Insecticide Susceptibility Status of Phlebotomus (Paraphlebotomus) Sergenti and Phlebotomus (Phlebotomus) Papatasi in Endemic Foci of Cutaneous Leishmaniasis in Morocco

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In Morocco, cutaneous leishmaniasis is transmitted by Phlebotomus sergenti and Ph. papatasi. Vector control is mainly based on environmental management but indoor residual spraying with synthetic pyrethroids is applied in many foci of Leishmania tropica. However, the levels and distribution of sandfly susceptibility to insecticides currently used has not been studied yet. Hence, this study was undertaken to establish the susceptibility status of Ph. sergenti and Ph. papatasi to lambdacyhalothrin, DDT and malathion.

Methods

The insecticide susceptibility status of Ph. sergenti and Ph. papatasi was assessed during 2011, following the standard WHO technique based on discriminating dosage. A series of twenty-five susceptibility tests were carried out on wild populations of Ph. sergenti and Ph. papatasi collected by CDC light traps from seven villages in six different provinces. Knockdown rates (KDT) were noted at 5 min intervals during the exposure to DDT and to lambdacyhalothrin. After one hour of exposure, sandflies were transferred to the observation tubes for 24 hours. After this period, mortality rate was calculated. Data were analyzed by Probit analysis program to determine the knockdown time 50% and 90% (KDT50 and KDT90) values.

Results

Study results showed that Ph.sergenti and Ph. papatasi were susceptible to all insecticides tested. Comparison of KDT values showed a clear difference between the insecticide knock-down effect in studied villages. This effect was lower in areas subject to high selective public health insecticide pressure in the framework of malaria or leishmaniasis control.

Conclusion

Phlebotomus sergenti and Ph. papatasi are susceptible to the insecticides tested in the seven studied villages but they showed a low knockdown effect in Azilal, Chichaoua and Settat. Therefore, a study of insecticide susceptibility of these vectors in other foci of leishmaniasis is recommended and the level of their susceptibility should be regularly monitored.

Authors: Chafika Faraj, Souad Ouahabi, El Bachir Adlaoui, Mohamed Elkohli, Lhoussine Lakraa, Mohammed ElRhazi and Btissam Ameur

Full Article: Insecticide susceptibility status of Phlebotomus (Paraphlebotomus) sergenti and Phlebotomus (Phlebotomus) papatasi in endemic foci of cutaneous leishmaniasis in Morocco (PDF)

Source: Parasites & Vectors 2012, 5:51 doi:10.1186/1756-3305-5-51

Published: 19 March 2012

Copyright: © 2012 Chafika Faraj et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Mobile Phone Text Messaging: Tool for Malaria Control in Africa

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Across many malaria-endemic areas in rural Africa, the communication gap between managers, health workers, and patients is a significant barrier to efficient malaria control. The rapid expansion of mobile network coverage and the widespread availability of basic handsets have the potential to substantively bridge the communication gap. Text messaging, as the least-expensive mobile phone function found on all handsets, could improve the delivery of health services and health outcomes.

Six major areas of malaria control in which deficiencies are apparent and text messaging interventions could be beneficial are:

  1. Disease and treatment effectiveness surveillance
  2. Monitoring of the availability of health commodities
  3. Pharmacovigilance and post-marketing surveillance of the safety and quality of antimalarial drugs
  4. Health worker adherence to guidelines
  5. Patient adherence to medication regimen
  6. Post-treatment review

Text messages transmitting information from the periphery of the health systems to malaria control managers are in the first three malaria control areas: (1) disease and treatment effectiveness surveillance, (2) monitoring of the availability of health commodities, and (3) pharmacovigilance and post-marketing surveillance of the safety and quality of antimalarial medicines. Future projects in these three areas should demonstrate responses to data signals and comparative advantages with routine information systems.

Text messages in the second three areas transmit information to health workers and patients to support the management of malaria patients by improving (4) health workers’ adherence to guidelines, (5) patient adherence to medicines, and (6) post-treatment review. Future priorities in these areas are cost-effectiveness evaluations, qualitative research, and studies measuring impact on the processes of care and health outcomes.


