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Failure to detect Plasmodium vivax in West and Central Africa by PCR species typing

Richard L Culleton112*, Toshihiro Mita2, Mathieu Ndounga3, Holger Unger4, Pedro VL Cravo5, Giacomo M Paganotti7, Nobuyuki Takahashi2, Akira Kaneko6, Hideaki Eto2, Halidou Tinto10, Corine Karema11, Umberto D'Alessandro9, Virgilio do Rosário5, Takatoshi Kobayakawa2, Francine Ntoumi8, Richard Carter4 and Kazuyuki Tanabe1*

Author Affiliations

1 Laboratory of Malariology, International Research Centre of Infectious Diseases, Research Institute of Microbial Diseases, Osaka University, Osaka, Japan

2 Tokyo Women's Medical University, Tokyo, Japan

3 Centre d'Etudes des Resources Vegetales, Brazzaville, Republic of Congo

4 Institute of Immunology and Infection Research, University of Edinburgh, Edinburgh, UK

5 Centro de Malária e Outras Doenças Tropicais, Lisbon, Portugal

6 Department of Medicine, Karolinska University Hospital, Solna, Sweden

7 Istituto Pasteur, Fondazione Cenci-Bolognetti, Università di Roma 'La Sapienza', Rome, Italy

8 Medical Research Unit, Albert Schweitzer Hospital, Lambaréné, Gabon

9 Institute of Tropical Medicine, Antwerp, Belgium

10 Centre Muraz, Bobo Dioulasso, Burkina Faso

11 Programme Nationale de Lutte Integrée contre le Paludisme, Kigali, Rwanda

12 Department of Protozoology, Institute of Tropical Medicine, Nagasaki University, Nagasaki, Japan

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Malaria Journal 2008, 7:174  doi:10.1186/1475-2875-7-174

The electronic version of this article is the complete one and can be found online at: http://www.malariajournal.com/content/7/1/174


Received:28 March 2008
Accepted:11 September 2008
Published:11 September 2008

© 2008 Culleton et al; licensee BioMed Central Ltd.

This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Background

Plasmodium vivax is estimated to affect 75 million people annually. It is reportedly absent, however, from west and central Africa due to the high prevalence of the Duffy negative phenotype in the indigenous populations. Despite this, non-African travellers consistently return to their own countries with P. vivax malaria after visiting this region. An attempt was made, therefore, to detect the presence of P. vivax parasites in blood samples collected from the indigenous populations of west and central Africa.

Methods

Parasite species typing (for all four human malaria parasites) was carried out by PCR on 2,588 blood samples collected from individuals from nine African malaria-endemic countries.

Results

Most infections (98.5%) were Plasmodium falciparum, Plasmodium malariae was identified in 8.5% of all infections, and Plasmodium ovale in 3.9%. The prevalence of both parasites varied greatly by country. Only one case of P. vivax was detected from Sao Tome, an island off the west coast of Africa, confirming the scarcity of this parasite in Africa.

Conclusion

The prevalence of P. vivax in local populations in sub-Saharan Africa is very low, despite the frequent identification of this parasite in non-African travellers.

Background

Plasmodium vivax has the widest geographic range of the four parasites responsible for malaria in man. Historically, its range has extended as far north as Finland and northern China, and as far south as northern Australia and South Africa [1]. Concerted malaria control initiatives in countries in temperate zones have today confined P. vivax mainly to the tropics, where its range overlaps that of the most important malaria parasite in terms of public health, Plasmodium falciparum. Thus, the two parasites co-exist in large parts of the tropical and semi-tropical world, except, strikingly, in large parts of western and central Africa, where P. vivax appears to be almost completely absent [2]. This situation is apparently caused by the high prevalence of the Duffy negative phenotype in the local populations, which confers complete protection against P. vivax malaria [3]. The Duffy antigen/receptor for chemokines (DARC) is a transmembrane glycoprotein that is present on epithelial cells [4], endothelial cells [5], and erythrocytes. It is utilized by P. vivax parasites as the receptor for attachment to the red cell surface [6]. Duffy negative individuals are homozygous for a DARC allele, FY*Bnull, which carries a single nucleotide mutation which impairs promoter activity by disrupting a binding site for the h-GATA-1 erythroid transcription factor [7]. This results in the loss of DARC expression on erythrocytes, but does not affect expression in epithelial or endothelial cells. Individuals who are homozygous for this allele thus express no DARC protein on the red cell surface and are completely protected from the erythrocytic cycle of P. vivax. The Duffy negative phenotype occurs in over 95% of the population of west and central Africa, but is extremely rare outside Africa and the Arabian peninsula [8].

