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A Research Agenda for Malaria Eradication: Basic Science and Enabling Technologies


Today's malaria control efforts are limited by our incomplete understanding of the biology of Plasmodium and of the complex relationships between human populations and the multiple species of mosquito and parasite. Research priorities include the development of in vitro culture systems for the complete life cycle of P. falciparum and P. vivax and the development of an appropriate liver culture system to study hepatic stages. In addition, genetic technologies for the manipulation of Plasmodium need to be improved, the entire parasite metabolome needs to be characterized to identify new druggable targets, and improved information systems for monitoring the changes in epidemiology, pathology, and host-parasite-vector interactions as a result of intensified control need to be established to bridge the gap between bench, preclinical, clinical, and population-based sciences.


Published in the journal: A Research Agenda for Malaria Eradication: Basic Science and Enabling Technologies. PLoS Med 8(1): e32767. doi:10.1371/journal.pmed.1000399
Category: Review
doi: https://doi.org/10.1371/journal.pmed.1000399

Summary

Today's malaria control efforts are limited by our incomplete understanding of the biology of Plasmodium and of the complex relationships between human populations and the multiple species of mosquito and parasite. Research priorities include the development of in vitro culture systems for the complete life cycle of P. falciparum and P. vivax and the development of an appropriate liver culture system to study hepatic stages. In addition, genetic technologies for the manipulation of Plasmodium need to be improved, the entire parasite metabolome needs to be characterized to identify new druggable targets, and improved information systems for monitoring the changes in epidemiology, pathology, and host-parasite-vector interactions as a result of intensified control need to be established to bridge the gap between bench, preclinical, clinical, and population-based sciences.

Summary Points

  • Creative and collaborative multidisciplinary basic science approaches are needed to address pressing questions about the biology of Plasmodium

  • The research paradigm needs to shift from a focus on solely parasite or host to one that incorporates the triad of parasite, mosquito, and human host and their respective interactions

  • Key research priorities include: the development of in vitro culture systems for all life stages of P. falciparum and P. vivax, in particular, hepatic stages; improved genetic technologies for the manipulation of Plasmodium; and systems-based approaches incorporating cutting-edge technologies such as metabolomics

  • Parasite, human, and vector research needs to be backed up by in-depth population-based field studies

  • Most importantly, eradication of malaria will require bridging of the artificial gap between bench-based research, preclinical research, clinical research, and population-based science

Introduction

The current malaria control effort has focused on developing existing products and procedures (for example, drugs and the distribution of bednets) to reduce malaria morbidity and mortality. However, it is commonly accepted that eradication will not be achieved with current tools. Thus, we must now accelerate the development of a new generation of tools and knowledge aimed specifically at malaria eradication. As we look towards this ambitious goal, we must recognize that cutting-edge basic science, novel research strategies, and creative multidisciplinary approaches all need to be mobilized to bridge the gap between bench, preclinical, clinical, and population-based sciences. The malaria science community is now at a turning point where major advances are needed to move the field forward from control towards the goal of global malaria eradication.

The malERA Consultative Group on Basic Science and Enabling Technologies was convened to identify the major knowledge gaps in basic science and to prioritize basic/fundamental science approaches that might have an impact on malaria eradication, particularly with respect to the design of vaccines, drugs, and diagnostics. We recognize that there are likely to be many more research questions that merit equal importance in the broad field of malaria biology than we can cover in this paper, but herein we highlight only those approaches that were discussed by the consultative group and that may have a direct bearing on malaria eradication.

Leading the charge are new molecular, chemical, immunological, and epidemiological research tools that, whilst requiring adaptation to malaria, have realizable rewards in the near future. In particular, developments in systems biology, metabolomics, glycomics, and lipid metabolism and new high-throughput approaches involving chemical biology are likely to be of great use in the field of malaria eradication. From these new avenues of investigation, it is reasonable to expect advances in vaccine development and the identification of novel drug targets. Moreover, the interlacing of high-throughput molecular technologies with population studies will greatly facilitate the rational application of interventions in diverse malaria-endemic environments and, we anticipate, will significantly increase our ability to shed light on complex and heterogeneous host-parasite-vector interactions.

At the basic science level, we specifically identified a deeper understanding of the whole parasitic life cycle and the interaction of the parasite with human and vector hosts at different stages as a high priority. Such knowledge will augment our ability to evaluate current and future interventions and allow us to determine the potential action of drugs or vaccines across all parasite developmental stages. In addition, a life cycle–based perspective will provide insights into the transitions from one host to another and highlight key points, triggers, decisions, and co-incident events as the parasite moves from one life stage to the next that could prove crucial in malaria eradication attempts.

