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Species-specific escape of Plasmodium sporozoites from oocysts of avian, rodent, and human malarial parasites

Abstract

Background

Malaria is transmitted when an infected mosquito delivers Plasmodium sporozoites into a vertebrate host. There are many species of Plasmodium and, in general, the infection is host-specific. For example, Plasmodium gallinaceum is an avian parasite, while Plasmodium berghei infects mice. These two parasites have been extensively used as experimental models of malaria transmission. Plasmodium falciparum and Plasmodium vivax are the most important agents of human malaria, a life-threatening disease of global importance. To complete their life cycle, Plasmodium parasites must traverse the mosquito midgut and form an oocyst that will divide continuously. Mature oocysts release thousands of sporozoites into the mosquito haemolymph that must reach the salivary gland to infect a new vertebrate host. The current understanding of the biology of oocyst formation and sporozoite release is mostly based on experimental infections with P. berghei, and the conclusions are generalized to other Plasmodium species that infect humans without further morphological analyses.

Results

Here, it is described the microanatomy of sporozoite escape from oocysts of four Plasmodium species: the two laboratory models, P. gallinaceum and P. berghei, and the two main species that cause malaria in humans, P. vivax and P. falciparum. It was found that sporozoites have species-specific mechanisms of escape from the oocyst. The two model species of Plasmodium had a common mechanism, in which the oocyst wall breaks down before sporozoites emerge. In contrast, P. vivax and P. falciparum sporozoites show a dynamic escape mechanism from the oocyst via polarized propulsion.

Conclusions

This study demonstrated that Plasmodium species do not share a common mechanism of sporozoite escape, as previously thought, but show complex and species-specific mechanisms. In addition, the knowledge of this phenomenon in human Plasmodium can facilitate transmission-blocking studies and not those ones only based on the murine and avian models.

Background

Malaria remains a life-threatening disease that threatens approximately 3.4 billion people in 104 tropical countries, mainly in Africa, Asia, and South America, with an estimated 207 million cases and half a million deaths reported per year [1]. This vector-borne disease is caused by protozoa of the genus Plasmodium, of which Plasmodium falciparum, endemic to Africa, is the most prevalent species, followed by Plasmodium vivax in Asia and the Americas [1]. Other Plasmodium species infect other animal species, such as Plasmodium gallinaceum and Plasmodium berghei, responsible for avian and murine malaria, respectively [2, 3]. Many experimental studies have used P. berghei and P. gallinaceum as laboratory models to investigate the interactions between the parasites and their vectors. These two Plasmodium species are easily maintained in experimental animals, facilitating investigative research in laboratories [48].

The Plasmodium life cycle begins in a permissive vector when a female mosquito takes a blood meal from an infected vertebrate host that contains gametocytes, the stage of the parasite that can infect the invertebrate vector. Only a few minutes after the infective blood meal enters the midgut lumen of the susceptible mosquito, these gametocytes undergo activation to generate micro- and macro-gametes that fertilize to produce a diploid zygote. After DNA replication and the production of a 4N parasite, the zygote will differentiate into an ookinete over the next 18-24 h depending on the respective parasite species. Ookinetes are a motile form of the parasite that invade and pass through the midgut epithelium until they reach the midgut basal lamina towards the haemocoel of the mosquito. At this location, between the epithelial cells of the midgut and the basal lamina, the ookinete differentiates into a protruding rounded oocyst facing the mosquito haemocoel [812]. The presence of well-developed protruding oocysts in the midgut wall is indicative of infection by Plasmodium [1315], and is a reliable measurement to determine the infection rate and the susceptibility of a mosquito species to a particular Plasmodium species. In the midgut wall, the oocysts progress to the asexual phase of multiplication known as sporogony, which is completed in approximately 1–2 weeks, the longest phase of the Plasmodium life cycle in the mosquito vector. Ultimately, this biological process produces thousands of sporozoites, the final form of Plasmodium in the vector. The sporozoites are motile sickle forms that escape from the oocysts into the mosquito hemocoel and invade the salivary gland. Once inside the salivary gland, the sporozoites are ready to be injected into a new vertebrate host via a mosquito bite, completing the Plasmodium life cycle in the invertebrate vector [1618].

Completion of the Plasmodium life cycle in the vector requires passage through several barriers inside and outside the midgut. One important and poorly studied barrier is the exit of sporozoites from the oocyst, a critical step that allows sporozoite release into the haemolymph and subsequent invasion of the mosquito salivary gland. Knowledge of the escape mechanism of various Plasmodium species is largely unknown for the human malaria parasites, and only a few reports using the laboratory models have previously been published. Studies of the development of P. berghei oocysts using a scanning electron microscope (SEM) showed a single small hole in the oocyst wall, inside which sporozoites could be seen [19]. Sinden and Strong reported a torn oocyst from which several P. falciparum sporozoites had been released [20]. Meis and collaborators studying the sporogony of P. falciparum and P. berghei, reported some details of sporozoite escape and concluded that the two species showed similar mechanisms of escape, i.e., the oocysts burst and sporozoites were released into the hemocoel of the mosquito vector [21]. Although published studies have provided some details, knowledge of sporozoite escape from the oocysts of distinct Plasmodium species remains incomplete and is primarily based on P. berghei, a classical murine malarial parasite used as an experimental model in several laboratories. Moreover, most of the studies on the molecular mechanism of oocyst formation and sporozoite escape have been done using murine P. berghei mutant parasites, resulting in conclusions that have been generalized to human Plasmodium species without further morphological study.

Understanding the mechanisms of sporozoite escape in various Plasmodium species as well as correlations with molecular findings, may contribute to our knowledge of the parasite life cycle in the mosquito vector. Scanning electron microscopy analysis of the external side of the dissected midguts of infected mosquitos is a valuable tool for studying sporozoite escape from oocysts and has not been well explored. Here, this study provides comprehensive insight into the microanatomy of the mechanism of sporozoite escape from oocysts in four species of Plasmodium: the two laboratory models, avian P. gallinaceum and rodent P. berghei, and the two primary causative agents of human malaria, P. vivax and P. falciparum. It was showed that sporozoite escape is not a common biological process, as previously thought, but the mechanism is complex and species-specific.