Present day prevalence of P. vivax in Africa

Although P. vivax is known to be present in parts of northern, eastern and southern Africa, with some areas reporting a prevalence of around 20% of all malaria infections [9], it is extremely rare in west and central Africa. In fact, there are very few cases of P. vivax in the indigenous population at all, with the exception of the island of Sao Tome, which is known to harbour all four human malaria parasites [10]. It is possible that the lack of "local" P. vivax reported from these areas is due to the fact that its perceived absence precludes its identification. So ingrained may be the notion of the absence of P. vivax from west and central Africa that many surveys of parasite species composition from these areas do not include assays for the identification of the parasite [11], and many microscopists automatically designate any parasite associated with Schüffner's dotted erythrocytes as P. ovale [12]. There are, however, sporadic reports of its presence. One report from Equatorial Guinea describes the discovery of four cases of P. vivax in children of mixed race parentage [13], and another describes a mild infection of P. vivax in a Duffy negative woman from the Democratic Republic of Congo [14]. These rare accounts are supported by more extensive reports detailing P. vivax infections in non-African travellers returning from these areas. For example, an analysis of 618 imported P. vivax cases diagnosed in European clinics between 1999 and 2003, found that 17% of travellers had contracted the parasite in west and central Africa [15]. Furthermore, between 1995 and 1998 there were 73 reports of P. vivax imported into France from this region [16]. Imported malaria surveys from the USA report a similar pattern, with data from 2004 revealing that 65% of P. vivax imported into the USA from Africa in that year (n = 67) originated in countries in west and central regions [17]. As some of these reports [15,17] rely on microscopy for identification of parasite species, it may be argued that confusion between P. ovale and P. vivax may lead to a degree of misdiagnosis. However, there are an increasing number of reports that identify parasite species with molecular techniques [16,18], which are much less prone to misidentification of species. Given these data, it seems certain that transmission of P. vivax does occur in west and central Africa. However, it remains unclear how transmission is maintained in populations where the Duffy negative phenotype is almost at fixation.

In 1985, Van Ros described the presence of P. vivax in a Duffy negative individual [14] from the Democratic Republic of Congo. Recently, two new reports have also described this intriguing situation. One, from western Kenya, describes the presence of P. vivax circumsporozoite protein in 0.65% of mosquitoes from an area of high Duffy negativity [19]. More recently, Cavasini et al [20] reported clear evidence of P. vivax infections in two Duffy negative individuals in Brazil. It has been proposed that the parasite may be in the process of evolving mechanisms which allow the infection of Duffy negative individuals [21]. Such findings highlight the need for a clear investigation of the prevalence and population dynamics of P. vivax in west and central Africa, using accurate molecular species typing methods.

In order to assess the current prevalence of P. vivax in west and central Africa, PCR species typing of 2,588 samples from nine different countries throughout the continent was carried out.

Methods

Blood sample collection and parasite DNA extraction

A total of 2,588 blood samples collated from various surveys undertaken in nine African countries (Figure 1) between 1998 and 2006 were analysed by PCR for the presence of each of the four human malaria parasites, P. falciparum, P. vivax, P. malariae and P. ovale. The original sample collections were predominantly carried out as part of unrelated investigations and the methodology of individual collection varies. Table 1 outlines the details of these collections. In all cases, ethical clearance for sampling was obtained from the relevant ethical committees (for samples collected specifically for this study, details are given in the following paragraphs).

Table 1. Details of sample collections.

Samples from Burkina Faso

In 2002, samples were collected from asymptomatic children under 10 years old by Active Case Detection (ACD) in two villages (Bassy and Zanga) 60 Km east of Ouagadougou, the capital of Burkina Faso at the end of the transmission season [22]. DNA was extracted by the use of TRIZOL® reagent [22]. 108 P. falciparum positive samples (by PCR), were used in this study.