Most importantly, the consultative group recognized that multidisciplinary approaches will be required to exploit and apply new knowledge and techniques in order to make significant and novel gains in combating malaria. The malaria community needs to involve experts who can bring technologies from other seemingly distant areas of basic and applied research such as physics, electronics, information technology, and engineering. By defining desired outcomes, free from the constraints of preconceived ideas based on current tools, an expansion of the malaria research community skill base will create opportunities for lateral thinking and bring with it new approaches not previously considered.

This paper considers the key research priorities identified by the malERA Consultative Group for basic sciences and enabling technologies. Some of these key priorities have also been identified and discussed by the malERA Consultative Groups on vaccines, drugs, and diagnoses and diagnostics [1][3].

Plasmodium In Vitro Culture Systems

The development of Plasmodium in vitro culture systems that encompass the entire parasite life cycle of P. falciparum and P. vivax is critical for efforts to develop new vaccines, drugs, diagnostic tests, and challenge/test systems for clinical trials. The development of such systems will require a sustained community-wide collaborative effort and a long-term commitment. Specific stages of the life cycle for human malaria parasites that remain key priorities for in vitro culture development are sporogony, sustained blood-stage culture for P. vivax, and the pre-erythrocytic liver stage.

In Vitro Culture of Mosquito Stages

To date, in vitro culture of mosquito stage parasites and, in particular, in vitro development of sporozoites (sporogonic development) has only been achieved for rodent malaria parasite species; the reproduction of these achievements for P. falciparum—and even more so P. vivax—has met with limited success [4][10]. The need for an effective, in vitro sporogonic culture system is highlighted by the following example. In Brazil, the major local vector Anopheles darlingi cannot be reared in the lab and, as in other malaria endemic countries, the importation of laboratory colonies of nonindigenous vector species is understandably prohibited. Such a situation makes it difficult for endemic country scientists to address one of the key issues pertaining to eradication—parasite transmission through the mosquito. Moreover, despite several attempts in the past, an appropriate Anopheles midgut cell line model does not exist, which prevents an intimate analysis of Plasmodium ookinete invasion of this mosquito tissue [11]. Thus, to facilitate malaria control efforts in Brazil (and in other endemic areas), it is essential that researchers work towards the development of a simple, widely utilizable, and robust mosquito-free (axenic) sporogonic culture system and an in vitro midgut cell invasion assay for the major human malaria parasites.

P. vivax Blood-Stage Cultures

The availability of continuous in vitro blood-stage culture of P. falciparum has revolutionized our understanding of the parasite [12], but there is no analogous culture system for P. vivax research. In part, this is because P. vivax has a predilection for reticulocytes, a cell type that may need to be purified or generated from hematopoietic stem cell progenitor cells—a process that has met with only limited success [13][19]. The development of an efficient inexpensive, automated P. vivax blood-stage culture system would undoubtedly enhance the study of this parasite's biology. It would also enable in vitro drug susceptibility testing, the development of growth inhibitory assays to test humoral immunity, and, ultimately, the development of new genetic research methods. Importantly, both the asexual and sexual stages would become available for study, which would facilitate the generation of the other stages of the life cycle using defined parasite strains, without the requirement for primates.

Liver-Stage Cultures

Our current understanding of the biology of the parasite's liver stage (the hypnozoite stage) suggests this stage will be an important target in efforts to eradicate malaria [20]. Specifically, hepatic development occupies a critical position in mediating the establishment of blood-stage infection and, consequently, the transmission of malaria. Moreover, in the case of P. vivax, the dormant hypnozoite stages remain in the liver for a variable and protracted period before leading to relapse. Clearly, eradication of P. vivax (and P. ovale) is unlikely to be attained without developing effective hypnozoiticides.

The availability of a Plasmodium liver-stage model would allow the investigation of the host factors that are involved in primary and latent intrahepatic development and of the metabolic pathways that regulate development of this parasitic stage. In addition, the existence of such a model would allow the development of much needed drug screens for this stage that could, like the recently available drug screens for asexual blood-stage infections [21][27], take advantage of the unprecedented access to the three chemical compound libraries—GlaxoSmithKline's Tres Cantos Antimalarial TCAMS dataset [24], the Novartis-GNF Malaria Box Dataset, and the St. Jude Children's Hospital Malaria dataset [25]—that are hosted at ChEMBL-NTD (www.ebi.ac.uk/chemblntd), an Open Access repository of primary screening and medicinal chemistry data.

