Plasmodium Topoisomerase VIB and Spo11 Constitute Functional Type IIB Topoisomerase in Malaria Parasite: Its Possible Role in Mitochondrial DNA Segregation.

The human malaria parasite undergoes a noncanonical cell division, namely, endoreduplication, where several rounds of nuclear, mitochondrial, and apicoplast replication occur without cytoplasmic division. Despite its importance in Plasmodium biology, the topoisomerases essential for decatenation of replicated chromosome during endoreduplication remain elusive. We hypothesize that the topoisomerase VI complex, containing Plasmodium falciparum topiosomerase VIB (PfTopoVIB) and catalytic P. falciparum Spo11 (PfSpo11), might be involved in the segregation of the Plasmodium mitochondrial genome. Here, we demonstrate that the putative PfSpo11 is the functional ortholog of yeast Spo11 that can complement the sporulation defects of the yeast Δspo11 strain, and the catalytic mutant Pfspo11Y65F cannot complement such defects. PfTopoVIB and PfSpo11 display a distinct expression pattern compared to the other type II topoisomerases of Plasmodium and are induced specifically at the late schizont stage of the parasite, when the mitochondrial genome segregation occurs. Furthermore, PfTopoVIB and PfSpo11 are physically associated with each other at the late schizont stage, and both subunits are localized in the mitochondria. Using PfTopoVIB- and PfSpo11-specific antibodies, we immunoprecipitated the chromatin of tightly synchronous early, mid-, and late schizont stage-specific parasites and found that both the subunits are associated with the mitochondrial genome during the late schizont stage of the parasite. Furthermore, PfTopoVIB inhibitor radicicol and atovaquone show synergistic interaction. Accordingly, atovaquone-mediated disruption of mitochondrial membrane potential reduces the import and recruitment of both subunits of PfTopoVI to mitochondrial DNA (mtDNA) in a dose-dependent manner. The structural differences between PfTopoVIB and human TopoVIB-like protein could be exploited for development of a novel antimalarial agent. IMPORTANCE This study demonstrates a likely role of topoisomerase VI in the mitochondrial genome segregation of Plasmodium falciparum during endoreduplication. We show that PfTopoVIB and PfSpo11 remain associated and form the functional holoenzyme within the parasite. The spatiotemporal expression of both subunits of PfTopoVI correlates well with their recruitment to the mitochondrial DNA at the late schizont stage of the parasite. Additionally, the synergistic interaction between PfTopoVI inhibitor and the disruptor of mitochondrial membrane potential, atovaquone, supports that topoisomerase VI is the mitochondrial topoisomerase of the malaria parasite. We propose that topoisomerase VI may act as a novel target against malaria.

A Chimeric Peptide Inhibits Red Blood Cell Invasion by Plasmodium falciparum with Hundredfold Increased Efficacy.

Inhibiting the formation of a tight junction between two malaria parasite proteins, apical membrane antigen 1 and rhoptry neck protein 2, crucial for red blood cell invasion, prevents progression of the disease. In this work, we have used a unique approach to design a chimeric peptide, prepared by fusion of the best features of two peptide inhibitors, that has displayed parasite growth inhibition ex vivo with nanomolar IC50 , which is 100 times better than any of its parent peptides. Furthermore, to gain structural insights, we computationally modelled the hybrid peptide on its receptor.

Heat Shock Protein 90 Regulates the Activity of Histone Deacetylase Sir2 in Plasmodium falciparum.