Methods

Mosquito rearing

Mosquitoes of Anopheles gambiae, Anopheles aquasalis and Aedes aegypti were reared at 27 °C with 80 % humidity on 12 h light/dark cycle under insectary conditions. They were provided with 10 % sucrose solution ad libitum until 1 day before the infective blood meal, as described previously [8, 15].

Infection of mosquitoes with Plasmodium

Susceptible female mosquitoes (4–5 days old) were chosen to be experimentally infected with one of the four Plasmodium species through a membrane feeder device at 37 °C for 30 min, as described previously [8]. Anopheles gambiae were infected with stage IV and V gametocytes of the cultured P. falciparum NF54 strain. The mature gametocytes were mixed with type O+ blood and offered to the mosquitoes [2224]. Anopheles gambiae were also infected with P. berghei by direct skin feeding on infected Swiss Webster female mice with a parasitaemia level of 4–8 % and containing 2–3 gametocyte exflagellations per field when observed at 400× under a light microscope. Aedes aegypti were infected with P. gallinaceum by direct skin feeding on an infected chicken (Gallus domesticus) with a 10 % parasitaemia level and at least 2 % circulating gametocytes [25]. Anopheles aquasalis were fed on P. vivax-infected blood collected from patients diagnosed with malaria, as described in the Ethics statement.

Ethics statement

For the acquisition of P. vivax infected human blood, patients were selected among the people visiting the Hospital at the Foundation of Tropical Medicine located in Manaus, Brazil looking for malaria diagnosis and treatment during outbreaks. Diagnosis was performed by Giemsa stained blood smear. After positive diagnosis and visualization of gametocytes, patients were interviewed and inquired about the possibility of volunteer donation of a small amount of blood for research purposes. After verbal agreement, a term of consent was first read to the potential volunteers, with detailed verbal explanation, and, after final consent, signed by the patient. After this, one 200 ml sample of venous blood was drawn from each patient and placed in heparinized tubes. Blood samples were kept under refrigeration in an icebox (at approximately 15 °C) for about 15 min, taken to the laboratory. The infected P. vivax blood samples were offered to mosquitoes through membrane feeder devices. Patient selection criteria were: to be P. vivax positive, to have about 4–8 % of circulating gametocytes as determined by the National Institutes of Health international protocols, and to consent to be part of the research consent form that was approved by the Brazilian Ministry of Health, National Council of Health, National Committee of Ethics in Research (CONEP—Approval Number 3726). All patients were treated in accordance with the Brazilian Malaria National Control Programme guidelines.

Also, mice and chickens were maintained at the Animal Care Facility of the FIOCRUZ-MG under specific pathogen-free conditions and were used in accordance to a study protocol approved by the FIOCRUZ Ethical Committee for Animal Use (CEUA; license number LW30/10). It was followed the Public Health Service Animal Welfare Assurance #A4149-01 guidelines according to the National Institutes of Health (NIH) Office of Animal Care and Use (OACU) since these studies were done according to the NIH animal study protocol (ASP) approved by the NIH Animal Care and User Committee (ACUC), with approval ID ASP-LMVR5.

Scanning electron microscopy of infected mosquito midgut

The mosquito midguts were dissected daily, from day 8 to day 16 after the infective blood meal. The dissected midguts were fixed for 2 h in 4 % glutaraldehyde solution in 0.1 M cacodylate buffer, pH 7.2 and then post-fixed with 1 % osmium tetroxide for 2 h. The fixed samples were dehydrated using a graded acetone series, CO2-dried in a critical-point drying device (Emitech K850, USA) and gold-coated in a sputter coater (Emitech K550, USA) as detailed previously [26]. The samples were analyzed and imaged using a JSM-5600 scanning electron microscope (Jeol USA, Inc).

Results

Careful comparative SEM analyses of infected midguts dissected from susceptible mosquito vectors, containing distinct Plasmodium species, revealed several new details of the oocyst surface and the sporozoite escape process that are unique to each Plasmodium species.

Escape of Plasmodium gallinaceum sporozoites from oocysts

Magnification of dissected midguts showed hundreds of rounded avian P. gallinaceum oocysts on the midgut surface of the infected Ae. aegypti. Most of the oocysts formed small groups on the midgut surface (Fig. 1a, b). Flattened oocysts and completely smooth oocysts were observed side by side, some with haemocytes attached to the surface (Fig. 1c). On the 14th day after infection, it was possible to observe sporozoites escaping from oocysts in the dissected midguts. These dissected midguts were carefully scrutinized for the presence of oocysts, in order to observe the details of sporozoite escape. Several cracked oocysts of P. gallinaceum were observed at distinct stages, from some with small cracks in the surface, to some that were completely broken, exposing hundreds of escaping sporozoites (Fig. 1d–f). The completely cracked oocysts liberated thousands of sporozoites into the mosquito haemocoel (Fig. 1d, e). In empty oocyst shells, it was possible to observe the porous surface of the internal side of the oocyst wall (Fig. 1e, f).

Fig. 1
figure 1

Plasmodium gallinaceum sporozoites escaping from oocysts. a and b Hundreds of rounded P. gallinaceum oocysts of similar size protruding from the external surface of the midgut (Mdgt) among the muscle fibers (Mfb) and tracheoles (Tch). Most oocysts form clusters of a few individuals (asterisks). All oocysts have a completely smooth surface. Magnification = ×100. c Two oocysts attached side by side to the midgut surface; one is completely smooth (S-ooc) and the other is flattened (F-ooc). Note the single hemocyte attached over the completely smooth oocyst wall (arrow). Magnification = ×1400. d One completely smooth oocyst (S-ooc) with a cracked wall (arrows) and a partly cracked oocyst (asterisks) showing hundreds of escaping sporozoites (Spz). Magnification = ×1700. e Thousands of clustered sporozoites (Spz) can be seen inside and escaping from a partly cracked oocyst (white asterisk). In the upper portion of the image, an empty half-shell of a broken oocyst can be seen, in which it is possible to observe details of the internal wall (In-wall). S-ooc = completely smooth oocyst. Magnification = ×1500. f Magnified view of the dashed area of Fig. 1d, showing the porous surface of the internal wall (In-wall) of the oocyst. Spz = clusters of escaping sporozoites. Magnification = ×4500