Finally, with the resurgence in interest in genetically attenuated or irradiated sporozoite-based, pre-erythrocytic vaccines [28],[29], a liver-stage model would permit investigation of the molecular basis of their developmental arrest—an understanding that will be critical in both the licensing of such vaccines and in ensuring that breakthrough infections do not arise.

Thus, the development of in vitro systems to understand hypnozoite biology as it relates to liver-stage biology is a clear priority. However, the culture of parasites through the liver stage is likely to be a significant challenge given the intractability of this stage relative to other life stages. Such an endeavour will require a highly collaborative and interdisciplinary approach that includes specialists in the fields of hepatocyte and stem cell biology as well as biomedical engineering. The development of hepatocytes that maintain their polarity and normal trafficking properties is a necessary step towards this kind of model, as is development of primary or immortalized hepatocyte cultures with sufficient life span to allow hypnozoite formation and survival [30][34]. Cell lines that allow high infectivity and that can yield high parasite numbers would be especially valuable for generating more useful quantities of parasite material with which to work. Moreover, a single hepatocyte line may not be amenable or useful to all the different subdisciplines present in the malaria community. Some may be appropriate for immunological studies, while others may be suited to drug studies against primary or relapse infection from hypnozoites [1],[2]. Finally, it should be noted that the possibility of using humanized mouse models engrafted with functional human cells and tissues, including human hepatocytes or human hematolymphoid cells, presents a unique in vivo approach that could also facilitate our understanding of Plasmodium liver-stage biology [35].

Primate Models of Disease

Not every aspect of parasite biology can be studied using in vitro culture. In some cases, whole animal models will be needed. For example, validated biomarkers for intrahepatic development and markers of past infection that could help distinguish between new infection and relapse will be important during elimination and can only be identified in whole animal models [3],[36]. Data from primate studies could provide an interim platform for developing novel diagnostics that could inform future work in parallel with in vitro models [37][39]. Mechanisms to support cross-institute/laboratory collaborations and access to the few centres with expertise and resources in primate/malaria research would facilitate and enhance a wide range of essential research.

Development of Genetic Tools for P. vivax and Approaches for Systematic Mutagenesis in Plasmodium

Major advances towards understanding fundamental aspects of model organisms inherently follow technological innovations that move fields in new directions. Thus, the ability to manipulate the genomes of different Plasmodium species has revolutionized malaria research. Nevertheless, we are still a long way from the systematic use of reverse genetics seen in other model systems such as yeast. For example, although the P. falciparum genome was completed more than 5 years ago, as many as half of the annotated genes are still listed as having a hypothetical or unknown function; around 90% of the genes have little biological evidence for function. Furthermore, little is being done currently to coordinate the study of individual genes or gene families, with the exception of recent efforts to systematically define the function of proteins involved in erythrocyte remodeling and export [40].

Despite many recent improvements to genetic technologies in Plasmodium, many roadblocks that prevent scale-up of genetic manipulation and functional analysis of essential genes need to be overcome [41][44]. These roadblocks include the low frequency of homologous recombination in Plasmodium, difficulties associated with the manipulation of large fragments of AT-rich and repetitive genomic DNA, and the lack of robust and scalable systems for conditional gene expression. In addition, there are no practical strategies for achieving saturation mutagenesis. Technologies to tackle some of these roadblocks are available for other organisms [45],[46] and need to be introduced to the malaria research agenda.

If these technical limitations can be overcome, systematic mutagenesis on a genome-wide scale will allow us to distinguish essential from redundant metabolic pathways and will be critical to obtaining a comprehensive picture of the stage-specific biology of the parasite that could be targeted with drugs or vaccines. Stable, conditional knock-out approaches for genes that are essential in one life stage but not in another would also identify potential drug targets. Improved genetic technologies will also enable the systematic production of large-scale repositories of gene knock-out or epitope-tagged versions for every plasmodial gene. Such community resources would avoid duplication and benefit from the economy of scale. More importantly, easy access to large numbers of mutants would inspire new experimental approaches, as they have in the yeast field [47][49], and widen access to genetic technology.

Finally, the recent completion of several parasite and mosquito genomes [50][54] and new insights into the contribution of human and mosquito host genotype to transmission have radically changed how researchers approach malaria. This information, together with an internationally accessible repository of transgenic lines for every Plasmodium gene, will change the way that the research community approaches the most basic and relevant questions related to Plasmodium biology (of all species) and interactions of the various Plasmodium species with their hosts.

