Abstract
Background
Haemoproteus parasites are widespread, and some species cause disease in wild and domestic birds. However, the insect vectors remain unknown for the majority of species and genetic lineages of avian Haemoproteus. This information is crucial for better understanding the biology of haemoproteids, the epidemiology of haemoproteosis, and the development of morphological characters of sporogonic stages in wildlife haemosporidian parasites. It remains unclear whether the specificity of Haemoproteus parasites for vectors is broad or the transmission of a given parasite can be restricted to a single or few species of vectors. The aim of this study was to examine the sporogonic development of four species of common European avian haemoproteids in the common biting midge Culicoides impunctatus.
Methods
Wild-caught females of C. impunctatus were infected experimentally by allowing them to take blood meals on naturally infected Muscicapa striata, Cyanistes caeruleus, Ficedula hypoleuca and Motacilla flava harbouring mature gametocytes of Haemoproteus balmorali (genetic lineage hSFC9), H. majoris (hPARUS1), H. motacillae (hYWT1) and H. pallidus (hPFC1), respectively. Infected insects were collected, maintained under laboratory conditions and dissected daily in order to detect the development of ookinetes, oocysts and sporozoites. Microscopic examination and polymerase chain reaction based methods were used to detect the parasites. Bayesian analysis was applied to identify phylogenetic relationships among Haemoproteus lineages.
Results
All investigated parasites completed sporogony in C. impunctatus, indicating broad susceptibility of this biting midge for numerous Haemoproteus parasites. Ookinetes, oocysts and sporozoites were reported, described and compared morphologically. The investigated parasite species can be distinguished at the sporogony stage, particularly with regards to the morphology and rate of development of mature ookinetes. Analysis of data from the literature, and this study, shows that 12 genetically distantly related Haemoproteus parasites complete sporogony in C. impunctatus.
Conclusions
Susceptibility of C. impunctatus is broad for Haemoproteus parasites, indicating that this biting midge is an important natural vector of numerous species of avian haemoproteids in Europe. Some Haemoproteus species can be readily distinguished using morphological characters of ookinetes and sporozoites, as well as the rate of ookinete development. These characters can be used for the identification of Haemoproteus species during sporogony in vectors, and are worth more attention in these parasite taxonomy studies at the species levels.
Electronic supplementary material
The online version of this article (doi:10.1186/s13071-017-2317-z) contains supplementary material, which is available to authorized users.
Keywords: Sporogony, Haemoproteus, Birds, Culicoides impunctatus, Vectors, Transmission
Background
Species of Haemoproteus are widespread and infect birds throughout the world [1–4]. Recent molecular studies have revealed the great diversity of haemosporidian parasites [5, 6]; however, the insect vector species of the majority of avian Haemoproteus parasites as well as their role in transmission remain unknown [2, 7]. Information about the sporogonic development of over 90% of the described avian Haemoproteus species is absent or remains fragmentary [1, 8]. Experimental studies on the transmission of Haemoproteus species by biting midges are difficult to design, because of the difficulties to infect, rear and dissect these tiny insects.
Currently used PCR-based tools markedly increased the determination of significant links between parasite lineages and blood-sucking insects [9–11]. However, this methodology does not distinguish invasive (sporozoites) and non-invasive (blood forms, ookinetes and oocysts) stages, and thus cannot provide conclusive evidence regarding whether the PCR-positive insects can act as vectors. In other words, the results of solely molecular diagnostics indicate only the possibility as natural vectors [8, 12–15]. Many recent studies used solely PCR-based tools in vector studies of Haemoproteus [9, 16, 17] and Plasmodium [10, 13, 18, 19] parasites in wild-caught blood-sucking dipteran insects. Results of these studies simplify the search for possible vectors due to a narrowing of the range of potential blood-sucking insects, which might act as vectors. However, the detection of infective sporozoites is required to prove that a given insect species can act as a vector. This is a particularly sensitive issue, due to the possibility of long-lasting abortive sporogonic development of Haemoproteus parasites in resistant insects. Recent experimental studies show that PCR-based diagnostics should be used carefully in vector studies because they can detect DNA of parasites in insects for several weeks after the initial infection. Moreover, they do not identify abortive sporogonic development and thus cannot prove if the insects are competent vectors of the parasites [11].
Research on haemoproteids and their vectors is important because some Haemoproteus parasites have been reported to cause disease and even lethal pathology in non-adapted avian hosts [20–26]. Moreover, intense infections of these parasites are virulent to the blood-sucking insects and can cause their mortality [27–30]. Only few experimental studies have focused on the transmission of Haemoproteus parasites in wildlife [1, 31, 32], posing an obstacle to understanding the epidemiology of diseases caused by these infections and the patterns of their distribution in wildlife. The available information about sporogony of Haemoproteus species and knowledge on their transmission and specificity for blood-sucking insects is currently insufficient.