Escape of Plasmodium berghei sporozoites from oocysts

At 13 and 14 days after infection of An. gambiae with P. berghei, several oocysts were observed to be protruding between the muscle fibers covering the midgut surface, at different stages of rupture (Fig. 2a–d). The upper surface of these oocysts was wrinkled, and the basal surface, inserted in the midgut tissue, was smooth; it was also possible to observe some flattened oocysts (Fig. 2a). In most of the oocysts, the wall showed distinct stages of “decortication” until the sporozoites were liberated. This decortication was always present in the upper surface and in the wrinkled areas of the oocyst wall (Fig. 2a–c). In some images, it is possible to observe the advanced stages of sporozoite escape, indicated by dissolution of the oocyst wall (Fig. 2c). However, even after the oocyst had opened completely, the sporozoites remained attached to the internal side of the wall, probably until the wall was completely destroyed (Fig. 2d, e).

Fig. 2
figure 2

Plasmodium berghei sporozoites escaping from oocysts. a P. berghei oocysts protruding among muscle fibers (Mfb) on the external surface of the midgut. The surfaces of the oocysts are partly smooth (white asterisks) and partly wrinkled (black asterisks), with the exception of a few flattened oocysts (F-ooc). Several oocysts have openings on their wrinkled surfaces, which appears as if the wall has peeled away, and sporozoites can be seen inside the hole (arrows). Muscle fibers = Mfb. Magnification = ×1000. b Small opening (arrowhead) in the oocyst (ooc) wall showing the orderly arrangement of several sporozoites (Spz) inside the oocyst. Note the wrinkled surface of the oocyst. Magnification = ×1900. c Oocyst (ooc) with a large opening, approximately half-size, showing a sponge-like part of the dissolving oocyst wall (D-wall). Note cluster of sporozoites (Spz) ready to escape from the oocyst. Magnification = ×1900. d A single oocyst (ooc) showing a large opening with a “cap” (asterisk) that appears to allow sporozoite escape. Note cluster of sporozoites (spz) attached to the internal side of the oocyst wall (arrows). Magnification = ×1700. e Magnified view of the dashed area from figure d, showing a large opening with several orderly arranged sporozoites (Spz) attached to the internal side of the oocyst wall (In-wall). Magnification = ×4300

Escape of P. vivax sporozoites from oocysts

The dissected midgut of the infected An. aquasalis revealed approximately ten to a few hundred P. vivax oocysts of similar size on the midgut surface. Most oocysts were isolated or in pairs and they were protruding from the basal midgut surface (Fig. 3a). Detailed analysis of infected midgut using high-magnification images allowed the observation of active escape of a single sporozoite in a rigid perpendicular position (resembling a pointing finger) at 14 days after infection. This sporozoite was forcing its way out of the oocyst by making a hole in the oocyst wall with its anterior tip (Fig. 3b), arguing that sporozoite release is directly initiated by individual or small groups of sporozoites. Additional images of 15 and 16 days after infection show the escape of a group of few sporozoites from a small hole, all with a “pointing finger” shape, indicating that they were actively forcing themselves through the wall in a striking first step to sporozoite release (Fig. 3c, d). Finally, it was observed free sporozoites with the characteristic “comma-shape” in distinct regions of the mosquito hemocoel (Fig. 3e, f). Empty oocysts, with discernible holes where sporozoites had escaped, were occasionally observed (Fig. 3g), along with some undeveloped flattened oocysts immediately adjacent to completely smooth oocysts (Fig. 3g).

Fig. 3
figure 3

Plasmodium vivax sporozoites escaping from oocysts. a Low-power magnification of the external surface of the midgut showing protruding P. vivax oocysts (asterisks) of similar size. The rounded oocysts are arranged individually or in pairs protruding among muscle fibers (Mfb), trachea (Tra), and tracheoles (Tch) that rest on the external surface of the midgut. Magnification = ×200. b High-power magnification of a single sporozoite actively escaping by creating a hole (arrows) in the smooth oocyst (S-ooc) wall with its anterior end (asterisk). Note the rigid perpendicular shape of the escaping sporozoite (Spz). Magnification = ×8000. c and d Tens of grouped sporozoites (arrowheads) escaping from the lateral wall of an oocyst (S-ooc). Figure d is an enlarged image of the dashed area from figure c. Note the “rigid perpendicular shape” of the escaping sporozoites (Spz). Magnifications D = ×1400 and E = ×4000. e and f Free sporozoites (Spz) with the characteristic “comma-shape,” as seen in the mosquito hemocoel. Magnifications E = ×4100 and F = ×4300. g Empty oocyst (E-ooc) showing a hole through which the sporozoites escaped from the oocyst (asterisk). Magnification = ×1800. h Two side-by-side oocysts attached to the muscle fibers (Mfb) of the midgut. One smooth oocyst shows a completely stretched wall (S-ooc) and the other shows a flattened wall (F-ooc). Magnification = ×1300

Escape of Plasmodium falciparum sporozoites from oocysts

The dissected midgut sections of the infected An. gambiae revealed approximately ten to a few hundred P. falciparum oocysts (data not shown), most of them of similar size, located on the midgut surface. Some oocysts protruded, isolated or in groups of 4–6 individuals, on the basal midgut surface. Plasmodium falciparum oocysts could be classified into two distinct types according their surface: completely smooth and wrinkled surfaces (Fig. 4a, b). At 14 days after infection, detailed analysis revealed the initial process of a single sporozoite actively escaping through a unique hole, always from a completely smooth oocyst. These escaping single sporozoites also presented the “pointing finger” shape similar to those seen with P. vivax, leading with the anterior tip (Fig. 4c). At 13 and 14 days after infection some completely smooth oocysts showed small broken areas from which a few sporozoites were escaping. These oocysts were beginning to show folded areas on the surface (Fig. 4d). During P. falciparum sporozoite escape, it was possible to observe a flattened oocyst with a lateral opening, showing a cluster of escaping sporozoites inside (Fig. 4e, f). Notably, only completely smooth oocysts appeared to produce escaping P. falciparum sporozoites, and were never observed escaping from wrinkled oocysts.

