Citation: Cell Death and Disease (2011) 2, e231; doi:10.1038/cddis.2011.118

& 2011 Macmillan Publishers Limited All rights reserved 2041-4889/11 http://www.nature.com/cddis

Web End =www.nature.com/cddis

Disruption of a mitochondrial protease machinery in Plasmodium falciparum is an intrinsic signal for parasite cell death

S Rathore1,2, S Jain1,2, D Sinha1,2, M Gupta1, M Asad1, A Srivastava1, MS Narayanan1, G Ramasamy1, VS Chauhan1, D Gupta1

and A Mohmmed*,1

The ATP-dependent ClpQY protease system in Plasmodium falciparum is a prokaryotic machinery in the parasite. In the present study, we have identied the complete ClpQY system in P. falciparum and elucidated its functional importance in survival and growth of asexual stage parasites. We characterized the interaction of P. falciparum ClpQ protease (PfClpQ) and PfClpY ATPase components, and showed that a short stretch of residues at the C terminus of PfClpY has an important role in this interaction; a synthetic peptide corresponding to this region antagonizes this interaction and interferes with the functioning of this machinery in the parasite. Disruption of ClpQY function by this peptide caused hindrance in the parasite growth and maturation of asexual stages of parasites. Detailed analyses of cellular effects in these parasites showed features of apoptosis-like cell death. The peptide-treated parasites showed mitochondrial dysfunction and loss of mitochondrial membrane potential. Dysfunctioning of mitochondria initiated a cascade of reactions in parasites, including activation of VADFMK-binding proteases and nucleases, which resulted in apoptosis-like cell death. These results show functional importance of mitochondrial proteases in the parasite and involvement of mitochondria in programmed cell death in the malaria parasites.

Cell Death and Disease (2011) 2, e231; doi:http://dx.doi.org/10.1038/cddis.2011.118

Web End =10.1038/cddis.2011.118 ; published online 24 November 2011

Subject Category: Internal Medicine

Malaria remains a major parasitic disease in the tropical and sub-tropical countries causing 12 million deaths globally every year.1,2 The malaria parasite harbors two organelles of prokaryotic origin, the mitochondrion and the apicoplast. The metabolic pathways in these organelles are important for growth cycle and survival of the parasite.35 Characterization of novel metabolic pathways in these organelles and understanding their functional role in parasite growth and survival may be a key step to design new anti-malarial strategies.

ATP-dependent protease machineries including the eukaryotic 26S proteasome and the prokaryotic casenolytic proteases (Clp) systems are large protein-degradation complexes that have an essential role in cell-cycle regulation.6,7

The ClpQY machinery is a multimeric ATP-dependent protease system in prokaryotes that resembles the eukaryotic 26S proteasome; it consists of two stacked hexameric rings of ClpQ protease that are capped on one of both sides with a hexameric ring of AAA-type ATPase, ClpY.8 The ATPases act as chaperons to unfold the substrate proteins, which subsequently get degraded by the protease component. Interaction of protease and ATPase components is essential for proper functioning of these protease machineries.8,9

The eukaryotic 26S proteasome machinery is an important regulatory system that controls level of key cell-cycle

regulators and transcription factors;7,10 Inhibition of the 26S proteasome dysregulates cell processes that leads to apoptosis of eukaryotic cells.1012 The ClpQY machinery

shows mechanistic resemblance with 26S proteasome.7 The ClpQY machinery is shown to regulate levels of cell division inhibitor and to function as an activator of capsular polysaccharide synthesis.13

The P. falciparum genome harbors two Clp protease systems, ClpQY and ClpAP. We have earlier characterized P. falciparum ClpQ (PfClpQ) protease and ClpP protease system.14,15 The

PfClpQ protease is localized in mitochondria whereas PfClpP is localized in apicoplast, relict plastid in the parasite.15,16 Our

interest in understanding functional importance of prokaryotic machineries in the parasite prompted us to assess possible functional role of the ClpQY machinery in the parasite. In the present study, we have functionally characterized complete ClpQY system in P. falciparum. Disruption of ClpQY activity using a small peptide that interferes with functioning of this machinery, caused dysregulation of mitochondrial functions, which in turn activated cascade of reactions leading to apoptosis-like cell death of the parasite. These results suggest role of mitochondrial proteases in maintenance of functional mitochondria and points towards involvement of mitochondria in apoptosis-like cell death in parasite.

1International Centre for Genetic Engineering and Biotechnology, New Delhi, India*Corresponding author: A Mohmmed, International Centre for Genetic Engineering and Biotechnology, Aruna Asaf Ali Marg, New Delhi 110067, India. Tel: 91 11 2674 1358; Fax: 91 11 2674 2316; E-mail: mailto:[email protected]

Web End [email protected]

2These authors contributed equally to this work.

Keywords: Plasmodium; ClpQY machinery; mitochondria; programmed cell deathAbbreviations: Clp, casenolytic proteases; PCD, programmed cell death; FITCVADFMK, uorescein isothiocyanate-valyl-alanyl-aspartyl-[O-methyl]-uoromethylketone; Ant, antennapedia internalization sequence; Dcm mitochondrial membrane potential; Z-GGL-AMC, benzyloxycarbonyl-glycyl-glycyl-leucyl-7-amido-4-methylcoumarin; TUNEL, terminal deoxynucleotidyl transferase dUTP nick end labeling

Received 13.5.11; revised 16.9.11; accepted 30.9.11; Edited by M Piacentini

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Results

PfClpQ and PfClpY are expressed in the asexual blood-stage parasites and form a protein complex. We have earlier identied and characterized P. falciparum homolog of ClpQ protease (PfClpQ).15 We have now identiedP. falciparum ClpY orthologue (PfClpY) (See supporting information) (Figures 1a and b and Supplementary Figure S1). Real-time quantitative PCR analyses showed that transcription of pfclpY and pfclpQ start in trophozoite stages, with maximum transcript levels in late-trophozoiteand schizont-stage parasites (Supplementary Figure S2). Western blot analysis using anti-PfClpY antibodies with total parasite lysates detected PfClpY as a B100 kDa protein in trophozoite and schizont stages (Figure 1c). In addition, a lower band of B55 kDa was also detected that may represent the processed fragment of PfClpY. The western-blot analysis using anti-PfClpQ antibodies detected the pro-PfClpQ (B22 kDa) and mature-PfClpQ (B18 kDa) in trophozoite- and schizont- stage parasites with maximum expression in schizont stage. These results suggest that both PfClpQ and PfClpY are expressed in the blood-stage parasites in the late-trophozoite and schizont stages.