Funding: DZ is supported by the Wellcome Trust project grant [#084253]. RWS is supported by the Wellcome Trust as Principal Research Fellow [#079080]. AOT is supported by the Worldwide Antimalarial Resistance Network (WWARN) through a Bill & Melinda Gates Foundation grant [#48807.01]. All authors acknowledge support from the Wellcome Trust core grant [#092654/Z/10/A]. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Citation: Zurovac D, Talisuna AO, Snow RW (2012) Mobile Phone Text Messaging: Tool for Malaria Control in Africa. PLoS Med 9(2): e1001176. doi:10.1371/journal.pmed.1001176

Copyright: © 2012 Zurovac et al. This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Full Article: Mobile Phone Text Messaging: Tool for Malaria Control in Africa (PDF)

 

Blood-Feeding Patterns of Anopheles Mosquitoes in Bangladesh

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Blood-feeding patterns of mosquitoes are crucial for incriminating malaria vectors. However, little information is available on the host preferences of Anopheles mosquitoes in Bangladesh. Therefore, the objective of the present study was to determine the hematophagic tendencies of the anophelines inhabiting a malaria-endemic area of Bangladesh. [Read more…]

Hitting Hotspots: Spatial Targeting of Malaria for Control and Elimination

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Current malaria elimination guidelines are based on the concept that malaria transmission becomes heterogeneous in the later phases of malaria elimination [1]. In the pre-elimination and elimination phases, interventions have to be targeted to entire villages or towns with higher malaria incidence until only individual episodes of malaria remain and become the centre of attention [1]. With increasing evidence of clustering of malaria episodes within villages, we argue that there is an intermediate step. Heterogeneity in malaria transmission within villages is present long before areas enter the pre-elimination phase, and identifying and targeting hotspots of malaria transmission should form the cornerstone of both successful malaria control and malaria elimination. [Read more…]

Central Venous Catheter Use in Severe Malaria: Time to Reconsider the World Health Organization Guidelines?

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To optimize the fluid status of adult patients with severe malaria, World Health Organization (WHO) guidelines recommend the insertion of a central venous catheter (CVC) and a target central venous pressure (CVP) of 0-5 cmH2O. However there are few data from clinical trials to support this recommendation.

Methods
Twenty-eight adult Indian and Bangladeshi patients admitted to the intensive care unit with severe falciparum malaria were enrolled in the study. All patients had a CVC inserted and had regular CVP measurements recorded. The CVP measurements were compared with markers of disease severity, clinical endpoints and volumetric measures derived from transpulmonary thermodilution.

Results
There was no correlation between the admission CVP and patient outcome (p = 0.67) or disease severity (p = 0.33). There was no correlation between the baseline CVP and the concomitant extravascular lung water (p = 0.62), global end diastolic volume (p = 0.88) or cardiac index (p = 0.44). There was no correlation between the baseline CVP and the likelihood of a patient being fluid responsive (p = 0.37). On the occasions when the CVP was in the WHO target range patients were usually hypovolaemic and often had pulmonary oedema by volumetric measures. Seven of 28 patients suffered a complication of the CVC insertion, although none were fatal.

Conclusion
The WHO recommendation for the routine insertion of a CVC, and the maintenance of a CVP of 0-5 cmH2O in adults with severe malaria, should be reconsidered.

Authors: Josh Hanson1,2*, Sophia WK Lam1,2, Sanjib Mohanty3, Shamshul Alam4, Md Mahtab U Hasan5, Sue J Lee2, Marcus J Schultz6, Prakaykaew Charunwatthana2, Sophie Cohen7, Ashraf Kabir8, Saroj Mishra3, Nicholas PJ Day2,9, Nicholas J White2,9 and Arjen M Dondorp2,9

* Corresponding author: Josh Hanson drjoshhanson@gmail.com

Author Affiliations

1 Department of Medicine, Cairns Base Hospital, Queensland, Australia
2 Mahidol Oxford Research Unit, Mahidol University, Bangkok, Thailand
3 Department of Medicine, Ispat General Hospital, Rourkela, India
4 Department of Intensive Care Medicine, Chittagong Medical College Hospital, Chittagong, Bangladesh
5 Department of Medicine, Chittagong Medical College Hospital, Chittagong, Bangladesh
6 Department of Intensive Care Medicine, Academic Medical Center, University of Amsterdam, Amsterdam, The Netherlands
7 Department of Vascular Medicine, Academic Medical Center, University of Amsterdam, Amsterdam, the Netherlands
8 Department of Anaesthetics, Cox’s Bazar Medical College, Cox’s Bazar, Bangladesh
9 Nuffield Department of Clinical Medicine, University of Oxford, Oxford, UK

