Alternatives to currently used antimalarial drugs: in search of a magic bullet

Bhagavathula, Akshaya Srikanth; Elnour, Asim Ahmed; Shehab, Abdulla

doi:10.1186/s40249-016-0196-8

Cited by 24 publications

(16 citation statements)

References 76 publications

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“…Highly efficient asexual replication is fundamental to the ability of apicomplexan parasites to spread infections in their hosts, and this is evident by the fact that the actions of the best drugs used to combat these infections all reduce or block parasite proliferation. Unfortunately, existing therapies, particularly against malaria ( 1 ), are under constant pressure from acquired parasite drug resistance, and new treatments are continually needed. The peculiar proliferative cell cycles of Apicomplexa parasites differ substantially from the hosts they inhabit, and it seems safe to predict that a better understanding of the molecular basis of parasite cell division could yield new drug targets.…”

Section: Introductionmentioning

confidence: 99%

The Toxoplasma Centrocone Houses Cell Cycle Regulatory Factors

Naumov

Kratzer

Ting

et al. 2017

mBio

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Our knowledge of cell cycle regulatory mechanisms in apicomplexan parasites is very limited. In this study, we describe a novel Toxoplasma gondii factor that has a vital role in chromosome replication and the regulation of cytoplasmic and nuclear mitotic structures, and we named this factor ECR1 for essential for chromosome replication 1. ECR1 was discovered by complementation of a temperature-sensitive (ts) mutant that suffers lethal, uncontrolled chromosome replication at 40°C similar to a ts mutant carrying a defect in topoisomerase. ECR1 is a 52-kDa protein containing divergent RING and TRAF-Sina-like zinc binding domains that are dynamically expressed in the tachyzoite cell cycle. ECR1 first appears in the unique spindle compartment of the Apicomplexa (centrocone) of the nuclear envelope in early S phase and then in the nucleus in late S phase where it reaches maximum expression. Following nuclear division, but before daughter parasites separate from the mother parasite, ECR1 is downregulated and is absent in new daughter parasites. The proteomics of ECR1 identified interactions with the ubiquitin-mediated protein degradation machinery and the minichromosome maintenance complex, and the loss of ECR1 led to increased stability of a key member of this complex, MCM2. ECR1 also forms a stable complex with the cyclin-dependent kinase (CDK)-related kinase, T. gondii Crk5 (TgCrk5), which displays a similar cell cycle expression and localization during tachyzoite replication. Importantly, the localization of ECR1/TgCrk5 in the centrocone indicates that this Apicomplexa-specific spindle compartment houses important regulatory factors that control the parasite cell cycle.

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Section: Introductionmentioning

confidence: 99%

The Toxoplasma Centrocone Houses Cell Cycle Regulatory Factors

Naumov

Kratzer

Ting

et al. 2017

mBio

View full text Add to dashboard Cite

show abstract

“…Highly efficient asexual replication is fundamental to the ability of apicomplexan parasites to spread infections in their hosts and this is evident by the action of drugs used to combat these infections as the best treatments all reduce or block parasite proliferation. Unfortunately, existing therapies, particularly against malaria (1), are under constant pressure from acquired parasite drug resistance requiring a continuing search for new treatments. The peculiar proliferative cell cycles of Apicomplexa parasites differ substantially from the hosts they inhabit and it seems safe to predict that a better understanding of the molecular basis of parasite cell division could yield new drug targets.…”