We next carried out co-immunoprecipitation studies to ascertain that the PfClpQ and PfClpY form a protein complex

in the parasite. Western-blot analysis of immunoprecipitated complex showed that the PfClpQ gets co-immunoprecipitated with PfClpY from parasite lysate (Figure 1d). The PfClpQ was not detected in eluates from control reactions with pre-immune sera or with non-specic antibodies in place of anti-PfClpY antibodies. These experiments suggest that the ClpQ and ClpY are present in the same protein complex in the parasite; detailed in vitro and yeast two-hybrid assays were carried out, as described below, to assess if these two proteins interact directly to form the protein complex as in case of other organisms.68

PfClpY interacts with PfClpQ through its C terminus to form a protein complex. To ascertain the direct interaction of PfClpQ and PfClpY and to decipher role of C-terminal region of PfClpY in this interaction, we carried out different proteinprotein binding assays using recombinant proteins, as well as by yeast-two-hybrid assays. In an in vitro solution-binding assay, PfClpQ formed a protein complex with PfClpY that was pulled down by anti-PfClpY antibodies (Figure 2a); however PfClpQ did not form a protein complex in control experiments where PfClpY was replaced with another recombinant protein, PfMSP119. Next, we also carried out in vitro solid-phase interaction studies using recombinant PfClpY and PfClpQ to ascertain their interaction. The PfClpQ

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Figure 1 PfClpQ and PfClpY are expressed in the asexual-stage parasites and form a protein complex in the parasite. (a) Schematic domain structure of PfClpY (Gene ID PFI0355c) showing location of N, I and C domains, respective amino-acid positions and walker A and B domains are also indicated. (b) Schematic representation of structure of PfClpQ showing location of pro-domain and mature protease. The locations of conserved residues of active site triad are also marked. (c) Western blot analyses of total lysates of equal number of synchronized parasites at ring (810 h post invasion (hpi)), trophozoite (3032 hpi) and schizont (4245 hpi) stages with antibodies against the PfClpQ and PfClpY showing expression of both the proteins in trophozoite-schizont stages. Anti-histidine rich protein-II (HRPII) antibodies were used to probe a blot run in parallel to show equal loading in each well. (d) Co-immunoprecipitation of PfClpQ and PfClpY from parasite lysate using anti-PfClpY antibodies; PfClpQ protein was detected in the immunoprecipitated protein complex by western blot analysis. Immunoprecipitation reactions using non-specic antibodies or no antibodies were used as controls

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Figure 2 (a and b) Interaction of PfClpQ with PfClpY and its C-terminal fragments. (a) Solution-binding assays of PfClpQ and PfClpY recombinant proteins followed by in vitro pulldown of the protein complex using anti-PfClpY antibodies; PfClpQ protein was detected in the pulled down protein complex by western blot analysis. Control reactions were carried out in the absence of PfClpY protein or replaced with a non-specic protein (PfMSP-119); in another reaction the anti-ClpY antibodies were replaced with control antibodies (pre-immune). (b) In vitro solid-phase interaction of PfClpQ with increasing concentration of PfClpY and its C-terminal fragments; proteinprotein interaction was estimated by ELISA using anti-PfClpY antibody. The PfClpY and PfClpY-C showed concentration-dependent interaction with PfClpQ, whereas PfClpY-DC showed no signicant binding. (ce) Interaction of synthetic peptide corresponding to C terminus of PfClpY (FI-peptide) with PfClpQ protein. (c) A solution-binding assay of

PfClpQ with Dansyl-labeled FI-peptide (Dansyl-FI), complex formation lead to change in uorescence in the reaction. Fluorescence change (DF) was estimated using different concentration of the labeled peptide. The labeled peptide showed concentration-dependent binding with PfClpQ. (d) Inhibition of binding of Dansyl-FI and PfClpQ in presence of increasing concentration of unlabeled FI-peptide. Increasing concentration of unlabeled FI-peptide reduced binding of Dansyl-FI in a concentration-dependent manner. (e) Global tting of the sensograms obtained by owing increasing concentrations (5, 10, 20, 40 mM) of FI-peptide for 4 mins on PfCIpQ immobilized on the CM5 chip and dissociation for 4 min under similar ow conditions. Buffer alone was used as control that showed no responses to PfCIpQ. (f and g) FI-peptide and PfClpY shares the binding site on PfClpQ. (f) Percentage binding of FI-peptide and PfClpQ in a solution-binding assay in absence or presence of increasing concentration of PfClpY. Presence of PfClpY reduced the binding of FI-peptide and PfClpQ; a 10-fold increase in FI-peptide concentration restored the binding with PfClpQ. (g) Percentage binding of PfClpQ and PfClpY in a ELISA-based assay in absence or presence of increasing concentration of FI peptide

showed binding with the PfClpY in a concentration-dependent manner. Further, the C-terminal fragment of PfClpY, PfClpY-C, showed binding with PfClpQ in a similar manner. However, its truncated version, PfClpY-DC, showed

poor binding with PfClpQ (Figure 2b). Results of yeast two-hybrid analyses also suggested that PfClpQ and PfClpY interact with each other and form a protein complex, this interaction is through C-terminal domain of PfClpY and a

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stretch of residues in its C terminus has an important role in this interaction (see Supplementary information; Supplementary Figure S4; Supplementary Table S2).

C-terminal peptide of PfClpY (FI peptide) binds with PfClpQ and shares the binding site with PfClpY. To further study the role of C-terminal region of PfClpY in its interaction with PfClpQ, we used a 12-amino-acid-long synthetic peptide (FI-peptide) corresponding to the C terminus of PfClpY. Binding of PfClpQ with FI-peptide was studied by uorescence spectroscopy using dansylated derivative of FI-peptide, Dansyl-FI. The labeled peptide showed binding with recombinant PfClpQ in a concentration-dependent manner (Figure 2c). To ascertain specicity of this interaction, the interaction of labeled peptide (Dansyl-FI) was competed with increasing concentrations of unlabeled FI-peptide. The unlabeled peptide was able to compete effectively with the labeled peptide and inhibited its binding with PfClpQ (Figure 2d); however, no inhibition was seen with a non-specic peptide.

A surface plasma resonance-based biomolecular-interaction analysis was carried out to quantitatively assess binding of ClpQ and FI-peptide. In this assay, the recombinant PfClpQ was used as ligand and FI-peptide was used as analyte. The assay channel showed typical association and dissociation curves as compared with the control cells, which show little uctuation due to solvent (Figure 2e). However, no difference in response units was detected when FI-peptide was injected in either blank ow cells or ow cells coated with a non-specicP. falciparum recombinant protein (MSP-119). Similarly, no response was observed when a scrambled-FI-peptide was owed over immobilized PfClpQ. Therefore, BIACORE analysis shows specic binding of PfClpQ with the C-terminal peptide, FI. The calculated binding constant, Kd, for the ClpQ and FI-peptide interaction was estimated to be 62.4 mM with rate constants, ka, of 157/M s, and dissociation rate constants, kd, of 9.76 10 3/s (the chi-square value for the t is 2.39).

However, the binding constant and the dissociation constant of PfClpQFI interaction suggest that the interaction has low binding afnity. A low signal/background ratio in the danyslated-peptide assays and low binding-peptide afnity may be responsible for high peptide concentration required in the interaction studies (Figure 2).

To ascertain that the FI-peptide and PfClpY share the same binding site on PfClpQ, solution-binding assays of Dansyl-FI-peptide and PfClpQ were carried out in presence of PfClpY. As shown in Figure 2f, presence of PfClpY in the assay reduced binding of FI-peptide with PfClpQ. Level of inhibition was a function of PfClpY concentration at a xed concentration of FI-peptide. However, when FI-peptide concentration was increased, it was able to overcome this antagonism of PfClpY and restored its binding with PfClpQ. These results suggest that there is competition between FI-peptide and PfClpY to bind with PfClpQ, and thus the FI-peptide shares the PfClpQ-binding site with PfClpY protein. Further, we also assessed the inhibition of PfClpYPfClpQ binding in the ELISA experiment by FI-peptide. Interaction of PfClpQ and PfClpY was inhibited in presence of FI-peptide. The level of inhibition was a function of FI-peptide concentration (Figure 2g). However, as discussed above, a relatively high

concentration of FI-peptide is required to interfere with PfClpQPfClpY interaction.