Metabolomics

As with genomic innovations, new technological platforms that permit the deep characterization of the metabolome (complete set of small-molecule metabolites) of Plasmodium will identify new potentially druggable targets [55],[56]. Indeed, analysis of the parasite's metabolome is already revealing profound new insights into parasite biology that were not amenable to or that were missed by genomic approaches [57][59]. For metabolites that are readily identifiable, differences among parasite strains, under varying drug conditions, or in mutant backgrounds will enhance understanding of the known metabolic pathways present in Plasmodium spp. However, many of the measurable compounds are likely to derive from previously undetected novel metabolites (including the products of poorly understood lipid and carbohydrate metabolism). The identification of these compounds could yield key insights for the development of new antimalarial drugs or the control of drug resistance. Moreover, the identification of the metabolic similarities between different parasite stages could provide new approaches to the development of drugs with potential to kill the parasites at many points in their life cycle, possibly in both the human host and the mosquito vector [58][61].

Metabolomic approaches should also enable identification of metabolic differences between, for example, patients who are asymptomatic and those with advanced stage cerebral malaria (or other severe syndromes). Metabolomic studies of such samples may not only provide information about the state of the host, but also about the interaction between the host and the parasite. The Consultative Group felt that such studies, which bring together bench scientists and field clinicians, should be encouraged as the true picture of the diversity of metabolic effects can only be fully appreciated from field-derived samples. Finally, the group noted that the application of metabolomic technology will be particularly powerful in unraveling the biochemical strategies of parasites with no or poor genomic resources such as P. ovale or P. malariae.

The Importance of Relating Molecular Science to Field Science

The emergence of artemisinin resistance [62],[63] and changes in the interrelationships of humans, mosquitoes, and parasites as elimination proceeds will produce unexpected new challenges. The Consultative Group, therefore, considered it a priority to establish information systems for monitoring the changes in epidemiology, pathology, and host-parasite-vector interactions that result from intensified control and burgeoning elimination efforts so that basic research can react in a timely manner to changing circumstances (see also [36],[64]).

Indeed, a core theme in our discussions was that, throughout the eradication era, basic science and multidisciplinary approaches must be seen as integral components of a Malaria Eradication Research Agenda that are valuable even in the absence of clear field application because one can never predict the impact of novel insights. Enabling technologies cut across many themes in this agenda (see Box 1), and the application of basic science in the field is especially important. For example, genomic, proteomic, and high-throughput immunological methods can now be applied to population studies, greatly increasing their ability to shed light on complex host-parasite-vector interactions [65],[66].

Box 1. Enabling Technologies: Cross-Cutting Themes

  • Collaborative approaches that bridge the gap between basic laboratory, preclinical, and clinical/population-based sciences

  • Complete P. falciparum and P. vivax in vitro culture systems for the discovery of new targets, the characterization of the entire metabolome, and the evaluation of current and next generation interventions

  • Development and wide distribution of several viable, easy to maintain polarized hepatocyte cell lines that support enhanced (>2% infection) P. falciparum and P. vivax intrahepatic development, and that are amenable to metabolomic, proteomic, glycomic and immunological studies, and the evaluation of new interventions

  • Scalable genetic technologies that enable a shared resource containing genome-wide sets of genetically modified (knock-out/tagged) parasite lines (for P. falciparum, P. vivax, and the murine malaria parasites) to be maintained

  • Novel classes of molecules that can function as chemical tools for probing the function of genes at transition stages; most especially the commitment to dormant liver stages and gametocytogenesis

Human Host Factors and Improving Epidemiological Models

No campaign for the control or elimination of malaria can proceed without a detailed appreciation of the epidemiology of the disease and of host-parasite-vector interactions. As increasing parts of the world move towards elimination, a deeper understanding of the basic science of host-parasite-vector population interactions in disease transmission and of the changes in these interactions that result from intensified control and elimination efforts will be increasingly important [64].

For example, mixed species and strain infections are common in natural malaria infections in both human and vector hosts [67],[68]. Application of next generation high-throughput sequencing and genotyping of mixed infections in both obligate hosts will help to identify important target genes and phenotypes and will provide insights into whether and how parasites impact each other's behaviour in the context of the human host and transmission through the vector host that will be important as elimination proceeds.

Similarly, a better understanding of the human response to malaria will be increasingly important as elimination proceeds. Despite many decades of studies on immune responses to malaria, there is still no consensus on an immune correlate of protection [69],[70]. Well designed, longitudinal studies in which the exposure to malaria and protection against uncomplicated or severe malaria are reliably assessed are required to remedy this shortcoming. Other modern technologies that offer new approaches to understanding the potential mechanism of action of compounds or antibodies on malaria will also need to be fully introduced into ongoing and planned longitudinal studies of human populations.