Citation: Malaria Journal 2011, 10:342 doi:10.1186/1475-2875-10-342

Full Article: Central Venous Catheter Use in Severe Malaria: Time to Reconsider the World Health Organization Guidelines? (PDF)

Copyright © by the authors, 2011. This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

REVIEW: The Use of Intermittent Preventive Treatment in Pregnancy to Protect Against Malaria Infection

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Review of Le Port A, et al. (2011), ‘Prevention of Malaria during Pregnancy: Assessing the Effect of the Distribution of IPTp Through the National Policy in Benin’,  American Journal of Tropical Medicine and Hygiene, Vol 84 (Issue 2): pp 270-275

[Read more…]

Polymorphism in the Human FAS Gene Promoter Associated with Severe Childhood Malaria

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Human genetics and immune responses are considered to critically influence the outcome of malaria infections including life-threatening syndromes caused by Plasmodium falciparum. An important role in immune regulation is assigned to the apoptosis-signaling cell surface receptor CD95 (Fas, APO-1), encoded by the gene FAS.

Here, a candidate-gene association study including variant discovery at the FAS gene locus was carried out in a case-control group comprising 1,195 pediatric cases of severe falciparum malaria and 769 unaffected controls from a region highly endemic for malaria in Ghana, West Africa. We found the A allele of c.−436C>A (rs9658676) located in the promoter region of FAS to be significantly associated with protection from severe childhood malaria (odds ratio 0.71, 95% confidence interval 0.58–0.88, pempirical = 0.02) and confirmed this finding in a replication group of 1,412 additional severe malaria cases and 2,659 community controls from the same geographic area.

The combined analysis resulted in an odds ratio of 0.71 (95% confidence interval 0.62–0.80, p = 1.8×10−7, n = 6035). The association applied to c.−436AA homozygotes (odds ratio 0.47, 95% confidence interval 0.36–0.60) and to a lesser extent to c.−436AC heterozygotes (odds ratio 0.73, 95% confidence interval 0.63–0.84), and also to all phenotypic subgroups studied, including severe malaria anemia, cerebral malaria, and other malaria complications. Quantitative FACS analyses assessing CD95 surface expression of peripheral blood mononuclear cells of naïve donors showed a significantly higher proportion of CD69+CD95+ cells among persons homozygous for the protective A allele compared to AC heterozygotes and CC homozygotes, indicating a functional role of the associated CD95 variant, possibly in supporting lymphocyte apoptosis.

Author Summary

Severe malaria caused by infection with the protozoan parasite Plasmodium falciparum is a major health burden, causing approximately one million fatalities annually, predominantly among young children in Sub-Saharan Africa. The occurrence of severe malaria may depend on a complex interplay of transmission dynamics and the development of a protective immune response but also on heritable differences in the susceptibility to the disease.

In two large studies including a total of 2,607 affected children and 3,428 apparently healthy individuals from Ghana, West Africa, we investigated genetic variants of the FAS gene, which encodes CD95, a molecule critically involved in the programmed cell death of lymphocytes. We found that a single nucleotide variant in the FAS promoter was associated with a 29%–reduced risk of developing severe malaria. In individuals carrying two copies of the protective allele, a higher proportion of activated lymphocytes was found to express CD95. These findings indicate that a predisposition to an increased expression of CD95 may help to protect from severe malaria, possibly by rendering activated T-lymphocytes more susceptible to programmed cell death.

Citation: Schuldt K, Kretz CC, Timmann C, Sievertsen J, Ehmen C, et al. (2011) A −436C>A Polymorphism in the Human FAS Gene Promoter Associated with Severe Childhood Malaria. PLoS Genet 7(5): e1002066. doi:10.1371/journal.pgen.1002066

Editor: Daniel C. Jeffares, University College London, United Kingdom

Received: November 3, 2010; Accepted: March 18, 2011; Published: May 19, 2011

Copyright: © 2011 Schuldt et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Funding: The work was supported by the German National Genome Research Network (NGFN). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Authors: Kathrin Schuldt1,2*, Cosima C. Kretz3, Christian Timmann1,2, Jürgen Sievertsen1, Christa Ehmen1, Claudia Esser1, Wibke Loag4, Daniel Ansong5, Carmen Dering2, Jennifer Evans1, Andreas Ziegler2, Jürgen May4, Peter H. Krammer3, Tsiri Agbenyega5, Rolf D. Horstmann1