Effect of FI-peptide treatment on parasite growth. We next investigated effect of FI-peptide on parasite growth and development in vitro. To facilitate uptake of the peptide, a 16-aa sequence of Antennapedia (Ant) homeoprotein was coupled to the amino terminus of FI-peptide (Ant-FI) (Supplementary Figure S5). The Antennapedia internalization sequence has been known to facilitate uptake of peptides into P. falciparum.17,18 Treatment of parasite cultures with Ant-FI-peptide inhibited parasite growth in a dose dependent manner (Figure 3a). At 50 mM concentration

Ant-FI-peptide showed B50% growth inhibition, and at 100 mM it showed 9095% growth inhibition (Figure 3a) as compared with control. The effector concentration for half maximum response (EC50) value was B50 mM. No signicant growth inhibition was observed in culture treated with

Ant-Scr control peptide (Figure 3a).

We also assessed any eventual recovery of FI-peptide treated culture after removing the peptide at different time points. Removal of the peptide at 13 h after treatment resulted in almost complete reversal of growth inhibition and parasite cultures were able to recover; when peptide was removed at 4 h time point there was o20% growth inhibition suggesting that about 80% of parasites were able to recover the growth. However, when peptide was removed at 6 h after treatment, a large percentage of parasite (440%) population was not able to recover (Supplementary Figure S6). Similarly lower percentage population of parasite was able to recover the growth when the peptide was removed at 8 or 16 h after treatment (Supplementary Figure S6).

Disruption of PfClpQY activity by FI-peptide disrupts the intra-erythrocytic parasite cycle. To study the effect of Ant-FI-peptide on parasite development and morphology, synchronized parasite cultures at early-trophozoite stages were treated with Ant-FI-peptide at 50 mM or 90 mM concentrations (BEC50 and BEC90 respectively). In control sets, parasites developed from early-trophozoites to late-trophozoites in 68 h after treatment and subsequently into mature schizonts within 1216 h after treatment. The merozoites released from these schizonts invaded new RBCs and developed into ring-stage parasites 2430 h after treatment (Figure 3b). However, parasite treated with Ant-FI-peptide showed abnormal developmental morphology; in addition, these parasites were not able to develop into schizonts. A large percentage of parasites in cultures treated with Ant-FI-peptide showed condensed cytosol, darkly stained nucleus and abnormal shape of plasma membrane within 810 h after treatment (Figure 3c); later the parasite cytosol became completely condensed and parasites appeared as densely stained structures (Figure 3c). The percentage of parasites with these crisis form morphology increased with the incubation time and peptide concentration. At 50 mM, about 55%

of parasites showed crisis form morphology within 1015 h after treatment, whereas at 90 mM peptide concentration, almost all parasites showed abnormal morphology and turned into condensed round densely stained pycnotic

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Figure 3 Effect of FI-peptide treatment on growth and development of P. falciparum. (a) Tightly synchronized early-trophozoite-stage parasite cultures (B30 hpi) were treated with different concentration of FI-peptide, Ant-FI peptide, Ant-scrambled peptide and solvent alone, percentage parasite growth was estimated by formation of new ring-stage parasites as compared with untreated culture. (b) Effect of Ant-FI-peptide treatment (at 50 and 90 mM) on parasite stage composition at different time points (30

58 hpi). The percentage of parasites at young trophozoite (YT), late trophozoite (LT), early schizont (ES), late schizont (LS), ring stage (R), and stressed pycnotic forms (Pyc) are indicated. (c) Effect of Anti-FI-peptide treatment (at 90 mM) on parasite morphology at different time points (3058 hpi)

forms within 1015 h after treatment (Figure 3c). These parasites remained as pycnotic forms in the culture and did not show any vacuolated structure. These parasites were not able to develop into schizonts or form any merozoites (Figure 3b).

FI-peptide treatment disrupts mitochondria membrane potential (Dwm). The morphological phenotypes induced by FI-peptide treatment of parasites were reminiscent of apoptosis phenotype. Therefore, we examined the treated parasites for cellular features associated with the apoptosis.

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Figure 4 In situ mitochondrial membrane potential of P. falciparum parasite after treatment with Ant-FI-peptide as estimated by JC-1 staining. (a) Flow-cytometry histogram showing reduction in JC-1 red staining in the parasite population treated with Ant-FI-peptide as compared with parasites treated with scrambled peptide or solvent alone. (b) Graph showing ratio of JC-1 (red)/JC-1 (green) parasite population after treatment with Ant-FI, Ant-Scrambled (Ant-Scr) or solvent alone. (c) Fluorescent microscopic images of JC-1-stained parasite showing accumulation of aggregated JC-1 (red staining) in the mitochondria and monomeric JC-1 (green staining) in the cytosol. Treatment of Ant-FI-peptide caused loss of membrane potential, which reduced red staining in the mitochondria of the parasite. The parasite nuclei were stained with DAPI (blue) and parasites were visualized by uorescence microscope

Given that the mitochondria is a key component of onset of apoptosis and ClpQY machinery is functional in the parasite mitochondria, we rst studied the effect of Ant-FI-peptide treatment on mitochondria membrane potential by JC-1 dye staining. In the control set, the parasites showed JC-1-red staining that represents JC-1 aggregation in the mitochondria, suggesting presence of functional mitochondria (Figure 4a). The ratio of parasite population with mitochondrial red and cytosolic green staining in the control set was found to be

B1.0 (Figure 4b). Parasite treated with Ant-FI-peptide at BEC90 showed a signicant decrease in JC-1 red staining after 3 h (Figure 4a) leading to signicant decline in the ratio of

JC-1 red- and green-stained population to B0.4 (Figure 4b, Supplementary Figure S7). Fluorescence microscopy also showed loss of JC-1 red staining in the mitochondria of the treated parasites (Figure 4c). These results clearly show loss of mitochondria membrane potential (Dcm) in the parasite by

FI-peptide treatment. No or little effect was seen at 1 h after

treatment of the parasites as evident from JC-1 red/green ratio. Control parasite treated with solvent alone or with Ant-scrambled peptide showed no signicant change in the membrane potential (Figures 4a and b).

Loss of Dwm in FI-peptide treated parasites activates caspase-like proteases and leads to apoptosis-like cell death in parasite. We next assessed if loss of Dcm leads to activation of any caspase-like cysteine protease activity in the parasite. Synchronized parasite cultures were treated with peptide or solvent alone, and analyzed at different time points for staining with CaspACE (FITCVADFMK), a cell permeable and uorescent tagged in situ marker that binds with activated caspase-like proteases. In solvent control sets, a basal level of staining was detected in 510% of the parasites. The Ant-FI-peptide (90 mM) treated parasite showed activation of caspase-like protease activity within 4 h of treatment; the percentage of cell showing uorescent

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labeling increased for 412 h after treatment reaching to a maximum of B70% of parasites showing CaspACE staining (Figures 5a and b and Supplementary Figure S8). However, at time point earlier than 4 h there was no signicant increase in CaspACE-stained parasite population in the treated cultures as compared with the control, suggesting that activation of VADFMK-binding proteases occur B4 h after the treatment. At 16 h after treatment, there was some decrease in the number of stained parasites, which may be due to increase in number of parasites in pycnotic crisis form (Figures 5a and b and Supplementary Figure S8).