Vector-Host-Parasite Interactions

Strategies aimed at decreasing mosquito life span are predicted to impact upon transmission (see also [2],[71]). Research that investigates the parasite stages that develop within the mosquito and their transmission through the vector is likely to be of great use, therefore, in malaria control and eradication. Focused research efforts designed to understand the epidemiology of the gametocyte and how it varies with species, with host, and with the environment are required. Insights arising from such research will be critical for determining the driving factors for new human and mosquito infections, and manipulation of these factors will open up new avenues for targeting the key parasite regulatory switches that occur when a parasite undergoes a transition event. Importantly, however, such a focus on transmission need not necessarily be aimed at finding a magic bullet—a compound that can work against all parasite stages in all hosts. Instead, there will be significant utility in developing several inhibitors with similar pharmacokinetic and pharmacodynamic profiles that affect different metabolic pathways and stages in a combined drug treatment regimen. For now, the absence of compounds that preferentially affect gametocytogenesis, gamete-ookinete, or ookinete-oocyst transition as well as the lack of understanding of the mechanism of action for those very few currently available compounds highlights the need for renewed efforts in this area [72].

Concluding Remarks

From our discussions, we propose a basic science research and development agenda for malaria eradication (Box 2) that will hopefully yield new interventions that are not hindered by the current drug resistance status of the parasites or by changes in environmental and host factors.

Box 2. Summary of the Research and Development Agenda for Basic Science Research

  • A research paradigm shift away from the “parasite-first” approach to an examination of what the human and mosquito host cells provide to the developing parasite is needed to complement on-going approaches

  • A new approach is needed to support collaborative and truly cross-disciplinary arrangements among scientists to bridge the gap between basic laboratory and clinical/population-based sciences and to meet the scientific benchmarks outlined by malERA

  • Desired target product profiles need to be defined without preferred technological approaches being suggested to create opportunities for lateral thinking by experts bringing new approaches from different fields

  • Careful evaluation and appropriate use of today's technologies from the physical, chemical, and biomedical engineering sciences is needed to improve the molecular understanding of parasite developmental biology and of the mammalian host-parasite-vector interactions

  • Mechanism of action studies for drugs and vaccines in the current pipeline are also needed to inform future strategies for the development of the next generation of interventions and therapeutics

  • The study of human host and vector factors in large-scale, long-term population-based field studies and the use of appropriate technologies in translation applications is also essential.

Central to this agenda is our contention that the establishment of a spectrum of creative and novel eradication interventions will require a strong commitment to collaborative work, wherein interdisciplinary teams of basic scientists, both within and outside of the malaria field, are organized and tasked with achieving well-defined research milestones. It is crucial that scientists have the possibility and flexibility to move between the field and the bench for collaborative translational research, an emerging specialty in its own right. Once individuals embrace the diversity of expertise necessary in the malaria research of the future, the promotion of a greater collaborative culture will inevitably make translation from bench to bedside more readily achievable. However, the 10–15-year timeline of translation from the bench to practical use in the clinic or field remains a significant barrier to progress that has to be recognized. Finally and importantly, our challenge to basic and applied scientists to engage in stronger partnership across projects and disciplines overrides some of the current guiding principles in science such as institutional and individual performance assessments and impact factors. These criteria may have helped to shape individual careers but they have rarely helped to answer major public health questions and should not be allowed to interfere with progress towards malaria eradication.


Zdroje

1. The malERA Consultative Group on Vaccines 2011 A research agenda for malaria eradication: Vaccines. PLoS Med 8 e1000398 doi:10.1371/journal.pmed.1000398

2. The malERA Consultative Group on Drugs 2011 A research agenda for malaria eradication: Drugs. PLoS Med 8 e1000402 doi:10.1371/journal.pmed.1000402

3. The malERA Consultative Group on Diagnoses and Diagnostics 2011 A research agenda for malaria eradication: Diagnoses and diagnostics. PLoS Med 8 e1000396 doi:10.1371/journal.pmed.1000396

4. SindenRE

HartleyRH

WingerL

1985 The development of Plasmodium ookinetes in vitro: an ultrastructural study including a description of meiotic division. Parasitology 91 227 244

5. CarterEH

SuhrbierA

BeckersPJ

SindenRE

1987 The in vitro cultivation of P. falciparum ookinetes, and their enrichment on nycodenz density gradients. Parasitology 95 25 30