Samples from Angola, Mozambique, Rwanda, and the Democratic Republic of Sao Tome & Principe (DRSTP)

Blood samples were collected by Passive Case Detection (PCD) at clinics in the following countries: DRSTP, February 2004, at the Centro Policlínico de Saúde de Água Grande, São Tomé (all ages)[23]; Angola, 2003–2004 at the Hospital Pediatrico de Luanda (1–5 year olds)[24]; Mozambique from July to October 2004 at the Hospital Central de Maputo (1–5 year olds)[25]; Rwanda, November to December 2003, at the Rukara Health Centre (1–60 years old)[26]. Only samples identified by thick and thin smear microscopy as P. falciparum single species infections were available for analysis. Blood samples were spotted onto Whatman® n°4 (n°3 in the case of Rwanda) filter paper and parasite genomic DNA was obtained by boiling in Chelex-100 [27] and subsequent ethanol precipitation.

Samples from Gabon

206 samples were collected specifically for this study. Samples were collected in and around Lambarene, Departement du Moyen Ogooué at five different locations (Hôpital Albert Schweitzer, Hôpital General de Lambaréné, Dispensaire d'Isaac, Adouma and PK48, a village 48 kilometres from Lambaréné). 100–200 μl of venous blood was applied to Whatman® FTA® Classic Filter paper cards (Whatman®, USA) and left to air dry. Whatman® FTA® filter cards deactivate viral DNA/RNA and preserve human and parasite DNA for downstream analyses. DNA extractions were carried out according to the manufacturer's instructions. Briefly, a disc of 1.2 mm in diameter was punched from the centre of each dried blood spotted card and washed three times with Whatman® FTA® Purification Reagent, and twice with TE buffer. This treated disc was then used directly in subsequent PCR analyses. Ethical clearance for sampling in Gabon was obtained from the ethical committee of the International Foundation of the Albert-Schweitzer Hospital and Edinburgh University. Prior to sampling each patient was informed about the study, consent was obtained (in the case of children parents/guardians gave informed consent) and medical follow-up was provided if needed.

Samples from the Republic of Congo

359 samples were collected by passive case detection from two health centres (Madibou and Tenrikyo) within Brazzaville, the capital of the Republic of Congo, in 2005. No age restrictions were applied to sampled individuals. These samples were collected on Whatman® FTA® filter paper, and processed as previously described. A further 492 samples were collected in 2006 by PCD from three separate locations within the Republic of Congo, 150 from Pointe-Noire, on the west coast of the country, a further 201 from the Tenrikyo health centre in Brazzaville, and 141 from Gamboma, a town in the east. These samples were collected on Whatman® 31ETCHR filter paper, and DNA extraction was performed using the EZ1 BioRobot™ (QIAGEN, Hilden, Germany) according to the manufacturer's instructions. Ethical approval for this collection was obtained from the ethical committee at Osaka University, and sampling was authorized by the administrative authority of the Ministry for Research and Ministry for Health in the Republic of Congo. Informed consent was obtained from individual patients, and antimalarial treatment was provided when appropriate.

Samples from Kenya

722 samples were collected in 1998 by active case detection in the Kisii district of Kenya. All age groups were sampled. Blood was collected by finger-prick on Whatman® 31ETCHR filter paper, and DNA extracted by boiling in Chelex-100 [27] and subsequent ethanol precipitation. Ethical clearance for this collection was obtained from the Ministries of Health and Education in Kenya.

Samples from Ghana

352 samples were collected by ACD from 0–15 year old children in four villages near Winneba, a western coastal region of the country. Finger-prick blood was collected on Whatman® 31ETCHR filter paper, and DNA extraction was performed using the EZ1 BioRobot™. This study was approved by the Ministry of Health/Ghana Health Service.

Species typing PCR

DNA extracted from all samples was subjected to Plasmodium species typing PCR based on the nested PCR technique developed by Snounou et al [28] with some modifications. Oligonucleotide primers were identical to those previously described [28] but the PCR conditions were modified as follows: For the first round of PCR, 1 μl of extracted DNA was added to 14.85 μl of dH20, 1.75 μl of each primer (rPLU5 and rPLU6 at 5 uM), 2.5 μl of AmpliTaq Gold® 10× PCR Buffer II, 2 μl of 25 mM MgCl2 solution, 1 μl of dNTP mixture (2.5 mM each) and 0.15 μl of AmpliTaq Gold® in a 25 μl reaction. The following cycling conditions were applied using a GeneAmp® PCR 9700 thermocycler (Applied Biosystems, USA): 95°C for 10 min, 30 cycles of 57°C for 1 min, 72°C for 1 min, 94°C for 1 min and a final extension step of 72°C for 4 min. 1 μl of the resulting PCR product was used for the second round of PCR, with an identical reaction mix to that described for the first round (using pairs of species specific primers FAL-1 and FAL-2, VIV-1 and VIV-2, MAL-1 and MAL-2, and OVA-1 and OVA-2), and with the following cycle conditions: 95°C for 10 min, 32 cycles of 94°C for 1 min, 65°C for 1 min, and a final extension step of 65°C for 5 min. The resulting PCR products were visualized on 2% agarose gels, with the presence or absence of a band with each species primer pair indicative of the presence or absence of that species in the initial sample.

