Falciparum Protein Kinase Research Articles

Screening Carica Papaya Compounds as an Antimalarial Agent: In Silico Study

Malaria is a highly prevalent infectious disease caused by the Plasmodium parasite transmitted through Anopheles mosquitoes, which poses a significant public health challenge worldwide, including in Indonesia. Therefore, a study was conducted to identify potential drug compounds from the Carica papaya plant that could inhibit various antimalarial proteins or receptors, such as Plasmodium falciparum DXR reductase complex with fosmidomycin, Plasmepsin V Plasmodium vivax, P. falciparum dihydroorotate dehydrogenase, P. falciparum hexose transporter, P. falciparum protein kinase 5, and P. falciparum dihydrofolate reductase-thymidylate synthase. Theresearchers used the Pyrx application to dock the C. papaya compounds with the targeted antimalarial proteins to determine the binding affinity values. Additionally, they used the Yasara dynamics application to conduct molecular dynamics simulation to ensure the stability of the bonds formed between the ligands and proteins. The results showed that 14 compounds found in C. papaya, particularly flavonoids and terpenoids, had the potential to inhibit the six antimalarial proteins with the lowest binding affinity values. Furthermore, the molecular dynamics simulation on 6M20 and 1V0P proteins indicated that the compounds effectively inhibited Plasmodium proteins, as they had an RMSD value below 2.5 Angstrom. The study suggests that C. papaya could be a potential source of antimalarial compounds, which could be developed into new drugs to combat this disease.&nbsp

Protein kinase 9 is not required for completion of the Plasmodium berghei life cycle

Protein kinases uniquely expressed in Plasmodium represent attractive drug targets. Previous studies have reported that Plasmodium falciparum Protein kinase 9 (Pk9) phosphorylates regulatory serine 106 of the ubiquitin-conjugating enzyme (Ubc13) thereby negatively regulating its activity. We investigated the effect of Pk9 depletion and Ubc13 mutation at S106 on the progression of rodent malaria model P. berghei life cycle. Our studies demonstrate that while phosphorylation of the regulatory serine 106 of Ubc13 is essential in blood stages, the lack of Pk9 expression neither altered Ubc13 phosphorylation nor parasite viability at all life cycle stages, though Ubc13 and Pk9 showed co-localization in the cytosol of erythrocytic and liver stages. Further, phosphorylation of Ubc13 in the absence of Pk9 reiterated the redundancy of its regulation in P. berghei. These results highlight the indispensable role of Ubc13 in P. berghei life cycle and redundancy in its phosphorylation by protein kinase and reiterate the need to validate novel gene function through genetic approaches for drug development strategies.

Divergent allostery reveals critical differences between structurally homologous regulatory domains of Plasmodium falciparum and human protein kinase G

Malaria is a life-threatening infectious disease primarily caused by the Plasmodium falciparum parasite. The increasing resistance to current antimalarial drugs and their side effects has led to an urgent need for novel malaria drug targets, such as the P. falciparum cGMP-dependent protein kinase (pfPKG). However, PKG plays an essential regulatory role also in the human host. Human cGMP-dependent protein kinase (hPKG) and pfPKG are controlled by structurally homologous cGMP-binding domains (CBDs). Here, we show that despite the structural similarities between the essential CBDs in pfPKG and hPKG, their respective allosteric networks differ significantly. Through comparative analyses of chemical shift covariance analyses, molecular dynamics simulations, and backbone internal dynamics measurements, we found that conserved allosteric elements within the essential CBDs are wired differently in pfPKG and hPKG to implement cGMP-dependent kinase activation. Such pfPKG versus hPKG rewiring of allosteric networks was unexpected because of the structural similarity between the two essential CBDs. Yet, such finding provides crucial information on which elements to target for selective inhibition of pfPKG versus hPKG, which may potentially reduce undesired side effects in malaria treatments.

Application and Comprehensive Analysis of Neighbor Approximated Information Theoretic Configurational Entropy Methods to Protein-Ligand Binding Cases.