Section: Introductionmentioning

confidence: 99%

TheToxoplasmacentrocone houses cell cycle regulatory factors

Naumov

Kratzer

Ting

et al. 2017

Preprint

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Our knowledge of cell cycle regulatory mechanisms in apicomplexan parasites is very limited. In this study, we describe a novel Toxoplasma gondii factor, essential for chromosome replication 1 (ECR1), that has a vital role in chromosome replication and the regulation of cytoplasmic and nuclear mitotic structures. ECR1 was discovered by complementation of a temperature sensitive (ts) mutant that suffers lethal, uncontrolled chromosome replication at 40 o C similar to a ts-mutant carrying a defect in topoisomerase. ECR1 is a 52kDa protein containing divergent RING and TRAF-Sina like zinc-binding domains that is dynamically expressed in the tachyzoite cell cycle.ECR1 first appears in the centrocone compartment of the nuclear envelope in early S phase and then in the nucleus in late S phase where it reaches maximum expression. Following nuclear division, but before daughters resolve from the mother, ECR1 is down regulated and is absent in new daughter parasites. The proteomics of ECR1 identified interactions with the ubiquitinmediated protein degradation machinery and the minichromosome maintenance complex and the loss of ECR1 led to increased stability of a key member of this complex, MCM2. ECR1 also forms a stable complex with the CDK-related kinase, TgCrk5, which shares a similar cell cycle expression and localization during tachyzoite replication. Altogether, the results of this study suggest ECR1 may be a unique E3 ligase that regulates DNA licensing and other mitotic processes. Importantly, the localization of ECR1/TgCrk5 in the centrocone indicates this Apicomplexa-specific spindle compartment houses important regulatory factors that control the parasite cell cycle. IMPORTANCEParasites of the apicomplexan family are important causes of human disease including malaria, toxoplasmosis, and cryptosporidiosis. Parasite growth is the underlying cause of pathogenesis, yet despite this importance the molecular basis for parasite replication is poorly understood. Filling this knowledge gap cannot be accomplished by mining recent whole genome sequencing because apicomplexan cell cycles differ substantially and lack many of the key regulatory factors of wellstudied yeast and mammalian cell division models. We have utilized forward genetics to discover essential factors that regulate cell division in these parasites using the Toxoplasma gondii model.

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“…Antimalarial drug resistance remains a major challenge and continued to emerge creating an obstacle in malaria control and elimination [ 5 , 28 ]. At present, developing novel approaches and new alternative antimalarial drugs is pivotal to combat the disease [ 29 ]. From history, medicinal plants are endowed with active antimalarial compounds as artemisinin is obtained from Artemisia annua and quinine from Cinchona bark [ 30 ].…”

Section: Discussionmentioning

confidence: 99%

In Vivo Antimalarial Activity of the Solvent Fractions of Fruit Rind and Root of Carica papaya Linn (Caricaceae) against Plasmodium berghei in Mice

Zeleke

Kebebe

Mulisa

et al. 2017

Journal of Parasitology Research

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Background Currently, antimalarial drug resistance poses a serious challenge. This stresses the need for newer antimalarial compounds. Carica papaya is used traditionally and showed in vitro antimalarial activity. This study attempted to evaluate in vivo antimalarial activity of C. papaya in mice. Methods In vivo antimalarial activity of solvent fractions of the plant was carried out against early P. berghei infection in mice. Parasitemia, temperature, PCV, and body weight of mice were recorded. Windows SPSS version 16 (one-way ANOVA followed by Tukey's post hoc test) was used for data analysis. Results The pet ether and chloroform fractions of C. papaya fruit rind and root produced a significant (p < 0.001) chemosuppressive effect. A maximum parasite suppression of 61.78% was produced by pet ether fraction of C. papaya fruit rind in the highest dose (400 mg/kg/day). Only 400 mg/kg/day dose of chloroform fraction of C. papaya root exhibited a parasite suppression effect (48.11%). But, methanol fraction of the plant parts produced less chemosuppressive effect. Conclusion Pet ether fraction of C. papaya fruit rind had the highest antimalarial activity and could be a potential source of lead compound. Further study should be done to show the chemical and metabolomic profile of active ingredients.

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Alternatives to currently used antimalarial drugs: in search of a magic bullet

Cited by 24 publications

References 76 publications

The Toxoplasma Centrocone Houses Cell Cycle Regulatory Factors

The Toxoplasma Centrocone Houses Cell Cycle Regulatory Factors

TheToxoplasmacentrocone houses cell cycle regulatory factors

In Vivo Antimalarial Activity of the Solvent Fractions of Fruit Rind and Root of Carica papaya Linn (Caricaceae) against Plasmodium berghei in Mice

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