Sensitivity of species diagnosis PCR

Prior to commencement of PCR analysis of field samples, a pilot experiment was carried out to assess the sensitivity of the PCR conditions detailed above. This protocol consistently detected the presence of P. vivax in a dilution of genomic DNA that theoretically contained one copy of the parasite genome per μl (data not shown). Due to variation in DNA extraction technique between sample collections, a consistent volume of blood corresponding to the 1 μl of extracted genomic DNA used in the PCR cannot be given. However, it is estimated that no less than 0.5 μl of initial blood sample was used in each reaction. Therefore, the PCR detection method used in this investigation should detect P. vivax parasites in infections of as low as two parasites per μl of blood. Furthermore, microscopic evaluation of parasite presence was available for all samples, and these correlated well with PCR results. Although the very rare occurrence of a microscopically positive sample being found to be PCR negative did occur, the vast majority of discrepancies between microscopy and PCR diagnosis involved species misdiagnosis by microscopy, and the detection of parasite infections by PCR in microscopically negative samples, as is expected due to the greater sensitivity of the PCR technique.

Duffy status profiling

An FY* allele-specific PCR [29] was used to determine the Duffy status of the individual from Sao Tome infected with P. vivax. Product amplification took place in a 50 μl volume reaction containing 5 μl of 10× PCR buffer, 4 μl of 25 mM MgCl2, 0.1 mM of each dNTP, 2 μl of the two 5 μM allele specific primers, 1 μl of the 5 μM control primers and 6 units of AmpliTaq Gold® DNA polymerase (Applied Biosystems, USA). Amplification conditions were as follows; denaturation and activation of the AmpliTaqGold DNA polymerase at 96°C for 8 min, then 10 cycles of 94° for 20 s and 69°C for 1 min, leading to 25 cycles of 94°C for 20 s, 64°C for 30 s and 72°C for 1 min, followed by 5 cycles of 94°C for 20 s, 62°C for 30 s and 72°C for 1 min. Amplification of a 411 bp fragment of the ABO gene acted as the internal control for each reaction.

Results and discussion

Prevalence of P. vivax in sub-Saharan Africa

1,711 samples were positive for P. falciparum (1,526 single species infections, 51 with P. ovale, 129 with P. malariae, one with P. vivax and four with both P. malariae and P. ovale), 67 for P. ovale (12 single infections, 51 mixed with P. falciparum, and four triple infections with P. falciparum and P. malariae) 147 for P. malariae (14 single infections, 129 mixed with P. falciparum, and four triple infections with P. ovale and P. falciparum) and one for P. vivax (mixed infection with P. falciparum) (Table 2). The only P. vivax infected sample came from a Duffy positive individual from Sao Tome, an island off the west coast of Africa. No P. vivax from any other location within the continent was detected, confirming the scarcity of this parasite in Africa. When excluding samples from Rwanda, Mozambique, Angola and Sao Tome (self-selected as patients identified by microscopy with a mixed infection were excluded), P. malariae infections represented 8.5% of all malaria infections, and P. ovale 3.9%. The prevalence of both parasites varies greatly by country.

Table 2. Species composition of isolates analysed by PCR (%)

Scarcity of P. vivax

The prevalence of P. vivax in Africa is very low; no evidence for its presence in over 2,500 samples from nine African countries was found, with the exception of the island of Sao Tome, from which the parasite had previously been reported [10]. These results, combined with the sporadic reports of the transmission of P. vivax in indigenous populations [10,13,19] and the continued identification of imported cases originating in west and central Africa [15,17] indicate that a very low prevalence of P. vivax is sufficient to maintain transmission. It is conceivable that in areas with very high entomological inoculation rates (EIR), such as in many areas of west and central Africa [30], even very low numbers of Duffy positive individuals may allow the continued transmission of P. vivax.