1 Department of Molecular Medicine, Bernhard Nocht Institute for Tropical Medicine, Hamburg, Germany, 2 Institute of Medical Biometry and Statistics, University at Lübeck, University Hospital Schleswig-Holstein, Lübeck, Germany, 3 Division of Immunogenetics, German Cancer Research Centre, Heidelberg, Germany, 4 Infectious Disease Epidemiology Group, Bernhard Nocht Institute for Tropical Medicine, Hamburg, Germany, 5 School of Medical Sciences, Kwame Nkrumah University of Science and Technology, Kumasi, Ghana

Full text: A −436C>A Polymorphism in the Human FAS Gene Promoter Associated with Severe Childhood Malaria (PDF)

Of Macaques and Men

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Plasmodium knowlesi —a new challenge in the Roll Back Malaria Program?

Deforestation oil palm Malaysia

Oil palm plantation in Malaysia: Such land-use change may be affecting malaria transmission. Photo courtesy of Yusmar Yahaya (http://www.flickr.com/photos/leafbug/4880638055/sizes/m/)

Mention of malaria often conjures images of infants hospitalized in Africa. Although most deaths from malaria are children under 5 in sub-Saharan Africa, there are many different types of malaria that put over half of the world’s population at risk in subtropical and tropical regions worldwide.

There have historically been four species of Plasmodium parasites that cause malaria humans.  P. falciparum is the most lethal species that infects humans, whereas P. vivax is the most widespread.  P. vivax and P. ovale also cause clinical symptoms and decreased economic potential in certain regions.

[Read more…]

APL1 Malaria Resistance Genes of Anopheles Gambiae

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Immune defense genes are sometimes highly variable in host populations, reflecting selective pressure to combat diverse pathogens. In other instances, where there are only a few dominant pathogens, natural selection may favor only one or a few defense alleles. Here, we show that both adaptive strategies can occur in the same genes under different circumstances.

We examined diversity in the APL1 genes of the human malaria vector mosquito Anophleles gambiae, which play a role in defense against malaria parasites. We found that the APL1 genes are exceptionally polymorphic, being 10-fold more diverse than typical A. gambiae genes.
[Read more…]

Malaria Control with Transgenic Mosquitoes

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Malaria has been eliminated from a large part of the world. By the mid-twentieth century both North America and Europe were free of the disease, although both had suffered greatly during the prior century [1,2]. While a variety of means were used to achieve this eradication, the most important are thought to be reducing the number of breeding sites for malaria vectors and improving residential areas to separate humans from mosquitoes.

Other parts of the world have not been so fortunate. In sub-Saharan Africa, it is now estimated that there are more than 360 million clinical cases and one million deaths due to malaria each year [3,4]. Furthermore, despite ambitious goals such as those of the Roll Back Malaria Initiative to halve malaria deaths by 2010, mortality from the disease has actually risen halfway through the program [5]. Clearly the tools we have to control malaria, or the ways in which we are using them, are not working.

The failure of existing methods for malaria control has sparked interest in several new approaches. These include better and cheaper antimalarial drugs [6], renewed efforts to find a vaccine [7], and the development of genetically modified mosquitoes (GMMs) designed either to reduce population sizes or to replace existing populations with vectors unable to transmit the disease. In this review we describe some of the efforts currently underway to create GMMs and assess some of the obstacles they face.

Background

Malaria in humans results from infection by any of five species of Plasmodium: P. falciparum, P. vivax, P. ovale, P. malariae, and P. knowlesi. These are transmitted to humans by approximately 50 species of mosquitoes, all belonging to the genus Anopheles. In sub-Saharan Africa, the vast majority of deaths are caused by P. falciparum transmitted by An. gambiae and the closely related An. arabiensis. These species are difficult to work with in the laboratory, so other model systems of malaria are often used in laboratory studies.

Most species of mosquitoes do not transmit malaria, and even among species that do, many individuals seem incapable of transmitting the disease, i.e., are refractory. Accordingly, there is reason to hope that the genes that permit malarial infections in mosquitoes can be identified and then replaced or altered in terms of their function. In this way, it is hoped that mosquito populations will become refractory to the parasite, eventually leading to malaria transmission being halted.

A variety of methods for engineering refractory mosquitoes are currently being studied and show promise for malaria control. The laboratory of Marcelo Jacobs-Lorena at Johns Hopkins University has successfully engineered mosquitoes that confer resistance to rodent malaria [8]. Their approach was to first identify receptor sites for proteins that the parasite requires to pass through the gut after ingestion. They next produced small proteins that saturate the receptor sites and hence block amplification and transmission of the parasite (Figure 1). Future research in this area should focus on optimizing refractory genes to effectively confer resistance to human malaria.