Fig. 4
figure 4

Plasmodium falciparum sporozoites escaping from oocysts. a P. falciparum oocysts, with numerous completely smooth oocysts (white asterisks) and wrinkled oocysts (black asterisks) protruding among muscle fibers (Mfb), trachea (Tra), and tracheoles (Tch) that rests on the external surface of the midgut. Magnification = ×350. b High-power magnification of the dashed area from figure a showing a group of four oocysts attached to the midgut. It is possible to observe surface details of two completely smooth oocysts (S-ooc) and two wrinkled oocysts (W-ooc). Magnification = ×800. c Enlarged image of a small portion of the initial process of a single sporozoite actively escaping from a completely smooth oocyst (S-ooc) by creating a hole (arrows). Note the rigid perpendicular shape of the escaping sporozoite and the anterior tip (large arrow) of the parasite (large arrow). Magnification = ×3000. d One completely smooth oocyst (S-ooc) with small broken areas (arrows) showing a group of twelve escaping sporozoites (Spz). Magnification = ×3500. e Flattened opened oocyst (Op-ooc) showing a lateral opening (asterisk) with a cluster of escaping sporozoites (Spz) that remain inside. Note hemocytes attached to the oocyst wall (arrows) and folded areas (asterisks) of the oocyst surface. Magnification = ×1300. f Enlarged image of the dashed area from figure e showing the oocyst opening and several escaping sporozoites (Spz). Note the “comma-shaped” sporozoites. Oocyst = Op-ooc. Magnification = ×6000. g Flattened empty oocyst (E-ooc) showing the lateral opening (asterisk). No sporozoites can be seen inside or around the oocyst opening. Magnification = ×1800

The Table 1 shows the proportion of the distinct Plasmodium oocysts according to their main microanatomical aspects of their surfaces, as described in details above.

Table 1 Proportion of the oocysts according to their surface microanatomical details

Discussion

The longest developmental stage of the Plasmodium life cycle in the mosquito vector is sporogony, the process of formation of thousands of sporozoites. A single parasite invades the epithelium of the midgut of a mosquito vector and remains in the gut wall for several days. This single-celled protozoan remains outside the mosquito cells, and grows into a large-lobed syncytial nucleus by mitotic division, inside a structure named the oocyst, which forms mature sporozoites. These mature sporozoites escape from the oocysts into the mosquito cavity, after which they invade the salivary gland in preparation for injection in a new vector. The duration of this stage of the Plasmodium life cycle varies according to the species, but usually lasts 8–14 days after the mosquito vector has ingested the infective blood meal [79, 13, 27].

In this study, to examine the microanatomy of sporozoite escape from oocysts of the four Plasmodium species, 10–20 midgut sections were dissected daily from infected mosquito vectors, 6–16 days after the infective blood meal. The midgut samples were dissected, fixed, and processed in the same laboratory, following an identical rigorous protocol to facilitate comparative analyses. The microanatomical analyses presented here clearly and accurately show the ultrastructural aspects of the oocyst surfaces and the processes of sporozoite escape. Preliminary analyses revealed that in all Plasmodium species, the oocysts are rounded structures that protrude individually or in small groups from the exterior of the midgut wall of the mosquito vector. However, the oocysts of the four Plasmodium species differ in surface features of the external wall and in the process of sporozoite escape.

In the avian parasite P. gallinaceum, the outer surfaces of all oocysts were completely smooth. During the process of sporozoite escape, P. gallinaceum oocysts were cracked, suggestive of internal forces disrupting the oocyst wall from the inside. The broken oocysts were similar to broken eggs, exposing their internal surface, with subsequent release of large groups of sporozoites into the mosquito cavity. In contrast, all murine P. berghei oocysts showed a hybrid surface, wrinkled on the top and smooth on the base. Compared to P. gallinaceum, P. berghei sporozoites appear to have a less violent mechanism of escape from the oocysts. On the upper, wrinkled surface of the oocysts, a small part of the wall begins to decorticate, creating a small opening, followed by progressive dissolution of the oocyst wall. Then, the highly structured clusters of sporozoites detach from the internal oocyst wall. In the murine and avian species of Plasmodium, the final steps of the sporozoite escape process, no empty oocysts were observed, distinct from the species of Plasmodium that infect humans. Only one comparative study of P. gallinaceum and P. berghei oocysts has been published [19]. In both Plasmodium species, both completely smooth oocysts and rare, wrinkled oocysts were observed, which the authors considered matured oocysts or sample preparation artifacts. Although they only showed two images, they suggested these two Plasmodium species have similar sporozoite escape mechanisms.

All P. vivax oocysts showed similar completely smooth surfaces, and in this respect, they are morphologically similar to P. gallinaceum oocysts. In contrast, two types of P. falciparum oocysts were observed: completely smooth and wrinkled oocysts. These oocysts were randomly distributed, sometimes side-by-side, in the mosquito midgut at a 50:50 ratio. Previous studies found that infected P. falciparum mosquitoes contained only wrinkled oocysts, but no escaping sporozoites were observed [20, 21]. The authors suggested that the wrinkled surface was characteristic of mature oocysts. However, although we also observed two types of oocysts in P. falciparum, sporozoites were only observed escaping from completely smooth oocysts, indicating that completely smooth oocysts contain mature sporozoites. The wrinkled oocysts may be immature oocysts or oocytes that cannot produce healthy, mature sporozoites.