Further, we also analyzed the DNA fragmentation in the parasites by using the TUNEL assay. The Ant-FI-peptide-treated parasites showed TUNEL staining that overlapped with the DAPI staining, (Figures 6a and b) suggesting fragmentation of the nuclear DNA. The percentage of parasite showing TUNEL staining increased as a function of peptide

concentration and time after treatment. Parasites treated with peptide at BEC50 (50 mM) showed TUNEL-positive cells 4 h after the treatment with maximum percentage of TUNEL-positive parasites B50% at 16 h after treatment. Whereas cultures treated with peptide at BEC90 (90 mM) showed almost all the parasites (B90%) with TUNEL staining at 16 h after treatment (Figure 6a). Control parasite treated with DMSO alone and parasite treated with Ant-scrambled peptide did not show any TUNEL staining in the parallel assay.

Discussion

The ClpQY protease machinery consists of the ClpQ protease and an AAA chaperon ClpY, which together form multimeric

protein complex, presenting structural and functional analogies with the eukaryotic 26S proteasome. In the present study, we have identied full ClpQY system in the malaria parasite. Our results show that the ClpQ and ClpY protein inP. falciparum are part of a protein complex as shown in prokaryotes.68 We have earlier carried out homology modeling and molecular docking studies of ClpQY protein complex, these studies combined with computational alanine scanning suggested mechanism of interaction between PfClpQ and PfClpY subunits through the C-terminal residues of PfClpY in the loop region.19 To ascertain that the PfClpQ and PfClpY interact directly to form a protein complex, we carried out detailed in vitro and cell-based proteinprotein interaction studies. Our results show that the PfClpQ and PfClpY interact with each other; the C-terminal region of PfClpY representing the C-domain (PfClpY-C) is involved in its interaction with PfClpQ and a short stretch of amino acids in the C terminus of PfClpY has a key role in this interaction. These results corroborated with our in silico interaction studies of the PfClpQY protein complex.19 With a view to understand the functional role of ClpQY machinery in the parasite, we identied a peptide-based inhibitor that could be utilized to disrupt the interaction of PfClpQ and PfClpY, and hence inhibit function of ClpQY machinery in parasite. Small peptide-based antagonists that are copy of natural motifs involved in interactions of cognate proteins are being developed to disrupt high-afnity protein interactions and modulate target-protein machineries in the cells.2022 We assessed potential of

a synthetic peptide (FI-peptide), corresponding to the short stretch at the C terminus of PfClpY, to bind with PfClpQ. The FI-peptide showed specic binding with PfClpQ; competition-binding assays showed that PfClpY and FI-peptide share the same binding site on PfClpQ; further, the FI-peptide also antagonizes PfClpQ and PfClpY interaction. These results suggest that FI-peptide can be used to disrupt the ClpQY functioning in parasites and study functional signicance of this protease machinery. Recently, small peptides and peptide-based inhibitors have been successfully used to block function of different proteases and inhibit malaria parasite growth.17,18,23 The FI-peptide treatment caused

severe inhibition of parasite growth; further, development of treated parasites was effected and these parasites were not able to develop into mature schizonts. However, micromolar concentrations of FI-peptide are needed to exert the effect on parasite growth; this could be due to slow uptake of peptides by parasites. Indeed, only high

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ControlAnt-FI (100M) treated

4h8h 4h8h

DAPI

TdT

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Figure 6 DNA fragmentation in P. falciparum parasites as assessed by TUNEL staining. (a) Graph showing percentage of TUNEL-positive parasites in the cultures at different time points (4,6,8 and 16 h) after treatment with peptides Ant-FI (50 and 90 mM), Ant-scrambled (Ant-Scr, 90 mM) or solvent alone. (b) Fluorescent microscopic images of TUNEL-positive parasites (TdT red staining) in treated cultures as compared with controls. The parasite nuclei were stained with DAPI (blue) and parasites were visualized by uorescence microscope

micromolar concentrations of peptide inhibitors are shown to affect parasite growth in earlier studies.17,18

The ClpQ protease was recently localized in the matrix of the mitochondria in P. falciparum;23 similarly, ClpQ orthologue was also localized in mitochondria of Trypanosoma brucei.24

Parasite mitochondrion has an important role in critical biosynthetic processes, including ironsulfur cluster biosyn-thesis, heme biosynthesis and ubiquinone biosynthesis.25

As ClpQY is the only protease machinery localized in the mitochondria, it may be having an important role in the

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mitochondrial functioning in the apicomplexan parasites. Indeed, knocking down of ClpQ orthologue in T. brucei lead to reduced growth of parasites.24

The Plasmodium mitochondrion has a linear B6 kb-long genome that encodes three proteins, Cox1, CytB and Cox3, as well as a number of rRNA subunits.26,27 In addition, 4350 nuclear-encoded proteins are targeted to the parasite mitochondrion.28 These proteins have roles in different metabolic pathways in the mitochondrion. Deregulation of metabolic pathways in mitochondria and loss of mitochondrial membrane potential is usually lethal for eukaryotic cells. Inhibition of ATP-dependent Lon protease in mitochondria of eukaryotic cells caused accumulation of aggregated proteins, which subsequently lead to apoptosis of cells.29 The ClpQY

system in parasite mitochondria might have an important regulatory role for the parasite. Indeed, silencing of ClpQ inT. brucei showed loss of control of replication of minicircle DNA in the mitochondria leading to reduced parasite growth.24

Plasmodium mitochondrion does not possess minicircle DNA, and the ClpQY machinery may be involved in regulation of proteins involved in other metabolic pathways. Our results with parasite growth-inhibition assay using FI-peptide suggest that the ClpQY protease machinery has an important functional role in Plasmodium mitochondria; any interference in its activity could destabilize the mitochondrial functioning. Inhibition of ClpQY protease machinery using interfering FI-peptide caused signicant loss of mitochondrial membrane potential. This effect was combined with morphological phenotypes of the parasites that are reminiscent of the apoptosis-like phenotype, including condensation of cytosol and darkly stained nucleus. Induction of apoptosis-like features in asexual stage P. falciparum parasites is shown after chloroquine treatment, which include cellular characteristics, such as loss of mitochondrial membrane potential (Dcm), activation of caspase-like cytseine proteases and nuclear DNA fragmentation.30,31 In the present study, disrup

tion of ClpQY machinery also resulted in loss of Dcm, which subsequently lead to increased number of CaspACE-tagged parasites and DNA fragmentation of the parasites. These results suggest that inhibition of the ClpQY machinery caused deregulation of mitochondrial growth and functioning. Dys-functioning of mitochondria in turn acts as an intrinsic signal in the parasite, which initiates a cascade of reactions leading to apoptosis-like cell death. We also assessed any eventual recovery of the FI-peptide-treated culture after removing the peptide at different time points; the FI-peptide treatment can be reversed in early stage (14 h), however longer treatment induces changes in the parasite with point of no return.

We further show that activation of VADFMK-binding proteases and DNA fragmentation follow after the loss of Dcm in the parasite; loss in Dcm started at 23 h after treatment whereas caspase like-activity and DNA fragmentation were observed at 46 h after treatment. The P. falciparum genome does not contain any classical caspase-like protein. Caspase-like activity is also described during apoptosis in other organisms that lack classical caspases.3234 Although

P. falciparum genome also harbors two metacaspase-like proteases that are closely related to eukaryotic caspases, it is still not clear if these proteases are directly involved in apoptosis-like process in parasites. Our results show that

VADFMK-binding proteases get activated after loss of Dcm and dysfunctioning of the mitochondria. The identity of

VADFMK-binding proteases, exact role of these proteases, specic target substrates and complex cascade of induction/ activation during apoptosis in parasites remains to be elucidated.