The binding entropy is an important thermodynamic quantity which has numerous applications in studies of the biophysical process, and configurational entropy is often one of the major contributors in it. Therefore, its accurate estimation is important, though it is challenging mostly due to sampling limitations, anharmonicity, and multimodality of atomic fluctuations. The present work reports a Neighbor Approximated Maximum Information Spanning Tree (A-MIST) method for conformational entropy and presents its performance and computational advantage over conventional Mutual Information Expansion (MIE) and Maximum Information Spanning Tree (MIST) for two protein-ligand binding cases: indirubin-5-sulfonate to Plasmodium falciparum Protein Kinase 5 (PfPK5) and P. falciparum RON2-peptide to P. falciparum Apical Membrane Antigen 1 (PfAMA1). Important structural regions considering binding configurational entropy are identified, and physical origins for such are discussed. A thorough performance evaluation is done of a set of four entropy estimators (Maximum Likelihood (ML), Miller-Madow (MM), Chao-Shen (CS), and James and Stein shrinkage (JS)) with known varying degrees of sensitivity of the entropy estimate on the extent of sampling, each with two schemes for discretization of fluctuation data of Degrees of Freedom (DFs) to estimate Probability Density Functions (PDFs). Our comprehensive evaluation of influences of variations of parameters shows Neighbor Approximated MIE (A-MIE) outperforms MIE in terms of convergence and computational efficiency. In the case of A-MIE/MIE, results are sensitive to the choice of root atoms, graph search algorithm used for the Bond-Angle-Torsion (BAT) conversion, and entropy estimator, while A-MIST/MIST are not. A-MIST yields binding entropy within 0.5 kcal/mol of MIST with only 20-30% computation. Moreover, all these methods have been implemented in an OpenMP/MPI hybrid parallel C++11 code, and also a python package for data preprocessing and entropy contribution analysis is developed and made available. A comparative analysis of features of current implementation and existing tools is also presented.

Plasmodium falciparum protein kinase as a potential therapeutic target for antimalarial drugs development.

Malaria is one of the most dangerous infectious diseases due to its high infection and mortality rates, especially in the tropical belt. Plasmodium falciparum (P. falciparum), the most virulent malaria parasite in humans, was recently reported to develop resistance against the final efficient antimalarial drug, artemisinin. Little is known about the resistance mechanisms, which further complicates the problem as a proper counteraction is unable to be taken. Hence, the understanding of drug mode of action and its molecular target is valuable knowledge that needs to be considered to develop the next generation of antimalarial drugs. P. falciparum protein kinase (Pf PK) is an attractive target for antimalarial chemotherapy due to its vital roles in all P. falciparum life stages. Moreover, overall structural differences and the presence of unique Pf PKs that are absent in human kinome, suggesting specific inhibition of Pf PK without affecting human cells is achievable. To date, at least 86 eukaryotic protein kinases have been identified in P. falciparum kinome, by which less than 40 were validated as potential targets at the erythrocytes stage. In this review, recent progress of the furthest validated Pf PKs; Pf Nek-1, Pf CDPK1, Pf CDPK4, Pf PKG, and Pf CLK-3 will be briefly discussed.

Potent inhibitors of malarial P. Falciparum protein kinase G: Improving the cell activity of a series of imidazopyridines

Development of a class of bicyclic inhibitors of the Plasmodium falciparum cyclic GMP-dependent protein kinase (PfPKG), starting from known compounds with activity against a related parasite PKG orthologue, is reported. Examination of key sub-structural elements led to new compounds with good levels of inhibitory activity against the recombinant kinase and in vitro activity against the parasite. Key examples were shown to possess encouraging in vitro ADME properties, and computational analysis provided valuable insight into the origins of the observed activity profiles.

In silico Screening and Evaluation of Plasmodium falciparum Protein Kinase 5 (PK5) Inhibitors.