The most noteworthy feature of the two human Plasmodium species, P. vivax and P. falciparum, is the dynamic mechanism of sporozoite escape from oocysts, distinct from that of the laboratory model Plasmodium species. Careful observation showed that the first signals of sporozoite escape are identical for the two human Plasmodium species: escape begins with a single sporozoite, in a rigid perpendicular position, forcing an exit from through the oocyst wall. The rigid perpendicular sporozoite opens a tiny hole in the oocyst wall with its anterior end. The oocyst wall is composed of two layers; the internal layer is of Plasmodium origin and the external thick layer that is derived from the basal lamina of the mosquito midgut [28, 29]. Moreover, in addition to allowing for growth, the capsule must have an ordered structure to allow for precursors and nutrients that support parasite growth and differentiation to enter the oocyst and metabolites to exit it [30, 31]. Subsequently, this tiny hole in the oocyst wall grows larger and allows other sporozoites to escape. Although this first step, with a single sporozoite making a tiny hole in the oocyst wall, is identical between the two species, the subsequent steps of sporozoite escape differ between P. vivax and P. falciparum. In P. vivax, a small group of sporozoites continue, in the same rigid perpendicular position as the first, to actively move forward to enlarge the hole in the oocyst wall. In P. falciparum oocysts, small groups of sporozoites escape, and individual sporozoites are flexible comma shapes, characteristic of random motion of the parasite [3234]. A geometrical model of malaria parasite migration demonstrated that sporozoites could be modeled as self-propelled individuals that can have curved or rigid structures for motion in distinct environments [35]. This programmed rigidness and flexibility of the human Plasmodium sporozoites appears to act distinctly in the two species of Plasmodium, since it plays a role in opening the oocyst wall, allowing escape.

Molecular mechanisms related to oocyst formation and sporozoite escape have been demonstrated, mainly using mutants of murine P. berghei, which infects rodents, but not in Plasmodium species that infect humans. It is important to note that these analyses demonstrate that P. berghei sporozoites escape from oocysts by a process that harms the oocyst wall. The circumsporozoite (CS) protein, secreted by sporozoites, covers the internal layer of the oocyst wall [36, 37]. It was demonstrated in P. berghei that the disruption or deletion of some regions of the CS protein affects the formation and maturation of sporozoites, escape from the oocyst, and subsequent progression of the Plasmodium life cycle [38, 39]. Likewise, several other gene deletions have been described that affect P. berghei oocyst formation and consequent sporozoite escape: an oocyst-specific papain-like cysteine protease, known as the egress cysteine protease (ECP1), oocyst capsule protein (PbCAP380), fertilization gene (Pb GEX), lectin adhesive proteins (PbLAPs), protein kinases (PbCDLK), and nuclear forming-like protein (PbMISFIT) [4048]. The results showed that P. berghei sporozoites are liberated from the oocyst by decortication and subsequent dissolution of the oocyst wall, which is consistent with a mechanism involving a proteolytic activity as has been proposed for P. berghei [42]. Thus, these findings indicate that proteins that act on the oocyst wall, rather than in the sporozoite, should be considered as target candidate molecules to stop transmission.

Analyses of the sporozoite escape processes in the Plasmodium species that infect humans clearly showed the action of the actively protunding sporozoites is dissimilar from that of murine and avian Plasmodium species. Plasmodium belongs to the phylum Apicomplexa, which is well defined by polarized extracellular stages, which contain specialized secretory organelles named micronemes and rhoptries in their anterior edge. Proteins secreted by these organelles play essential roles in attachment and invasion of target cells, as well as gliding motility, locomotion, and morphological changes [33, 4952]. The main mode of active locomotion of the sporozoite is an actomyosin-dependent motility that is important for forward locomotion, and penetration and invasion of target cells [53]. In addition, during sporozoite motility, TRAP may coordinate the formation of contact sites and the dissociation of these contact sites from the substrate, including involvement of actin filaments [54, 55]. This raises the possibility that secretory proteins that are involved in the interplay of adhesion molecules and the invasion mechanism, well studied in invasion of host cells, can also play roles in the initial active stage that guides the escape of P. vivax and P. falciparum from the oocyst.

Careful comparative microanatomical analyses of midguts of mosquitos infected with four distinct Plasmodium species allowed us to make novel observations of sporozoite escape from oocysts. The key findings of this study are the morphological features that reveal for first time the mechanisms of sporozoite escape from oocysts of four Plasmodium species, including avian, murine, and human malarial parasites. Sporozoites of the four Plasmodium species exit oocysts using different mechanisms. The avian P. gallinaceum and murine P. berghei have been used as experimental models in several laboratories for infection of vertebrates and mosquito vectors. Mice infected with P. berghei have been used as laboratory models for human malaria [5658] and to investigate interaction of the parasite with vectors of human malaria such as An. gambiae and An. stephensi [5961]. It is important to state that the findings of the escape of P. berghei and P. falciparum sporozoites from oocysts were obtained from experimental infections of the same mosquito species, the An. gambiae. This fact suggests that the distinct mechanisms of the sporozoite escape is not dependent of the Anopheles species but is regulated by the Plasmodium species. Nevertheless, it is noteworthy to consider that these Plasmodium species differ in the oocyst microanatomical appearance and in the process of the sporozoite escape. Although the molecular mechanism that regulates sporozoite escape remains largely unknown, this study clearly indicates that Plasmodium species do not share a common mechanism, as previously thought.

Conclusions

It was demonstrated that sporozoites of the human malarial parasites P. vivax and P. falciparum escape from the oocyst via a more active process than those of the avian and murine malarial parasites, P. gallinaceum and P. berghei. Detailed analysis showed that all four have distinct escape mechanisms. Sporozoites that infect humans actively create a hole in the oocyst wall, and are not dependent on the breakdown or dissolution of the oocyst wall for escape. These findings provide a strong basis for future studies of how to block sporozoite escape from oocysts in order to prevent transmission of malaria.

References

  1. WHO. World malaria report 2015. Geneva: World Health Organization; 2015. p. 1–280.

    Google Scholar 

  2. Garnham PC. Malaria parasites and other haemosporidia. Oxford: Blackwell Scientific Publ.; 1966. p. 1132.

    Google Scholar 

  3. Valkiunas G. Avian malaria parasites and other haemosporidia. Florida: CRC Press; 2005. p. 946.

    Google Scholar 

  4. Natarajan R, Thathy V, Mota MM, Hafalla JC, Menard R, Vernick KD. Fluorescent Plasmodium berghei sporozoites and pre-erythrocytic stages: a new tool to study mosquito and mammalian host interactions with malaria parasites. Cell Microbiol. 2001;3:371–9.