6. SuwanabunN

SattabongkotJ

TsuboiT

ToriiM

ManeechaiN

2001 Development of a method for the in vitro production of Plasmodium vivax ookinetes. J Parasitol 87 928 930

7. HurdH

Al-OlayanE

ButcherGA

2003 In vitro methods for culturing vertebrate and mosquito stages of Plasmodium. Microbes Infect 5 321 327

8. Porter-KelleyJM

DinglasanRR

AlamU

NdetaGA

SacciJBJr

2006 Plasmodium yoelii: Axenic development of the parasite mosquito stages. Exp Parasitol 112 99 108

9. DinglasanRR

AlagananA

GhoshAK

SaitoA

van KuppeveltTH

2007 Plasmodium falciparum ookinetes require mosquito midgut chondroitin sulfate proteoglycans for cell invasion. Proc Natl Acad Sci U S A 104 15882 15887

10. GhoshAK

DinglasanRR

IkadaiH

Jacobs-LorenaM

2010 An improved method for the in vitro differentiation of Plasmodium falciparum gametocytes into ookinetes. Malar J 9 194

11. WilkinsS

BillingsleyPF

2010 Mosquito cell line glycoproteins: An unsuitable model system for the plasmodium ookinete-mosquito midgut interaction? Parasit Vectors 3 22

12. TragerW

JensenJB

2005 Human malaria parasites in continuous culture. 1976. J Parasitol 91 484 486

13. GiarratanaMC

KobariL

LapillonneH

ChalmersD

KigerL

2005 Ex vivo generation of fully mature human red blood cells from hematopoietic stem cells. Nat Biotechnol 23 69 74

14. DornI

Lazar-KarstenP

BoieS

RibbatJ

HartwigD

2008 In vitro proliferation and differentiation of human CD34+ cells from peripheral blood into mature red blood cells with two different cell culture systems. Transfusion 48 1122 1132

15. PanichakulT

SattabongkotJ

ChotivanichK

SirichaisinthopJ

CuiL

2007 Production of erythropoietic cells in vitro for continuous culture of Plasmodium vivax. Int J Parasitol 37 1551 1557

16. UdomsangpetchR

SomsriS

PanichakulT

ChotivanichK

SirichaisinthopJ

2007 Short-term in vitro culture of field isolates of Plasmodium vivax using umbilical cord blood. Parasitol Int 56 65 69

17. UdomsangpetchR

KanekoO

ChotivanichK

SattabongkotJ

2008 Cultivation of Plasmodium vivax. Trends Parasitol 24 85 88

18. CuiL

TrongnipattN

SattabongkotJ

UdomsangpetchR

2009 Culture of exoerythrocytic stages of the malaria parasites Plasmodium falciparum and Plasmodium vivax. Methods Mol Biol 470 263 273

19. DouayL

LapillonneH

TurhanAG

2009 Stem cells–a source of adult red blood cells for transfusion purposes: Present and future. Crit Care Clin 25 383 98, Table of Contents

20. PrudencioM

RodriguezA

MotaMM

2006 The silent path to thousands of merozoites: The Plasmodium liver stage. Nat Rev Microbiol 4 849 856

21. ChongCR

ChenX

ShiL

LiuJO

SullivanDJJr

2006 A clinical drug library screen identifies astemizole as an antimalarial agent. Nat Chem Biol 2 415 416

22. BanieckiML

WirthDF

ClardyJ

2007 High-throughput plasmodium falciparum growth assay for malaria drug discovery. Antimicrob Agents Chemother 51 716 723

23. DeuE

LeyvaMJ

AlbrowVE

RiceMJ

EllmanJA

2010 Functional studies of Plasmodium falciparum dipeptidyl aminopeptidase I using small molecule inhibitors and active site probes. Chem Biol 17 808 819

24. GamoFJ

SanzLM

VidalJ

de CozarC

AlvarezE

2010 Thousands of chemical starting points for antimalarial lead identification. Nature 465 305 310

25. GuiguemdeWA

ShelatAA

BouckD

DuffyS

CrowtherGJ

2010 Chemical genetics of Plasmodium falciparum. Nature 465 311 315

26. KatoN

SakataT

BretonG

Le RochKG

NagleA

2008 Gene expression signatures and small-molecule compounds link a protein kinase to Plasmodium falciparum motility. Nat Chem Biol 4 347 356

27. CrowtherGJ

NapuliAJ

GilliganJH

GagaringK

BorboaR

2010 Identification of inhibitors for putative malaria drug targets among novel antimalarial compounds. Mol Biochem Parasitol 175 21 29

28. VanBuskirkKM

O'NeillMT

De La VegaP

MaierAG

KrzychU

2009 Preerythrocytic, live-attenuated Plasmodium falciparum vaccine candidates by design. Proc Natl Acad Sci U S A 106 13004 13009

