Figures
Abstract
Background
Although malaria cases have substantially decreased in Southeast Brazil, a significant increase in the number of Plasmodium vivax-like autochthonous human cases has been reported in remote areas of the Atlantic Forest in the past few decades in Rio de Janeiro (RJ) state, including an outbreak during 2015–2016. The singular clinical and epidemiological aspects in several human cases, and collectively with molecular and genetic data, revealed that they were due to the non-human primate (NHP) parasite Plasmodium simium; however, the understanding of the autochthonous malarial epidemiology in Southeast Brazil can only be acquired by assessing the circulation of NHP Plasmodium in the foci and determining its hosts.
Methodology
A large sampling effort was carried out in the Atlantic forest of RJ and its bordering states (Minas Gerais, São Paulo, Espírito Santo) for collecting and examining free-living NHPs. Blood and/or viscera were analyzed for Plasmodium infections via molecular and microscopic techniques.
Principal findings
In total, 146 NHPs of six species, from 30 counties in four states, were tested, of which majority were collected from RJ. Howler monkeys (Alouatta clamitans) were the only species found infected. In RJ, 26% of these monkeys tested positive, of which 17% were found to be infected with P. simium. Importantly, specific single nucleotide polymorphisms–the only available genetic markers that differentiate P. simium from P. vivax–were detected in all P. simium infected A. clamitans despite their geographical origin of malarial foci. Interestingly, 71% of P. simium infected NHPs were from the coastal slope of a mountain chain (Serra do Mar), where majority of the human cases were found. Plasmodium brasilianum/malariae was initially detected in 14% and 25% free-living howler monkeys in RJ and in the Espírito Santo (ES) state, respectively. Moreover, the malarial pigment was detected in the spleen fragments of 50% of a subsample comprising dead howler monkeys in both RJ and ES. All NHPs were negative for Plasmodium falciparum.
Author summary
The present work comprises an unprecedented capture effort and large-scale field survey of Plasmodium species in non-human primates (NHPs) in RJ, a state recording three-decade history of autochthonous human cases of benign tertian malaria lacking epidemiological clarification of their origin. This is the first study to describe the infection rates by Plasmodium spp. in free-living NHPs in RJ, thereby matching the spatial distribution of P. simium in NHP with that of the local human cases of benign tertian malaria occurring due to this parasite. This study confirmed howler monkeys as the only reservoir of this zoonotic malarial parasite in RJ and reported that specific single nucleotide polymorphisms were present in all P. simium infected howler monkeys, despite their geographical origin of malarial foci. Moreover, this is the first study to record P. brasilianum/malariae in free-living NHPs from RJ, and to illustrate their widespread distribution in this state. Collectively, these findings help us in evaluating the simian malaria prevalence in the Atlantic Forests and in assessing the zoonotic characteristics of autochthonous human malaria in Rio de Janeiro, thus providing assistance in shaping surveillance and control.
Citation: Abreu FVSd, Santos Ed, Mello ARL, Gomes LR, Alvarenga DAMd, Gomes MQ, et al. (2019) Howler monkeys are the reservoir of malarial parasites causing zoonotic infections in the Atlantic forest of Rio de Janeiro. PLoS Negl Trop Dis 13(12): e0007906. https://doi.org/10.1371/journal.pntd.0007906
Editor: Hans-Peter Fuehrer, Vienna, AUSTRIA
Received: July 29, 2019; Accepted: November 5, 2019; Published: December 9, 2019
Copyright: © 2019 Abreu 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.
Data Availability: All relevant data are within the manuscript and its Supporting Information files.
Funding: RLO was supported by Fundação Carlos Chagas Filho de Amparo à Pesquisa do Estado do Rio de Janeiro (E-26/010.001537/2014 and E-26/203.064/2016, http://www.faperj.br/) and Conselho Nacional de Desenvolvimento Científico e Tecnológico (309577/2013-6 and 312446/2018-7, http://www.cnpq.br/). MFFC was supported by Instituto Oswaldo Cruz (PAEFIOC-008-FIO-15-64, http://www.fiocruz.br/ioc). CTDR was supported by Ministério da Saúde, Secretaria de Vigilância em Saúde (IOC-0117-FIO-17, http://www.saude.gov.br/svs). CFAB was supported by Conselho Nacional de Desenvolvimento Científico e Tecnológico (407873/2018-0, www.cnpq.br). CBB was supported by Fundação de Amparo à Pesquisa de Minas Gerais (APQ-02620-15, http://fapemig.br/pt/). 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.
Introduction
In Brazil, more than 99% of malarial infections are acquired from the Amazon, and few isolated cases are occasionally found and recorded in regions outside the Amazon [1]. Malaria transmission was considered eradicated from South and Southeast regions of Brazil approximately 40 years ago [1]; however, in the last three decades, a significant increase in autochthonous malarial cases by Plasmodium vivax-like parasites in the Atlantic Forest areas in Southeast Brazil, where no index case that could have introduced the parasite from a malaria endemic region, has been reported [1,2]. These cases present similar parasitological, clinical, and epidemiological characteristics, such as low parasitemia, no P. vivax expected relapses, and recent visits to dense rain forest areas, where the bromeliad-inhabiting Anopheles mosquitoes belonging to the subgenus Kertezsia, specially An. cruzii, are found [2–4]. An. cruzii is the main vector of “bromeliad malaria”, which is endemic in South and Southeast Brazil, and is the only known natural vector of simian malaria in the country [5]. This particular epidemiological context revived the hypothesis raised by Deane et al. in the 1960s regarding the existence of human malaria cases of simian origin in Brazil. Specifically, these authors reported a human natural infection attributed to the Neotropical primate parasite P. simium Fonseca [6] in São Paulo (SP), Southeast region [7]. The patient presented a benign tertian malaria after being exposed to the mosquito bites during a tree-canopy entomological survey in a forest densely populated by An. cruzii. The description of vertical movement of An. cruzii between the canopy and ground level in the Atlantic rain forest of Southern Brazil reinforced Deane’s hypothesis that part of the transmission of bromeliad malaria in Southern and Southeastern Brazil would be of zoonotic character, with monkeys being the parasite reservoir [5–8].