Overall, we have identied the complete ClpQY machinery in P. falciparum and show that the ClpQY machinery is important for maintenance of functional mitochondria in parasites. Our results suggest that deregulation of parasite mitochondria triggers a cascade of reactions that leads to apoptosis-like cell death in the parasite.

Materials and MethodsParasite culture, and growth inhibition assays. P. falciparum strain 3D7 was cultured with human erythrocytes (4% hematocrit) in RPMI media (Invitrogen, Eugene, OR, USA) supplemented with 10% O human serum using a

protocol described previously.35 Cultures were synchronized by repeated sorbitol treatment, following Lambros and Vanderberg.36 The amino-acid sequences of all the peptides used in the study are given in Supplementary Table S1. Assays for growth inhibition by different peptides were performed as previously described.17

Briey, tightly synchronized P. falciparum 3D7 parasites at early-trophozoite stage were cultured in 96-well plates in which hematocrit and parasitemia were adjusted to4.0% and 0.8%, respectively. Puried peptides were added to the parasite cultures to variable nal concentrations (1.0125 mM). Control wells were treated with solvent alone. Each assay was performed in triplicate and the experiment was repeated at least twice. The cultures were incubated for 24 h, smears were made from each well at different time points and stained with Giemsa. To assess growth of the parasite, numbers of new ring-stage parasites formed were determined per 5000 RBCs, percentage parasitemia was calculated and percentage growth was calculated as compared with the parasitemia in solvent controls. To assess any recovery of the treated culture after peptide removal, the parasite cultures were treated with the peptide at BEC50 as described above, subsequently the cultures were washed with RPMI at different time points after treatment (116 h) to remove the peptide. Inhibition of parasite growth was assessed as described above and compared with unwashed controls.

Isolation of DNA, total RNA and quantitative RT-PCR. The genomic DNA was isolated from in vitro culture of P. falciparum following a standard protocol.37 Total RNAs were isolated from synchronized P. falciparum 3D7 parasite cultures using mini-RNA isolation kit (Qiagen, Hilden, Germany). An aliquot of 50 ng of total RNA was used to synthesize cDNA using cDNA synthesis kit (Invitrogen) following manufacturers recommendations. Gene-specic primers were designed using Beacon Designer4.0 software (Premier Biosoft, Palo Alto, CA, USA), for the genes pfclpY (416A, 50-TTATATCCTCATGAGATTGTGGAATATTTG-30 and 461-2A, 50-TTACCATGAAATCCAACTTCTGTAAAC-30), eba175 (EBA175RTF: 50-AAT TTCTGTAAAATATTGTGACCATATG-30 and EBA175RTR: 50-GATACTGCACAAC ACAGATTTCTTG-30) and falcipain 2 (Fal2F 50-GCTTGTAGGTTTTGGTATGAAAG AA-30 and Fal2 R 50-AGATAGGTCCCTTTTTAAAATACTATTGAC-30);38 18S rRNA control primers (18SF 50-GCTGACTACGTCCCTGCCC-30; 18SR 50-ACAATTCATC ATATCTTTCAATCGGTA-30) were used following.39 Quantitative real-time PCR were carried out in triplicate using the iCycler version 3.0 (Bio-Rad); each reaction was containing equal amount of cDNA, 100 ng of each gene-specic primers and 1 SYBR Green PCR mix (Bio-Rad, Hercules, CA, USA). Threshold cycle (Ct)

values were calculated by using iCycler software. Standard curves for each gene were obtained by using different dilutions of wild-type gDNA (1001 ng) as template, and these standard curves were used to determine genome equivalents of Ct values for every gene and 18S rRNA in each RNA sample.39 Genome equivalents of each gene were normalized using that of 18S rRNA for all RNA samples.

Expression and purication of recombinant proteins (PfClpQ, PfClpY and C-terminal fragments of PfClpY) and ATPase assay. Expression and purication of recombinant protein corresponding to mature region of PfClpQ (38170 aa) was carried out as described earlier.14

The threonine protease activity of puried-PfClpQ protein was assessed using uorogenic-peptide substrate Z-GGL-AMC as described earlier.14 A large fragment of PfClpY (485922 aa) harboring N-, I- and C-domains, was amplied from total

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cDNA of the parasite by PCR using primers 563A, 50-GGCGGATCCCTTATATCC TCATGAGATTGTGG-30 and 415A, 50-CCGAAGCTTCTCGAGTTATATGATATATT TATTATAGTCGTATTGC-30. The amplied PCR product was digested with BamHI and HindIII and cloned into BamHI and HindIII sites of pET28b vector (Novagen, Merck Biosciences Ltd., Darmstadt, Germany). The recombinant plasmid pET28b-PfClpY was transformed into Escherichia coli expression cells BL21(DE3) (Novagen) for expression of recombinant protein with N-terminal histidine tag. These cells were grown in Luria broth containing ampicillin (100 mg/ml) at 37 1C to an OD600nm of 0.50.6 and expression of the recombinant protein was induced with isopropyl-b-thioglactopyranoside (IPTG) at a nal concentration of 1.0 mM. The cultures were then allowed to grow for an additional 2 h at 37 1C with shaking and the E. coli cells were harvested by centrifugation. The cell pellet was suspended in lysis buffer (20 mM Tris pH 8.0, 250 mM NaCl, 5 mM benzamidine-HCl, 0.05% Tween 20), lysed by sonication (Torebeo Ultrasonic Processor36800, Cole Parmer, Vernon Hills, IL, USA) and centrifuged at 12 000 r.p.m. for 20 min at 4 1C. The inclusion-bodies pellet obtained was lysed in lysis buffer (10 mM Tris-HCl, 100 mM

NaCl, 6 M Gu-HCl, 10 mM Imidazole, pH 8.0) and the recombinant protein was puried by afnity chromatography using Ni-NTA resin. The protein was refolded by rapid dilution in a buffer containing 50 mM Tris-HCl buffer pH 7.4, 1 mM EDTA, 1 M urea, 2 mM reduced glutathione, 0.2 mM oxidized glutathione, 0.1 mM PMSF and 0.5 M L-Arginine, keeping a nal protein concentration of o0.8 mg/ml.

Subsequently, the sample was dialyzed against Tris-HCl buffer (pH 7.4) containing 20 mM NaCl, and the recombinant protein was puried by an-ion exchange chromatography using Q-Sepharose resin. Fractions containing pure PfClpY protein were pooled and concentrated.

A C-terminal fragment of PfClpY (725922 aa) harboring the C-domains, was amplied from total cDNA of the parasite by PCR using primers 601-2A, 50-GGC

GCCATGGAAGAAGGAATTGTTTTTATAG-30 and 570A, 50-GCCGGATCCTTATA TGATATATTTTTTTAAGTCGTATTGC-30. The amplied fragment was cloned into NcoI and BamHI sites of pET32b vector (Novagen) to give pET32-PfClpY-C construct. A similar PfClpY fragment with 12-residue deletion at the C terminus (725910 aa; PfClpY-DC) was amplied using primers 601-2A, and 571A, 50-GCC

GGATCCTTAAATAAAACCTTCCAGCG-30, the amplied fragment was cloned in pET32b vector to give pET32-PfClpY-DC. The recombinant PfClpY-C and

PfClpPY-DC proteins were expressed in E. coli cells harboring respective plasmid construct. The recombinant proteins were puried from cytosolic fractions by afnity chromatography as described above using a column of Ni-NTA resin.