That low numbers of Duffy positive individuals in west and central Africa are sufficient to maintain transmission on P. vivax, is not surprising considering the very high basic reproduction number of malaria in this region. The basic reproductive number of a pathogen, R0, is defined as the number of new infections arising from an infected individual introduced into a naïve population. When R0 > 1, transmission is maintained in a population, but when R0 < 1, transmission is interrupted and the pathogen cannot persist. A recent report showed that R0 for P. falciparum malaria transmission in Africa ranges from below one to nearly 11,000 with a median value of 86, depending on geographical location [30]. Given that both P. falciparum and P. vivax are vectored by the same mosquito species, the only factor that that differentiates R0 for both species in a given population is the human host's susceptibility to infection. In order for transmission to be blocked, the proportion of completely immune individuals (p) required in a population is given by the formula p > 1 - 1/R0. Thus, in areas where Duffy negativity is present in a population at a prevalence of up to 99%, as it is in many parts of west and Central Africa [8], then P. vivax transmission can be expected to occur when R0 (for P. falciparum) > 100, an entirely realistic value for many areas. It is entirely conceivable therefore, that P. vivax transmission occurs in populations in which there are a very high proportion Duffy negative individuals, given the very high P. falciparum R0 values associated with west and central Africa.

A number of researchers have recently suggested that P. vivax may be in the process of evolving mechanisms [21] that enable it to infect Duffy positive individuals. Given the extremely high EIRs and transmission dynamics of malaria parasites in sub-Saharan Africa, this scenario would appear highly unlikely given the extremely low incidences of the parasite reported here. Any P. vivax parasite that acquired the ability to infect Duffy negative individuals may be expected to rapidly spread throughout sub-Saharan Africa, and would be readily detectable in the population.

Discrepancy between P. vivax rates in travellers and localpopulations

Surveillance of malaria cases imported into the USA between 2001 and 2005 [31-35], reveals that 32 cases of P. vivax originated in four west and central African countries for which we also have species prevalence data from the local populations. In the same time period, there were 545 cases of imported P. falciparum from the same countries. This gives a ratio of 100:6 P. falciparum to P. vivax infections in these areas, a surprisingly high rate, especially considering that P. malariae and P. ovale are represented at ratios of 100:6 and 100:5 respectively (comparable with those of the local populations, see Table 3). How does one account, then, for the discrepancy between the imported P. vivax data, and the extremely low prevalence in the native population reported here?

Table 3. Parasite species prevalence of traveler's malaria imported into the USA (2001-2005) from Burkina Faso, Gabon, Republic of Congo / Democratic Republic of Congo and Ghana compared to that of the local populations.

It is possible that the geographical distribution of P. vivax within Africa is patchy, with sporadic areas of transmission scattered throughout the continent, possibly associated with human populations in which the Duffy negative phenotype is present at a lower frequency than elsewhere (such as on the island of Sao Tome). Travellers may preferentially visit areas of west and central Africa where there is a relatively high frequency of Duffy positive individuals in the local population (e.g. migrant workers and non-African expatriates) and where P. vivax is more likely to be transmitted.

Another factor that may contribute to this discrepancy is the higher transmissibility of P. vivax relative to other malaria parasites, and in particular relative to P. falciparum, under adverse conditions [9]. This has the consequence that there should be higher proportion of P. vivax relative to P. falciparum in the vector mosquitoes than there is in the corresponding human population. Consequently travellers, who are a probe of the infection rates in the local mosquitoes, can be expected to, and indeed do have (Carter and Mendis, unpublished analysis), higher proportions of P. vivax than are found in the endemic human populations amongst whom the travellers have briefly resided. This may explain the recent findings of Ryan et al [19], who report the presence of P. vivax in 0.65% of mosquitoes from an area of western Kenya with a high proportion of Duffy negativity in the local population. However, even an extremely small percentage of Duffy positive individuals in this population may be expected to support such a rate in mosquitoes.

The use of prophylactic anti-malaria drugs among travellers may also contribute to this phenomenon. Mefloquine is the recommended prophylactic drug for travellers to west and central Africa from the USA [31], and whilst effective against the blood stages of all malaria parasites, it does not affect the dormant hypnozoite stages of P. vivax, and will therefore not protect against relapses after cessation of drug use. This is also true of P. ovale, which is also capable of producing hypnozoites, and may explain the slightly higher rate of this parasite in returning travellers compared to the local populations (Table 3).