Figure 1 - Left: Mosquitoes become infected with the malaria parasite upon taking an infected human blood-meal. This produces an oocyst in the mosquito's gut wall (light red). When the oocyst ruptures, it releases sporozoites that pass through the gut (dark red) and into the hemocoel (white). The sporozoites are then amplified and migrate through the mosquito's body to the salivary glands, ready to infect a new human. Right: The laboratory of Marcelo Jacobs-Lorena at Johns Hopkins University has identified receptor sites for proteins that are necessary for the malaria parasite to pass through the gut wall after the oocyst ruptures. The same receptors are involved with the passage of sporozoites into the salivary glands. The laboratory has produced small proteins that preferentially occupy these sites (blue), blocking transmission of sporozoites through the gut wall and into the salivary glands. The appropriate gene constructs have been introduced into An. stephensi mosquitoes, thus rendering them refractory to P. berghei (a model system for human malaria). (doi:10.1371/journal.pmed.1000020.g001)

 

 

Other methods for generating refractoriness involve using antibodies that kill parasites within the mosquito [9] and discovering genes that govern refractoriness in natural populations [10]. A great deal is being discovered about the immune system of mosquitoes [11], leading many researchers in this field to believe that an effective gene construct to reduce the ability of mosquitoes to transmit malaria is not far away.

FIVE KEY PAPERS IN THE FIELD

Marshall, 2008 [18] This article focuses on TEs as a drive system and models the impact of dissociation between the drive system and refractory gene. It references much of the important work to this time on TEs.

Chen et al., 2007 [20] This article describes the biology and potential uses of a synthetic Medea element observed to spread through laboratory Drosophila populations.

James, 2005 [19] A general overview of the criteria required by gene drive systems intended to drive refractory genes into mosquito populations.

Alphey et al., 2002 [27] A discussion of the benefits, risks, and research priorities associated with using transgenic insects to control vector-borne diseases.

Ito et al., 2002 [8] An historic paper that describes one of the first candidate antiparasitic genes that works in a disease vector model system in the laboratory.

Drive Systems

More problematic is the means of driving a refractory construct quickly and efficiently through the vector mosquito population so that the population of susceptible mosquitoes will be replaced. Transposable elements (TEs) were one of the first gene drive systems to gain widespread attention for population replacement [12]. These elements are able to spread quickly through a population due to their ability to replicate within a host genome and hence to be inherited more frequently in the offspring’s genome. This increase in inheritance enables TEs to spread even in the presence of a fitness cost to the host [13]. It has also led to their widespread prevalence among many taxa, to the extent that various families of TEs represent 47% of the Aedes aegypti mosquito genome [14].

One source of encouragement for the use of TEs in population replacement is the observation that the P element spread through most of the global Drosophila melanogaster population within the span of a few decades following a natural acquisition from D. willistoni [15]. It is hoped that such an invasion could be repeated in a mosquito species using a TE that is attached to a refractory gene conferring resistance to malaria. Ideally, such an invasion would be repeated in each of the major mosquito species that transmits malaria.

Despite initial excitement, TEs have become less favored as a means of population replacement in recent years. The first major hurdle has been the failure to introduce a highly active TE into An. gambiae—the main vector of malaria in sub-Saharan Africa. TEs tend to repress their activity over time to avoid corrupting the host genome. Many TEs, including the P element, accumulate mutations leading to their inactivation. This may make the discovery of a highly active TE more challenging than originally anticipated.

Additionally, preliminary data suggest other reasons that TEs may be ill-suited to driving foreign DNA into populations. A study on the Himar1 mariner element suggests that TE activity declines substantially with increasing size [16]. Given current refractory gene sizes (e.g., [17]), the mariner element is estimated to have its replication rate reduced by at least 95% when burdened by a refractory construct [16]. Its drive would have to be very strong in order to suffer such a decline in replication.

This is compounded by the fact that TEs are particularly vulnerable to losing internal sequences during replication. Mathematical modeling suggests that, if the refractory gene is lost from the TE at a modest rate, the malaria-susceptible TE will return to again dominate the population [18]. Therefore, even if active TEs can be identified, their ability to drive refractory genes into a population is questionable.