Recently, a simple methodology of experimental infection of wild-caught Culicoides biting midges with Haemoproteus parasites was developed [1], and the sporogony of nine Haemoproteus species was investigated in Culicoides impunctatus biting midges [14, 15, 27, 33]. We predicted that many other common avian haemoproteids can be transmitted by this insect. To test this hypothesis, we examined the sporogony of four additional Haemoproteus parasites belonging to the subgenus Parahaemoproteus, Haemoproteus balmorali (cytochrome b genetic lineage hSFC9), Haemoproteus majoris (hPARUS1), Haemoproteus motacillae (hYWT1) and Haemoproteus pallidus (hPFC1) using the same methodology. These haemoproteid infections are widespread in Europe [1, 34]. The results have provided an opportunity for broad comparative research. The aim of this study was to follow sporogony of these parasites in C. impunctatus, which is widespread in Europe and willingly takes avian blood meals [33, 35]. Additionally, we reviewed previous studies addressing sporogonic development of Haemoproteus species in the same insect species, and provide comparative analysis of the morphological features of sporogonic stages of investigated parasites.
Methods
Collection of material and microscopic examination
This study was carried out at the Biological Station “Rybachy” of the Zoological Institute of the Russian Academy of Sciences on the Curonian Spit of the Baltic Sea (55°15’N, 20°86’E) between 23rd May and 29th June in 2015. Birds were captured by mist nets, stationary funnel traps [36] and nest box traps [37].
About 50 μl of blood was taken in heparinized microcapillaries by puncturing the brachial vein. A small drop was used for preparation of two blood smears from each individual. Residual blood was stored in SET-buffer for molecular analysis [38]. The smears were air-dried, fixed in absolute methanol and stained with Giemsa stain solution, as described by Valkiūnas et al. [39]. Approximately 100–150 fields were examined at low magnification (400×), and then at least 100 fields were studied at high magnification (1000×). Intensity of parasitemia was estimated as a percentage by actual counting of the number of parasites per 1000 erythrocytes or per 10,000 erythrocytes if infections were light (< 0.1%), as recommended by Godfrey et al. [40]. Haemoproteus parasites were identified according to Valkiūnas [1] and Dimitrov et al. [34]. Naturally infected birds with single infections of corresponding parasite species were kept indoors in a vector-free room under controlled conditions [20 ± 1 °C, 50–60% relative humidity (RH), the natural light-dark (L/D) photoperiod] and fed with standard diet for seed-eating or insectivorous bird species. These birds were used as donors to infect biting midges. All birds survived until the end of this study and were released in the same area as captured after experiments.
Sampling and experimental infections of biting midges
Experimental infection of biting midges with Haemoproteus parasites was performed near Lake Chaika, located close to the village Rybachy, where the density of biting midges is high [41]. All experimental infections were performed between 10th and 20th June when the first generation of C. impunctatus predominate [42]. Unfed flies (wild-caught controls) were collected by entomological nets at the same study site before experiments. Approximately 100 wild-caught females were sampled, fixed in 70% ethanol and used for species identification, which was done using morphological characters [43]. Possible natural infection by Haemoproteus parasites in the wild-caught insects was tested using PCR-based methods (see description below).
Wild C. impunctatus females were infected by allowing them to take blood meals on four naturally infected birds harbouring single infections of different species of Haemoproteus parasites [1, 14]. We used one individual of each spotted flycatcher Muscicapa striata, blue tit Cyanistes caeruleus, pied flycatcher Ficedula hypoleuca and blue-headed wagtail Motacilla flava harbouring mature gametocytes of H. balmorali (hSFC9), H. majoris (hPARUS1), H. motacillae (hYWT1) and H. pallidus (hPFC1), respectively. Low level parasitemia (< 1%) was present in all donor birds throughout the course of the experiment. Each bird was used 2–3 times for infection of midges. One uninfected common crossbill Loxia curvirostra was used to feed a control group of biting midges during experiments. Birds were hand held using rubber gloves. Biting midges were allowed to feed on the head of naturally infected bird for approximately 15 min. Culicoides impunctatus females willingly took blood meals on the feather-free region of bird’s head. Once several flies started to feed on a bird’s head, it was inserted into an insect cage. The cages (12 × 12 × 12 cm) were made of fine-mesh bolting silk. A zip fastener was sewn into one wall of the cage to permit entry of the bird’s head. Engorged midges flew off the bird’s head on the wall of the insect cage, which was then closed. The cages with engorged flies were transported to the laboratory and held at temperatures ranging between 14 °C (at night) and 24 °C (during the day), 60 ± 2% RH and photoperiod of 17:7 h L/D).
