Hostname: page-component-cd9895bd7-p9bg8 Total loading time: 0 Render date: 2024-12-29T01:31:26.162Z Has data issue: false hasContentIssue false

Morphological and molecular characterization of Prosthogonimus falconis n. sp. (Trematoda; Prosthogonimidae), found in a peregrine falcon (Falco peregrinus) (Aves: Falconidae) in the United Arab Emirates

Published online by Cambridge University Press:  07 January 2022

R.K. Schuster*
Affiliation:
Central Veterinary Research Laboratory, Dubai, UAE
B. Gajic*
Affiliation:
College of Agriculture and Veterinary Medicine, UAE University, Al Ain, UAE
M. Procter
Affiliation:
College of Agriculture and Veterinary Medicine, UAE University, Al Ain, UAE
G. Wibbelt
Affiliation:
Leibniz Institute for Zoo and Wildlife Research, Berlin, Germany
B. Arca Ruibal
Affiliation:
Al Aseefa Falcon Hospital, Dubai, UAE
M. Qablan
Affiliation:
College of Agriculture and Veterinary Medicine, UAE University, Al Ain, UAE
*
Authors for correspondence: R.K. Schuster, E-mail: [email protected]; B. Gajic, E-mail: [email protected]
Authors for correspondence: R.K. Schuster, E-mail: [email protected]; B. Gajic, E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

At a routine health check of a female peregrine falcon, 23 trematodes preliminary identified as Prosthogonimus sp. were removed from the bursa of Fabricius. Based on morphological and molecular examination, a new species, Prosthogonimus falconis, was described. The pear-shaped flukes were 4.3–6.9 mm long, with greatest width posterior to testes. Tegumental spines measuring between 17 and 21 μm long covered the whole body. Length and width ratio of oral to ventral suckers were 1:1.3. Extracaecal, multifollicular vitelline glands commenced prior to acetabulum and terminated posterior to testes. Eggs in the distal uterus measured 21 × 12 μm. Molecular analysis of internal transcribed spacer 2, cytochrome c oxidase subunit 1 and NADH dehydrogenase subunit 1 gene regions revealed that the new species described here is phylogenetically closest to Prosthogonimus cuneatus and Prosthogonimus pellucidus clusters.

Type
Research Paper
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2022. Published by Cambridge University Press

Introduction

Prosthogonimosis was an economically important parasitic disease in free-ranging chicken and has lost its significance under conditions of industrial poultry farming.

Rudolphi (Reference Rudolphi1803) described Fasciola ovata, an egg-shaped, flat trematode of 3.3–4.5 × 2.2 mm in size with the acetabulum two times bigger than the oral sucker. The trematodes found in the bursa of Fabricius of a rook (Corvus frugilegus) were given to him by his friend, JCR Meyer. Later, Rudolphi (Reference Rudolphi1809) described a similar trematode, Distoma cuneatum, in a great bustard (Otis tarda). Distoma cuneatum differed by a more pointed, cuneate shape, and eggs were concentrated posterior to ventral sucker. Rudolphi (Reference Rudolphi1819) listed both species and added for the first species the common magpie (Pica pica), the northern shoveler (Spatula clypeata) and the Eurasian coot (Fulica atra) as further hosts.

Wedl (Reference Wedl1858) gave more details on the morphology of a trematode that he found in the bursa of Fabricius of a common snipe (Gallinago gallinago), a common crane (Grus grus) and a Eurasian coot. He wrongly attributed this parasite to Distoma ovatum.

Another trematode with similar morphology was described in the oesophagus of a chicken (von Linstow, Reference von Linstow1873; von Linstow found five specimens in the oesophagus, a rather unusual location – he pointed out that flukes with a related morphology (D. ovatum) were always reported from the bursa of Fabricius). Compared to previously described species, oral and ventral suckers had a similar size, intestinal caeca reached far behind ventral sucker, vitellaria terminated at posterior end of ventral sucker. Since uterine coils were less dense at the posterior end and the worm had a transparent appearance, the name Distomum pellucidum was chosen. Eggs and tegumental spines of D. pellucidum were longer than in previously known species of the extended genus Prosthogonimus created by Lühe (Reference Lühe1899) for trematodes with a genital pore next to the left anterior end of the oral sucker and with parallel situated testes (in the same year, Looss (Reference Looss1899) proposed the genus Prymnoprion, but his paper was published three days later and for this reason Prymnoprion is treated as a junior synonym to Prosthogonimus (Stiles & Wardell, Reference Stiles and Wardell1902)). Not mentioning D. cuneatum, the author recognized D. ovatum and D. pellucidum as valid species.

By re-examining materials of the Berlin collection, Braun (Reference Braun1902) concluded that P. ovatus, P. pellucidus, P. japonicus and P. rarus belong to the genus Prosthogonimus and restored the status of the fifth species, P. cuneatus.