Two species of Plasmodium have been described in the Neotropical non-human primates (NHP): P. brasilianum Gonder e Berenberg-Gossler (1908) and P. simium, almost indistinguishable from the human malaria parasites P. malariae and P. vivax, respectively [5,6,9]. Besides subtle morphological variations [2,5], molecular markers such as microsatellites and single nucleotide polymorphisms (SNPs) were the only differences so far described between P. malariae and P. brasilianum, and P. vivax and P. simium [2,10,11]. P. brasilianum is widely distributed compared to P. simium, with its presence from México to Southern Brazil, thereby infecting at least 11 genera of the five families of Neotropical primates (Aotidae, Atelidae, Callitrichidae, Cebidae, and Phiteciidae) [5,12–15]. In contrast, P. simium has been found essentially in species belonging to two genera (Alouatta sp. and Brachyteles sp., family Atelidae) [5], from the Atlantic forest of South and Southeast Brazil.
To completely understand the epidemiology of recent autochthonous malaria in Southeast Brazil, it is necessary to confirm the circulation of NHP Plasmodium sp. in the transmission foci as well as to determine the parasite reservoirs. Studies on the prevalence of P. simium and P. brasilianum infections in NHPs and their potential reservoirs in Southeast Brazilian states were conducted during 1960–1990s. Almost 800 NHPs were sampled and their blood slides were examined by microscopy, which is a less sensitive technique compared to the molecular assays, thus recording a variation in the Plasmodium infection from 10.9% in the states of Espírito Santo to 56.5% in SP [5]. During these surveys, only free-living lion-tamarins (Callitrichidae) were examined within RJ and all were negative to malaria parasites [16]. However, RJ recorded 110 autochthonous human cases of benign tertian malaria between 2005 and 2018, with an outbreak in 2015–2016 of 49 cases [1,2]. Interestingly, all these human infections were acquired at the RJ sites located along Serra do Mar, an extensive mountain chain covered by the best-preserved rain forest mosaic in Southeast Brazil. This biome harbors a rich NHP fauna comprising species of six genera (Alouatta, Brachyteles, Callicebus, Callithrix, Leontophitecus, and Sapajus) [17], with An. cruzii being the most common anopheline mosquito [18]. Consequently, the hypothesis of simian origin in these RJ malarial cases has been raised [5,7]. In response, multidisciplinary malaria studies including clinical, epidemiological, parasitological, and molecular approaches have been conducted in RJ [2,4,19]. More recently, the molecular studies of parasites infecting humans and three howler monkeys clearly demonstrated that they shared the same P. simium parasite [2]; however, to date, scarce number of wild NHPs of few species from only three out of numerous autochthonous malaria foci in RJ and surroundings could be examined [2]. This study presents the largest sampling effort ever carried out in the Atlantic forest of RJ and its borders for capturing and examining free-living NHPs in order to describe the geographical distribution and frequency of simian malaria, as well as to determine the local animal reservoirs and confirm the identity of the parasite infecting humans and NHPs in the autochthonous malaria foci.
Material and methods
Study area
The work was carried out between May 2015 and January 2019, with a total of 120 days of fieldwork at 44 sites in 30 counties of the Atlantic Forest biome, mainly in RJ but also in its bordering areas including the states of Minas Gerais (MG), ES, and SP. In this survey, we included forest fragments from lowlands areas to mountain valleys and escarpments of mountain chains such as Serra do Mar, which divides the state territory into two sides, one facing the ocean (hereinafter called the coastal slope) and other the continent (continental slope) [20,21]. The choice of capture areas considered the local existence of NHPs, recent human malaria cases as well as alerts from the information network built with key institutions to continuously monitor the presence of howler monkeys, as previously described [21].
Capture and sample collection
The expeditions included up to 10-day surveys in the forests, conducted by 2–6 trained people in the target areas to search NHPs. The capture method was selected according to the NHP species, behavior, and size [22]. Briefly, Tomahawk model traps baited with banana were used for Callithrix, Leontopithecus, and Sapajus genera [22,23]. The traps were opened early during daytime and were inspected every hour until 3:30 pm, when they were closed. The captured animals were anesthetized with ketamine (15 mg/kg) + xilazine (0.5 mg/kg). Anesthetic darts containing ketamine (15 mg/kg), midazolam (1 mg/kg), and levomepromazine (1 mg/kg), or alternatively, a combination of tiletamine and zolazepam (4–5 mg/kg) were used for the Alouatta and Brachyteles genera, as well as for one titi monkey (Callicebus) [21,24]. Sick animals reported by the information network during the 2017–2018 yellow fever epizooties [25] were captured with nets [21]. A sample of 3–6 mL of blood was collected from the anesthetized or recently dead animals. Thick and thin blood films were immediately prepared, and the remaining blood was allowed to coagulate. After collections and the complete recovery from anesthesia (2–3 h), they were released to their habitats during the daytime from where they were captured. Liver samples were obtained from dead animals, which recently died due to yellow fever or any other disease. Liver and blood samples were stored at −80°C until DNA extraction. Importantly, only one monkey was injured during the fall post anesthesia, which was then treated and kept in a primate-breeding center (Centro de Primatologia do Rio de Janeiro—CPRJ) [21].
Malaria diagnosis
Giemsa’s solution stained thick and thin blood films were examined under a microscope with a 100× oil-immersion objective by two trained and independent microscopists. DNA was extracted from the blood clots as previously described [26] and from the liver samples [27] using the QIAGEN DNeasy mini kit according to manufacturer’s instructions. Molecular diagnosis was made via conventional PCR. All DNA samples were tested in triplicate for 18S rRNA Plasmodium genus-specific gene [28,29], and then for cysteine proteinase P. vivax and ssrRNA P. malariae and P. falciparum genes, as previously described [29,30]. The sensitivity thresholds of the protocols used were 0.5, 0.019, 1.0, and 1.0 parasite per μL for the Plasmodium genus, P vivax, P. malariae, and P. falciparum assays, respectively [28–30]. Moreover, an internal control (betaglobin primers) was used to assess eventual enzyme inhibitors that could generate false negative results and all the samples generated betaglobin amplicons.
P. vivax-positive samples were subjected to P. simium differential diagnosis based on a mitochondrial SNP, the only genetic marker available to differentiate them [2,10]. The molecular diagnosis was performed via nested-PCR of coxI gene fragment and subsequent enzymatic digestion, using primers and a previously described protocol, which detected 3.12 parasites/μL [10]. All the PCR products were visualized under UV light after electrophoresis on 2% agarose gels.