Sir2 protein of Plasmodium falciparum has been implicated to play crucial roles in the silencing of subtelomeric var genes and rRNA. It is also involved in telomere length maintenance. Epigenetic regulation of PfSIR2 transcription occurs through a direct participation of the molecular chaperon PfHsp90, wherein PfHsp90 acts as a transcriptional repressor. However, whether the chaperonic activity of PfHsp90 is essential for the maturation and stability of PfSir2A protein has not yet been explored. Here, we show that PfSir2A protein is a direct client of PfHsp90. We demonstrate that PfHsp90 physically interacts with PfSir2A, and the inhibition of PfHsp90 activity via chemical inhibitors, such as 17-AAG or Radicicol, results in the depletion of PfSir2A protein, and consequently its histone deacetylase activity. Thus, derepression of var genes and ribosomal silencing were observed under PfHsp90 inactivation. This finding that PfHsp90 provides stability to PfSir2A protein, in addition to the previous finding that PfHsp90 downregulates PfSIR2A transcription and subsequently cellular abundance, uncovers the multifaceted roles of PfHsp90 in regulating PfSir2 abundance and activity. Given the importance of PfSir2 protein in Plasmodium biology, it is reasonable to propose that the PfHsp90-PfSir2 axis can be exploited as a novel druggable target. IMPORTANCE Malaria continues to severely impact the global public health not only due to the mortality and morbidity associated with it, but also because of the huge burden on the world economy it imparts. Despite the intensive vaccine-research and drug-development programs, there is not a single effective vaccine suitable for all age groups, and there is no drug on the market against which resistance is not developed. Thus, there is an urgent need to develop novel intervention strategies by identifying the crucial targets from Plasmodium biology. Here, we uncover that the molecular chaperone PfHsp90 regulates the abundance and activity of the histone-deacetylase PfSir2, a prominent regulator of Plasmodium epigenome. Given that PfSir2 controls both virulence and multiplicity of the parasite, and that PfHsp90 is an essential chaperone involved in diverse cellular processes, our findings argue that the PfHsp90-PfSir2 axis could be targeted to curb malaria.

Synergistic Action between PfHsp90 Inhibitor and PfRad51 Inhibitor Induces Elevated DNA Damage Sensitivity in the Malaria Parasite.

The DNA recombinase Rad51 from the human malaria parasite Plasmodium falciparum has emerged as a potential drug target due to its central role in the homologous recombination (HR)-mediated double-strand break (DSB) repair pathway. Inhibition of the ATPase and strand exchange activity of P. falciparum Rad51 (PfRad51) by a small-molecule inhibitor, B02 [3-(phenylmethyl)-2-[(1E)-2-(3-pyridinyl)ethenyl]-4(3H)-quinazolinone], renders the parasite more sensitive to genotoxic agents. Here, we investigated whether the inhibition of the molecular chaperone PfHsp90 potentiates the antimalarial action of B02. We found that the PfHsp90 inhibitor 17-AAG [17-(allylamino)-17-demethoxygeldanamycin] exhibits strong synergism with B02 in both drug-sensitive (strain 3D7) and multidrug-resistant (strain Dd2) P. falciparum parasites. 17-AAG causes a greater than 200-fold decrease in the half-maximal inhibitory concentration (IC50) of B02 in 3D7 parasites. Our results provide mechanistic insights into such profound synergism between 17-AAG and B02. We report that PfHsp90 physically interacts with PfRad51 and promotes the UV irradiation-induced DNA repair activity of PfRad51 by controlling its stability. We find that 17-AAG reduces PfRad51 protein levels by accelerating proteasomal degradation. Consequently, PfHsp90 inhibition renders the parasites more susceptible to the potent DNA-damaging agent methyl methanesulfonate (MMS) in a dose-dependent manner. Thus, our study provides a rationale for targeting PfHsp90 along with the recombinase PfRad51 for controlling malaria propagation.

Febrile temperature causes transcriptional downregulation of Plasmodium falciparum Sirtuins through Hsp90-dependent epigenetic modification.

Sirtuins (PfSIR2A and PfSIR2B) are implicated to play pivotal roles in the silencing of sub-telomeric genes and the maintenance of telomere length in P. falciparum 3D7 strain. Here, we identify the key factors that regulate the cellular abundance and activity of these two histone deacetylases. Our results demonstrate that PfSIR2A and PfSIR2B are transcriptionally downregulated at the mid-ring stage in response to febrile temperature. We found that the molecular chaperone PfHsp90 acts as a repressor of PfSIR2A & B transcription. By virtue of its presence in the PfSIR2A & B promoter proximal regions PfHsp90 helps recruiting H3K9me3, conferring heterochromatic state, and thereby leading to the downregulation of PfSIR2A & B transcription. Such transcriptional downregulation can be reversed by the addition of 17-(allylamino)-17-demethoxygeldanamycin or Radicicol, two potent inhibitors of PfHsp90. The reduced occupancy of PfSir2 at sub-telomeric var promoters leads to the de-repression of var genes. Thus, here we uncover how exposure to febrile temperature, a hallmark of malaria, enables the parasites to manipulate the expression of the two prominent epigenetic modifiers PfSir2A and PfSir2B.