Already in the mid-1950s, the species inventory of the genus consisted of 23 species (Panin, Reference Panin1957) and Skrjabin (Reference Skrjabin and Skrjabin1961) allocated all 37 known Prosthogonimus species to five subgenera.

Here, we present detailed morphological characteristics and phylogenetic analysis of a new Prosthogonimus species found in the bursa of Fabricius of a Peregrine falcon.

Materials and methods

During a routine clinical examination of a female peregrine falcon in January 2020, a fluke infection was detected in the bursa of Fabricius and a total of 23 moving, pink-coloured trematodes were removed and sent for species determination. Intact flukes were washed in phosphate-buffered saline, stained in an aquatic solution of carmine, dehydrated in rising alcohol concentrations and temporary slides embedded in glycerine were used to take measurements. For scanning electron microscopy (SEM), two flukes fixed in 70% ethanol were dehydrated by increasing concentrations of ethanol, critical-point dried using carbon dioxide (Leica EM CPD300; Leica, Wetzlar, Germany) and subsequently mounted on specimen stubs. Dried specimens were sputter-coated with a 10 nm layer of gold–palladium alloy (Polaron Sputter coater SC 7600; Emitech, Montigny-le-Bretonneux, France) before examination with a scanning electron microscope (Supra 40VP; Zeiss, Oberkochen, Germany).

For molecular analyses, total DNA was extracted from three fluke specimens using a DNeasy Blood & Tissue kit (Qiagen, Hilden, Germany) following the manufacturer's recommendation. We amplified the regions of nuclear (internal transcribed spacer 2 (ITS2)) as well as mitochondrial loci (cytochrome c oxidase subunit 1 (cox1) and NADH dehydrogenase subunit 1 (ND1), respectively), using the specific primers listed in Heneberg et al. (Reference Heneberg, Sitko and Bizoz2015). Polymerase chain reaction (PCR) amplification was done in 25 μL reactions consisting of 12.5 μL of Taq PCR Master Mix (Qiagen), 0.4 μM of forward and reverse primers, 2 μL of DNA template and 8.5 μL of RNase-free water. Thermal protocol included initial polymerase activation at 95°C for 5 min followed by 35 cycles of denaturation at 95°C for 30 s, annealing at 57°C (ITS2 and cox1) or 58°C (ND1) for 30 s, extension at 72°C for 1 min and final extension at 72°C for 7 min. After purification, amplicons were subjected to the Sanger sequencing in both directions using ABI 3130 DNA sequencer (Applied Biosystems, Waltham, USA). Sequence alignment and construction of phylogenetic trees were carried out using MEGA 7 software (Kumar et al., Reference Kumar, Stecher and Tamura2016).

Nucleotide BLAST (https://blast.ncbi.nlm.nih.gov/Blast.cgi) analyses were done for sequences generated from the ITS2, cox1 and ND1 regions for preliminary identification. Program selection was optimized for the algorithm searching for somewhat similar sequences (blastn). Reference sequences were downloaded from GenBank (https://www.ncbi.nlm.nih.gov/), and correlated with Heneberg et al. (Reference Heneberg, Sitko and Bizoz2015). Datasets were constructed using MEGA 7 and aligned using the online version of MAFFT (version 7, https://mafft.cbrc.jp/alignment/server/) with the automated selection mode. The best model for maximum likelihood (ML) analyses for each gene region was selected, and the phylogenetic trees constructed using MEGA 7, with 1000 bootstrap replicas. The models used were as follows: ITS2 region – Kimura two-parameter model with gamma-distributed rates (K2 + G); cox1 and ND1 regions – Hasegawa–Kishino–Yano model with gamma-distributed rates with invariant sites (HKY + G + I). Trees were viewed and edited in MEGA 7 software.

One specimen of Prosthogonimus sp. is deposited in the Meguro Parasitological Museum with the registration number MPM Coll. No. 21737.

Results

Prosthogonimus falconis n. sp. (figs 1 and 2)

Type specimen. Holotype is deposited in the Meguro Parasitological Museum, Tokyo, Japan, with the registration number MPM Coll. No. 21737

Fig. 1. Prosthogonimus falconis. Scale bar: 0.5 mm.

Fig. 2. SEM micrographs of Prosthogonimus sp. from the peregrine falcon: (a) anterior end with oral sucker and cirrus tip – the rim of the oral sucker with rosette-like structures is spineless; (b) ventral sucker; (c) body spines in anterior body part; (d) sparse spination at the posterior end; (e) eggs with net-like structure on the egg shell.

Type host. Peregrine falcon, Falco peregrinus Tunstall, 1771 (Aves: Falconidae).

Site of infection. Bursa of Fabricius.

Intensity of infection. 23.

Type locality. Dubai, Dubai Emirate, United Arab Emirates (UAE) (25°08′28.18″N, 55°20′11.84″E).

Etymology. The species name is derived from the generic name of the host.