29. MuellerAK

CamargoN

KaiserK

AndorferC

FrevertU

2005 Plasmodium liver stage developmental arrest by depletion of a protein at the parasite-host interface. Proc Natl Acad Sci U S A 102 3022 3027

30. SnooksMJ

BhatP

MackenzieJ

CounihanNA

VaughanN

2008 Vectorial entry and release of hepatitis A virus in polarized human hepatocytes. J Virol 82 8733 8742

31. MeeCJ

GroveJ

HarrisHJ

HuK

BalfeP

2008 Effect of cell polarization on hepatitis C virus entry. J Virol 82 461 470

32. PlossA

KhetaniSR

JonesCT

SyderAJ

TrehanK

2010 Persistent hepatitis C virus infection in microscale primary human hepatocyte cultures. Proc Natl Acad Sci U S A 107 3141 3145

33. de JongYP

RiceCM

PlossA

2010 New horizons for studying human hepatotropic infections. J Clin Invest 120 650 653

34. KhetaniSR

BhatiaSN

2008 Microscale culture of human liver cells for drug development. Nat Biotechnol 26 120 126

35. de JongYP

RiceCM

PlossA

2010 New horizons for studying human hepatotropic infections. J Clin Invest 120 650 653

36. The malERA Consultative Group on Monitoring, Evaluation, and Surveillance 2011 A research agenda for malaria eradication: Monitoring, evaluation, and surveillance. PLoS Med 8 e1000400 doi:10.1371/journal.pmed.1000400

37. HerreraS

PerlazaBL

BoneloA

Arevalo-HerreraM

2002 Aotus monkeys: their great value for anti-malaria vaccines and drug testing. Int J Parasitol 32 1625 1635

38. NtumngiaFB

McHenryAM

BarnwellJW

Cole-TobianJ

KingCL

2009 Genetic variation among Plasmodium vivax isolates adapted to non-human primates and the implication for vaccine development. Am J Trop Med Hyg 80 218 227

39. CollinsWE

SullivanJS

JefferyGM

WilliamsA

GallandGG

2009 The chesson strain of Plasmodium vivax in humans and different species of Aotus monkeys. Am J Trop Med Hyg 80 152 159

40. MaierAG

RugM

O'NeillMT

BrownM

ChakravortyS

2008 Exported proteins required for virulence and rigidity of Plasmodium falciparum-infected human erythrocytes. Cell 134 48 61

41. JanseCJ

RamesarJ

WatersAP

2006 High-efficiency transfection and drug selection of genetically transformed blood stages of the rodent malaria parasite Plasmodium berghei. Nat Protoc 1 346 356

42. ArmstrongCM

GoldbergDE

2007 An FKBP destabilization domain modulates protein levels in Plasmodium falciparum. Nat Methods 4 1007 1009

43. BaluB

ChauhanC

MaherSP

ShoueDA

KissingerJC

2009 piggyBac is an effective tool for functional analysis of the Plasmodium falciparum genome. BMC Microbiol 9 83

44. CombeA

GiovanniniD

CarvalhoTG

SpathS

BoissonB

2009 Clonal conditional mutagenesis in malaria parasites. Cell Host Microbe 5 386 396

45. SchnutgenF

De-ZoltS

Van SlounP

HollatzM

FlossT

2005 Genomewide production of multipurpose alleles for the functional analysis of the mouse genome. Proc Natl Acad Sci U S A 102 7221 7226

