Diagnosis of an imported Plasmodium ovale wallikeri infection in Malaysia
© Liew at al. 2016
Received: 15 October 2015
Accepted: 23 December 2015
Published: 6 January 2016
Plasmodium ovale is rare and not exactly known to be autochthonous in Malaysia. There are two distinct forms of the parasite, namely P. ovale curtisi (classic form) and P. ovale wallikeri (variant form). Here, the first sequence confirmed case of an imported P. ovale wallikeri infection in Malaysia is presented. Microscopy found Plasmodium parasites with morphology similar to P. ovale or Plasmodium vivax in the blood films. Further confirmation using polymerase chain reaction (PCR) targeting the small-subunit rRNA gene of the parasite was unsuccessful. Genus-specific PCR was then performed and the product was sequenced and analysed. Sequence analyses confirmed the aetiological agent as P. ovale wallikeri. New species-specific primers (rOVA1v and rOVA2v) were employed and P. ovale wallikeri was finally confirmed. The findings highlight the need to look out for imported malaria infections in Malaysia and the importance of a constantly updated and validated diagnostic technique.
Malaria is caused by the blood parasite Plasmodium. Plasmodium falciparum, Plasmodium vivax, Plasmodium ovale curtisi, P. ovale wallikeri, Plasmodium knowlesi and Plasmodium malariae are known to infect humans. Current molecular-based diagnostic methods enable sensitive and specific detection of the five human malaria parasites, even in subclinical cases. Improved diagnostic techniques using polymerase chain reaction (PCR) detected a spike in prevalence of overall malaria infections. The relatively insensitive microscopic diagnosis has underestimated the prevalence of this disease, including P. ovale infection, which was once believed to be comparatively rare. Review of a series of studies led to a probable conclusion that a 2 to >10 % prevalence of P. ovale might actually exist in the general population of Africa and Papua New Guinea and among malaria patients in Southeast Asia .
Plasmodium ovale infection, a tertian malaria, is difficult to diagnose microscopically, owing to the generally low parasite density in patients and the parasite’s morphology which resembles that of P. vivax. Additionally, it is a relapsing infection, which can occur long after the primary exposure to the parasite, initiated by latent parasites (hypnozoites) residing in the liver . Moreover, dimorphism exists in the small-subunit rRNA (ssrRNA) gene of the parasite, causing some isolates to be undetectable by PCR but microscopically confirmed as P. ovale . Further gene studies demonstrated two distinct, non-recombining sympatric species of the parasite . Subsequently in 2010, Sutherland et al.  first coined P. ovale curtisi and P. ovale wallikeri as names for the classic and variant forms of P.ovale, respectively.
Hitherto, cases of P. ovale wallikeri infection have been described in certain countries in Southern Asia (e.g. Bangladesh and India) and almost throughout the whole of Southeast Asia [4–14]. In Malaysia currently, the most prevalent malaria parasite is P. knowlesi , with majority of the cases originating from Malaysian Borneo. Seven known cases of P. ovale were reported so far in Malaysia [15–18]. Here, the first sequence confirmed case of an imported P. ovale wallikeri infection in a patient in Malaysia is reported. Microscopy, nested PCR and sequence analyses of the ssrRNA gene confirmed the aetiological agent as P. ovale wallikeri.
A 19-year-old, Nigerian college student presented to Sunway Medical Centre, Selangor, Malaysia with a 4-day history of fever associated with chills, rigors and body ache. Prior to onset of symptoms, he had gone back to Nigeria for 10 days during semester break and became unwell 5 days after returning to Malaysia. He was febrile upon admission with body temperature of 39.8 °C, pulse rate of 126 beats per minute and blood pressure of 128/87 mm Hg. There were no other significant physical findings noted. He recalled to have had three episodes of malaria during childhood, but was uncertain about the causative Plasmodium species. Blood investigation showed thrombocytopaenia with a platelet count of 71,000 per microlitre (normal: 150,000–400,000 per microlitre) and raised C-reactive protein (97 mg/L; normal: <5 mg/L). White blood cell count, haemoglobin and albumin levels were within the normal range. Dengue NS-1Ag, dengue IgM and IgG, Leptospira IgM, Mycoplasma antibody test and Widal-Weil-Felix test were all negative. Blood cultures did not yield any result.
Description of PCR protocols used in this report
Annealing temperature (°C)
Product size (bp)
P. ovale curtisi
P. ovale wallikeri
P. ovale curtisi and P. ovale wallikeri
Mixed P. ovale c
rOVA1/rOVA2 and rOVA1v/rOVA2v
P. ovale curtisi and P. ovale wallikeri
NM- and NG-PCR
New PLFshort with
The patient was immediately treated with a course of Riamet® (artemether/lumefantrine) following detection of malaria parasites. His symptoms improved within 24 h of treatment but blood film for malaria became negative only after 36 h of treatment. However his platelet count seems to be slow to recover while C-reactive protein, which is known as a marker for severity in malaria , improved steadily following treatment. Primaquine 30 mg base daily was added 2 days after Riamet. He requested for discharge and agreed to complete the two-week course of primaquine at home. He continued to improve clinically post-discharge but could not afford to repeat his blood tests and dropped out from subsequent out-patient follow up visit.
The study was approved by the University of Malaya Medical Centre Medical Ethics Committee (MEC Ref. No: 817.18).
