Emerging Drug Resistance of Plasmodium sp Associate with Misdiagnosis of Malaria

January 2014

archives@tulane.edu / 1 / Brittany J Dodson

Malaria, Drug Resistance

Characterisation and evaluation of novel potential target (tubulin) for antimalarial chemotherapy /

Low, Chee Kin Andrew.

January 2004

Thesis (Ph.D.)--Murdoch University, 2004. / Thesis submitted to the Division of Health Sciences. Bibliography: leaves 214-249.

Characterization of ABC transporters in both mammalian cells (ABCG2, ABCC2) and Plasmodium falciparum (Pgh1)

Leimanis, Mara L.

January 1900

Thesis (Ph.D.). / Written for the Institute of Parasitology. Title from title page of PDF (viewed 2008/02/12). Includes bibliographical references.

New approaches for measuring fitness of Plasmodium falciparum mutations implicated in drug resistance

Carrasquilla, Manuela

January 2019

The repeated emergence of drug resistance in Plasmodium falciparum underscores the importance of understanding the genetic architecture of current resistance pathways, as well as any associated fitness costs. Why resistance emerges in particular regions of the world has been linked to particular genetic backgrounds that better tolerate resistance-associated polymorphisms; this is likely to play a key role in driving the epidemiology of drug resistance, however is infrequently studied at a large scale in a laboratory setting. The first results chapter establishes a barcoding approach for P. falciparum with the aim of tracking parasite growth in vitro. The strategy used was adapted for P. falciparum by using a pseudogene (PfRh3) as a safe harbour to insert unique molecular barcodes. These libraries of barcoded P. falciparum vectors were also used as a readout of transfection efficiency. The second chapter establishes a proof of principle for phenotyping by barcode sequencing, using a panel of barcoded parasites generated in different genetic backgrounds that comprise sufficient genetic diversity to pilot the method. These were grown in the presence and absence of antimalarial compounds, and growth phenotypes were measured in parallel using BarSeq. The third results chapter studies the contribution of mutations in Pfkelch13, a molecular marker of artemisinin resistance, to parasite fitness. Combining CRISPR/Cas9-based genome editing and high throughput sequencing, the impact of Pfkelch13 alleles on fitness in the context of particular strain backgrounds is revealed. In particular, the impact of genetic background in the emergence and spread of drug-resistant lineages (referred to as KEL1) in Southeast Asia carrying a Y580 Pfkelch13 allele. Overall, given the current pace of genome sequencing of pathogenic organisms such as P. falciparum, it will be important to increase the scale of experimental genetics, in order to tackle in real-time natural variation that might be under constant selection from drugs, thus anticipating the emergence of drug resistance in changing parasite populations. Through this work, tools were developed to facilitate parallel phenotyping by measuring in vitro growth using high-throughput sequencing. The work also develops novel approaches to address the importance of genetic background and a potential role for positive epistasis in a lineage responsible for the recent outbreak of drug-resistant malaria in Southeast Asia.

Molecular characterization of the hexose transporter (PfHT1) of Plasmodium falciparum in Xenopus laevis oocytes

Manning, Suzanne Kathryn

21 November 2005

Please read the abstract in the section 00front of this document / Dissertation (MSc (Biochemistry))--University of Pretoria, 2005. / Biochemistry / unrestricted

Malaria drug resistance research

Malaria chemotherapy

UCTD

Unique Features Of Heme-Biosynthetic Pathway In The Human Malaria Parasite, Plasmodium Falciparum

Arun Nagaraj, V

07 1900

Malaria is a life-threatening vector borne infectious disease caused by protozoan parasites of the genus Plasmodium. More than 100 species of Plasmodium can infect numerous animal species such as reptiles, birds and various mammals. However, human malaria is caused by four Plasmodium species -Plasmodium falciparum, Plasmodium vivax, Plasmodium ovale and Plasmodium malariae, and occasionally by the simian malaria parasite, Plasmodium knowlesi. Of these, P. falciparum and P. vivax are the major causative agents and P. falciparum is the most virulent. About 300-500 million malaria infections occur every year leading to over 1-2 million deaths, of which 75% occur in African children of less than 5 years infected with P. falciparum. In spite of major global efforts to eliminate this disease over the past few decades, it continues to persist as a major affliction of human-kind imposing serious health and economic burden, especially to the poor countries. In India, the present scenario is about 2 million malaria positive cases every year, with almost 50% being caused by P. falciparum. Although remarkable attempts have been made over the years to develop vaccines against sexual and asexual stages of malaria parasite, an effective vaccine is still not in sight and remains as a distant goal. Hence, highly potent, less toxic and affordable antimalarial drugs remain as a first line therapy for malaria. Unfortunately, these parasites have been evolving against every known antimalarial drug and many of these drugs have lost their potency due to rapid emergence and spread of drug resistant strains. With development of resistance against frontline antimalarials such as chloroquine and antifolates, artemisinin and its derivatives seem to be the only effective antimalarials. However, recent reports on the possible emergence of artemisinin resistant strains, have led to the implementation of artemisinin-based combination therapies as a strategy to prevent drug resistance. Also, this continuous emergence of drug resistance has necessitated the development of new antimalarial drugs to combat this disease. While, Anopheles mosquitoes transmit parasites that infect humans, monkeys and rodents, Culex and Aedes mosquitoes predominate in the natural transmission to birds, and vectors of reptilian parasites are largely unknown. Of the approximately 400 species of Anopheles throughout the world, about 60 are malaria vectors under natural conditions, and 30 of which are of major importance. Ironically, the strategies implemented for controlling Anopheles, have also been hampered by insecticide resistance and other practical difficulties that exist in the scope of their applicability. In the past few years several milestones have been achieved in parasite genome, transcriptome and proteome studies, which could be exploited for the development of new drugs and drug targets. One such promising target includes the metabolic pathways of the malaria parasite which differ significantly from its human host. This thesis entitled “Unique Features of the Heme-Biosynthetic Pathway in Human Malaria Parasite, Plasmodium falciparum” unravels the unique biochemical features of heme-biosynthetic enzymes of P. falciparum, which have the potential for being drug targets. This pathway was first identified in this laboratory over 15 years ago. In the present study, five of the 7 enzymes of this pathway have been cloned, expressed, properties studied and sites of localization identified. With the knowledge on the first two enzymes coming from earlier studies, it is now possible to depict the unique hybrid pathway for heme biosynthesis in P. falciparum with full experimental validation.

Malaria

Plasmodium Falciparum

Heme Biosynthesis

Malaria - Drug Resistance

Heme Biosynthetic Enzymes

Antimalarial Drugs

Malaria Drugs

Malarial Parasite

Ferrochelatase

Heme-Biosynthetic Pathway

Biochemistry