46. LangridgeGC

PhanMD

TurnerDJ

PerkinsTT

PartsL

2009 Simultaneous assay of every Salmonella typhi gene using one million transposon mutants. Genome Res 19 2308 2316

47. WinzelerEA

ShoemakerDD

AstromoffA

LiangH

AndersonK

1999 Functional characterization of the S. cerevisiae genome by gene deletion and parallel analysis. Science 285 901 906

48. GiaeverG

ChuAM

NiL

ConnellyC

RilesL

2002 Functional profiling of the Saccharomyces cerevisiae genome. Nature 418 387 391

49. ParsonsAB

LopezA

GivoniIE

WilliamsDE

GrayCA

2006 Exploring the mode-of-action of bioactive compounds by chemical-genetic profiling in yeast. Cell 126 611 625

50. GardnerMJ

HallN

FungE

WhiteO

BerrimanM

2002 Genome sequence of the human malaria parasite Plasmodium falciparum. Nature 419 498 511

51. PainA

BohmeU

BerryAE

MungallK

FinnRD

2008 The genome of the simian and human malaria parasite Plasmodium knowlesi. Nature 455 799 803

52. CarltonJM

AdamsJH

SilvaJC

BidwellSL

LorenziH

2008 Comparative genomics of the neglected human malaria parasite Plasmodium vivax. Nature 455 757 763

53. AurrecoecheaC

HeigesM

WangH

WangZ

FischerS

2007 ApiDB: Integrated resources for the apicomplexan bioinformatics resource center. Nucleic Acids Res 35 D427 D430

54. HoltRA

SubramanianGM

HalpernA

SuttonGG

CharlabR

2002 The genome sequence of the malaria mosquito Anopheles gambiae. Science 298 129 149

55. GardinerDL

Skinner-AdamsTS

BrownCL

AndrewsKT

StackCM

2009 Plasmodium falciparum: New molecular targets with potential for antimalarial drug development. Expert Rev Anti Infect Ther 7 1087 1098

56. KafsackBF

LlinasM

2010 Eating at the table of another: Metabolomics of host-parasite interactions. Cell Host Microbe 7 90 99

57. OlszewskiKL

LlinasM

2010 Central carbon metabolism of plasmodium parasites. Mol Biochem Parasitol. In press

58. OlszewskiKL

MatherMW

MorriseyJM

GarciaBA

VaidyaAB

2010 Branched tricarboxylic acid metabolism in Plasmodium falciparum. Nature 466 774 778

59. OlszewskiKL

MorriseyJM

WilinskiD

BurnsJM

VaidyaAB

2009 Host-parasite interactions revealed by Plasmodium falciparum metabolomics. Cell Host Microbe 5 191 199

60. TengR

JunankarPR

BubbWA

RaeC

MercierP

2009 Metabolite profiling of the intraerythrocytic malaria parasite Plasmodium falciparum by (1)H NMR spectroscopy. NMR Biomed 22 292 302

61. BesteiroS

Vo DuyS

PerigaudC

Lefebvre-TournierI

VialHJ

2010 Exploring metabolomic approaches to analyse phospholipid biosynthetic pathways in Plasmodium. Parasitology 137 1343 1356

62. HuntP

MartinelliA

ModrzynskaK

BorgesS

CreaseyA

2010 Experimental evolution, genetic analysis and genome re-sequencing reveal the mutation conferring artemisinin resistance in an isogenic lineage of malaria parasites. BMC Genomics 11 499

63. DondorpAM

NostenF

YiP

DasD

PhyoAP

2009 Artemisinin resistance in Plasmodium falciparum malaria. N Engl J Med 361 455 467

64. The malERA Consultative Group on Modeling 2011 A research agenda for malaria eradication: Modeling. PLoS Med 8 e1000403 doi:10.1371/journal.pmed.1000403

65. DailyJP

ScanfeldD

PochetN

Le RochK

PlouffeD

2007 Distinct physiological states of Plasmodium falciparum in malaria-infected patients. Nature 450 1091 1095

66. Arastu-KapurS

PonderEL

FonovicUP

YeohS

YuanF

2008 Identification of proteases that regulate erythrocyte rupture by the malaria parasite Plasmodium falciparum. Nat Chem Biol 4 203 213

67. ArezAP

PintoJ

PalssonK

SnounouG

JaensonTG

2003 Transmission of mixed Plasmodium species and Plasmodium falciparum genotypes. Am J Trop Med Hyg 68 161 168

68. BousemaJT

DrakeleyCJ

MensPF

ArensT

HoubenR

2008 Increased Plasmodium falciparum gametocyte production in mixed infections with P. malariae. Am J Trop Med Hyg 78 442 448

69. OsierFH

FeganG

PolleySD

MurungiL

VerraF

2008 Breadth and magnitude of antibody responses to multiple Plasmodium falciparum merozoite antigens are associated with protection from clinical malaria. Infect Immun 76 2240 2248

70. CromptonPD

KayalaMA

TraoreB

KayentaoK

OngoibaA

2010 A prospective analysis of the ab response to Plasmodium falciparum before and after a malaria season by protein microarray. Proc Natl Acad Sci U S A 107 6958 6963

71. The malERA Consultative Group on Vector Control 2011 A research agenda for malaria eradication: Vector control. PLoS Med 8 e1000401 doi:10.1371/journal.pmed.1000401

72. LawpoolsriS

KleinEY

SinghasivanonP

YimsamranS

ThanyavanichN

2009 Optimally timing primaquine treatment to reduce Plasmodium falciparum transmission in low endemicity thai-myanmar border populations. Malar J 8 159

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