It is also probable that a small proportion of imported cases may be P. ovale infections rather than P. vivax, as is often difficult to distinguish the two species by microscopy [15]. As previously mentioned, there are an increasing number of reports detailing imported African P. vivax diagnosed by accurate molecular typing techniques [16,18].

In conclusion, the present study indicates that the prevalence of P. vivax in local populations in sub-Saharan Africa is very low, despite the frequent identification of this parasite in travellers. P. vivax malaria, therefore, does not constitute a health risk to the indigenous populations of west and central Africa, though Duffy positive individuals, including non-African travellers to the area, may be at risk.

Competing interests

The authors declare that they have no competing interests.

Authors' contributions

RCu, RCa and KT conceived the study and participated in its design and coordination. RCu wrote the manuscript. MN, FN, HU, RCa, UdA, AK and KT helped to draft the manuscript. RCu, HU, TM, HE and NT performed molecular parasite typing. MN coordinated and carried out sample collection in the Republic of Congo, HU and FN in Gabon, GP in Burkina Faso, HT, CK and UdA in Rwanda, PC and VdR in Sao Tome, Angola, and Mozambique, and TM, AK and TK in Ghana and Kenya. All authors read and approved the final manuscript.

Acknowledgements

This study was supported by Grant-in-Aid for Scientific Research on Priority Areas from The Japanese Ministry of Education, Culture, Sports, Science and Technology (18073013) and Grant-in-Aid for Scientific Research from the Japan Society for the Promotion of Science (17–05495, 18390131, 18GS03140013). We are grateful for a travel award to HU from the John Scaife Fund, Edinburgh. We thank Dr. Rikard Dryselius for helpful discussion, and Dr. Naoko Sakihama for technical assistance.

References

  1. Carter R, Mendis KN: Evolutionary and historical aspects of the burden of malaria.

    Clin Microbiol Rev 2002, 15:564-594. PubMed Abstract | Publisher Full Text | PubMed Central Full Text OpenURL

  2. Guerra CA, Snow RW, Hay SI: Mapping the global extent of malaria in 2005.

    Trends Parasitol 2006, 22:353-358. PubMed Abstract | Publisher Full Text OpenURL

  3. Miller LH, Mason SJ, Clyde DF, McGinniss MH: The resistance factor to Plasmodium vivax in blacks. The Duffy-blood-group genotype, FyFy.

    N Engl J Med 1976, 295:302-304. PubMed Abstract OpenURL

  4. Horuk R, Martin AW, Wang Z, Schweitzer L, Gerassimides A, Guo H, Lu Z, Hesselgesser J, Perez HD, Kim J, Parker J, Hadley TJ, Peiper SC: Expression of chemokine receptors by subsets of neurons in the central nervous system.

    J Immunol 1997, 158:2882-2890. PubMed Abstract | Publisher Full Text OpenURL

  5. Hadley TJ, Lu ZH, Wasniowska K, Martin AW, Peiper SC, Hesselgesser J, Horuk R: Postcapillary venule endothelial cells in kidney express a multispecific chemokine receptor that is structurally and functionally identical to the erythroid isoform, which is the Duffy blood group antigen.

    J Clin Invest 1994, 94:985-991. PubMed Abstract | Publisher Full Text | PubMed Central Full Text OpenURL

  6. Miller LH, Mason SJ, Dvorak JA, McGinniss MH, Rothman IK: Erythrocyte receptors for (Plasmodium knowlesi) malaria: Duffy blood group determinants.

    Science 1975, 189:561-563. PubMed Abstract | Publisher Full Text OpenURL

  7. Tournamille C, Colin Y, Cartron JP, Le Van Kim C: Disruption of a GATA motif in the Duffy gene promoter abolishes erythroid gene expression in Duffy-negative individuals.

    Nat Genet 1995, 10:224-228. PubMed Abstract | Publisher Full Text OpenURL

  8. Cavalli-Sforza LL: Africa. In The History and Geography of Human Genes. Princeton University Press; 1994:158-194. OpenURL

  9. Mendis K, Sina BJ, Marchesini P, Carter R: The neglected burden of Plasmodium vivax malaria.

    Am J Trop Med Hyg 2001, 64:97-106. PubMed Abstract | Publisher Full Text OpenURL

  10. Snounou G, Pinheiro L, Antunes AM, Ferreira C, do Rosario VE: Non-immune patients in the Democratic Republic of Sao Tome e Principe reveal a high level of transmission of P. ovale and P. vivax despite low frequency in immune patients.