    Article  CAS  PubMed  Google Scholar 

  5. Boete C. Malaria parasites in mosquitoes: laboratory models, evolutionary temptation and the real world. Trends Parasitol. 2005;21:445–7.

    Article  PubMed  Google Scholar 

  6. Cohuet A, Osta MA, Morlais I, Awono-Ambene PH, Michel K, Simard F, et al. Anopheles and Plasmodium: from laboratory models to natural systems in the field. EMBO Rep. 2006;7:1285–9.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  7. Smith RC, Vega-Rodriguez J, Jacobs-Lorena M. The Plasmodium bottleneck: malaria parasite losses in the mosquito vector. Mem Inst Oswaldo Cruz. 2014;109:644–61.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  8. Pimenta PF, Orfano AS, Bahia AC, Duarte AP, Rios-Velasquez CM, Melo FF, et al. An overview of malaria transmission from the perspective of Amazon Anopheles vectors. Mem Inst Oswaldo Cruz. 2015;110:23–47.

    Article  PubMed  PubMed Central  Google Scholar 

  9. Sinden RE. Gametogenesis in Plasmodium. Bull Soc Pathol Exot. 1999;92:437.

    CAS  PubMed  Google Scholar 

  10. Ghosh A, Edwards MJ, Jacobs-Lorena M. The journey of the malaria parasite in the mosquito: hopes for the new century. Parasitol Today. 2000;16:196–201.

    Article  CAS  PubMed  Google Scholar 

  11. Dinglasan RR, Devenport M, Florens L, Johnson JR, McHugh CA, Donnelly-Doman M, et al. The Anopheles gambiae adult midgut peritrophic matrix proteome. Insect Biochem Mol Biol. 2009;39:125–34.

    Article  CAS  PubMed  Google Scholar 

  12. Nikolaeva D, Draper SJ, Biswas S. Toward the development of effective transmission-blocking vaccines for malaria. Expert Rev Vaccines. 2015;14:653–80.

    Article  CAS  PubMed  Google Scholar 

  13. Beier JC. Malaria parasite development in mosquitoes. Annu Rev Entomol. 1998;43:519–43.

    Article  CAS  PubMed  Google Scholar 

  14. Gamage-Mendis AC, Rajakaruna J, Weerasinghe S, Mendis C, Carter R, Mendis KN. Infectivity of Plasmodium vivax and P. falciparum to Anopheles tessellatus; relationship between oocyst and sporozoite development. Trans R Soc Trop Med Hyg. 1993;87:3–6.

    Article  CAS  PubMed  Google Scholar 

  15. Rios-Velasquez CM, Martins-Campos KM, Simoes RC, Izzo T, dos Santos EV, Pessoa FA, et al. Experimental Plasmodium vivax infection of key Anopheles species from the Brazilian Amazon. Malar J. 2013;12:460.

    Article  PubMed  PubMed Central  Google Scholar 

  16. Pimenta PF, Touray M, Miller L. The journey of malaria sporozoites in the mosquito salivary gland. J Eukaryot Microbiol. 1994;41:608–24.

    Article  CAS  PubMed  Google Scholar 

  17. Hillyer JF, Barreau C, Vernick KD. Efficiency of salivary gland invasion by malaria sporozoites is controlled by rapid sporozoite destruction in the mosquito haemocoel. Int J Parasitol. 2007;37:673–81.

    Article  PubMed  Google Scholar 

  18. Mueller AK, Kohlhepp F, Hammerschmidt C, Michel K. Invasion of mosquito salivary glands by malaria parasites: prerequisites and defense strategies. Int J Parasitol. 2010;40:1229–35.

    Article  PubMed  PubMed Central  Google Scholar 

  19. Strome CP, Beaudoin RL. The surface of the malaria parasite. I. Scanning electron microscopy of the oocyst. Exp Parasitol. 1974;36:131–42.

    Article  CAS  PubMed  Google Scholar 

  20. Sinden RE, Strong K. An ultrastructural study of the sporogonic development of Plasmodium falciparum in Anopheles gambiae. Trans R Soc Trop Med Hyg. 1978;72:477–91.

    Article  CAS  PubMed  Google Scholar 

  21. Meis JF, Wismans PG, Jap PH, Lensen AH, Ponnudurai T. A scanning electron microscopic study of the sporogonic development of Plasmodium falciparum in Anopheles stephensi. Acta Trop. 1992;50:227–36.

    Article  CAS  PubMed  Google Scholar 

  22. Trager W, Jensen JB. Human malaria parasites in continuous culture. Science. 1976;193:673–5.

    Article  CAS  PubMed  Google Scholar 

  23. Ifediba T, Vanderberg JP. Complete in vitro maturation of Plasmodium falciparum gametocytes. Nature. 1981;294:364–6.

    Article  CAS  PubMed  Google Scholar 

  24. Billker O, Shaw MK, Margos G, Sinden RE. The roles of temperature, pH and mosquito factors as triggers of male and female gametogenesis of Plasmodium berghei in vitro. Parasitology. 1997;115:1–7.

    Article  PubMed  Google Scholar 

  25. Rocha AC, Braga EM, Araujo MS, Franklin BS, Pimenta PF. Effect of the Aedes fluviatilis saliva on the development of Plasmodium gallinaceum infection in Gallus (gallus) domesticus. Mem Inst Oswaldo Cruz. 2004;99:709–15.

    Article  PubMed  Google Scholar 

  26. Secundino NFC, Nacif-Pimenta R, Hajmova M, Volf P, Pimenta PF. Midgut muscle network in Lutzomyia longipalpis and Phlebotomus duboscqi sand flies: spatial organization and structural modification after blood meal. Arthropod Struct Dev. 2005;34:167–78.

    Article  Google Scholar 

  27. Vaughan JA. Population dynamics of Plasmodium sporogony. Trends Parasitol. 2007;23:63–70.

    Article  PubMed  Google Scholar 

  28. Aikawa M. Parasitological review. Plasmodium: the fine structure of malarial parasites. Exp Parasitol. 1971;30:284–320.