An in silico screen of 350 000 commercially available compounds was conducted with an unbiased approach to identify potential malaria inhibitors that bind to the Plasmodium falciparum protein kinase 5 (PfPK5) ATP-binding site. PfPK5 is a cyclin-dependent kinase-like protein with high sequence similarity to human cyclin-dependent kinase 2 (HsCDK2), but its precise role in cell-cycle regulation remains unclear. After two-dimensional fingerprinting of the top scoring compounds, 182 candidates were prioritized for biochemical testing based on their structural diversity. Evaluation of these compounds demonstrated that 135 bound to PfPK5 to a similar degree or better than known PfPK5 inhibitors, confirming that the library was enriched with PfPK5-binding compounds. A previously reported triazolodiamine HsCDK2 inhibitor and the screening hit 4-methylumbelliferone were each selected for an analogue study. The results of this study highlight the difficult balance between optimization of PfPK5 affinity and binding selectivity for PfPK5 over its closest human homologue HsCDK2. Our approach enabled the discovery of several new PfPK5-binding compounds from a modest screening campaign and revealed the first scaffold to have improved PfPK5/HsCDK2 selectivity. These steps are critical for the development of PfPK5-targeting probes for functional studies and antimalarials with decreased risks of host toxicity.

Trisubstituted thiazoles as potent and selective inhibitors of Plasmodium falciparum protein kinase G (PfPKG)

A series of trisubstituted thiazoles have been identified as potent inhibitors of Plasmodium falciparum (Pf) cGMP-dependent protein kinase (PfPKG) through template hopping from known Eimeria PKG (EtPKG) inhibitors. The thiazole series has yielded compounds with improved potency, kinase selectivity and good in vitro ADME properties. These compounds could be useful tools in the development of new anti-malarial drugs in the fight against drug resistant malaria.

Screening a protein kinase inhibitor library against Plasmodium falciparum

BackgroundProtein kinases have been shown to be key drug targets, especially in the area of oncology. It is of interest to explore the possibilities of protein kinases as a potential target class in Plasmodium spp., the causative agents of malaria. However, protein kinase biology in malaria is still being investigated. Therefore, rather than assaying against individual protein kinases, a library of 4731 compounds with protein kinase inhibitor-like scaffolds was screened against the causative parasite, Plasmodium falciparum. This approach is more holistic and considers the whole kinome, making it possible to identify compounds that inhibit more than one P. falciparum protein kinase, or indeed other malaria targets.ResultsAs a result of this screen, 9 active compound series were identified; further validation was carried out on 4 of these series, with 3 being progressed into hits to lead chemistry. The detailed evaluation of one of these series is described.DiscussionThis screening approach proved to be an effective way to identify series for further optimisation against malaria. Compound optimisation was carried out in the absence of knowledge of the molecular target. Some of the series had to be halted for various reasons. Mode of action studies to find the molecular target may be useful when problems prevent further chemical optimisation.ConclusionsProgressible series were identified through phenotypic screening of a relatively small focused kinase scaffold chemical library.

Exploration of 3-methylisoquinoline-4-carbonitriles as protein kinase A inhibitors of Plasmodium falciparum

A series of isoquinolines have been evaluated in a homology model of Plasmodium falciparum Protein Kinase A (PfPKA) using molecular dynamics. Synthesis of these compounds was then undertaken to investigate their structure–activity relationships. One compound was found to inhibit parasite growth in an in vitro assay and provides a lead to further develop 3-methylisoquinoline-4-carbonitriles as antimalarial compounds. Development of a potent and selective PfPKA inhibitor would provide a useful tool to shed further insight into the mechanisms enabling malaria parasites to establish infection.

Melatonin-induced temporal up-regulation of gene expression related to ubiquitin/proteasome system (UPS) in the human malaria parasite Plasmodium falciparum.

There is an increasing understanding that melatonin and the ubiquitin/proteasome system (UPS) interact to regulate multiple cellular functions. Post-translational modifications such as ubiquitination are important modulators of signaling processes, cell cycle and many other cellular functions. Previously, we reported a melatonin-induced upregulation of gene expression related to ubiquitin/proteasome system (UPS) in Plasmodium falciparum, the human malaria parasite, and that P. falciparum protein kinase 7 influences this process. This implies a role of melatonin, an indolamine, in modulating intraerythrocytic development of the parasite. In this report we demonstrate by qPCR analysis, that melatonin induces gene upregulation in nine out of fourteen genes of the UPS, consisting of the same set of genes previously reported, between 4 to 5 h after melatonin treatment. We demonstrate that melatonin causes a temporally controlled gene expression of UPS members.