In Malaysia, two of the seven ovale malaria were reported to be caused by P. ovale curtisi . No known ovale infection in the country was sequence-confirmed to be caused by P. ovale wallikeri, up till now. Diagnosis of ovale malaria is a challenge, due to the parasite’s low density and close morphological resemblance to P. vivax. Both the classic and variant forms of P. ovale are also morphologically indistinguishable from each other . Rapid diagnostic tests (RDT) have aided in the rapid diagnosis of malaria and other infectious diseases. Nonetheless, their apparent ineffectiveness in detecting P. ovale turns out to be well documented [28, 29]. In this case, the result of the RDT, BinaxNOW® Malaria Test was negative twice before a faint line indicating Plasmodium species infection appeared on the third attempt.
Nested PCR for molecular detection of Plasmodium spp.  has emerged as a standard molecular method for malaria diagnosis. However, the primers for P. ovale detection (rOVA1/rOVA2) were unable to identify the variant form of the parasite, until a new set of primers (rOVA1v/rOVA2v) specific for P. ovale wallikeri and a set of primers (rOVA1WC/rOVA2WC) to detect both forms were introduced [3, 26]. The initial negative PCR result using the species-specific primers and subsequent sequencing analyses were indicative of P. ovale wallikeri infection, prompting the use of these new primers. Besides, primer sets rOVA1/rOVA2 and rOVA1v/rOVA2v were mixed to detect both P. ovale wallikeri and P. ovale curtisi in a single Nest 2 duplex PCR reaction. The mixed primers and primer set rOVA1WC/rOVA2WC in the PCR reaction appeared to be a mean for quick and cost-efficient detection of both species of P. ovale , and therefore should replace primers rOVA1/rOVA2 for routine diagnosis of malaria.
The accurate diagnosis of P. ovale infection, in fact of all malaria infection, is crucial to avoid the delay of treatment and clinical complications. Though ovale malaria is thought to be rather benign, associated severe complications such as acute respiratory distress syndrome (ARDS) [31, 32], splenic complication , acute renal failure and ultimately, death [18, 34] have been reported. There are certain clinical features slightly distinctive of the two different forms of P. ovale. The latency periods of P. ovale curtisi and P. ovale wallikeri infection are reported to be 66.1–111.1 days and 28.9–57 days, respectively, with one case of P. ovale curtisi infection displaying an extraordinarily long latency period of 1083 days . This shorter latency period may lead to higher relapse rate of P. ovale wallikeri infection. A trend toward a shorter stay in Africa and shorter period of time between onset of symptoms and diagnosis was found among patients with P. ovale wallikeri infection, possibly reflecting easier transmission, shorter latency or higher relapse rates . In addition, patients with P. ovale wallikeri infection have significantly more severe thrombocytopaenia and relatively higher parasitaemia than those with P. ovale curtisi infection. Other non-significant, differentiating features include shorter pre-patent period, lower albumin level, higher body temperature and more markers of haemolysis in P. ovale wallikeri infection compared to that of P. ovale curtisi . Taken together, it may seem that management of P. ovale wallikeri could be slightly more complicated than P. ovale curtisi.
Plasmodium ovale is not exactly known to be autochthonous in Malaysia. It is absolutely undesirable for P. ovale to be transmitting within the country, especially when Malaysia is progressing towards elimination of malaria by 2020. Relapsing ovale infection is often asymptomatic, detected only by continued examination of blood films . In other words, human reservoir of P. ovale may stay under the radar. This poses a threat to the public health because natural transmission of ovale malaria in Malaysia is possible in view of the availability of two vectors, Anopheles maculatus  and Anopheles dirus  which have been shown to be good experimental vectors for P. ovale. Nolder et al.  also found that, compared to other human malaria, ovale malaria is less likely to be prevented by chemoprophylaxis. Furthermore, as pointed out by Mellon et al. , with non-specific clinical signs as well as long latency period of P. ovale infection [2, 6, 35], what then should the maximum exclusion period be for blood donors who had travelled to endemic areas? Transfusion-transmitted P. ovale infection had been reported and can be severe .
It was not discernable if the patient was experiencing a relapse or acute malaria. Prepatent period (time between sporozoite inoculation and the first detection of parasites in blood) for ovale malaria is reported to be 12–20 days . Lastly, a similar case was reported by Li et al. , whereby P. ovale wallikeri infection was diagnosed in a Chinese worker returning from West Africa. This and other increasing worldwide reports of P. ovale infections [40–43] and misdiagnosed cases  urge the health and research sectors to devise and utilise accurate techniques to diagnose this infectious disease.
The current findings highlight the need for continuously updating and validating diagnostic techniques for malaria. Complete history taking is of utmost importance in patients as it aids diagnosis, especially in the case of P. ovale infection where it can remain latent and asymptomatic for a long period of time. Imported cases of malaria are a concern for public health, especially in countries where malaria is non-existent or has been eliminated. With Malaysia’s open policy and the ease of travel, healthcare personnel should be made aware of the possible imported infections entering the country.
JWKL performed the molecular biology techniques and drafted the manuscript. RM performed the microscopy. LHT presented the patient’s history and clinical symptoms. YLL conceptualize the manuscript. All authors read and approved the final manuscript.
This work was supported by University of Malaya High Impact Research Grant (UM.C/625/1/HIR/MOHE/CHAN/14/3) from the Ministry of Higher Education, Malaysia. The authors would like to thank the Parasites: South East Asian Diagnostic (PARA:SEAD) Laboratory, Kuala Lumpur, Malaysia for the assistance during diagnosis.
The authors declare that they have no competing interests.
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