The hydrolysis of ATP by PfClpY was analyzed by pyrophosphate (32P)-release assay using g32P-ATP. The reaction mixture consisting of labeled g32P-ATP (9 mCi)

and unlabeled ATP (1 mM), 110 mg of recombinant PfClpY protein in 20 mM Tris-HCl (pH 8.0) buffer containing 8 mM DTT, 1.0 mM MgCl2 and 10 mM KCl was incubated at 37 1C for 2 h followed by thin-layer chromatography. The chromatography plate was air dried and exposed to the X-ray lm.

Generation of polyclonal anti-sera and western immunoblotting. To generate polyclonal anti-sera against PfClpY, female BALB/c mice were immunized (on day 0) with the puried recombinant protein (25 mg) formulated in complete Freunds adjuvant (Sigma, St. Louis, MO, USA). The mice were administered two booster doses (day 14 and 28) of the proteins formulated in Freunds incomplete adjuvant. The mice serum was collected 10 days after the second boost.

For western blot analyses, parasites were isolated from tightly synchronized cultures at different developmental stages by lyses of infected erythrocyte with0.15% saponin. Parasite pellets were washed with PBS, suspended in Laemmli buffer, boiled, centrifuged, and the supernatant obtained was separated on 12% SDS-PAGE. The fractionated proteins were transferred from gel onto the nitrocellulose membrane (Amersham, Piscataway, NJ, USA) and blocked in blocking buffer (1 PBS, 0.1% Tween-20, 5% milk powder) for 2 h. The blot was

washed and incubated for 1 h with primary antibody (mouse anti-PfClpY (1 : 500); rabbit anti-PfClpQ (1 : 1000); rabbit anti-HRPII (1 : 2000)) diluted in dilution buffer (1 PBS, 0.1% Tween-20, and 1% milk powder). Later, the blot was washed and

incubated for 1 h with appropriate secondary antibody (anti-rabbit or anti-mouse, 1 : 2000) conjugated to HRP, diluted in dilution buffer. Bands were visualized by using ECL detection kit (Amersham).

In vitro binding assays for proteinprotein and proteinpeptide interactions. Proteinprotein interaction was assessed by solution binding of the two proteins followed by in vitro pulldown of the protein complex. Briey, anti-PfClpY antibodies were allowed to bind with protein-A sepharose beads in 20 mM

Tris pH 7.4, NaCl 150 mM (TBS) for 30 min at 4 1C with gentle agitation, the beads were then blocked with 5% BSA in TBS. Recombinant ClpY and ClpQ were allowed to bind with each other at 4 1C for 2 h (nal concentration in the reaction 2 mg/ml of each) in the binding buffer. The mixture was then incubated (4 1C for 2 h) with protein A Sepharose beads having immobilized-anti-ClpY antibodies, to pull down the complex. After extensive washing with TBS-T (TBS containing 0.1% Triton- X 100) the beads were boiled in SDS-PAGE buffer and centrifuged. The supernatant was separated on SDS-PAGE, transferred to nitrocellulose and probed with anti-PfClpQ antibodies. In control reactions, the ClpY protein was either absent or replaced with a non-specic P. falciparum recombinant protein (MSP-119); in

another control the anti-ClpY antibodies were replaced with control antibodies (pre-immune).

In vitro proteinprotein interactions were also studied in an ELISA-based assay. Briey, wells of Maxi-Sorp micro-titer plates (Nunc International, Nunc, Langenselbold, Germany) were adsorbed with recombinant PfClpY (100 ng in each well) at 4 1C. The wells were washed thrice with 1 PBS containing 0.05% Tween-

20 (PBS-T) and blocked with 1% BSA in 1 PBS for 2 h. Puried recombinant ClpQ

in varying concentrations (20200 ng) was added to the ClpY-coated wells and incubated for 2 h at room temperature. Plates were then washed ve times with PBS-T followed by sequential incubation with puried anti-ClpQ antibody (dilution 1 : 2000) and goat anti-mouse horse radish peroxidase (HRP)-labeled secondary antibody (dilution 1 : 3000). After repeated washing, the enzyme reactions were developed with 50 ml of o-phenylenediamine dihydrochloride-H2O2 in a citrate phosphate buffer (pH 5.0), the reactions were stopped with 25 ml of 2N H2SO4 and OD490 was measured using a 96-well micro-plate reader (Genios Pro; Tecan Instruments, Tecan, Mannedorf, Switzerland).

Solution-binding assays were carried out to study interaction of ClpQ protein and peptides following Ramachandran et al.40 The dansylated FI-peptide (Dansyl-FIKQYDLKKYII) was added to varying nal concentration (10100 mM) in wells of a at-bottom micro-titer plate containing 200 ml protein ClpQ (monomeric concentration of 13 mM) in 20 mM Tris, 300 mM NaCl. The uorescence spectra from each well were recorded at emission and excitation wavelengths of 335 and 533 nm, respectively, using Fluo-Star micro-plate reader (BMG Technologies, BMG LABTECH, Ortenberg, Germany). Enhancement in uorescence values (DF533)

were calculated after subtracting values from respective control wells where the dansylated peptide was added only to the buffer. For competition assay between dansylated and unlabeled FI peptide, increasing concentrations (1070 mM) of unlabeled peptide (FIKQYDLKKYII) were added to the wells containing ClpQ and 80 mM of dansylated peptide for the same assay. To assess the competition between FI-peptide and ClpY for binding with recombinant ClpQ, the solution-binding assays were carried out in the same way using dansylated FI-peptide in presence of varied concentrations of ClpY protein.

Surface-plasmon resonance analysis. Real-time interactions of PfClpQ with FI-peptide (FIKQYDLKKYII) were analyzed by surface plasmon resonance studies under ow condition using Biacore 2000 instrument. The carboxymethylated-dextran surfaces of Biacore CM5 sensor chips were activated by injection of 1 : 1 mixture of N-hydroxysuccinimide (NHS) (Biacore AB, Biacore, Uppsala, Sweden) and 1-ethyl-3-(3-dimethylaminopropyl)-carbodiimide hydrochloride (EDC) (Biacore AB) for 7 min at a ow rate of 10 ml/min. Recombinant

PfClpQ (10 mg/ml in 10 mM sodium acetate buffer, pH 4.5) was injected over the activated surface of a sensor chip ow cell at a ow rate of 10 ml/min so as to achieve an immobilization equivalent to 500 RU. A non-specic recombinant protein was immobilized on surface of another sensor chip ow cell in similar way and was used as a negative control. A third sensor chip ow cell was blocked by injection of ethanolamine (Biacore AB) at a ow rate of 10 ml/min for 5 min and was used as blank. Kinetic-binding analysis for interaction of PfClpQ was carried out by injecting the FI-peptide at different concentrations (5, 10, 20, 40 mM) in independent experiments. The peptide or recombinant proteins were injected for 4 min at a ow rate of 30 ml/min with the running buffer (10 mM HEPES, pH 7.4, 150 mM NaCl, 3 mM EDTA and 0.005% P20 surfactant); the dissociation was monitored for 240 seconds with the running buffer at the same ow rate. To correct for refractive index changes caused by running buffer and instrument noise, running buffer was injected at a ow rate of 30 ml/min in the blank ow cells and the observed response difference was subtracted from the experimental data. The ow rate of the peptide and the recombinant proteins was varied from 10 to 75 ml/min in order to assess whether the binding interactions were limited by mass transfer. A non-specic peptide (Ant peptide) was used in the control experiments. The experimental surface was regenerated by injecting regeneration solution (1 M ethanolamine) at a

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ow rate of 30 ml/min for 1 min. The binding constant, Kd, was calculated as kd1/ka1 by using data analysis program BIAevaluation 3.2RC1 (Biacore AB). Kinetic rate constants were determined by tting the corrected response data to a simple 1 : 1 (HillLangmuir binding isotherm model using BIAevaluation 3.2RC1 software).