Involvement of Plasmodium falciparum protein kinase CK2 in the chromatin assembly pathway

BackgroundProtein kinase CK2 is a pleiotropic serine/threonine protein kinase with hundreds of reported substrates, and plays an important role in a number of cellular processes. The cellular functions of Plasmodium falciparum CK2 (PfCK2) are unknown. The parasite's genome encodes one catalytic subunit, PfCK2α, which we have previously shown to be essential for completion of the asexual erythrocytic cycle, and two putative regulatory subunits, PfCK2β1 and PfCK2β2.ResultsWe now show that the genes encoding both regulatory PfCK2 subunits (PfCK2β1 and PfCK2β2) cannot be disrupted. Using immunofluorescence and electron microscopy, we examined the intra-erythrocytic stages of transgenic parasite lines expressing hemagglutinin (HA)-tagged catalytic and regulatory subunits (HA-CK2α, HA-PfCK2β1 or HA-PfCK2β2), and localized all three subunits to both cytoplasmic and nuclear compartments of the parasite. The same transgenic parasite lines were used to purify PfCK2β1- and PfCK2β2-containing complexes, which were analyzed by mass spectrometry. The recovered proteins were unevenly distributed between various pathways, with a large proportion of components of the chromatin assembly pathway being present in both PfCK2β1 and PfCK2β2 precipitates, implicating PfCK2 in chromatin dynamics. We also found that chromatin-related substrates such as nucleosome assembly proteins (Naps), histones, and two members of the Alba family are phosphorylated by PfCK2α in vitro.ConclusionsOur reverse-genetics data show that each of the two regulatory PfCK2 subunits is required for completion of the asexual erythrocytic cycle. Our interactome study points to an implication of PfCK2 in many cellular pathways, with chromatin dynamics being identified as a major process regulated by PfCK2. This study paves the way for a kinome-wide interactomics-based approach to elucidate protein kinase function in malaria parasites.

QSAR studies on imidazopyridazine derivatives as PfPK7 inhibitors

Quantitative structure–activity relationship (QSAR) studies were carried out on a series of 35 recently synthesised imidazopyridazine derivatives to investigate the structural requirements of their inhibitory activity against malarial kinase, Plasmodium falciparum protein kinase 7 (PfPK7). Partial least square (PLS) methodology coupled with various feature selection methods, viz. stepwise (SW), genetic algorithm (GA) and simulated annealing, was applied to derive QSAR models which were further validated for statistical significance and predictive ability by internal and external validation. The statistically significant best 2D-QSAR model having correlation coefficient r 2 = 0.9190 and cross-validated squared correlation coefficient q 2 = 0.8575 with external predictive ability of pred_r 2 = 0.7212 was developed by SW-PLS with the descriptors like StNE-index, T_N_O_2, T_N_O_7, YcompDipole and SaasCE-index. Molecular field analysis was used to construct the best 3D-QSAR model using GA-PLS method, showing good correlative and predictive capabilities in terms of q 2 = 0.7494 and pred_r 2 = 0.8841. The information rendered by 2D- and 3D-QSAR models may lead to a better understanding of structural requirements of PfPK7 inhibitors and also aid in designing novel potent antimalarial molecules.