Histopathological analysis
Spleen fragments of a subsample comprising 16 howler monkeys (12 from RJ and 4 from ES), presumably found dead due to yellow fever, were fixed in Carson’s formalin-Millonig [31] and further processed according to the standard histological techniques for paraffin embedding. Sections (5-μm-thick) from each block were stained with hematoxylin–eosin [32] or Lennert Giemsa [33] and analyzed for malarial pigments under an AxioHome microscope equipped with an HRc Axiocam digital camera (Carl Zeiss, Germany).
Ethical issues
The collection methods, biosafety, and anesthesia protocols adhered to the Brazilian law (11.794 of July 8, 2008) on the use of animals in scientific research, and complied with the rules and regulations of Brazilian Ministry of Health [22], having been previously approved by the institutional Ethics Committee for Animal Experimentation of Instituto Oswaldo Cruz (protocol CEUA/IOC-004/2015, license L-037/2016) and by Brazilian Ministry of the Environment (SISBIO 41837–3 and 54707–4) and Rio de Janeiro’s Environment agency (INEA 012/2016 and 019/2018). The research also adhered to the American Society of Primatologists Principles for the Ethical Treatment of Nonhuman Primates.
Results
In total, we examined 146 animals belonging to six species from 30 counties in four Brazilian states, with majority of animals being from RJ (S1 Table and Fig 1); of these, 130 animals were screened by microscopy and PCR using blood samples, seven by microscopy and PCR from blood samples and histopathology of spleen fragments, and nine by PCR of viscera and histopathology of spleen fragments.
Each circle represents one examined NHP. The figure was prepared using free software QGIS 2.18.
Despite their geographical origin, the only NHP species found to be infected with Plasmodium was the howler monkey Alouatta guariba clamitans (Table 1). The PCR method was more sensitive compared to the microscopic examination of blood films, which eventually failed to detect Plasmodium in two infected howler monkeys, one harboring P. simium and another P. brasilianum/malariae (Table 1). Nevertheless, the results suggest that infected howler monkeys generally exhibit detectable parasitemia during microscopic examination of blood slides, for both Plasmodium species. The parasitemia ranging from 15–300 parasites/μL (median = 40 p/μL). Trophozoites were the most commonly visualized blood forms; however, schizonts and gametocytes were also detected (Fig 2). In addition, by using PCR, we were able to detect both Plasmodium species in four animals from liver, spleen and blood samples, which showed concordant diagnostic results.
Giemsa’s solution-stained thick (A-D) and thin (E-I) blood samples, and histopathological analysis of hematoxylin-eosin-stained spleen fragments of howler monkeys that were naturally infected with Plasmodium in Rio de Janeiro state, Brazil, presenting (J) hypertrophy of red pulp with malarial pigments and white pulp atrophy and (K) details of malarial pigments in the red pulp.
Only 12 NHPs were examined from the bordering states of RJ, being two howler monkeys from MG and four from ES and none of these were infected by P. simium. One of the four examined A. clamitans from ES was PCR positive for P. brasilianum/malariae (25%; Table 1).
Regarding RJ, 11 (26.1%) howler monkeys were infected with malarial parasites during sampling and, among these, seven (16.7%) were infected by P. simium, the causative agent of the autochthonous human malaria in this state (Tables 1 and 2). Importantly, the unique specific P. simium SNPs used to distinguish P. simium from P. vivax were detected in 100% of these tertian malarial parasite infected howler monkeys. Moreover, most of these animals originated from the coastal slope of Serra do Mar, where counties face the ocean and are influenced by its humidity, where several human cases have been recorded in the last decade (Table 2 and Fig 3). Six A. g. clamitans from RJ were infected by the quartan-malarial parasite P. brasilianum/malariae (14.3%), of which two were co-infected with P. simium (Tables 1 and 2). All samples were negative for P. falciparum parasites.
Brown shaded areas represent the counties with registered autochthonous malaria in humans: 1. Macaé, 2. Nova Friburgo, 3. Cachoeira de Macacu, 4. Teresópolis, 5. Sapucaia, 6. Guapimirim, 7. Petrópolis, 8. Magé, 9. Duque de Caxias 10. Miguel Pereira, 11. Angra dos Reis. Number 12 represents Sumidouro, where human cases were not detected. The figure was prepared using free software QGIS 2.18.
Previous malaria infections could be investigated by searching the malarial pigment in a subsample of 16 dead howler monkeys. Accordingly, the malarial pigment (Fig 2) was detected in the spleen fragments of five out of 13 animals with negative PCR at the time of death and, as expected, in three animals with positive PCR (Table 1). Interestingly, this pigment was found in the spleen samples of 50% (eight out of 16) of dead howler monkeys in both RJ (six of 12) and ES (two of four), indicating that malarial parasite is frequent in monkeys from both states.
Howler monkeys were examined from 15 counties in RJ, of which 6 counties presented records of autochthonous human malaria in the last years. Present infections by P. simium were diagnosed in howlers from four (66.6%) of the surveyed counties reporting human cases of benign tertian malaria in the state, and in a neighboring county (Sumidouro) where the human cases were never detected (Fig 3). Interestingly, in Macaé, where the highest number of human cases was recorded, all dead howler monkeys had malarial pigments in their spleen, suggesting that simian malaria is highly enzootic in that county (Table 2).
Discussion
The present study demonstrates an unprecedented capture effort and large-scale field survey of plasmodial species in NHPs in RJ, a state recording a three-decade history of autochthonous human cases of benign tertian malaria [1,2]. To our knowledge, this is the first study to describe the NHP infection rates by Plasmodium, and match the spatial distribution of P. simium in NHP with the local human cases previously recorded; howler monkeys were the only confirmed reservoirs of this zoonotic malaria in the state, and the presence of specific SNPs was demonstrated in all P. simium infected howler monkeys, despite their geographical origin. Although P. brasilianum/malariae has already been found in captive NHPs from RJ [13], this is the first study to demonstrate that this parasite species was located in free-living NHPs, thereby contributing to its widespread distribution and zoonotic potential in the state.