    Article  CAS  PubMed  Google Scholar 

  29. Arrighi RB, Hurd H. The role of Plasmodium berghei ookinete proteins in binding to basal lamina components and transformation into oocysts. Int J Parasitol. 2002;32:91–8.

    Article  CAS  PubMed  Google Scholar 

  30. Adini A, Warburg A. Interaction of Plasmodium gallinaceum ookinetes and oocysts with extracellular matrix proteins. Parasitology. 1999;119:331–6.

    Article  CAS  PubMed  Google Scholar 

  31. Vanderberg J, Rhodin J. Differentiation of nuclear and cytoplasmic fine structure during sporogonic development of Plasmodium berghei. J Cell Biol. 1967;32:C7–10.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  32. Vanderberg JP. Studies on the motility of Plasmodium sporozoites. J. Protozool. 1974;21:527–37.

    Article  CAS  PubMed  Google Scholar 

  33. Kappe SH, Buscaglia CA, Nussenzweig V. Plasmodium sporozoite molecular cell biology. Annu Rev Cell Dev Biol. 2004;20:29–59.

    Article  CAS  PubMed  Google Scholar 

  34. Munter S, Sabass B, Selhuber-Unkel C, Kudryashev M, Hegge S, Engel U, et al. Plasmodium sporozoite motility is modulated by the turnover of discrete adhesion sites. Cell Host Microbe. 2009;6:551–62.

    Article  PubMed  Google Scholar 

  35. Battista A, Frischknecht F, Schwarz US. Geometrical model for malaria parasite migration in structured environments. Phys Rev E Stat Nonlin Soft Matter Phys. 2014;90:042720.

    Article  PubMed  Google Scholar 

  36. Menard R, Sultan AA, Cortes C, Altszuler R, van Dijk MR, Janse CJ, et al. Circumsporozoite protein is required for development of malaria sporozoites in mosquitoes. Nature. 1997;385:336–40.

    Article  CAS  PubMed  Google Scholar 

  37. Golenda CF, Starkweather WH, Wirtz RA. The distribution of circumsporozoite protein (CS) in Anopheles stephensi mosquitoes infected with Plasmodium falciparum malaria. J Histochem Cytochem. 1990;38:475–81.

    Article  CAS  PubMed  Google Scholar 

  38. Wang Q, Fujioka H, Nussenzweig V. Exit of Plasmodium sporozoites from oocysts is an active process that involves the circumsporozoite protein. PLoS Pathog. 2005;1:e9.

    Article  PubMed  PubMed Central  Google Scholar 

  39. Ferguson DJ, Balaban AE, Patzewitz EM, Wall RJ, Hopp CS, Poulin B, et al. The repeat region of the circumsporozoite protein is critical for sporozoite formation and maturation in Plasmodium. PLoS One. 2014;9:e113923.

    Article  PubMed  PubMed Central  Google Scholar 

  40. Roques M, Wall RJ, Douglass AP, Ramaprasad A, Ferguson DJ, Kaindama ML, et al. Plasmodium P-type cyclin CYC3 modulates endomitotic growth during oocyst development in mosquitoes. PLoS Pathog. 2015;11:e1005273.

    Article  PubMed  PubMed Central  Google Scholar 

  41. Bushell ES, Ecker A, Schlegelmilch T, Goulding D, Dougan G, Sinden RE, et al. Paternal effect of the nuclear formin-like protein MISFIT on Plasmodium development in the mosquito vector. PLoS Pathog. 2009;5:e1000539.

    Article  PubMed  PubMed Central  Google Scholar 

  42. Aly AS, Matuschewski K. A malarial cysteine protease is necessary for Plasmodium sporozoite egress from oocysts. J Exp Med. 2005;202:225–30.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  43. Ecker A, Bushell ES, Tewari R, Sinden RE. Reverse genetics screen identifies six proteins important for malaria development in the mosquito. Mol Microbiol. 2008;70:209–20.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  44. Aly AS, Vaughan AM, Kappe SH. Malaria parasite development in the mosquito and infection of the mammalian host. Annu Rev Microbiol. 2009;63:195–221.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  45. Curra C, Pace T, Franke-Fayard BM, Picci L, Bertuccini L, Ponzi M. Erythrocyte remodeling in Plasmodium berghei infection: the contribution of SEP family members. Traffic. 2012;13:388–99.

    Article  CAS  PubMed  Google Scholar 

  46. Engelmann S, Silvie O, Matuschewski K. Disruption of Plasmodium sporozoite transmission by depletion of sporozoite invasion-associated protein 1. Eukaryot Cell. 2009;8:640–8.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  47. Kariu T, Yuda M, Yano K, Chinzei Y. MAEBL is essential for malarial sporozoite infection of the mosquito salivary gland. J Exp Med. 2002;195:1317–23.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  48. Leite JA, Bargieri DY, Carvalho BO, Albrecht L, Lopes SC, Kayano AC, et al. Immunization with the MAEBL M2 domain protects against lethal Plasmodium yoelii infection. Infect Immun. 2015;83:3781–92.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  49. Dubremetz JF, Garcia-Reguet N, Conseil V, Fourmaux MN. Apical organelles and host-cell invasion by Apicomplexa. Int J Parasitol. 1998;28:1007–13.

    Article  CAS  PubMed  Google Scholar 

  50. Besteiro S, Dubremetz JF, Lebrun M. The moving junction of apicomplexan parasites: a key structure for invasion. Cell Microbiol. 2011;13:797–805.

    Article  CAS  PubMed  Google Scholar 

  51. Sharma P, Chitnis CE. Key molecular events during host cell invasion by Apicomplexan pathogens. Curr Opin Microbiol. 2013;16:432–7.

    Article  CAS  PubMed  Google Scholar 

  52. Hliscs M, Sattler JM, Tempel W, Artz JD, Dong A, Hui R, et al. Structure and function of a G-actin sequestering protein with a vital role in malaria oocyst development inside the mosquito vector. J Biol Chem. 2010;285:11572–83.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  53. Baum J, Richard D, Healer J, Rug M, Krnajski Z, Gilberger TW, et al. A conserved molecular motor drives cell invasion and gliding motility across malaria life cycle stages and other apicomplexan parasites. J Biol Chem. 2006;281:5197–208.