QSAR analysis on PfPK7 inhibitors using HQSAR, CoMFA, and CoMSIA

Plasmodium falciparum protein kinase 7 (PfPK7) is an important drug target for the development of anti-malarial treatment. In this study, hologram quantitative structure–activity relationship (HQSAR), comparative molecular field analysis (CoMFA), and comparative molecular similarity indices analysis (CoMSIA) were performed on a series of imidazopyridazine derivatives of PfPK7 inhibitors. The best HQSAR model was obtained using atoms, connection, donor, and acceptor as fragment distinction parameter with fragment size (4–7) using a hologram length of 353 and 6 components (q2 = 0.770, r2 = 0.964). The receptor-guided alignment has produced better statistical results for both CoMFA (q2 = 0.590, r2 = 0.986) and CoMSIA (q2 = 0.735, r2 = 0.988). The predictive ability of the developed models was further validated by a test set of eight compounds. HQSAR contribution map identified the presence of phenyl ring and cyclohexane moiety makes positive contribution for activity. Furthermore, CoMFA and CoMSIA contour maps suggested that additional bulky groups in cyclohexane moiety would increase the biological activity of PfPK7 inhibitors. Finally, these QSAR models were used to design new virtual molecules for imidazopyridazine derivatives and the results obtained from this study could be useful for further investigations.

Phenotypic and transcriptomic analyses of Plasmodium falciparum protein kinase A catalytic subunit inhibition

The emergence and dissemination of drug-resistant malaria parasites represent one of the most important problems in malaria case management. Plasmodium falciparum is the causative agent of the most lethal form of human malaria. The molecular mechanisms that control the life cycle of the malaria parasite are still poorly understood. The published genome sequence (P. falciparum strain 3D7) reveals that several homologs of eukaryotic signaling proteins, such as protein kinases and phosphatases, are conserved in P. falciparum. Proteins kinases are now widely recognized as valuable drug targets in protozoan parasites. In this study, gene silencing with double-stranded RNA (dsRNA) and microarray techniques were used to study the biological function of the cAMP-dependent protein kinase catalytic subunit (PfPKAc) in the parasite erythrocytic life cycle. Treatment of parasites with PfPKAc dsRNA resulted in a marked reduction of endogenous PfPKAc mRNA associated with a compensatory decrease of PfPKAr mRNA followed by morphological changes in schizont stages and cell cycle arrest. The global effects of gene silencing were also investigated using a P. falciparum pan-genomic microarray. Transcriptomic analysis showed that the expression of 329 genes was altered in response to downregulation of PfPKAc mRNA particularly genes in specific metabolic pathways linked with merozoite invasion processes, the calcium/calmodulin signaling, and kinases network and mitochondrial functions.

Expression and biochemical characterization of the Plasmodium falciparum protein kinase A catalytic subunit

Dissemination of drug-resistant malaria parasites represents one of the most important public health problems; therefore, the development of new antimalarial compounds is required. Cyclic AMP-dependent protein kinase is implicated in numerous cellular processes and an essential role for this enzyme has also been reported in the intraerythrocytic growth of the malaria parasite. The cAMP-dependent protein kinase from Plasmodium falciparum (PfPKA) plays an important role in the parasite life cycle and represents an attractive target for the development of antimalarial drugs. In this work, a recombinant PfPKA catalytic subunit (PfPKAc) was over-expressed in Escherichia coli and successfully purified using a two-step chromatographic process. The enzymatic properties of the recombinant PfPKAc were then determined using a sensitive fluorogenic assay suitable for biochemical characterization and inhibitor screening. This work provides new insights on the study of PfPKAc that will contribute to future investigations of the parasite cAMP signaling pathway and to high-throughput screening of specific malarial PKA inhibitors.

Characterization of Plasmodium falciparum protein kinase 2

A sustained elevation of free Ca 2+ is observed on the rupture and release of merozoites of Plasmodium falciparum from the erythrocytes. The immunoelectron micrographs demonstrate that calmodulin is localized in merozoites. To elucidate the Ca 2+ signal of P. falciparum invasion, we attempted to characterize P. falciparum protein kinase 2 (PfPK2), which is homologous to human calcium calmodulin-dependent protein kinase (CaMK). PfPK2 was purified as a fusion protein that was labeled with [γ- 32P]ATP; this labeling was then eliminated by phosphatase. This phosphorylation was eliminated when the putative catalytic lysine residue of PfPK2 was replaced with alanine. PfPK2 phosphorylated histone II AS as a representative substrate in a Ca 2+- and calmodulin-dependent manner. Calmodulin antagonists inhibited the phosphorylation of PfPK2 in vitro and markedly decreased the parasitemia of ring forms in an invasion assay, whereas CaMKII-specific inhibitors had no effect. PfPK2 was localized in the merozoites in the culture of P. falciparum. Thus, purified PfPK2 possesses protein kinase activity in a Ca 2+- and calmodulin-dependent manner and the catalytic lysine of this protein was determined. These data suggest that PfPK2 is the Plasmodium protein kinase expressed in the merozoites during the invasion stage.