P. simium and P. vivax have similar morphologies [5], immune response [34], and several genetic targets [35,36], for example, PCR based on 18S SSU rRNA, largely used for malaria diagnosis in humans [30], was unable to distinguish these parasites [10,13]. The only genetic markers that can differentiate P. simium from P. vivax are the SNPs (3535 T>C and 3869 A>G) in the 6 Kb region of the mitochondrial genome [2]. Excluding the taxonomic issue and focusing on public health impacts, our results confirm that, to date, the P. simium specific SNP is carried by all parasites isolated from NHPs in the Atlantic Forest, which is in accordance with the study by Alvarenga et al. (2018) [10]. Furthermore, P. simium was detected in howler monkeys captured in five out of 11 counties recently reporting autochthonous human malaria cases in RJ (Fig 2). Despite numerous efforts, we failed in capturing howler monkeys in four malarial foci due to some local hindrances such as the hunting pressure that scared the monkeys, steep terrains, and low A. g. clamitans population densities [21,37]. Nevertheless, the strong geographical overlap of howler monkey and human infections by parasites displaying specific P. simium SNPs in five of six malarial foci, strengthens the importance of howler monkeys as the main reservoir of benign tertian human malaria over the zoonotic transmission areas in Southeast Brazil [4,5,38,39]. Howler monkeys have also been by far the NHPs most commonly parasitized with both P. simium and P. brasilianum in Southern and Southeastern Brazil [5,40]. Besides their susceptibility to Plasmodium infection [5], their acrodendrophilic behavior, huge bodies, and the slower movement through the tree canopies (compared to the smaller monkeys) [41] may make them more prone to mosquito biting vectors. Importantly, the detection of malarial pigment in spleen fragments of eight (50%) of the subsample consisting of 16 howler monkeys from RJ and ES, some of which were Plasmodium-negative by PCR at the time of death, suggest that simian malaria is very frequent in this species. Indeed, in some areas with the highest human cases (e.g., Macaé), four out of six (66.6%) howler monkeys were exposed to Plasmodium sp., when considering those with present and past malarial infections. This finding may also suggest that spontaneous healing from malarial infections may occur in the howler monkeys found in nature, as observed in the P. simium experimental infections in certain Neotropical NHPs [42] and in a human natural infection [7].
The frequency of P. simium infection in free-living howler monkeys in RJ (16.6%) was higher than that previously found in the bordering state of SP (5.8%) [39]; however, it was lower than that found in the entire South and Southeast Brazilian regions (26.3–35%) [5,43]. No previous data are available for comparison in RJ, as this was the first time that howler monkeys were captured in the state in a systematized manner. A. g. clamitans was also the only free-living NHP from RJ in which blood forms by microscopy and plasmodial DNA were detected. Recently, DNA but not blood forms of P. simium was detected in captive Cebus and Sapajus from the Southeast [27]. The parasite could be unable to establish the erythrocytic cycle or erythrocytic infection could be transitory, due to unspecificity during cell invasion or host immune competence. Thus, their role as a reservoir for zoonotic malaria in the region remains unclear [27]. P. brasilianum DNA was detected in captive capuchin, titi, howler, and owl monkeys, as well as in tamarins and marmosets [13,27], most of these being exotic species, that are not found in RJ. All these NHPs were confined in a breeding institution CPRJ located in a well-known simian malarial enzootic transmission area in RJ. Therefore, it was suspected that the local ecological conditions favored the accidental infection of these captive NHPs by parasites carried from infected free-living howler monkeys. Moreover, one free living specimen was infected by P. simium near CPRJ [27]; however, no evidence is available confirming if the parasite DNA found in the blood of these captive animals implies that they really undergo Plasmodium infections or only bear a transient parasitemia. Nevertheless, it is important to continuously monitor their potential role as a zoonotic Plasmodium reservoir, besides howler monkeys.
Although P. brasilianum has been found in several NHP genera [5,44–48] around other Brazilian regions, the previous studies conducted in Brazilian Atlantic forest and Cerrado biomes did not find any capuchin (56 examined) or marmosets (out of 44) infected with Plasmodium [39]. Similarly, more than 270 marmosets and lion-tamarins from the Southeast region were Plasmodium negative [5]. Splenectomized capuchins remained uninfected when injected with P. simium infected blood, whereas splenectomized marmoset endured low parasitemia [42]. Thus, the epidemiological role of other NHPs besides howler monkeys in the zoonotic transmission of malaria in Southeast Brazil, including the RJ state, if any, is presumably negligible.
P. brasilianum/malariae was found in a frequency similar to that of P. simium, six (14.3%) versus seven (16.7%), respectively–in howler monkeys from RJ, and mixed infections were recorded in two (4.6%) animals. P. brasilianum/malariae was the only malarial parasite detected in A. clamitans from ES (Table 1). Besides, the geographical co-occurrence of these parasites seems to be frequent in RJ, as it was revealed in three out of five counties, wherein howler monkeys were detected with the malarial parasites (Fig 2). Interestingly, despite this coincident distribution and similar frequency of P. brasilianum/malariae and P. simium in RJ, autochthonous human cases in this state have been diagnosed microscopically and/or molecularly as benign tertian malaria due to P. vivax for decades [1,5,7,38,49,50]. In particular, P. simium was only identified by molecular tests and DNAmt sequencing as the causative agent in the 2015–2016 malaria outbreak in RJ, wherein the patients were essentially nonresidents of foci [2]. Nevertheless, six human asymptomatic infection by P. malariae were detected by PCR in residents of Guapimirim in RJ, in 2011 [19], and a subsample of reactive local individuals for any plasmodial species revealed antibodies against erythrocytic antigens of P. malariae in 30.9%. The hypothesis of infection of NHP origin due to P. brasilianum was proposed because no index case of introduced or imported human case of P. malariae was identified in Guapimirim, and because the cases had close contact with the Atlantic forest [19]. Similar situations have been reported in neighboring states, covered by the Atlantic forest, such as SP and ES [3,4,11,51–54]. Noteworthy, P. brasilianum is a widespread and common simian malarial parasite in the Amazon [5,14] that is experimentally found to infect humans, either by inoculation of parasitized monkey blood or by the bite of infected mosquitoes [9]. High prevalence of antibodies against sporozoites antigens and erythrocytic forms of P. brasilianum/malariae in people living or frequently working in the Amazon forests (e.g., Indians, miners, settlers) of Brazil, French Guiana, and Venezuela suggested infection of this simian quartan malaria parasite in humans [55–57]. Infections by P. brasilianum/malariae in humans would be, therefore, expected to occur in RJ and other southeast states where P. simium has been described. In particular, the natural vector of both parasites is the same (An. cruzii) [5]. However, it remains unclear why malaria cases due to P. brasilianum/malariae have not been consistently reported in the state. Further, strengthening of malaria surveillance either in residents or visitors of the Atlantic forest to evaluate the zoonotic potential of P. brasilianum/malariae in South and Southeast Brazil is recommended [1].