Disenchantment with TEs as a means of population replacement has coincided with interest in several other gene drive systems. Some of the most promising drive mechanisms currently being investigated include Medea elements, homing endonuclease genes (HEGs), engineered underdominance constructs, and the intracellular bacterium Wolbachia. Other systems that are being investigated include engineered underdominance constructs and meiotic drive [19].

The favorability of one gene drive system over another will depend on its ability to quickly and efficiently spread a refractory gene. However, this on its own is not enough. The ideal gene drive system will also address ecological, epidemiological, and social concerns that such a system engenders and minimize the likelihood of any risks. In our opinion, the most promising system at present is Medea.

Medea has attracted much attention as a tool for population replacement in recent years, following the observation that an engineered Medea element is able to rapidly spread through D. melanogaster populations in the laboratory [20]. The design of this synthetic element is based on a naturally occurring selfish genetic element first discovered in a species of flour beetle, Tribolium castaneum. Medea is able to rapidly spread through a population in the presence of a fitness cost by distorting the offspring ratio in its favor. It does this by causing the death of all offspring of heterozygous females that do not inherit the allele, thus giving rise to its name—an acronym for maternal-effect dominant embryonic arrest, with reference to the mythological Greek figure who murdered her own children.

The synthetic Medea element developed by Chen et al. [20] works by the hypothesis that Medea encodes both a maternally expressed toxin and a zygotically expressed antidote. The toxin causes the death of all progeny lacking the Medea allele, and the antidote rescues Medea-bearing progeny from an otherwise imminent dealth (Figure 2). In this way, the proportion of Medea-bearing individuals is increased with each generation; and it is hoped that an attached refractory gene conferring resistance to malaria could come along for the ride.

Figure 2 - Parental Crosses Representing the Reproductive Advantage of the Medea Allele Females carrying the Medea allele produce a maternally expressed toxin (red outer circle) that is deleterious to their offspring. Offspring who carry the Medea allele are rescued by a zygotically expressed antidote (green inner circle) expressed by the same allele. Offspring of heterozygous females who do not inherit the Medea allele are killed by the toxin because they lack the antidote (yellow represents lack of the toxin/antidote). This distorts the offspring ratio in favor of the Medea allele. (doi:10.1371/journal.pmed.1000020.g002)

Medea does not suffer from many of the ailments inflicted upon TEs—an active Medea element has been engineered, its spread is not retarded by the insertion of foreign DNA, and a solution has been proposed to minimize the rate of dissociation of refractory genes [20]. Additionally, in the event that a refractory gene should be recalled following an environmental release with unwanted consequences, it has been proposed that another strain of Medea could be introduced to replace the first, thus removing the refractory gene from the population.

One attractive feature of Medea is that its rate of spread is strongly dependent on its release ratio [21]. While Medea will spread very quickly following a large intentional release, it is very likely to go extinct following a small accidental release [22]. This is particularly important since it is impossible to guarantee that there will be no escapes while outdoor cage trials assess the potential outcomes of an environmental release [23]. Medea therefore presents a desirable balance between invasiveness and containment. At present, there is an active effort to construct Medea systems for mosquitoes, but as yet no such systems have been made.

HEGs are another system for which there are active development efforts. These genes are able to spread through a population by expressing an endonuclease that creates a double-stranded break at a highly specific site lacking the HEG. Homologous DNA repair then copies the HEG to the cut chromosome, thus increasing its representation over subsequent generations [24].

Next Steps in Research

The first requirement of any transgenic mosquito project will be the discovery of genes that confer resistance to human vector-borne diseases. The proof of principle has been shown for rodent and chicken malaria, and it remains to optimize genes to confer resistance to human malaria. Several refractory genes will be necessary for a successful intervention both to improve the efficacy of refractoriness, and to reduce the probability that resistance to antipathogen genes will emerge in the Plasmodium population.

Possibly more challenging will be the optimization of gene drive systems to deliver these refractory genes into mosquito populations. Medea has been shown to drive population replacement in Drosophila; and future research should work towards repeating this in mosquitoes. If this can be achieved, Medea will be a very promising candidate for population replacement; however, potential hazards for Medea and other gene drive systems must be identified and responded to, such as their ability to spread through reproductively isolated populations, and their persistence following an accidental release. Mathematical modeling can assist in assessing the severity of these concerns.