Midges were supplied with 5–10% saccharose solution; pads of cotton wool moistened in this solution were placed on the top of each insect cage. Eighty-two C. impunctatus biting midges infected with H. balmorali (n = 17 infected insects), H. majoris (n = 20), H. motacillae (n = 19) and H. pallidus (n = 26) were dissected for detection of ookinetes, oocysts and sporozoites. Twenty engorged C. impunctatus biting midges were used as controls during experiments.
Dissection of biting midges and preparation of ookinetes, oocysts and sporozoites specimens
Details of the dissection and staining methods of ookinetes, oocysts and sporozoites were described in [1, 14, 44]. Briefly, infected females were anesthetized by placing them into a tube with a cotton pad wetted with 96% ethanol and closed for several minutes. Dissection was performed under the binocular stereoscopic microscope Olympus SZX10 (Tokyo, Japan). To eliminate contamination of samples, we used a new dissecting needle for each dissected biting midge.
We examined midgut contents for ookinetes between 1 h post-infection (hpi) and 4 days post-infection (dpi), midgut wall for oocysts 2–5 dpi, and salivary glands for sporozoites 5–12 dpi. Content of the midgut was extracted by cutting a terminal segment of the abdomen and pressing the content out on the glass slide. The midgut content was mixed with drop of normal saline and a thin smear was prepared; the smears were dried in the air, fixed with methanol, and stained with 10% Giemsa stain, in the same way as blood films.
Oocysts were visualised by adding a minute drop of 2% mercurochrome solution on freshly prepared midgut preparation, which was then covered with a coverslip. Midguts with oocysts were fixed in 10% formalin solution and then in 70% ethanol for permanent preparations [1]. Thereafter midgut preparations were washed with distilled water, stained with Ehrlich’s haematoxylin, steeped in water containing a 0.45 g of sodium bicarbonate and differentiated with acid ethanol and then again steeped in water containing sodium bicarbonate. Then, each preparation was dehydrated with 70 and 96% ethanol, cleared by putting a drop of clove oil and xylene over the preparation, and finally mounted in Canada balsam, covered with a cover slip and dried in the air for approximately 1 week.
Preparations of sporozoites were made after extraction of salivary glands from biting midges. Insects head and thorax were placed in a small drop of saline. Salivary glands were gently pressed out from the thorax, crushed using a needle and mixed with a tiny drop of saline. Preparations were dried in the air, fixed with absolute methanol, and stained with 4% Giemsa stain. After dissection, all residual parts of insects were placed in 96% ethanol for PCR-based confirmation of the parasite lineages and insect species (see description below).
Representative preparations of blood stages (accession numbers 48,948–48951NS), ookinetes (48952–48955NS), oocysts (48956–48958NS) and sporozoites (48959–48962NS) were deposited in Nature Research Centre, Vilnius, Lithuania. The statistical analyses of parasites sporogonic stages were carried out using the “Statistica 7” package. Student’s t-test for independent samples was used to determine statistical significance between mean linear parameters of parasite features. A P-value < 0.05 was considered significant.
DNA extraction, PCR and sequencing
The total DNA was extracted from all samples (bird blood and biting midges) using an ammonium acetate extraction method [45]. For the parasite lineage determination, we used a nested PCR protocol [39, 46]. A segment of parasite mitochondrial cytb gene fragment was amplified using initial primers HAEMNFI and HAEMNR3 which amplify fragments of cytb gene of haemosporidians belonging to genera Haemoproteus, Plasmodium and Leucocytozoon. For the second PCR, we used HAEMF and HAEMR2 primers, which are specific to Haemoproteus and Plasmodium spp. All amplification procedures were in accord to the protocols by [38, 46]. Additionally, we used primers reported by Beadell et al. [47] for cytb gene fragment amplification from investigated bird blood to confirm that birds were infected by a single Haemoproteus infection. The amplification was evaluated by running 1.5 μl of the final PCR product on a 2% agarose gel. One negative control (nuclease-free water), one positive control (Haemoproteus spp. microscopy positive blood sample in the case of blood testing, and thorax of biting midge experimentally infected with Haemoproteus belopolskyi, in the case of biting midge testing) were used per every 8 samples to control for false amplifications. Mixed infections were determined both by the microscopic examination of blood films and the visualization of double-base calling in sequence electropherograms.
Fragments of DNA from all positive samples were sequenced from the 5′- end with the primer HAEMF using dye terminator cycle sequencing (big dye) and loaded on an ABI PRISM 3100 capillary sequencing robot (Applied Biosystems, Foster City, California) [46]. The “Basic Local Alignment Search Tool” (National Centre for Biotechnology Information website: http://www.ncbi.nlm.nih.gov/BLAST) was used to determine genetic lineages of detected DNA sequences, which were deposited in GenBank (KY451714–KY451721).
