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Zoonotic transmission of simian malaria parasites to humans have been occurring in Southeast Asia and South America. Among the 3 simian malaria parasites in Southeast Asia experimentally shown to infect humans (1), Plasmodium knowlesi, P. cynomolgi, and P. inui, only P. knowlesi and P. cynomolgi have been reported in cases of natural infection (2). We report 2 natural, asymptomatic P. inui human infections detected by using nested PCR (nPCR) on concentrated high-volume blood.

The Study

We conducted an epidemiologic and entomological study at a campsite in Kem Sri Gading, Pahang, Malaysia (3°45′46.24″N, 102°34′20.32″E), because of frequent reports of human P. knowlesi infections acquired from this area. Kem Sri Gading is a receptive area, a location in which the ecosystem permits malaria transmission because vector and reservoir host populations both inhabit it.

On March 2, 2020, we obtained <3 mL of venous blood from 71 persons at the camp who provided consent. Participants had undergone training in the forest at Kem Sri Gading during January 27–28, 2020. The Medical Research and Ethics Committee, Ministry of Health Malaysia, approved this study (approval no. NMRR-15-672-23975 for the human study and approval no. NMRR-19-962-47606 for the mosquito study).

The 2 case-patients we report, PMAR0041, a 20-year-old woman, and PMAR0052, a 19-year-old woman, had no previous history of malaria. Before our study, PMAR0041 was in a nonreceptive city in Selangor 1–2 weeks before training at the camp; PMAR0052 regularly entered forested areas >2 times per month. During January 29–March 2, 2020, neither case-patient visited any potentially receptive areas. Both persons reported they were healthy before, during, and after blood collection.

Figure 1

Species-specific nested PCR amplification products for a study of Plasmodium inui infections among humans, Malaysia. Samples were subjected to electrophoresis on a 1.5% agarose gel. A) Results for detection of P. knowlesi, P. falciparum, P. vivax, P. malariae, P. ovale, and P. cynomolgi. Lane 1, human case-patient PMAR0041; lane 2, human case-patient PMAR0052; lane 3, no-template control. B) Results for the detection of P. inui in human case-patient PMAR0041. Lane 1, case-patient PMAR0041; lane 2, negative control; lane 3, no-template control. The solid vertical line indicates these are separate parts of the same image. C) Results for the detection of P. inui in human case-patient PMAR0052. Lane 1, case-patient PMAR0052; lane 2, no-template control.

Figure 1. Species-specific nested PCR amplification products for a study of Plasmodium inuiinfections among humans, Malaysia. Samples were subjected to electrophoresis on a 1.5% agarose gel. A) Results for detection…

Figure 2

Micrographs of the thick blood smears showing Plasmodium trophozoites in 2 human cases of Plamodium inui infection, Malaysia. A) Smear from case-patient PMAR0041, taken by using an Olympus BX51 microscope (Olympus Corporation, https://www.olympus-lifescience.com). B) Smear from case-patient PMAR0041, taken by using Redmi Note 4 (Xiaomi Corporation, https://www.mi.com) smartphone camera. C) Smear from case-patient PMAR0052, taken by using an Olympus BX51 microscope. Arrows indicate P. inui trophozoites in each image. Scale bars indicate 20 µm.

Figure 2. Micrographs of the thick blood smears showing Plasmodium trophozoites in 2 human cases of Plamodium inuiinfection, Malaysia. A) Smear from case-patient PMAR0041, taken by using an…

Using the amount of DNA equivalent to 200 µL of whole blood (3), we detected Plasmodium in the 2 cases in separate nPCR assays (Appendix). We used primers targeting both the asexual and sexual 18S rRNA genes of Plasmodium (4). Sequence analysis of the cloned genus PCR products confirmed P. inui (Table). We performed species-specific nPCR assays to detect 5 known human malaria parasites, including P. knowlesi, and to detect P. cynomolgi and P. inui, by using previously published primers (46). However, the species-specific PCR amplification demonstrated spurious results; we were unable to produce consistent results over repeated tests. Thus, P. inui was detected only in case-patient PMAR0041 (Figure 1) because the protocol produced insufficient DNA, which hampered further analyses. However, we found likely trophozoites in thick blood smears of each case during 2 hours of observation (Figure 2).

On October 9, 2020, we obtained a second blood sample from case-patient PMAR0041; case-patient PMAR0052 did not consent to a second blood collection. Between the first and follow-up blood collections, PMAR0041 did not travel to any receptive areas. We did not detect any Plasmodium DNA in the second blood sample from PMAR0041 after repeated tests.