Noteworthy, most of the P. simium and P. brasilianum/malariae-infected howler monkeys (eight of 11;73%) were from the forest coastal slope of Serra do Mar, where all autochthonous human malaria cases have been acquired [2,19]. At least two main premises may explain this geographical association: from the entomological and climatic view point, the higher relative humidity in the costal slope [58,59] may increase An. cruzii survival rates, supporting the sporogonic cycle of the Plasmodium. Sea moisture also favors the density of epiphyte shade bromeliads, the larval habitat of An. cruzii, and generates higher rainfall indexes [58,59], which in turn increases the amount of water accumulated in the vector larval habitats, positively influencing the mosquito density. Greater longevity and density directly influence the vector capacity of the mosquito to transmit Plasmodium [60,61]. Vector competence is governed by genetics of vector population, and therefore, influences Plasmodium transmission dynamics [61,62]. Indeed, Deane (1992) has emphasized that environmental conditions highly influence the presence and densities of Neotropical NHP hosts, bromeliads, and An. cruzii, and consequently, define the occurrence or absence of simian malaria in nearby sites. Moreover, two genetic lineages of An. cruzii with partial reproductive isolation have been recently described in Serra do Mar, one curiously occurring in the coastal region and another in the continental slopes [63]. Compared to the continental side, coastal slopes of Serra do Mar comprise a higher number of sites where people from major cities choose to reside in country houses in the forest and include ecotourism areas such as waterfalls and natural parks attracting many visitors (personal observation). As elaborated, the autochthonous human cases in the Atlantic forest in RJ have been reported mainly in the nonresidents [1,2,19]. Collectively, the environmental, entomological, ecological, and epidemiological characteristics seem to indicate that the costal slope of Serra do Mar is the riskiest place to acquire malaria of NHP origin. Protective measures such as the use of repellents and long clothes should be encouraged specifically for those who live or practice ecotourism in this slope.
During the present study, a YFV outbreak erupted in the Southeast Brazil, a region without records of this virus presence for almost 80 years [25,64]. Hundreds of epizootics of NHPs were reported, causing a significant impact on the population size of howler monkeys, an extremely susceptible host to YFV [22,65–70]. Considering the role of the howler monkeys as a reservoir of Plasmodium infective to humans, it is plausible to suppose that dynamics of zoonotic transmission of malaria will undergo short or mid-term changes in RJ and bordering states affected by the YFV epizooties. In this context, we postulate that the rapid decrease of Alouatta populations would also reduce the source of plasmodial infection to An. cruzii, which would further hamper the circulation of Plasmodium sp. in the Atlantic forest. Despite the short duration since the 2016–2018 YFV epizootics, records from the Brazilian Ministry of Health surveillance program seem to confirm this scenario. In fact, there was an abrupt drop in the human malaria case records between 2018 and 2019 (only one autochthonous case) [71], which was contradictory with the numbers reported between 2006 and 2014, when 4.7 cases were registered per year, on an average [2]. If the reduction of autochthonous malarial cases in the Atlantic Forest is a consequence of the Alouatta deaths, leading to plasmodial sources reduction, the role of howler monkeys for the occurrence of malaria in the Atlantic Forest would be reinforced.
Previous sampling efforts on examining free-living NHPs in the Southeastern Atlantic Forest over the last 30 years revealed limited geographical coverage, with samplings essentially limited to the wildlife rescues or carried out in areas close to cities, or were based on few individuals [4,38,39]. As a result, our data contribute in understanding the simian malarial parasite distribution and frequency as well as the zoonotic characteristics of autochthonous human malaria in RJ, which in turn provides assistance in shaping surveillance and control. The evidence of the NHP origin of parasites infecting humans and the widespread occurrence of anophelines vectors in the Southeast region increased the concern of the reemergence of endemic or epidemic autochthonous transmission in the region independent of the enzootic cycle [2]. However, it is not clear whether the parasitemic humans infected by the bite of An. cruzii carrying esporozoites of P. simium acquired from howler monkeys could be a source of infection to An. cruzii or any other malarial vector present in the region. It is known that P. simium infected humans usually display scanty to null parasitemia, and can be cured spontaneously in few days without treatment and any relapse; moreover, the molecular detection of parasites during treatment follow-ups has been described [2,5]. Besides, all autochthonous human cases of benign tertian malaria detected for decades in Southeast have reported recent contact with the P. simium enzootic forest, and no secondary transmission directly derived from a human infected in the zoonotic cycle has ever been detected outside the sylvatic foci. These epidemiological and parasitological profiles appear to indicate that humans are not a source of P. simium infection for mosquitoes. Thus, determining vector competence of An. cruzii and other traditional human malaria vector occurring in the Southeast region (e.g., An. darlingi, An. Aquasalis, and An. albitarsis) for transmitting P. simium and P. brasilianum between humans and from NHPs and humans and vice-versa is imperative.
Supporting information
S1 Table. Number of examined NHPs, by species, habitat, and capture method.
https://doi.org/10.1371/journal.pntd.0007906.s001
(DOCX)
Acknowledgments
To Carlos Alberto C. da Silva, Alexandre B. de Souza, Vicente Klonowski, Romenique L. Araújo, Luiz R. Nogueira, Fernando Barreto, Ana L. Quijada, Luiz P. P. Silva, Gelson Medeiros, Adilson B. Ramos, Marcilene B. Ramos, Carlos A. A. Júnior, Paulo G. Barbosa, Sérgio F. Fragoso, Adilson R. Silva, Cecília Cronemberger, Marcelo Rheingantz, Leonardo Nascimento, João Marins for the support in the field. To André Lanna and collaborators for the Brachyteles capture and sample efforts. Orzinete Rodrigues Soares for non-human primates’ blood slides’ review. To Grupo Técnico de Vigilância de Arboviroses (GT‑Arbo—Secretaria de Vigilância em Saúde—Brazilian Ministry of Health) for field and material supports. We would like to thank Editage (www.editage.com) for English language editing.
References
- 1. Pina-Costa A de, Brasil P, Santi SM Di, Araujo MP de, Suárez-Mutis MC, Santelli ACF e S, et al. Malaria in Brazil: what happens outside the Amazonian endemic region. Mem Inst Oswaldo Cruz. 2014;109: 618–633. pmid:25185003
- 2. Brasil P, Zalis MG, de Pina-Costa A, Siqueira AM, Júnior CB, Silva S, et al. Outbreak of human malaria caused by Plasmodium simium in the Atlantic Forest in Rio de Janeiro: a molecular epidemiological investigation. Lancet Glob Heal. 2017;5.