DNA extracted from individual biting midges was used to confirm the identification of C. impunctatus used in our experiments. We applied the insect specific primers LCO149 and HCO2198 to amplify a fragment of cytochrome c oxidase subunit 1 (cox1) of mitochondrial DNA [48]. Sequences corresponded to the C. impunctatus DNA sequences available in GenBank (KY627800).
Phylogenetic analysis
To define the phylogenetic placement of obtained lineages, we used amplified cytb sequences (478 bp fragments) and available DNA fragments from the MalAvi database (http://mbio-serv2.mbioekol.lu.se/Malavi/). Bayesian phylogeny was constructed using MrBayes version 3.1.2 [49]. We used the General Time Reversible Model including rate variation among sites (GTR + I + G), as selected model of sequence evolution suggested by the mrModeltest 2v software [50]. The analysis was run for a total of 8 million generations with a sample frequency every 100 generations. Before constructing a majority consensus tree, 25% of the initial trees in each run were discarded as “burn in” periods. The remaining trees were used to construct a Majority rule consensus tree. Phylogeny was visualized using Tree View 1.6.6 (http://evolution.genetics.washington.edu/phylip/software.html). The sequence divergence between lineages was calculated using a Jukes-Cantor model of substitution, with all substitutions weighted equally, implemented in the program MEGA 4 [51].
Results
Microscopic examination and PCR-based testing of wild-caught insects and birds
All biting midges used in experiment belonged to C. impunctatus. PCR-based analysis did not detect natural infections of Haemoproteus parasites in wild-caught biting midges, indicating that natural infection was unlikely in wild-caught experimental insects.
Experimental birds (parasite donors) were naturally infected with single Haemoproteus infections: M. striata was parasitized by H. balmorali (lineage hSFC9) (Fig. 1c-g), C. caeruleus by H. majoris (hPARUS1) (Fig. 1b-f), M. flava by H. motacillae (hYWT1) (Fig. 1d-h) and F. hypoleuca by H. pallidus (hPFC1) (Fig. 1a-e). Both microscopy and two PCR assays revealed single Haemoproteus infections in all donor birds. No double-base calling in sequence electropherograms were detected.
Sporogony research
Microscopic examination confirmed that H. balmorali (hSFC9) (Fig. 1c-t), H. majoris (hPARUS1, Fig. 1b-s), H. motacillae (hYWT1, Fig. 1d-u) and H. pallidus (hPFC1, Fig. 1a-r) completed sporogony in C. impunctatus biting midges. PCR and sequencing confirmed the presence of corresponding genetic lineages in experimentally infected C. impunctatus biting midges. The morphometric parameters of ookinetes, oocysts and sporozoites of all parasite species are given in Table 1.
Table 1.
Feature | Measurementsa | |||
---|---|---|---|---|
H. pallidus | H. majoris | H. motacillae | H. balmorali | |
Ookinete | ||||
Length | 7.5–9.6 (8.3 ± 0.5) | 9.4–14.4 (12.1 ± 1.5) | 11.1–20.0 (16.7 ± 2.5) | 15.0–21.4 (18.0 ± 1.7) |
Width | 2.1–4.3 (3.0 ± 0.6) | 1.4–3.0. (2.1 ± 0.4) | 1.3–3.3 (2.3 ± 0.6) | 1.4–3.0 (2.3 ± 0.4) |
Area | 12.3–24.8 (16.9 ± 3.3) | 11.8–33.3 (19.5 ± 5.7) | 20.2–47.4 (31.5 ± 8.8) | 20.7–49.7 (32.3 ± 7.8) |
Oocyst | ||||
Min. diameter | 2.7–4.6 (3.5 ± 0.6) | 2.7–4.5 (3.6 ± 0.7) | 3.5–6.1 (4.8 ± 1.0) | 3.0–5.1 (4.2 ± 0.6) |
Max. diameter | 3.6–5.2 (4.3 ± 0.5) | 3.6–6.0 (4.9 ± 0.8) | 5.4–7.1 (6.3 ± 0.6) | 3.8.1–6.9 (5.2 ± 0.8) |
Area | 7.3–16.0 (11.7 ± 2.5) | 7.7–18.7 (14.5 ± 4.2) | 17.4–33.4 (23.7 ± 6.0) | 7.8–25.3 (17.7 ± 5.0) |
Sporozoite | ||||
Length | 6.2–11.5 (8.9 ± 1.3) | 6.6–13.5 (9.5 ± 1.5) | 8.7–12.7 (10.2 ± 0.9) | 7.7–12.0 (11.0 ± 1.0) |
Width | 0.6–1.4 (1.0 ± 0.2) | 0.9–1.5 (1.1 ± 0.2) | 0.7–1.7 (1.0 ± 0.1) | 0.6–1.2 (0.9 ± 0.1) |
Area | 5.0–9.8 (7.3 ± 1.3) | 5.7–13.2 (8.2 ± 2.0) | 5.2–11.5 (8.2 ± 1.6) | 5.0–9.5 (7.3 ± 1.1) |