We collected Anopheles cracens, An. introlatus, and An. barbirostris sensu lato mosquitoes at the camp by using human landing catches and Mosquito Magnet Independence Net (Woodstream Corp., https://www.woodstream.com). An. cracens was the predominant mosquito species collected. Only 1 nonblood fed An. cracens mosquito, caught on August 24, 2020, was Plasmodium-positive in its head and thorax by nPCR (4). We found no oocysts upon dissection of the mosquito gut. We were unable to successfully dissect the salivary glands because the mosquito was dead. We used published primers (7) to amplify the P. inui 18S rRNA gene and confirmed P. inui by sequencing the PCR product (Table). We tested the entomological team by using the same PCR methods described for the case-patients but detected no Plasmodium.

Our analyses showed that the P. inui sequence obtained from case-patient PMAR0041 was identical to the corresponding region on the asexual type 18S rRNA sequence obtained from the An. cracens mosquito (Appendix Figure 2), but the P. inui sequence obtained from case-patient PMAR0052 was of the sexual type 18S rRNA (Table). The human P. inui–positive cases we detected originated from separate DNA extractions and PCR assays on different days by using dedicated benchtops for different procedures. The case-patients had the only P. inui–positive samples, but we identified a few P. knowlesi–positive samples among the 71 persons screened at the camp (Appendix Figure 1). The An. cracens mosquito was the only Plasmodium-positive mosquito we detected. We hypothesize that PMAR0041, PMAR0052, and the Plasmodium-positive mosquito were monoinfected with P. inui because we found no other Plasmodium species in any of them.


In experimentally infected humans, patent P. inui infections appeared >31 days after infectious mosquito bites (8). Similarly, both cases we report show a patent infection ≈30 days after alleged exposure. P. inui undergoes a 72-hour erythrocytic cycle, causing quartan fever (8). Infection by the quartan P. inui could be self-limiting in humans because the parasite was not detected in case-patient PMAR0041 ≈8 months after exposure. Indeed, P. inui infections in monkeys are usually low-grade and chronic and can be self-limiting (9,10). In addition, the P. inui OS strain parasite count in experimentally infected humans was <2,520/µL blood. Symptoms were mild, and parasitemia could be submicroscopic or undetectable for certain periods. Antimalarial intervention was deemed unnecessary in these experimental infections (8).

Natural human P. inui infection seems possible, but because of the very low number of parasites and sharp fluctuations between negative and moderate parasitemia by microscopy (8,10), previous studies that used less sensitive methods, including standard PCR, were not able to detect it (11). We show that nPCR on concentrated, high-volume blood was more sensitive at detecting low-grade infection than standard PCR (12), which highlights the need for ultrasensitive detection tools.

We found 2 forms of Plasmodium 18S rRNA genes: the asexual type, which is expressed during the parasite’s asexual life cycle in the vertebrate host; and the sexual type, which is expressed during its sexual life cycle in the mosquito vector. The Plasmodium-genus PCR primers we used amplify asexual and sexual 18S rRNA, but the P. inui–specific primers only amplify the asexual type, which explains the negative results from the species-specific nPCR despite the positive amplifications in the Plasmodium-genus PCR. Nonetheless, successful PCR amplification is compounded by low levels of parasites and the subsequent chance effect that can lead to occasional spurious results, as we experienced.

P. inui sporozoites have been found naturally occurring in An. cracens mosquitoes (2). Other mosquito species from the Leucosphyrus group can transmit P. inui naturally (2). In addition, laboratory experiments showed P. inui adapted to co-indigenous Anopheles mosquito species (13).

P. inui has a wide geographic range in Asia, including southern India, Southeast Asia, and Taiwan (13). A surveillance study reported that the prevalence of P. inui among wild macaques in Pahang was 66.7% (26/39 macaques sampled); 76.9% of these infections were co-infections with other Plasmodium species (14). Given the high prevalence of P. inui among macaques and natural Anopheles mosquito vectors (2), humans could be exposed to P. inui via vectorborne transmission from infected macaques, particularly at a location where humans, macaque hosts, and mosquito vectors co-exist. Furthermore, studies report that P. inui often occurs in co-infections with P. knowlesi and P. cynomolgi in monkeys and mosquitoes (2), and that humans frequently can be exposed to a mix of nonhuman primate malaria sporozoites (15). Because human P. inui infections can be asymptomatic, P. inui could evolve to efficiently infect humans (2), especially considering patent human infection can be established by just a few parasites (8). Strains from different geographic locations might even exhibit different infection patterns. Investigators should use ultrasensitive methods for epidemiologic and entomological studies of simian malaria transmissions in Malaysia and other countries in malaria elimination efforts.

Dr. Liew is a post-doctoral researcher at Universiti Malaya, Kuala Lumpur, Malaysia. His research interest is in vectorborne diseases especially malaria and dengue. His research work includes the entomological and epidemiological, as well as fundamental aspects of these diseases.


The conclusions, findings, and opinions expressed by authors contributing to this journal do not necessarily reflect the official position of the U.S. Department of Health and Human Services, the Public Health Service, the Centers for Disease Control and Prevention, or the authors’ affiliated institutions. Use of trade names is for identification only and does not imply endorsement by any of the groups named above.

Source : CDC Emerging Infectious Diseases Journal

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