- 3. Curado I, dos Santos Malafronte R, de Castro Duarte AMR, Kirchgatter K, Branquinho MS, Bianchi Galati EA. Malaria epidemiology in low-endemicity areas of the Atlantic Forest in the Vale do Ribeira, São Paulo, Brazil. Acta Trop. 2006;100: 54–62. pmid:17126279
- 4. Cerutti C, Boulos M, Coutinho AF, Hatab M do CL, Falqueto A, Rezende HR, et al. Epidemiologic aspects of the malaria transmission cycle in an area of very low incidence in Brazil. Malar J. 2007;6: 33. pmid:17371598
- 5. Deane LM. Simian malaria in Brazil. Mem Inst Oswaldo Cruz. 1992;87: 1–20. pmid:1343676
- 6. Fonseca F. Plasmódio de primata do Brasil. Mem Inst Oswaldo Cruz. 1951. pp. 543–553. pmid:14890537
- 7. Deane LM, Deane MP, Ferreira Neto J. Studies on transmission of simian malaria and on a natural infection of man with Plasmodium simium in Brazil. Bull World Health Organ. 1966;35: 805–8. pmid:5297817
- 8. Deane LM, Ferreira Neto JA, Lima MM, Deane LM, Ferreira Neto JA, Lima MM. The vertical dispersión of Anopheles (Kerteszia) cruzi in a forest in southern Brazil suggests that human cases of malaria of simian origin might be expected. Mem Inst Oswaldo Cruz. 1984;79: 461–463. pmid:6533421
- 9. Coatney GR. The Simian Malaria: Zoonoses, Anthroponoses, or Both? Am J Trop Med Hyg. 1971;20: 795–803. pmid:5002245
- 10. de Alvarenga DAM, Culleton R, de Pina-Costa A, Rodrigues DF, Bianco C, Silva S, et al. An assay for the identification of Plasmodium simium infection for diagnosis of zoonotic malaria in the Brazilian Atlantic Forest. Sci Rep. 2018;8: 86. pmid:29311638
- 11. Guimarães LO, Bajay MM, Wunderlich G, Bueno MG, Röhe F, Catão-Dias JL, et al. The genetic diversity of Plasmodium malariae and Plasmodium brasilianum from human, simian and mosquito hosts in Brazil. Acta Trop. 2012;124: 27–32. pmid:22705349
- 12. Rylands AB, Mittermeier RA, Silva JS. Neotropical primates: taxonomy and recently described species and subspecies. Int Zoo Yearb. 2012;46: 11–24.
- 13. Alvarenga DAM, Pina-Costa A, Bianco C, Moreira SB, Brasil P, Pissinatti A, et al. New potential Plasmodium brasilianum hosts: tamarin and marmoset monkeys (family Callitrichidae). Malar J. 2017;16: 71. pmid:28187764
- 14. Lourenço-de-Oliveira R, Deane LM. Simian malaria at two sites in the Brazilian Amazon. I—The infection rates of Plasmodium brasilianum in non-human primates. Memórias do Instituto Oswaldo Cruz. 1995. pp. 331–339. pmid:8544737
- 15. Eyles DE. The Species of Simian Malaria: Taxonomy, Morphology, Life Cycle, and Geographical Distribution of the Monkey Species. J Parasitol. 1963;49: 866–87. pmid:14084190
- 16. Lourenço-de-Oliveira R, Ziccardi M. Natural infection of Golden lion tamarin, Leontopithecus rosalia, with Trypanosoma cruzi, in the state of Rio de Janeiro, Brazil. Mem Inst Oswaldo Cruz. 1990;85: 15.
- 17.
Paglia AP, Rylands AB, Herrmann G, Aguiar LMS, Chiarello AG, Leite YLR, et al. Lista anotada dos mamiferos do Brasil, segunda edicao. 2nd ed. Arlington: Conservation International; 2012.
- 18. Guimarães AE, Arlé M, Machado RNM. Mosquitos no Parque Nacional da Serra dos Órgãos, Estado do Rio de Janeiro, Brasil. II. Distribuição vertical. Mem Inst Oswaldo Cruz. 1985;80: 171–85.
- 19. Miguel RB, Albuquerque HG, Sanchez MCA, Coura JR, Santos S da S, Silva S da, et al. Asymptomatic Plasmodium infection in a residual malaria transmission area in the Atlantic Forest region: Implications for elimination. Rev Soc Bras Med Trop. 2019;52: 1–9. pmid:30942262
- 20. Ribeiro MC, Metzger JP, Martensen AC, Ponzoni FJ, Hirota MM. The Brazilian Atlantic Forest: How much is left, and how is the remaining forest distributed? Implications for conservation. Biol Conserv. 2009;142: 1141–1153.
- 21. Abreu FVS, dos Santos E, Gomes MQ, Vargas WP, Oliveira Passos PH, Nunes e Silva C, et al. Capture of Alouatta guariba clamitans for the surveillance of sylvatic yellow fever and zoonotic malaria: Which is the best strategy in the tropical Atlantic Forest? Am J Primatol. 2019;81: e23000. pmid:31192493
- 22.
Brasil. Guia de vigilância de epizootias em primatas não humanos e entomologia aplicada à vigilância da febre amarela. 2nd ed. Brasília: Ministério da Saúde; 2017.
- 23. Santos Sales I dos, Ruiz-Miranda CR, Santos C de P. Helminths found in marmosets (Callithrix penicillata and Callithrix jacchus) introduced to the region of occurrence of golden lion tamarins (Leontopithecus rosalia) in Brazil. Vet Parasitol. 2010;171: 123–129. pmid:20378249
- 24. Scott NJ, Scott AF, Malmgren LA. Capturing and marking howler monkeys for field behavioral studies. Primates. 1976;17: 527–533.
- 25. Possas C, Lourenço-de-oliveira R, Tauil PL, Pinheiro FDP, Pissinatti A, Venâncio R, et al. Yellow fever outbreak in Brazil: the puzzle of rapid viral spread and challenges for immunisation. 2018;113: 1–12.