aMeasurements of ookinetes (n = 21, methanol-fixed preparations 12–24 hpi), oocysts (n = 8–12, formalin-fixed preparations of mature parasites 2.5–4 dpi) and sporozoites (n = 21, methanol-fixed preparations 8 dpi)
Ookinetes of H. pallidus (Fig. 1i) developed quickly. Mature ookinetes of this parasite (Fig. 1i) were seen in the midgut contents of experimentally infected flies between 4 and 12 hpi. After 12 hpi, they were absent from midgut contents. This should be taken into consideration in future sporogony studies of this parasite. Fully grown ookinetes are carrot-like in form, with one end broader than another. The nucleus is located slightly off-centre (Fig. 1i). A small vacuole was visible near the nucleus in 40% of reported ookinetes. Pigment granules in ookinetes are located close to the narrower end, and rarely at the opposite end or close to both ookinete ends. Ookinetes of H. pallidus are significantly shorter than H. majoris (Student’s test, t (40) = 10.87, P < 0.0001), H. motacillae (t (40) = 15.03, P < 0.0001) and H. balmorali (t (40) = 24.29, P < 0.0001) ookinetes (Table 1, Additional file 1: Table S1). Mean area of H. pallidus and H. majoris ookinetes does not differ significantly (P = 0.07), but area of H. pallidus ookinetes was significantly smaller than area of H. motacillae (t (40) = 7.11) and H. balmorali (t (40) = 8.34) ookinetes (both P < 0.0001).
Ookinetes of H. majoris (Fig. 1j) developed more slowly as compared to H. pallidus. They were seen between 12 and 24 hpi. Many large vacuoles were visible in the H. majoris ookinetes. Pigment granules are located in narrower end of young ookinetes (Fig. 1j). Fully developed ookinetes of H. majoris, H. balmorali and H. motacillae are elongate worm-like bodies, with the nucleus located slightly off-centre. The ookinetes of H. balmorali possess prominent vacuoles in the cytoplasm of the parasite (Fig. 1k). Ookinetes of H. motacillae (Fig. 1l) and H. balmorali (Fig. 1k) developed more slowly than those of H. pallidus and H. majoris; they were seen between 24 hpi and 1.5 dpi (Table 2).
Table 2.
Haemoproteus species | mtDNA lineage | Bird species | Report of sporogonic stage in experimentally infected femalesa | Reference | ||
---|---|---|---|---|---|---|
Ookinetes | Oocysts | Sporozoites | ||||
H. balmorali | –b | Muscicapa striata | 1.5 | 3–4 | 5 | [33] |
H. balmorali | hSFC9 | Muscicapa striata | 1–1.5 | 4–6.5 | 6.5–10 | This study |
H. belopolskyi | hHIICT1 | Hippolais icterina | 1–3 | 3–6 | 7–12 | [14] |
H. dolniki | – | Fringilla coelebs | 1.5 | 3–4 | 5 | [33] |
H. fringillae | – | Fringilla coelebs | 1–2 | 3–4 | 5–8 | [27] |
H. lanii | – | Lanius collurio | 1–2 | 3–4 | 5–8 | [27] |
H. majoris | hPARUS1 | Cyanistes caeruleus | 12–24d | 2–4.5 | 6.5–7.5 | This study |
H. minutus | hTURDUS2 | Turdus merula | 1–4d | 3–6 | 7–12 | [14] |
H. motacillae | hYWT1 | Motacilla flava | 1–1.5 | 3–4 | 5–8 | This study |
H. noctuae | hCIRCUM01 | Asio otus | 12d | – | 7–9 | [15] |
H. pallidus | hPFC1 | Ficedula hypoleuca | 4–12d | 1.5–2.5 | 6.5–7.5 | This study |
H. parabelopolskyi c | – | Sylvia atricapilla | 1–1.5 | 3 | 5–12 | [27, 67] |
H. tartakovskyi | – | Loxia curvirostra | 1.5 | 3–4 | 5 | [33] |
aTime of sporogonic development is given in dpi, except several cases of ookinete development, which are given in hpi
bData are absent
cOriginally described as Haemoproteus belopolskyi [67]
dHours post - infection
In different parasite species, oocysts were first seen in the midgut wall 2–4 dpi (Table 2), and they were reported in the midgut preparations 4–6 dpi (Fig. 1m-p). Oocysts appeared as small roundish bodies, and pigment granules were visible in some of them. In flattened midgut preparations, there was no significant difference in the mean area of oocysts (Table 1) among all parasites species (P > 0.05, Additional file 1: Table S2).