    Acta Trop 1998, 70:197-203. PubMed Abstract | Publisher Full Text OpenURL

  11. Marques PX, Saute F, Pinto VV, Cardoso S, Pinto J, Alonso PL, Rosario VE, Arez AP: Plasmodium species mixed infections in two areas of Manhica District, Mozambique.

    Int J Biol Sci 2005, 1:96-102. PubMed Abstract | Publisher Full Text | PubMed Central Full Text OpenURL

  12. Garnham PCC: Plasmodium vivax and Plasmodium schwetzi. In Malaria Parasites and other Haemosporidia. Blackwell; 1966:116-158. OpenURL

  13. Rubio JM, Benito A, Roche J, Berzosa PJ, Garcia ML, Mico M, Edu M, Alvar J: Semi-nested, multiplex polymerase chain reaction for detection of human malaria parasites and evidence of Plasmodium vivax infection in Equatorial Guinea.

    Am J Trop Med Hyg 1999, 60:183-187. PubMed Abstract | Publisher Full Text OpenURL

  14. Van Ros G: [Data collected from African concerning factors influencing the susceptibility of erythrocytes to Plasmodium falciparum and Plasmodium vivax].

    Ann Soc Belg Med Trop 1985, 65(Suppl 2):45-51. PubMed Abstract OpenURL

  15. Muhlberger N, Jelinek T, Gascon J, Probst M, Zoller T, Schunk M, Beran J, Gjorup I, Behrens RH, Clerinx J, Björkman A, McWhinney P, Matteelli A, Lopez-Velez R, Bisoffi Z, Hellgren U, Puente S, Schmid ML, Myrvang B, Holthoff-Stich ML, Laferl H, Hatz C, Kollaritsch H, Kapaun A, Knobloch J, Iversen J, Kotlowski A, Malvy DJ, Kern P, Fry G, Siikamaki H, Schulze MH, Soula G, Paul M, Gómez i Prat J, Lehmann V, Bouchaud O, da Cunha S, Atouguia J, Boecken G: Epidemiology and clinical features of vivax malaria imported to Europe: sentinel surveillance data from TropNetEurop.

    Malar J 2004, 3:5. PubMed Abstract | BioMed Central Full Text | PubMed Central Full Text OpenURL

  16. Gautret P, Legros F, Koulmann P, Rodier MH, Jacquemin JL: Imported Plasmodium vivax malaria in France: geographical origin and report of an atypical case acquired in Central or Western Africa.

    Acta Trop 2001, 78:177-181. PubMed Abstract | Publisher Full Text OpenURL

  17. Skarbinski J: Malaria Surveillance, United States, 2004.

    2006, 55(SS04):23-27.

  18. Blossom DB, King CH, Armitage KB: Occult Plasmodium vivax infection diagnosed by a polymerase chain reaction-based detection system: a case report.

    Am J Trop Med Hyg 2005, 73:188-190. PubMed Abstract | Publisher Full Text OpenURL

  19. Ryan JR, Stoute JA, Amon J, Dunton RF, Mtalib R, Koros J, Owour B, Luckhart S, Wirtz RA, Barnwell JW, Rosenberg R: Evidence for transmission of Plasmodium vivax among a duffy antigen negative population in Western Kenya.

    Am J Trop Med Hyg 2006, 75:575-581. PubMed Abstract | Publisher Full Text OpenURL

  20. Cavasini CE, Mattos LC, Couto AA, Bonini-Domingos CR, Valencia SH, Neiras WC, Alves RT, Rossit AR, Castilho L, Machado RL: Plasmodium vivax infection among Duffy antigen-negative individuals from the Brazilian Amazon region: an exception?

    Trans R Soc Trop Med Hyg 2007, 101:2-1044. Publisher Full Text OpenURL

  21. Rosenberg R: Plasmodium vivax in Africa: hidden in plain sight?

    Trends Parasitol 2007, 23:193-196. PubMed Abstract | Publisher Full Text OpenURL

  22. Paganotti GM, Palladino C, Modiano D, Sirima BS, Raberg L, Diarra A, Konate A, Coluzzi M, Walliker D, Babiker HA: Genetic complexity and gametocyte production of Plasmodium falciparum in Fulani and Mossi communities in Burkina Faso.

    Parasitology 2006, 132:607-614. PubMed Abstract | Publisher Full Text OpenURL

  23. Ferreira ID, Rosario VE, Cravo PV: Real-time quantitative PCR with SYBR Green I detection for estimating copy numbers of nine drug resistance candidate genes in Plasmodium falciparum.