Functional studies of Plasmodium falciparum's prohibitin1 and prohibitin 2 in yeast.

Prohibitins (PHBs) are evolutionarily conserved mitochondrial integral membrane proteins, shown to regulate mitochondrial structure and function, and can be classified into PHB1 and PHB2. PHB1 and PHB2 have been shown to interact with each other, and form heterodimers in mitochondrial inner membrane. Plasmodium falciparum has orthologues of PHB1 and PHB2 in its genome, and their role is unclear. Here, by homology modelling and yeast two-hybrid analysis, we show that putative Plasmodium PHBs (Pf PHB1 and Pf PHB2) interact with each other, which suggests that they could form supercomplexes of heterodimers in Plasmodium, the functional form required for optimum mitochondrial function.

Functional studies of Plasmodium falciparum putative SURF1 in Saccharomyces cerevisiae.

BACKGROUND AND OBJECTIVES: The mitochondrial electron transport chain (mtETC) of Plasmodium falciparum is an important drug target. Identification and functional validation of putative mitochondrial proteins of the mtETC is critical for drug development. Many of the regulatory subunits and assembly factors of cytochrome c oxidase readily identifiable in humans and yeast are missing in P. falciparum. Here, we describe our efforts to identify and validate the function of putative Pfsurf1, a key assembly factor of complex IV of the mtETC. METHODS: Multiple sequence alignment of SURF 1/Shy 1 was carried out in Clustal X 2.1. Phylogenetic tree was constructed using "Draw tree" option in Clustal X, and was analyzed using interactive Tree of Life software. To identify the conserved sequences, domain search was done using Jalview version 2.8.2 (BLOSUM 62 scoring). The haploid Saccharomyces cerevisiae strain (BY4741) containing the null allele shy1 (Orf: YGR112w) (shy1::Kan) was complemented with putative Pfsurf1 to study its ability to rescue the growth defect. RESULTS: Similarity searches of PfSURF1-like protein in the Pfam shows statistically significant E = 4.7e-10 match to SURF1 family. Sequence alignment of PfSURF1 with other SURF1-like proteins reveals the conservation of transmembrane domains, α-helices and ß-pleated sheets. Phylogenetic analysis clusters putative PfSURF1 with apicomplexan SURF1-like proteins. Yeast complementation studies show that Pfsurf1 can partially rescue the yeast shy1 mutant, YGR112w. INTERPRETATION & CONCLUSION: Bioinformatics and complementation studies in yeast show that P. falciparum's SURF1 is the functional ortholog of human SURF1 and yeast Shy1.

Benzimidazolinone-Free Peptide o-Aminoanilides for Chemical Protein Synthesis.

The thioester surrogate 3,4-diaminobenzoic acid (Dbz) facilitates the efficient synthesis of peptide thioesters by Fmoc chemistry solid phase peptide synthesis and the optional attachment of a solubility tag at the C-terminus. The protection of the partially deactivated ortho-amine of Dbz is necessary to obtain contamination-free peptide synthesis. The reported carbamate protecting groups promote a serious side reaction, benzimidazolinone formation. Herein we introduce the Boc-protected Dbz that prevents the benzimidazolinone formation, leading to clean peptide o-aminoanilides suitable for the total chemical synthesis of proteins.

Glu-108 in Saccharomyces cerevisiae Rad51 Is Critical for DNA Damage-Induced Nuclear Function.