Structures of P. falciparum Protein Kinase 7 Identify an Activation Motif and Leads for Inhibitor Design

Malaria is a major threat to world health. The identification of parasite targets for drug development is a priority and parasitic protein kinases suggest themselves as suitable targets as many display profound structural and functional divergences from their host counterparts. In this paper, we describe the structure of the orphan protein kinase, Plasmodium falciparum protein kinase 7 (PFPK7). Several Plasmodium protein kinases contain extensive insertions, and the structure of PFPK7 reveals how these may be accommodated as excursions from the canonical eukaryotic protein kinase fold. The constitutively active conformation of PFPK7 is stabilized by a structural motif in which the role of the conserved phosphorylated residue that assists in structuring the activation loop of many protein kinases is played by an arginine residue. We identify two series of PFPK7 ATP-competitive inhibitors and suggest further developments for the design of selective and potent PFPK7 lead compounds as potential antimalarials.

Purification and Characterization of Recombinant PfPK6, a Cyclin‐dependent Kinase from the Malarial Parasite P. falciparum

Cyclin-dependent kinases (CDKs) are essential regulators of the cell cycle. Plasmodium falciparum protein kinase 6 (PfPK6), a Ser/Thr protein kinase produced by the malaria parasite Plasmodium falciparum is an enzyme with homology to human CDKs and the closely related mitogen-activated protein kinases (MAPKs). PfPK6 does not require a cyclin for activation and is activated by autophosphorylation. These significant differences between the plasmodial PfPK6 and its human CDK homologues, make PfPK6 a possible plasmodia-specific anti-malarial therapeutic target. Consequently, our aim is to characterize the catalytic activity of PfPK6. Recombinant PfPK6 was produced in E. coli as a glutathione-s-transferase fusion protein and purified by glutathione affinity chromatography. The ability of PfPK6 to phosphorylate a substrate peptide (PKTPKKAKKL) and hydrolyze ATP in the absence of this substrate was assessed through an assay that couples enzyme activity to oxidation of NADH. These kinetic parameters are compared with available data from human CDK2/cyclinA, and the MAPK ERK2 to assess the similarities in kinetic mechanism.

Characteristics of the Plasmodium falciparum PK5 ATP-binding site: implications for the design of novel antimalarial agents

Increasing worldwide resistance of Plasmodium falciparum ( P. falciparum) to traditional chemotherapy strategies such as chloroquine and mefloquine demonstrates the urgent need for the discovery of novel chemotherapeutic agents in the fight against malaria. The recent discovery of P. falciparum Protein Kinase 5 (P fPK5) invites the possibility of selectively targeting the life cycle of P. falciparum in order to prevent cerebral malaria. P fPK5 bears a high degree of sequence identity (>58%) to a structurally conserved family of mammalian kinases known as the cyclin-dependent kinases (CDKs). The CDKs are the key regulatory elements governing the ordered progression of the mammalian cell cycle. With numerous X-ray crystal structures of CDK2 to provide a structural template, here we present a three-dimensional structural model of P fPK5 constructed using computer-based homology modeling techniques. Our model was used to compare the ATP binding site of P fPK5 with that of the mammalian kinase CDK2. Furthermore, kinase–ligand interactions of P fPK5 with known inhibitors were investigated and compared to available crystal structures of CDK2 with inhibitors bound. The focus of the study is to identify similarities and differences between the ATP binding sites of the two kinases that can be exploited for future rational drug design.