Sporozoites of H. pallidus (Table 1, Fig. 1r) and H. majoris (Fig. 1s) were reported in the salivary glands preparations between 6 and 7 dpi, and sporozoites of H. motacillae (Fig. 1u) and H. balmorali (Fig. 1t) between 5 and 10 dpi. Sporozoites of all species are fusiform bodies with slightly off-centre located nuclei and approximately equally pointed ends. There were no differences discernible in the length or area between sporozoites of H. pallidus and H. majoris and between H. majoris and H. motacillae (P > 0.05). However, the sporozoites of H. pallidus are significantly shorter (t (40) = 3.83, P = 0.0004) and smaller (t (40) = 2.06, P = 0.046) in area than those of H. motacillae and shorter (t (40) = 4.84, P < 0.0001) than sporozoites of H. balmorali (Table 1). Sporozoites of H. balmorali are longer than sporozoites of H. majoris (t (40) = 2.57, P = 0.014). Area of sporozoites significantly differs between H. motacillae and H. balmorali (t (40) = 2.16, P = 0.037, Table 1, Additional file 1: Table S3).
Phylogenetic analysis
Bayesian analysis revealed that the investigated parasite lineages are distantly related (Fig. 2), with genetic divergence among them ranging between 4.3 and 6.4%. Three examined lineages cluster in separate well-defined monophyletic subclades representing morphologically characterized species; these are clades of several lineages belonging to H. motacillae, H. balmorali and H. majoris (Fig. 2). Haemoproteus pallidus (hPFC1) is phylogenetically the most distantly related lineage of the four parasites, and it is a representative of two morphologically characterized lineages of this morphospecies (Fig. 2). Phylogenetic analysis concurs with the marked morphological differences and patterns of ookinete development between H. pallidus and the three other examined Haemoproteus species.
Discussion
The first studies on development of Haemoproteus parasites in Culicoides insects were carried out in the twentieth century [52–54]. They were reviewed by [1, 2, 8]. The studies on the development of haemoproteids in blood-sucking insects are few in comparison to numerous and detailed descriptions of these parasites in vertebrate hosts. In recent years, several studies provided detailed information about the sporogonic development of Haemoproteus spp. in vectors [1, 2, 8] however, information on this subject is crucial for better understanding the epidemiology of haemoproteosis [20, 22–24].
This study shows that complete sporogony of H. balmorali (hSFC9), H. majoris (hPARUS1), H. motacillae (hYWT1) and H. pallidus (hPFC1) occurs in the C. impunctatus biting midge, and these blood-sucking insects likely are natural vectors. Ideally, these results should be tested by transmission experiments using sporozoites developed in C. impunctatus. However, such experiments are difficult to perform due to the difficulties in obtaining and maintaining non-infected wild birds in captivity and permit obstacles in experimental research with wild birds. Culicoides impunctatus is common in Europe and is abundant at our study site [33, 41, 42, 55]. Culicoides impunctatus was often considered as mainly a mammalophilic species [56], but it willingly takes blood meal on birds [14, 15, 35, 41, 42]. According to former studies (Table 2), C. impunctatus is a competent vector of Haemoproteus lanii, Haemoproteus fringillae, H. balmorali, Haemoproteus tartakovskyi, Haemoproteus dolniki, Haemoproteus parabelopolskyi (genetic lineages of these parasites were not determined) and also Haemoproteus minutus (hTURDUS2), Haemoproteus belopolskyi (hHIICT1) and Haemorpoteus noctuae (hCIRCUM01). This study adds four Haemoproteus species, with their molecularly defined genetic lineages, to the list of parasites completing sporogony in C. impunctatus biting midges, indicating the susceptibility of this insect to numerous haemoproteid species (Table 2). These insects are worth more attention in studies of the transmission and epidemiology of avian Haemoproteus spp. The role of other species of Culicoides in the transmission of Haemoproteus species remains unknown at the study site.
Recently, it was shown that H. tartakovskyi (hSISKIN1), Haemoproteus syrnii (hCULCIB01) and H. noctuae (hCIRCUM01) complete development in Culicoides nubeculosus biting midges [15, 57]. Former experimental studies indicated that H. fringillae develops sporozoites in Culicoides crepuscularis, C. stilobezziodes and C. sphagnumensis [2, 53]. Interestingly, C. sphagnumensis is a vector of 4 haemoproteids (Haemoproteus mansoni, H. velans, H. fringillae and H. danilewskyi) [2, 53, 58]. Culicoides stilobezziodes is a vector of 3 haemoproteids (H. velans, H. fringillae and H. danilewskyi) [53, 58, 59]. This is in accordance with results of this study, indicating susceptibility of the same Culicoides species to many Haemoproteus parasites.
