LETTER coplast, and nuclear gene sequences have shown that all avail- able P. falciparum sequences are nested within the radiation of -derived sequences (2), providing compelling Source of the human malaria parasite evidence for a gorilla origin of human P. falciparum. Inclusion Plasmodium falciparum of the new -derived sequence (MO454) does not affect these relationships in any way but, instead, identifies MO454 as a gorilla parasite in a monkey (Fig. 1). Thus, the finding The origin of Plasmodium falciparum, the cause of malignant of this single infected pet monkey has no bearing on the origin malaria in , has been the subject of much debate since of human P. falciparum. closely related parasites were found in (mostly captive) chim- Although infections with Laverania parasites appear to be panzees, bonobos, and (reviewed in 1). However, anal- host-specific in the wild (2), human-derived P. falciparum has yses of nearly 3,000 fecal samples from wild-living African been detected in captive bonobos (4) and (5), and identified P. falciparum-like parasites only in western gorillas an apparently gorilla-derived parasite has now been found in (Gorilla gorilla), thus pointing to this species as the original a captive monkey (3). Thus, certain and human parasites source of human infections (2). Prugnolle et al. (3) have now seem capable of infecting new host species when given the op- reported the amplification of P. falciparum-like sequences portunity. Further surveys of African primates for Plasmodium from the blood of a pet monkey. They propose that this infections are clearly warranted, and it will be important to de- “finding challenges the gorilla origin of the human strains of termine the factors that restrict or permit productive trans- P. falciparum,” but this conclusion is not justified by the missions of Plasmodium among different primate species to data presented. gauge the prospect of future zoonoses. Prugnolle et al. (3) examined blood samples from 338 African a,1 b b monkeys representing 10 different species but were able to am- Paul M. Sharp , Weimin Liu , Gerald H. Learn , Julian C. Raynerc, Martine Peetersd, and Beatrice H. Hahnb P. falciparum plify -like mtDNA sequences only from one spec- a imen from a greater spot-nosed monkey (Cercopithecus Institute of Evolutionary Biology, University of Edinburgh, Edin- burgh EH9 3JT, United Kingdom; bDepartments of Medicine and nictitans). Thus, although the title of their paper states that Microbiology, University of Pennsylvania, Philadelphia, PA 19104; “African monkeys are infected by Plasmodium falciparum non- cWellcome Trust Sanger Institute, Hinxton, Cambridge CB10 1SA, fi ” human primate-speci c strains (3), in fact, only a single United Kingdom; and dInstitut de Recherche pour le Développe- fi P. falciparum-like strain was identi ed in a single monkey from ment and University of Montpellier, 34394 Montpellier, France a single species. Moreover, the newly identified monkey parasite provided no evidence for their main conclusion that human 1. Rayner JC, Liu W, Peeters M, Sharp PM, Hahn BH (2011) A plethora of Plasmodium species in wild apes: A source of human infection? Trends Parasitol 27:222–229. P. falciparum was as likely derived from monkeys as from gorillas 2. Liu W, et al. (2010) Origin of the human malaria parasite Plasmodium falciparum in (3). Prugnolle et al. (3) found only 1 of 29 greater spot-nosed gorillas. Nature 467:420–425. 3. Prugnolle F, et al. (2011) African monkeys are infected by Plasmodium falciparum monkeys to be Plasmodium-positive. In contrast, western gorillas nonhuman primate-specific strains. Proc Natl Acad Sci USA 108:11948–11953. are infected at high prevalence rates with three Plasmodium 4. Krief S, et al. (2010) On the diversity of malaria parasites in African apes and the origin of Plasmodium falciparum from Bonobos. PLoS Pathog 6:e1000765. species of the Laverania subgenus, one of which is nearly iden- 5. Duval L, et al. (2010) African apes as reservoirs of Plasmodium falciparum and the tical to human P. falciparum (2); this species has been shown origin and diversification of the Laverania subgenus. Proc Natl Acad Sci USA 107: 10561–10566. to infect wild gorillas at 11 different field sites up to 750 km apart (2). Thus, it is clear that western gorillas represent a natural

reservoir of this parasite, whereas similar evidence for greater Author contributions: P.M.S., W.L., G.H.L., J.C.R., M.P., and B.H.H. wrote the paper. spot-nosed monkeys (or any other monkey species) is lacking. The authors declare no conflict of interest. Finally, phylogenetic analyses of over 1,100 mitochondrial, api- 1To whom correspondence should be addressed. E-mail: [email protected].

www.pnas.org/cgi/doi/10.1073/pnas.1112134108 PNAS Early Edition | 1of2 Downloaded by guest on September 25, 2021 BBptt238 BBptt238 ABDGptt540 BQptt392 GTptt23 DGptt540 LBptt176 WEpte440 100 DGptt540 BBptt234 CDC1 GTptt722 100 BQptt480 LBptt208 BFpts1170 WEpte440 BFpts1171 BQptt480 DRC_S3 GTptt23 CDC1 BFpts1171 99 WEpte440 BQgor60 DPptt294 LBgor185 DRC_S3 LBgor314 BApts1402 NDgor3203 BFpts1172 93 BApts1409 NDgor3203 BApts1370 NKgor735 BFpts1171 Human (n=74) KApts382 Human (n=3) BFpts1172 Human (n=2) GTgor84 Human (n= 1) NDgor3203 n GTgor10 Human ( =1) GTgor10 Human (n=1) GTgor10 92 Human (n=2) BBgor228 Human (n=1) LBgor177 Human (n=16) BQgor60 n BBgor228 Human ( =1) LBgor314 Human (n=1) NDgor3203 Human (n=1) NKgor736 Human (n=1) Human (n=1) n GTgor118 Human ( =1) 100 99 Human (n=1) GTgor118 Human (n=102) GTgor84 DDgor3656 GTgor10 DSgor86 DDgor3656 GTgor118 DSgor86 MOEB MO454 DDgor3656 DDgor27 MOEB 100 BQgor61 99 MO454 BQgor58 97 GTgor34 GTgor34 GTgor84 1 aa 1 nt

Fig. 1. Evolutionary relationships among P. falciparum-related parasites from apes, humans, and a monkey. Phylogenetic trees of mitochondrial protein (980 aa; Left) and nonoverlapping nucleotide (2,502 bp; Right) sequences are shown. Only the closest relatives of human P. falciparum (black, numbers indicate sequences per haplotype) from gorillas (green) and chimpanzees (Plasmodium reichenowi, brown) are included; the Plasmodium sequence from a pet monkey (MO454) described by Prugnolle et al. (3) is shown in magenta. The trees were inferred using maximum likelihood methods [as in the study by Liu et al. (2)]. Numbers on branches indicate percentage bootstrap values (only values above 70% are shown). [Scale bars: Left, 1 amino acid (aa) substitution per site; Right, 1 nucleotide (nt) substitution per site.]

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