Co-immunoprecipitation of PfClpQY complex in the parasite lysate. Infected RBCs were collected from synchronized parasite culture (late-trophozoite stage), suspended in 1 PBS pH 7.4 containing cleavable

protein cross-linker DTSSP (Pierce Biotechnology Inc., Rockford, IL, USA) (nal concentration 2 mM) and incubated for 2 h on ice. The parasites were harvested by lysis of the infected RBCs by 0.15 % saponin in RPMI for 10 min on ice. Parasite pellet was suspended in TEN buffer (Tris 50 mM pH 7.4, 20 mM EDTA) containing protease-inhibitor cocktail (Roche, Indianapolis, IN, USA) and then lysed by three freeze-thaw cycles. The lysate was claried by centrifugation at 12 000 g for

30 min at 4 1C and pre-cleared with Protein-A Sepharose beads. The pre-cleared parasite extract was incubated with Protein-A Sepharose beads having immobilized anti-PfClpY antibodies (anti-PfClpY-Protein A Sepharose beads) for 2 h at 4 1C with gentle agitation. After incubation the beads were washed extensively in TEN buffer containing 0.1% Tween-20. The immune complex were dissociated by boiling the beads in SDS-PAGE buffer and centrifuged to separate the beads. The supernatant was separated on SDS-PAGE and analyzed by immunoblotting using anti-PfClpQ antibodies. In control reactions, the anti-PfClpY antibodies were replaced with control antibodies (pre-immune) or with antibodies against a non-specic P. falciparum protein, PfAARP.41

Mitochondria membrane potential assay. The mitochondrial membrane potential was assessed in the parasite using MitoProbe JC-1 Assay Kit for Flow Cytometry (Molecular Probe, Eugene, OR, USA), this kit uses a unique cationic dye, JC-1 (5,50,6,60-tetrachloro-1,10,3,30- tetraethylbenzimidazolylcarbocyanine iodide), that remains in monomeric form in the cytoplasm and has a green uorescence (525 nm). However, the membrane potential of functional mitochondria establishes a negative charge that allows the lipophilic dye to accumulate and form aggregates in the mitochondria, which have red uorescence (590 nm). Infected RBCs were collected from parasite cultures in control and experimental sets at different time points and incubated with JC-1 dye (at a nal concentration. of 10 mM) for 30 min at 37 1C. Cells were washed with PBS and analyzed by ow cytometry using

FACSCalibur ow cytometer and CellQuestPro software (Becton Dickinson, San Jose, CA, USA). The infected RBCs were analyzed using green (488 nm) and red (635 nm) lters. Ratio of JC-1 (red)/JC-1 (green) were calculated to assess the loss of mitochondrial membrane potential. The JC-1-stained uninfected RBCs were used as background controls.

Caspase-like cysteine protease-activation assay. A specic caspase-inhibitor CaspACE FITCVADFMK In Situ Marker (Promega, Mannheim, Germany) was used to assess activation of Caspase-like cysteine protease activity in the parasite, following manufacturers instructions. Briey, the infected RBCs were collected from parasite cultures in control and experimental sets at different time points and incubated with 10 mM of CaspACE FITCVADFMK for 30 min at 37 1C followed by washing with 1 PBS. The stained samples were analyzed by ow

cytometer using FACSCalibur ow cytometer and CellQuestPro software (Becton Dickinson) to assess uorescence staining of infected RBCs. Uninfected RBCs were used as background control and parasite culture treated with solvent alone was used as negative controls.

Terminal deexynucleotidyl transferase (TdT) mediated dUTP nick-end labeling (TUNEL). The DNA fragmentation in the parasite was assessed by TUNEL using In Situ Cell Death Detection Kit, TMR Red (Roche Applied Science), following manufacturers instructions. Briey, the infected RBCs from control and experimental wells were collected at different time points, xed with 4% paraformaldehyde (PFA) for 1 h and washed with 1 PBS. Subsequently, the

cells were incubated with a mixture of TdT enzyme and TMR Red-labeled dUTP for 1 h at 37 1C. The labeled parasites were observed under uorescence microscope and percentage of TUNEL-positive parasites was calculated. Untreated parasites and parasites treated with DNase were used as negative and positive controls, respectively.

Fluorescence microscopy. P. falciparum cultures stained with JC-1 dye and by TUNEL assay were visualized by uorescence microscopy. These parasites were stained with DAPI at a nal concentration of 2 mg/ml for 30 min at 37 1C before

imaging. The stained parasites were viewed using a Nikon TE 2000-U uorescence microscope or Nikon A1R confocal laser scanning microscope (Nikon, Tokyo, Japan). For TUNEL assay, total number of parasites was counted by nuclear staining and percentage of TUNEL-positive parasites was calculated. To study uptake of peptide in the parasite, the peptide was labeled with EZ-Link Sulfo-NHSLC-LC-Biotin (Pierce) following manufacturers instruction; the treated parasite were xed in 4% PFA, stained with streptavidin-FITC and MitoTracker Red CMXRos (Invitrogen) as described earlier15 and the parasite was visualized using uorescence microscope.

Conict of Interest

The authors declare no conict of interest.

Acknowledgements. We thank Rotary blood bank, New Delhi for providing the human RBCs. SR and MA are supported by research fellowship from ICMR, Govt. of India. SJ is supported by research fellowship from CSIR, Govt. of India. The research work in AMs laboratory is supported by Department of Biotechnology, Govt. of India.

1. Snow RW, Guerra CA, Noor AM, Myint HY, Hay SI. The global distribution of clinical episodes of Plasmodium falciparum malaria. Nature 2005; 434: 214217.

2. Hay SI, Guerra CA, Gething PW, Patil AP, Tatem AJ, Noor AM et al. A world malaria map: Plasmodium falciparum endemicity in 2007. PLoS Med 2009; 6: e1000048.

3. Waller RF, McFaddenm GI. The apicoplast: a review of the derived plastid of apicomplexan parasites. Curr Issues Mol Biol 2005; 7: 5779.

4. Goodman CD, Su V, McFadden GI. The effects of anti-bacterials on the malaria parasite Plasmodium falciparum. Mol Biochem Parasitol 2007; 152: 181191.

5. Dahl EL, Rosenthal PJ. Apicoplast translation, transcription and genome replication: targets for antimalarial antibiotics. Trends Parasitol 2008; 24: 279284.

6. De Mot R, Nagy I, Walz J, Baumeister W. Proteasomes and other self compartmentalizing proteases in prokaryotes. Trends Microbiol 1999; 7: 8892.

7. Ciechanover A. Intracellular protein degradation: from a vague idea thru the lysosome and the ubiquitin-proteasome system and onto human diseases and drug targeting. Cell Death Differ 2005; 12: 11781190.