Several studies have examined the in vitro gametogenesis and development of ookinetes in Haemoproteus species. Information about the development of haemoproteids both in vivo and in vitro is available for H. fringillae, H. pallidus, H. parabelopolskyi, H. tartakovskyi, H. balmorali, H. dolniki, H. majoris, H. lanii, H. minutus ([1, 60–62], this study) and H. motacillae (hYWT1) ([34], this study). The patterns of development of the same species in vivo and in vitro are similar, however some differences were recorded. For example, morphological differences during development of the same parasite species in vivo and in vitro were observed. Mainly, vacuoles were not reported in ookinetes of H. pallidus during in vitro development [60], but were often seen in this study. It is possible that these differences are due to differences of in vivo and in vitro conditions (midgut of vector vs artificial medium in a microtube). Development of Haemoproteus ookinetes can be readily initiated in vitro, however the results of such studies should be interpreted with caution, and some questions regarding the host-parasite interactions can be answered only using experiments performed in natural environments (vectors).
It is difficult to compare the rate of the parasites’ development using data from different studies because it depends markedly on temperature, which varied in the available studies. However, some patterns were reported. Available data show that H. minutus, H. pallidus, H. majoris and H. noctuae develop both in vivo and in vitro particularly fast, with mature ookinetes present within 0.5 dpi (Table 2). All other parasites tested developed mature ookinetes 1 dpi. This should be taken into consideration during haemoproteid vector research aiming to study mature ookinetes in midgut of insects.
The morphology of ookinetes differed in the four studied species (Fig. 1j- l). It appears that parasites which develop most rapidly have the smallest ookinetes. For example, ookinetes of H. minutus (hTURDUS2) [14] and H. pallidus (hPFC1) (this study) were exceptionally small (< 10 μm in length on average), and the time of their maturation in vivo is significantly faster (1–12 hpi) than of H. majoris (12 hpi) or H. motacillae ookinetes (24–36 hpi) (Table 2). The latter parasites have significantly larger mature ookinetes, in both length and area (Table 1) ([14], this study). Interestingly, H. minutus (hTURDUS2) and H. pallidus (hPFC1) are phylogenetically closely related parasites (Fig. 2), with a genetic divergence of only 0.9% in cytb gene. Small genetic differences between these two possibly relatively recently diverged parasites are in accordance with the similar morphology of their ookinetes and the rate of their ookinete development in comparison to other investigated species. It is thus possible that ookinetes of phylogenetically closely related haemosporidian species should have similar morphologies and rates of ookinete development. However, at present it is unclear to what extent phylogenetic differences are reflected by sporogonic stages; this needs more extensive research with phylogenetically closely and distantly related parasites.
A recent study by Nilsson et al. [63] used a multigene phylogenetic analysis to show that five H. majoris cytb lineages are closely related and cluster together, but likely represent distinct biological species. Mechanisms of reproductive isolation contributing to the maintenance of these closely related lineages at the same study site remain unclear, and they might be related to the different abilities and/or rates to develop in vectors. It worth mentioning that H. pallidus and H. motacillae complete sporogonic development in C. impunctatus, which can act as a vector at our study site. These parasites are prevalent in adult birds, but are extremely rare (H. pallidus) or absent (H. motacillae) in juveniles of the same bird species at our study site [1, 64]. Obstacles to the transmission of H. pallidus and H. motacillae remain unclear. Culicoides impunctatus biting midges are widespread at our study site and the period of their imago activity coincides with the birds’ breeding period [42]. The observed overlapping of vector activity and the appearance of birds’ offspring should favour transmission of infections to juvenile birds. However, this apparently does not happen, and the absence of some haemoproteids in juvenile birds raise questions about the presence of other important factors preventing transmission. For instance, there are no records of H. motacillae in juvenile yellow wagtails in northern Europe. At our study site, the absence of H. motacillae in juvenile birds can probably be explained by the different habitats occupied by vectors and the yellow wagtails. Culicoides impunctatus lives and breeds in moist forests [41], while the yellow wagtail inhabits meadows and wet pastures [65]. According to the literature [66], C. impunctatus midges only fly within 75 m from their breeding areas. Thus, differences in occupied habitats can separate insect and vertebrate hosts and act as an ecological barrier for transmission in breeding areas. Certainly, ecological factors require more attention in studies of transmission of haemosporidian parasites.