DNA damage-induced Rad51 focus formation is the hallmark of homologous recombination-mediated DNA repair. Earlier, we reported that Rad51 physically interacts with Hsp90, and under the condition of Hsp90 inhibition, it undergoes proteasomal degradation. Here, we show that the dynamic interaction between Rad51 and Hsp90 is crucial for the DNA damage-induced nuclear function of Rad51. Guided by a bioinformatics study, we generated a single mutant of Rad51, which resides at the N-terminal domain, outside the ATPase core domain. The mutant with an E to L change at residue 108 (Rad51E108L) was predicted to bind more strongly with Hsp90 than the wild-type (Rad51WT). A coimmunoprecipitation study demonstrated that there exists a distinct difference between the in vivo associations of Rad51WT-Hsp90 and of Rad51E108L-Hsp90. We found that upon DNA damage, the association between Rad51WT and Hsp90 was significantly reduced compared to that in the undamaged condition. However, the mutant Rad51E108L remained tightly associated with Hsp90 even after DNA damage. Consequently, the recruitment of Rad51E108L to the double-stranded broken ends was reduced significantly. The E108L-rad51 strain manifested severe sensitivity toward methyl methanesulfonate (MMS) and a complete loss of gene conversion efficiency, a phenotype similar to that of the Δrad51 strain. Previously, some of the N-terminal domain mutants of Rad51 were identified in a screen for a Rad51 interaction-deficient mutant; however, our study shows that Rad51E108L is not defective either in the self-interaction or its interaction with the members of the Rad52 epistatic group. Our study thus identifies a novel mutant of Rad51 which, owing to its greater association with Hsp90, exhibits a severe DNA repair defect.IMPORTANCE Rad51-mediated homologous recombination is the major mechanism for repairing DNA double-strand break (DSB) repair in cancer cells. Thus, regulating Rad51 activity could be an attractive target. The sequential assembly and disassembly of Rad51 to the broken DNA ends depend on reversible protein-protein interactions. Here, we discovered that a dynamic interaction with molecular chaperone Hsp90 is one such regulatory event that governs the recruitment of Rad51 onto the damaged DNA. We uncovered that Rad51 associates with Hsp90, and upon DNA damage, this complex dissociates to facilitate the loading of Rad51 onto broken DNA. In a mutant where such dissociation is incomplete, the occupancy of Rad51 at the broken DNA is partial, which results in inefficient DNA repair. Thus, it is reasonable to propose that any small molecule that may alter the dynamics of the Rad51-Hsp90 interaction is likely to impact DSB repair in cancer cells.

Hsp90 Is Essential for Chl1-Mediated Chromosome Segregation and Sister Chromatid Cohesion.

Recent studies have demonstrated that aberrant sister chromatid cohesion causes genomic instability and hence is responsible for the development of a tumor. The Chl1 (chromosome loss 1) protein (homolog of human ChlRl/DDX11 helicase) plays an essential role in the proper segregation of chromosomes during mitosis. The helicase activity of Chl1 is critical for sister chromatid cohesion. Our study demonstrates that Hsp90 interacts with Chl1 and is necessary for its stability. We observe that the Hsp90 nonfunctional condition (temperature-sensitive iG170Dhsp82 strain at restrictive temperature) induces proteasomal degradation of Chl1. We have mapped the domains of Chl1 and identified that the presence of domains II, III, and IV is essential for efficient interaction with Hsp90. We have demonstrated that Hsp90 inhibitor 17-AAG (17-allylamino-geldenamycin) causes destabilization of Chl1 protein and enhances significant disruption of sister chromatid cohesion, which is comparable to that observed under the Δchl1 condition. Our study also revealed that 17-AAG treatment causes an increased frequency of chromosome loss to a similar extent as that of the Δchl1 cells. Hsp90 functional loss has been earlier linked to aneuploidy with very poor mechanistic insight. Our result identifies Chl1 as a novel client of Hsp90, which could be further explored to gain mechanistic insight into aneuploidy.IMPORTANCE Recently, Hsp90 functional loss has been linked to aneuploidy; however, until now none of the components of sister chromatid cohesion (SCC) have been demonstrated as the putative clients of Hsp90. In this study, we have established that Chl1, the protein which is involved in maintaining sister chromatid cohesion as well as in preventing chromosome loss, is a direct client of Hsp90. Thus, with understanding of the molecular mechanism, how Hsp90 controls the cohesion machinery might reveal new insights which can be exploited further for attenuation of tumorigenesis.