A broad study is required of the ecology of mosquito vectors through which the refractory genes are intended to be driven. Comprehensive ecological studies have been carried out in selected regions (e.g., [25]); however, these must be extended to other regions of Africa to gain a broader picture of species distributions and rates of gene flow. Malaria is a complex disease, and the biology of its vectors is also complex. In most parts of Africa, there is more than one species of Anopheles that transmits malaria. If hybridization among species is judged to be insufficient, then the feasibility of altering several species of malaria vectors will need to be considered.

We have focused our review on the effort to produce GMMs for malaria control; however, developing GMMs for dengue control will likely be achieved much earlier. Dengue virus, transmitted by the vector Ae. aegypti, is likely the second-most important vector-borne disease system after malaria. It is also much simpler than malaria—Ae. aegypti is easier to rear and experiment with than An. gambiae, and dengue does not have a complicated life cycle like Plasmodium. Much of the current work on GMMs is being conducted with dengue virus, and many of the problems confronting vector replacement will probably be worked out first with this system.

Finally, a large number of ethical concerns must be addressed and resolved satisfactorily before GMMs can be introduced. These include questions about the meaning of informed consent in communities that are largely illiterate, unfamiliar with genetic modification, and sometimes uneducated on the role of mosquitoes in disease transmission. These consent issues are confounded by the possibility of unknown and potentially serious side effects of a release, for example, an increase in the transmission of non-target diseases. Furthermore, acceptance by one community, or even country, is likely to affect many of its neighbors, whether they agree with the decision to release or not. Such a release may occur accidentally from an outdoor cage trial; however, an intentional release cannot be conducted prior to evaluation in cage trials.

Despite this, mosquito-borne diseases kill in excess of a million people every year, mostly children under five years old. GMMs offer some hope of reducing this burden of disease, and hence their risks, both known and unknown, must be weighed against the certain toll of inaction. In addition to some helpful initial studies [22,26,27], there is a clear need for much more analysis of the human research participant issues posed by these new methods.

GLOSSARY

Refractory gene: Gene conferring inability to transmit malaria.

Transposable elements: Genomic components that express a transposase enzyme catalyzing their replication in the genome. This enables them to spread through a population despite a fitness cost.

Fitness costs: Reduction in fitness associated with carrying foreign DNA.

Himar1 mariner element: A transposable element of the Mariner class. It contains its own transposase gene and moves by a cut-and-paste mechanism.

Internal sequences: Region of DNA between the characteristic end sequences of a transposable element.

Homing endonuclease gene: A selfish gene that spreads through a population by expressing an endonuclease that creates a double-stranded break in a DNA sequence and then copies itself to this site.

Medea element: A selfish genetic element that is able to spread through a population through its ability to cause the death of all offspring of heterozygous females that do not inherit the allele.

Wolbachia: A maternally inherited intracellular bacterium that can disrupt reproduction with noninfected sperm. This may be used to drive refractory genes into vector populations.

Engineered underdominance constructs: A form of underdominance in which there are two transgenic constructs, each of which possess a lethal gene and a suppressor gene that down-regulates the expression of the lethal gene on the other construct.

Meiotic drive: Any mechanism by which a heterozygous locus segregates at a greater-than-Mendelian frequency, often by destroying or disabling the homologous chromosome.

Dissociation of refractory genes: Loss of refractory gene DNA from a gene drive construct such that the refractory gene no longer functions.

Release ratio: The ratio of transgenic mosquitoes to natives ones at the time of a release.

Conclusion

Malaria control with transgenic mosquitoes will be challenging; however, recent advances suggest that it may be a possibility in the foreseeable future. Progress towards discovering refractory genes for rodent malaria and gene drive systems for Drosophila provide hope that similar advances may be made for human malaria in mosquito vector species.

That said, the African malaria burden has proved exceptionally difficult to diminish by all means tried thus far; and it is unlikely that transgenic mosquitoes will provide an all-in-one solution. Transgenic mosquitoes should be considered within the context of an integrated vector management strategy which should also include insecticide-treated bed-nets, indoor residual spraying with insecticides, and treatment of infected individuals with antimalarial drugs. Integrated strategies will be a necessity for any successful African malaria control program [28]; and transgenic mosquitoes should be considered as a potential ingredient in the future goal of continent-wide disease control.

Acknowledgments

We thank Marcelo Jacobs-Lorena, who kindly provided an illustration that became the model for Figure 1, Gregory Lanzaro, who provided a photo of An. gambiae, and Benny Gee, who made the figures.

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