- 26. de Abreu FVS, Gomes LR, Mello ARL, Bianco-Júnior C, de Pina-Costa A, dos Santos E, et al. Frozen blood clots can be used for the diagnosis of distinct Plasmodium species in man and non-human primates from the Brazilian Atlantic Forest. Malar J. 2018;17: 338. pmid:30249260
- 27. de Alvarenga D, de Pina-Costa A, de Sousa T, Pissinatti A, Zalis MG, Suaréz-Mutis MC, et al. Simian malaria in the Brazilian Atlantic forest: first description of natural infection of capuchin monkeys (Cebinae subfamily) by Plasmodium simium. Malar J. 2015;14: 81. pmid:25889933
- 28. Gama BE, Silva-Pires F do ES, Lopes MNR, Cardoso MAB, Britto C, Torres KL, et al. Real-time PCR versus conventional PCR for malaria parasite detection in low-grade parasitemia. Exp Parasitol. 2007;116: 427–432. pmid:17433301
- 29. Torres KL, Figueiredo D V., Zalis MG, Daniel-Ribeiro CT, Alecrim W, Ferreira-da-Cruz M de F. Standardization of a very specific and sensitive single PCR for detection of Plasmodium vivax in low parasitized individuals and its usefulness for screening blood donors. Parasitol Res. 2006;98: 519–524. pmid:16416292
- 30. Snounou G, Viriyakosol S, Zhu Xin Ping, Jarra W, Pinheiro L, do Rosario VE, et al. High sensitivity of detection of human malaria parasites by the use of nested polymerase chain reaction. Mol Biochem Parasitol. 1993;61: 315–320. pmid:8264734
- 31. Carson FL, Martin JH, Lynn JA. Formalin Fixation for Electron Microscopy: A Re-evaluation. Am J Clin Pathol. 1973;59: 365–373. pmid:4119901
- 32.
Mayer P. Die Caprellidae der Siboga-Expedition. Leiden, Buchhandlung und druckerei vormals E.J. Brill; 1903.
- 33.
Lennert K. Methodologic Prerequisites for a Differential Diagnosis of Lymphomas. Malignant Lymphomas Other than Hodgkin’s Disease. Berlin, Heidelberg: Springer Berlin Heidelberg; 1978. pp. 73–82. https://doi.org/10.1007/978-3-642-81092-3_2
- 34. Barnwell J. Antigens of Plasmodium vivax blood stage parasites identifiedby monoclonal antibodies. Mem Inst Oswaldo Cruz. 1986;81: 56–61.
- 35. Tazi L, Ayala FJ. Unresolved direction of host transfer of Plasmodium vivax v. P. simium and P. malariae v. P. brasilianum. Infect Genet Evol. 2011;11: 209–221. pmid:20849978
- 36. Escalante AA, Barrio E, Ayala FJ. Evolutionary origin of human and primate malarias: evidence from the circumsporozoite protein gene. Mol Biol Evol. 1995;12: 616–626. pmid:7659017
- 37. Araújo RM, Souza MB, Ruiz-Miranda CR. Densidade e tamanho populacional de mamíferos cinegéticos em duas Unidades de Conservação do Estado do Rio de Janeiro, Brasil. Iheringia Série Zool. 2008;98: 391–396.
- 38. Buery JC, Rodrigues PT, Natal L, Salla LC, Loss AC, Vicente CR, et al. Mitochondrial genome of Plasmodium vivax/simium detected in an endemic region for malaria in the Atlantic Forest of Espírito Santo state, Brazil: do mosquitoes, simians and humans harbour the same parasite? Malar J. 2017;16: 437. pmid:29084553
- 39. de Castro Duarte AMR, Malafronte R dos S, Cerutti C, Curado I, de Paiva BR, Maeda AY, et al. Natural Plasmodium infections in Brazilian wild monkeys: Reservoirs for human infections? Acta Trop. 2008;107: 179–185. pmid:18620330
- 40. Yamasaki T, Duarte AMRC, Curado I, Summa MEL, Neves DVDA, Wunderlich G, et al. Detection of etiological agents of malaria in howler monkeys from Atlantic Forests, rescued in regions of São Paulo city, Brazil. J Med Primatol. 2011;40: 392–400. pmid:21933192
- 41.
Kowalewski MM, Garber PA, Cortés-Ortiz L, Urbani B, Youlatos D. Howler monkeys: behavior, ecology, and conservation. New York, NY: Springer; 2014. https://doi.org/10.1007/978-1-4939-1960-4
- 42. Deane LM. Studies on simian malaria in Brazil. Bull World Health Organ. 1964;31: 752–3. pmid:14278011
- 43. Costa DC, Cunha VP da, Assis GMP de, Souza Junior JC de, Hirano ZMB, Arruda ME de, et al. Plasmodium simium/Plasmodium vivax infections in southern brown howler monkeys from the Atlantic Forest. Mem Inst Oswaldo Cruz. 2014;109: 641–653. pmid:25099335
- 44. Lourenço-de-Oliveira R, Luz SLB. Simian malaria at two sites in the Brazilian Amazon—II. Vertical distribution and frequency of anopheline species inside and outside the forest. Mem Inst Oswaldo Cruz. 1996;91: 687–694. pmid:9283645
- 45. Figueiredo MAP, Di Santi SM, Manrique WG, André MR, Machado RZ. Identification of Plasmodium spp. in Neotropical primates of Maranhense Amazon in Northeast Brazil. PLoS One. 2017;12: 1–14. pmid:28796820
- 46. Bueno MG, Catão-Dias JL, de Oliveira Laroque P, Arruda Vasconcellos S, Ferreira Neto JS, Gennari SM, et al. Infectious Diseases in Free-Ranging Blonde Capuchins, Sapajus flavius, in Brazil. Int J Primatol. 2017;38: 1017–1031.
- 47. Araújo MS, Messias MR, Figueiró MR, Gil LHS, Probst CM, Vidal NM, et al. Natural Plasmodium infection in monkeys in the state of Rondônia (Brazilian Western Amazon). Malar J. 2013;12: 1–8.