    Malar J 2006, 5:1. PubMed Abstract | BioMed Central Full Text | PubMed Central Full Text OpenURL

  24. Pimentel S, Nogueira F, Benchimol C, Quinhentos V, Bom J, Varandas L, do Rosario V, Bernardino L: Detection of atovaquone-proguanil resistance conferring mutations in Plasmodium falciparum cytochrome b gene in Luanda, Angola.

    Malar J 2006, 5:30. PubMed Abstract | BioMed Central Full Text | PubMed Central Full Text OpenURL

  25. Fernandes N, Figueiredo P, do Rosario VE, Cravo P: Analysis of sulphadoxine/pyrimethamine resistance-conferring mutations of Plasmodium falciparum from Mozambique reveals the absence of the dihydrofolate reductase 164L mutant.

    Malar J 2007, 6:35. PubMed Abstract | BioMed Central Full Text | PubMed Central Full Text OpenURL

  26. Tinto H, Rwagacondo C, Karema C, Mupfasoni D, Vandoren W, Rusanganwa E, Erhart A, Van Overmeir C, Van Marck E, D'Alessandro U: In-vitro susceptibility of Plasmodium falciparum to monodesethylamodiaquine, dihydroartemisinin and quinine in an area of high chloroquine resistance in Rwanda.

    Trans R Soc Trop Med Hyg 2006, 100:509-514. PubMed Abstract | Publisher Full Text OpenURL

  27. Polski JM, Kimzey S, Percival RW, Grosso LE: Rapid and effective processing of blood specimens for diagnostic PCR using filter paper and Chelex-100.

    Mol Pathol 1998, 51:215-217. PubMed Abstract | Publisher Full Text | PubMed Central Full Text OpenURL

  28. Snounou G, Viriyakosol S, Zhu XP, Jarra W, Pinheiro L, do Rosario VE, Thaithong S, Brown KN: High sensitivity of detection of human malaria parasites by the use of nested polymerase chain reaction.

    Mol Biochem Parasitol 1993, 61:315-320. PubMed Abstract | Publisher Full Text OpenURL

  29. Olsson ML, Hansson C, Avent ND, Akesson IE, Green CA, Daniels GL: A clinically applicable method for determining the three major alleles at the Duffy (FY) blood group locus using polymerase chain reaction with allele-specific primers.

    Transfusion 1998, 38:168-173. PubMed Abstract | Publisher Full Text OpenURL

  30. Smith DL, McKenzie FE, Snow RW, Hay SI: Revisiting the basic reproductive number for malaria and its implications for malaria control.

    PLoS Biol 2007, 5:e42. PubMed Abstract | Publisher Full Text | PubMed Central Full Text OpenURL

  31. Thwing J, Skarbinski J, Newman RD, Barber AM, Mali S, Roberts JM, Slutsker L, Arguin PM: Malaria surveillance – United States, 2005.

    MMWR Surveill Summ 2007, 56:23-40. PubMed Abstract | Publisher Full Text OpenURL

  32. Filler S, Causer LM, Newman RD, Barber AM, Roberts JM, MacArthur J, Parise ME, Steketee RW: Malaria surveillance–United States, 2001.

    MMWR Surveill Summ 2003, 52:1-14. PubMed Abstract OpenURL

  33. Shah S, Filler S, Causer LM, Rowe AK, Bloland PB, Barber AM, Roberts JM, Desai MR, Parise ME, Steketee RW: Malaria surveillance–United States, 2002.

    MMWR Surveill Summ 2004, 53:21-34. PubMed Abstract | Publisher Full Text OpenURL

  34. Eliades MJ, Shah S, Nguyen-Dinh P, Newman RD, Barber AM, Nguyen-Dinh P, Roberts JM, Mali S, Parise ME, Barber AM, Steketee R: Malaria surveillance–United States, 2003.

    MMWR Surveill Summ 2005, 54:25-40. PubMed Abstract | Publisher Full Text OpenURL

  35. Skarbinski J, James EM, Causer LM, Barber AM, Mali S, Nguyen-Dinh P, Roberts JM, Parise ME, Slutsker L, Newman RD: Malaria surveillance–United States, 2004.

    MMWR Surveill Summ 2006, 55:23-37. PubMed Abstract | Publisher Full Text OpenURL