8. Bochtler M, Hartmann C, Song HK, Bourenkov GP, Bartunik HD, Huber R. The structures of HsIU and the ATP-dependent protease HsIU-HsIV. Nature 2000; 403: 800805.

9. Seong IS, Kang MS, Choi MK, Lee JW, Koh OJ, Wang J et al. The C-terminal tails of HslU ATPase act as a molecular switch for activation of HslV peptidase. J Biol Chem 2002; 277: 2597625982.

10. Navon A, Ciechanover A. The 26 S proteasome: from basic mechanisms to drug targeting. J Biol Chem 2009; 284: 3371333718.

11. Fribley A, Wang CY. Proteasome inhibitor induces apoptosis through induction of endoplasmic reticulum stress. Cancer Biol Ther 2006; 5: 745748.

12. MacLaren AP, Chapman RS, Wyllie AH, Watson CJ. p53-dependent apoptosis induced by proteasome inhibition in mammary epithelial cells. Cell Death Differ 2001; 8: 210218.

13. Kanemori M, Yanagi H, Yura T. The ATP-dependent HslVU/ClpQY protease participates in turnover of cell division inhibitor SulA in Escherichia coli. J Bacteriol 1999; 181: 36743680.

14. Ramasamy G, Gupta D, Mohmmed A, Chauhan VS. Characterization and localization of Plasmodium falciparum homolog of prokaryotic ClpQ/HslV protease. Mol Biochem Parasitol 2007; 152: 139148.

15. Rathore S, Sinha D, Asad M, Bttcher T, Afreen F, Chauhan VS et al. A cyanobacterial serine protease of Plasmodium falciparum is targeted to the apicoplast and plays important role in its growth and development. Mol Microbiol 2010; 77: 873890.

16. Tschan S, Kreidenweiss A, Stierhof YD, Sessler N, Fendel R, Mordmller B. Mitochondrial localization of the threonine peptidase PfHslV, a ClpQ ortholog in Plasmodium falciparum. Int J Parasitol 2010; 40: 15171523.

17. Dhawan S, Dua M, Chishti AH, Hanspal M. Ankyrin peptide blocks falcipain-2-mediated malaria parasite release from red blood cells. J Biol Chem 2003; 278: 3018030186.18. Korde R, Bhardwaj A, Singh R, Srivastava A, Chauhan VS, Bhatnagar RK et al. A prodomain peptide of Plasmodium falciparum cysteine protease (falcipain-2) inhibits malaria parasite development. J Med Chem 2008; 51: 31163123.

19. Subramaniam S, Mohmmed A, Gupta D. Molecular modeling studies of the interaction between Plasmodium falciparum HslU and HslV subunits. J Biomol Struc Dyn 2008; 26: 473479.

20. Kheifets V, Mochly-Rosen D. Insight into intra- and inter-molecular interactions of PKC: design of specic modulators of kinase function. Pharmacol Res 2007; 55: 467476.21. Caputo GA, Litvinov RI, Li W, Bennett JS, Degrado WF, Yin H. Computationally designed peptide inhibitors of protein-protein interactions in membranes. Biochemistry 2008; 47: 86008606.

22. Hernez B, Tarrag T, Giralt E, Escribano JM, Alonso C. Small peptide inhibitors disrupt a high-afnity interaction between cytoplasmic dynein and a viral cargo protein. J Virol 2010; 84: 1079210801.

Cell Death and Disease

PCD in Plasmodium by disruption of ClpQY machinery S Rathore et al

12

23. Jean L, Hackett F, Martin SR, Blackman MJ. Functional characterization of the propeptide of Plasmodium falciparum subtilisin-like protease-1. J Biol Chem 2003; 278: 2857228579.

24. Li Z, Lindsay ME, Motyka SA, Englund PT, Wang CC. Identication of a bacterial-like HslVU protease in the mitochondria of Trypanosoma brucei and its role in mitochondrial DNA replication. PLoS Pathog 2008; 4: e1000048.

25. Mather MW, Henry KW, Vaidya AB. Mitochondrial drug targets in apicomplexan parasites. Curr Drug Targets 2007; 8: 4960.

26. Feagin JE. The 6-kb element of Plasmodium falciparum encodes mitochondrial cytochrome genes. Mol Biochem Parasitol 1992; 52: 145.

27. Suplick K, Morrisey J, Vaidya AB. Complex transcription from the extrachromosomal DNA encoding mitochondrial functions of Plasmodium yoelii. Mol Cell Biol 1990; 10: 63816388.

28. Bender A, van Dooren GG, Ralph SA, McFadden GI, Schneider G. Properties and prediction of mitochondrial transit peptides from Plasmodium falciparum. Mol Biochem Parasitol 2003; 132: 5966.

29. Bota DA, Ngo JK, Davies KJ. Down regulation of the human Lon protease impairs mitochondrial structure and function and causes cell death. Free Radic Biol Med 2005; 38: 665677.

30. Meslin B, Barnadas C, Boni V, Latour C, De Monbrison F, Kaiser K et al. Features of apoptosis in Plasmodium falciparum erythrocytic stage through a putative role of PfMCA1 metacaspase-like protein. J Infect Dis 2007; 195: 18521859.

31. Chng JH, Kotturi SR, Chong AG, Lear MJ, Tan KS. A programmed cell death pathway in the malaria parasite Plasmodium falciparum has general features of mammalian apoptosis but is mediated by clan CA cysteine proteases. Cell Death Dis 2010; 1: e26.

32. Das M, Mukherjee SB, Shaha C. Hydrogen peroxide induces apoptosis-like death in Leishmania donovani promastigotes. J Cell Sci 2001; 114 (Part 13): 24612469.

33. Lee N, Bertholet S, Debrabant A, Muller J, Duncan R, Nakhasi HL. Programmed cell death in the unicellular protozoan parasite Leishmania. Cell Death Differ 2002; 9: 5364.

34. Madeo F, Herker E, Maldener C, Wissing S, Lachelt S, Herlan M et al. A caspase-related protease regulates apoptosis in yeast. Mol Cell 2002; 9: 911917.

35. Trager W, Jensen JB. Human malaria parasites in continuous culture. Science 1976; 193: 673675.

36. Lambros C, Vanderberg JP. Synchronization of Plasmodium falciparum erythrocytic stage in culture. J Parasitol 1979; 65: 418420.

37. Schlichtherle M, Wahlgren M, Perlmann H, Scherf A. Methods in Malaria Research. MR4/ATCC: Manassas, 2000.

38. Dasaradhi PV, Mohmmed A, Kumar A, Hossain MJ, Bhatnagar RK, Chauhan VS, VAet al. A role of falcipain-2, principal cysteine proteases of Plasmodium falciparum in merozoite egression. Biochem Biophys Res Commun 2005; 336: 10621068.

39. Blair PL, Witney A, Haynes JD, Moch JK, Carucci DJ, Adams JH. Transcripts of developmentally regulated Plasmodium falciparum genes quantied by realtime RT-PCR. Nucleic Acids Res 2002; 30: 22242231.

40. Ramachandran R, Hartmann C, Song HK, Huber R, Bochtler M. Functional interactions of HslV (ClpQ) with the ATPase HslU (ClpY). Proc Natl Acad Sci 2002; 99: 73967401.

41. Wickramarachchi T, Devi YS, Mohmmed A, Chauhan VS. Identication and characterization of a novel Plasmodium falciparum merozoite apical protein involved in erythrocyte binding and invasion. PLoS One 2008; 3: e1732.

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