- 48. Bueno MG, Rohe F, Kirchgatter K, Di Santi SMF, Guimarães LO, Witte CL, et al. Survey of Plasmodium spp. in free-ranging neotropical primates from the brazilian Amazon region impacted by anthropogenic actions. Ecohealth. 2013;10: 48–53. pmid:23404035
- 49. Gomes ADC, De Paula MB, Duarte AMRDC, Lima MA, Malafronte RDS, Mucci LF, et al. Epidemiological and ecological aspects related to malaria in the area of influence of the lake at Porto Primavera dam, in western São Paulo State, Brazil. Rev Inst Med Trop Sao Paulo. 2008;50: 287–295. pmid:18949348
- 50. Brasil P, Costa A, Longo C, Silva S, Ferreira-da-Cruz M, Daniel-Ribeiro CT. Malaria, a difficult diagnosis in a febrile patient with sub-microscopic parasitaemia and polyclonal lymphocyte activation outside the endemic region, in Brazil. Malar J. 2013;12: 402. pmid:24200365
- 51. de Alencar FEC, Malafronte R dos S, Cerutti Junior C, Natal Fernandes L, Buery JC, Fux B, et al. Assessment of asymptomatic Plasmodium spp. infection by detection of parasite DNA in residents of an extra-Amazonian region of Brazil. Malar J. 2018;17: 113. pmid:29540186
- 52. de Alencar FEC, Malafronte R dos S, Cerutti C, Natal Fernandes L, Buery JC, Fux B, et al. Reassessment of asymptomatic carriers of Plasmodium spp. in an endemic area with a very low incidence of malaria in extra-Amazonian Brazil. Malar J. 2017;16: 452. pmid:29121963
- 53. Lima GFMC, Arroyo Sanchez MC, Levi JE, Fujimori M, Da Cruz Caramelo L, Sanchez AR, et al. Asymptomatic infections in blood donors harbouring Plasmodium: an invisible risk detected by molecular and serological tools. Blood Transfus. 2018;16: 17–25. pmid:27893347
- 54. Hristov AD, Sanchez MCA, Ferreira JJB, Lima GFM de C, Inoue J, Costa-Nascimento M de J, et al. Malaria in pregnant women living in areas of low transmission on the southeast Brazilian Coast: molecular diagnosis and humoural immunity profile. Mem Inst Oswaldo Cruz. 2014;109: 1014–1020. pmid:25494466
- 55. de Arruda M, Nardin EH, Nussenzweig RS, Cochrane AH. Sero-epidemiological studies of malaria in Indian tribes and monkeys of the Amazon Basin of Brazil. Am J Trop Med Hyg. 1989;41: 379–85. pmid:2508499
- 56. Volney B, Pouliquen J-F, De Thoisy B, Fandeur T. A sero-epidemiological study of malaria in human and monkey populations in French Guiana. Acta Trop. 2002;82: 11–23. pmid:11904099
- 57. Lalremruata A, Magris M, Vivas-Martínez S, Koehler M, Esen M, Kempaiah P, et al. Natural infection of Plasmodium brasilianum in humans: Man and monkey share quartan malaria parasites in the Venezuelan Amazon. EBioMedicine. 2015;2: 1186–1192. pmid:26501116
- 58. Brito TT, Oliveira-Júnior JF, Lyra GB, Gois G, Zeri M. Multivariate analysis applied to monthly rainfall over Rio de Janeiro state, Brazil. Meteorol Atmos Phys. 2017;129: 469–478.
- 59. Machado RL, Ceddia MB, Carvalho DF de, Cruz ES da, Francelino MR. Spatial variability of maximum annual daily rain under different return periods at the Rio de Janeiro state, Brazil. Bragantia. 2010;69: 77–84.
- 60. Coutinho JO, Rachou R. Data on the biology and the malaria vector capacity of anophelines of sub-group Kerteszia under natural conditions. Rev Bras Malariol Doencas Trop. 1966;18: 557–80. pmid:5998435
- 61. Cohuet A, Harris C, Robert V, Fontenille D. Evolutionary forces on Anopheles: what makes a malaria vector? Trends Parasitol. 2010;26: 130–136. pmid:20056485
- 62. Beerntsen BT, James AA, Christensen BM. Genetics of mosquito vector competence. Microbiol Mol Biol Rev. 2000;64: 115–37. pmid:10704476
- 63. de Rezende Dias G, Fujii TTS, Fogel BF, Lourenço-de-Oliveira R, Silva-do-Nascimento TF, Pitaluga AN, et al. Cryptic diversity in an Atlantic Forest malaria vector from the mountains of South-East Brazil. Parasit Vectors. 2018;11: 36. pmid:29335015
- 64. Bonaldo MC, Gómez MM, dos Santos AA, Abreu FVS de, Ferreira-de-Brito A, Miranda RM de, et al. Genome analysis of yellow fever virus of the ongoing outbreak in Brazil reveals polymorphisms. Mem Inst Oswaldo Cruz. 2017;112: 447–451. pmid:28591405
- 65.
Brasil. Monitoramento do Período Sazonal da Febre Amarela [Internet]. 2018 pp. 1–15. Available: http://portalarquivos2.saude.gov.br/images/pdf/2018/fevereiro/21/Informe-n14-FA-20fev18-c.pdf
- 66. Moreno ES, Agostini I, Holzmann I, Di Bitetti MS, Oklander LI, Kowalewski MM, et al. Yellow fever impact on brown howler monkeys (Alouatta guariba clamitans) in Argentina: A metamodelling approach based on population viability analysis and epidemiological dynamics. Mem Inst Oswaldo Cruz. 2015;110: 865–876. pmid:26517499
- 67. Almeida M., Dos Santos E, Da Cruz Cardoso J, Da Fonseca DF, Noll CA, Silveira VR, et al. Yellow fever outbreak affecting Alouatta populations in southern Brazil (Rio Grande do Sul State), 2008–2009. Am J Primatol. 2012;74: 68–76. pmid:22020690
- 68. Araújo FAA, Ramos DG, Santos AL, Passos PH de O, Elkhoury ANSM, Costa ZGA, et al. Epizootias em primatas não humanos durante reemergência do vírus da febre amarela no Brasil, 2007 a 2009. Epidemiol e Serviços Saúde. 2011;20: 527–536.
- 69. Bicca-marques JC, Calegaro-marques C, Rylands AB, Karen B, Mittermeier RA, Almeida MAB De, et al. Yellow fever threatens Atlantic Forest primates Júlio. Sci Adv. 2017;1600946: 18–20.
- 70.
Duchiade A. Brazilian Forests Fall Silent as Yellow Fever Decimates Threatened Monkeys. In: Scientific American [Internet]. 12 May 2018 [cited 12 May 2019]. Available: https://www.scientificamerican.com/article/brazilian-forests-fall-silent-as-yellow-fever-decimates-threatened-monkeys/
- 71.
Datasus Ministério da Saúde. TabNet Win32 3.0: MALÁRIA—Casos confirmados Notificados no Sistema de Informação de Agravos de Notificação—Rio de Janeiro [Internet]. [cited 12 May 2019]. Available: http://tabnet.datasus.gov.br/cgi/tabcgi.exe?sinannet/cnv/malarj.def