    Article  CAS  PubMed  Google Scholar 

  54. Sultan AA, Thathy V, Frevert U, Robson KJ, Crisanti A, Nussenzweig V, et al. TRAP is necessary for gliding motility and infectivity of Plasmodium sporozoites. Cell. 1997;90:511–22.

    Article  CAS  PubMed  Google Scholar 

  55. Mlambo G, Coppens I, Kumar N. Aberrant sporogonic development of Dmc1 (a meiotic recombinase) deficient Plasmodium berghei parasites. PLoS One. 2012;7:e52480.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  56. Martins YC, Carvalho LJ, Daniel-Ribeiro CT. Challenges in the determination of early predictors of cerebral malaria: lessons from the human disease and the experimental murine models. NeuroImmunoModulation. 2009;16:134–45.

    Article  CAS  PubMed  Google Scholar 

  57. Langhorne J, Quin SJ, Sanni LA. Mouse models of blood-stage malaria infections: immune responses and cytokines involved in protection and pathology. Chem Immunol. 2002;80:204–28.

    Article  CAS  PubMed  Google Scholar 

  58. Cirimotich CM, Dong Y, Garver LS, Sim S, Dimopoulos G. Mosquito immune defenses against Plasmodium infection. Dev Comp Immunol. 2010;34:387–95.

    Article  CAS  PubMed  Google Scholar 

  59. Barillas-Mury C. CLIP proteases and Plasmodium melanization in Anopheles gambiae. Trends Parasitol. 2007;23:297–9.

    Article  CAS  PubMed  Google Scholar 

  60. Whitten MM, Shiao SH, Levashina EA. Mosquito midguts and malaria: cell biology, compartmentalization and immunology. Parasite Immunol. 2006;28:121–30.

    Article  CAS  PubMed  Google Scholar 

  61. Christophides GK, Vlachou D, Kafatos FC. Comparative and functional genomics of the innate immune system in the malaria vector Anopheles gambiae. Immunol Rev. 2004;198:127–48.

    Article  CAS  PubMed  Google Scholar 

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Authors’ contributions

ASO, RNP, LCP, KMMC, YTP, BC, RCS carried out the infection experiments of the mosquitoes, participated in the microscopy analysis and drafted the manuscript. LMV, APMD, NBR, MGVB, WMM, AMC participated in the analysis of the results and drafted the manuscript. MVGL, NFCS, MJL, CBM, participated in the design of the study, performed the analysis and helped to draft the manuscript. PFPP conceived the study, in its design and coordination and write the manuscript. All authors read and approved the final manuscript.

Authors’ information

ASO and RNP are Ph.D. students of the Graduate Program in Health Sciences of the FIOCRUZ-Minas Gerais. KMMC, YTP and BC are Ph.D. students of the Graduate Program in Tropical Medicine of the UEA/FMT-HVD. APMD, LMV, NBR and LCP are pos-doctoral fellows. PFPP is a senior visiting fellow at the FMT-HVD supported by Amazonas State Research Support Foundation (FAPEAM). PFPP, NFCS, MGVB and MVGL are senior fellows from the Brazilian Council for Scientific and Technological Development (CNPq).

Acknowledgements

To the technicians of the Tropical Medicine Foundation Dr. Heitor Vieira Dourado namely: Iria C. Rodrigues and Sara G. M. da Silva for rearing mosquitoes and membrane-feeding assays; also acknowledgement for patient recruitment, blood collection and malaria thick smear preparation to Wellington Silva and Maria R. da Costa; and José E. A. Lessa for smear evaluation for malaria diagnoses. We thank the technicians da Foundation Oswaldo Cruz in Minas Gerais, Raphaela G. P. Araújo and Marcilio S. Tomaz for rearing and infecting mosquitoes. We would especially like to thank all the innumerable unnamed malarial patients for donating their blood samples, without whom this research project would not be possible.

Competing interests

The authors declare that they have no competing interests.

Availability of data and material

All data will be made available upon request to all interested researchers.

Consent for publication

All authors read and approved the final manuscript for publication.

Ethics approval and consent to participate

Patient selection criteria were determined by the National Institutes of Health international protocols, and to consent to be part of the research consent form that was approved by the Brazilian Ministry of Health, National Council of Health, National Committee of Ethics in Research (CONEP—approval number 3726).

Also, mice and chickens were maintained at the Animal Care Facility of the FIOCRUZ-MG were used in accordance to a study protocol approved by the FIOCRUZ Ethical Committee for Animal Use (CEUA; License Number LW30/10). It was followed the Public Health Service Animal Welfare Assurance #A4149-01 guidelines according to the National Institutes of Health (NIH) Office of Animal Care and Use (OACU) and NIH animal study protocol (ASP) approved by the NIH Animal Care and User Committee (ACUC), with approval ID ASP-LMVR5.

Funding

This study was partially funded by Bill and Melinda Gates Foundation (TransEpi Study), by grant from the National Institutes of Health R01AI031478 and by the following Brazilian agencies: Foundation of the Institute Oswaldo Cruz (FIOCRUZ), Strategic Programme for Supporting Health Research (PAPES V), Brazilian Council for Scientific and Technological Development (CNPq), Minas Gerais State Research Support Foundation (FAPEMIG) and Amazonas State Research Support Foundation (FAPEAM). ASO, RNP, KMMC, YTP and BC received Ph.D. scholarships from one of the following Brazilian agencies: FAPEAM, FIOCRUZ, CNPq and CAPES. APMD, LMV, NBR and LCP received pos-doctoral scholarships from CNPq or CAPES. PFPP, NFCS, MGVB and MVGL are senior fellows from CNPq.

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Correspondence to Paulo F. P. Pimenta.

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Orfano, A.S., Nacif-Pimenta, R., Duarte, A.P.M. et al. Species-specific escape of Plasmodium sporozoites from oocysts of avian, rodent, and human malarial parasites. Malar J 15, 394 (2016). https://0-doi-org.brum.beds.ac.uk/10.1186/s12936-016-1451-y

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