This study adds four haemoproteid species that complete sporogony in C. impunctatus and strengthen the published information, indicating that sporogony of Haemoproteus parasites is not restricted to a single species of biting midges [2]. Many Haemoproteus species can complete sporogonic development in the same species belonging to the genus Culicoides ([1, 2], this study). Our findings together with several other recent studies show that one species of biting midge is capable of transmitting many species of Haemoproteus ([1, 2, 8], this study). This conclusion is important epidemiologically. It could explain the high frequency of haemoproteid co-infections in some bird species, for example in Turdidae birds [1], and is worthy of additional investigation.
The following steps can be recommended in research aiming to better understand the patterns of transmission of avian haemosporidian parasites at a study site. First, the prevalence and identity of Haemoproteus parasites should be determined using morphological and PCR-based methods in juvenile and adult birds. Secondly, one should use molecular methods to detect haemosporidian parasites in wild caught biting midges to provide data about links between parasites and possible vectors. Thirdly, it is necessary to prove that a given parasite lineage develops to the sporozoite stage in possible vectors [1, 14, 15]. Thus, a combination of microscopic, molecular and ecological approaches is needed in determining the natural vectors and patterns of parasite transmission. This methodology is essential for better understanding the epidemiology of avian haemoproteosis.
Conclusions
Culicoides impunctatus is the likely natural vector of H. pallidus (hPFC1), H. majoris (hPARUS1), H. motacillae (hYWT1) and H. balmorali (hSFC9), and is susceptible to nine other species of avian haemoproteids. Phylogenetic analyses using partial cytb sequences is helpful in predicting possible vectors and some patterns of sporogonic development (morphology, rate of ookinete development), especially in closely related genetic lineages of Haemoproteus species. Morphological characters of ookinetes and sporozoites, as well as the rate of ookinete development, are markedly different in some Haemoproteus species, and these characters are worth more attention in the taxonomic research of haemoproteids at the species levels.
Acknowledgments
We would like to thank the staff of the Biological Station “Rybachy”, for assistance in the field. The director of the Biological Station “Rybachy” Nikita Chernetsov is acknowledged for generously providing facilities for the experimental research, and Elena Platonova for participation in fieldwork. We are grateful to Prof. Ravinder Sehgal for correcting the English. The experiments described herein comply with the current laws of Lithuania and Russia.
Funding
This study was funded partly by the Research Council of Lithuania (MIP038/2015), the Russian Foundation for Basic Research (grant# 15–04-00417 to A.M.) and the Zoological Institute of Russian Academy of Science (registered research project No AAAA-A16–116123010004-1).
Availability of data and materials
The datasets supporting the conclusions of this article are included within the article and Additional file 1: Tables S1, S2 and S3. DNA sequences were deposited in the GenBank database (KY451714–KY451721).
Abbreviations
- dpi
Days post-infection
- hpi
Hours post-infection
- L/D
Light-dark
- RH
Relative humidity
Additional file
Authors’ contributions
Experimental conception and design: RŽ, VP and GV; donor bird collection and testing: TAI, VP, MYM and AM; biting midge fieldwork: RŽ and VP; biting midge dissection and laboratory maintenance and preparation of specimens: RŽ; molecular analysis: RB; phylogenetic analysis and its discussion: VP, GV, RŽ and RB; paper writing: RŽ, VP and GV. All authors read and approved the final manuscript.
Ethics approval
Experimental procedures of this study were approved by the International Research Cooperation.
Agreement between the Biological Station “Rybachy” of the Zoological Institute of the Russian Academy of Sciences and Nature Research Centre (25–05-2010). All efforts were made to minimize handling time and potential suffering of birds. None of the experimental birds suffered apparent injury during the experiments.
Consent for publication
Not applicable.
Competing interests
The authors declare that they have no competing interests.
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Footnotes
Electronic supplementary material
The online version of this article (doi:10.1186/s13071-017-2317-z) contains supplementary material, which is available to authorized users.
Contributor Information
Rita Žiegytė, Email: rita.ziegyte@gamtostyrimai.lt.
Mikhail Yu. Markovets, Email: mikhail.markovets@gmail.com
Rasa Bernotienė, Email: bern.rasa@gmail.com.
Andrey Mukhin, Email: a.l.mukhin@gmail.com.
Tatjana A. Iezhova, Email: tatjana@ekoi.lt
Gediminas Valkiūnas, Email: gedvalk@ekoi.lt.
Vaidas Palinauskas, Email: vaidas@ekoi.lt.
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Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Data Availability Statement
The datasets supporting the conclusions of this article are included within the article and Additional file 1: Tables S1, S2 and S3. DNA sequences were deposited in the GenBank database (KY451714–KY451721).