

Hsp40

Heat Shock Response Pathway

PfHsp70

PfHsp70-x

Malaria Parasite

Biochemistry