Light microscopy

Body flattened, 4.3–6.9 mm long, pear-shaped with greatest width posterior to testes, posterior end rounded (fig. 1 and table 1). Whole body covered with 17–21 μm-long triangle-shaped spines with a base 6–7 μm wide, sparse spination at posterior end. Subterminal oral sucker followed by small pharynx. Acetabulum in anterior half, slightly larger than oral sucker. Oesophagus 155 to 190 μm in length. Intestinal bifurcation in the first fifth of the body. Caeca terminate far posterior to testes in the last fifth of the body. Symmetrical unlobed testes intracaecal. Vasa deferentia unite between anterior rim of ventral sucker and intestinal bifurcation into a short common duct that pass into sausage shaped cirrus sac containing internal seminal vesicle. Common genital pore inconspicuous on left anterior rim of oral sucker. Ovary deeply lobed consisting of 9–11 lobes, posterior or partly dorsal to ventral sucker on opposite body half of genital pore. Seminal receptacle and Mehlis’ gland postovarian. Extracaecal, multifollicular vitelline glands commence prior to acetabulum and terminate posterior to testes. Uterus with descending and ascending coils fill postacetabular space, partly overlapping testes and crossing distal intestinal caeca without forming loops in preacetabular space. Distal uterus as thin tube lateral to cirrus sac. Operculated eggs 21 × 12 μm.

Table 1. Morphology of four Prosthogonimus species according to Heneberg et al. (Reference Heneberg, Sitko and Bizoz2015) and own data.

a Numbers in the parentheses represent the number of examined specimens/number of examined hosts

b All measurements are in μm except for body length and body width, which are given in mm

SEM

Rim of the oral sucker with rosette-like structures, spineless. Rim of the ventral sucker with sparse spination. Body spines 10–11 μm long, spines at posterior body less dense. Egg shell covered with the net-like structure of irregular pore size (fig. 2a–e).

Molecular examination

Sequencing of PCR products generated ITS2 (585 bp), cox1 (438 bp) and ND1 (449 bp) sequences, which were deposited to GenBank under accession numbers OK044379, OK044305 and OK086769–OK086771, respectively. Three polymorphic sites with single nucleotide polymorphisms were detected within ND1 sequences of our three analysed fluke specimens. However, all mutations were silent, causing no change in the amino acid sequence.

Nucleotide BLAST analyses showed the highest similarity of our ITS2, cox1 and ND1 sequences to the respective sequences of P. cuneatus (98.5%, 84.2% and 85.4%, respectively) from GenBank (accession numbers KP192725, KP192742, KP192757). In addition, ML analyses of individual sequences placed our fluke sample in a distinct clade, closely related to P. cuneatus and P. pellucidus clusters (fig. 3).

Fig. 3. ML analysis of Prosthogonimus spp. sequences from GenBank. (a) ITS2; (b) cox1; (c) ND1. Sequences generated from the specimens analysed in our study are bolded. The bar represents percentage of genetic variation.

Discussion

Based on the morphology, it is difficult allocating our findings to any of the many described Prosthogonimus species. The paper of Heneberg et al. (Reference Heneberg, Sitko and Bizoz2015) contains not only one of the most comprehensive morphological descriptions but also offers molecular data for four European Prosthogonimus species. In our case, P. ovatus can be excluded as the potential species since uterine coils in P. ovatus fill the entire space between vitelline glands, including the space dorsal to and in front of the ventral sucker; moreover, in P. ovatus body spination discontinues at the posterior edge of testes. Also, the suckers of P. ovatus are relatively small. Oral suckers in P. ovatus, P. cuneatus and P. pellucidus are roughly two times smaller than ventral suckers, while in P. rarus and in our material this relationship was 1:1.24 and 1:1.3, respectively. The maximum body width in P. ovatus, P. cuneatus and P. pellucidus is at the level of the testes, while in P. rarus and our material it is posterior to the testes. Prosthogonimus rarus differs by long intestinal caeca, intracaecal uterine loops and broad vitelline glands that partly overlap the caeca. Our Prosthogonimus specimens from a falcon reveal tegumental spines also on distal body, although spination was less dense and spines were 17–21 μm long by light microscopy, comparable to those of P. rarus (17–24 μm). Measurements on the SEM image revealed shorter lengths, but this is most likely the case because the bases of the spines are deeply embedded in the tegument covering parts of the entire surface. The SEM image of Prosthogonimus eggs showed a net-like structure on the shell similar to other small trematode eggs (Shin et al., Reference Shin, Lim and Choi2009; Lee et al., Reference Lee, Jung, Lim, Lee, Choi, Shin and Chai2012). Eggs in the distal uterus in our material measured only 23 × 14 μm, closest to the eggs from P. cuneatus (26 × 14 μm), and they were considerably smaller than those of other species. With regards to other European Prosthogonimus species, our material can be distinguished from Prosthogonimus longusmorbificans, which has a large body length of 14–16 mm, nearly equal dimension of suckers and short vitellaria, from Prosthogonimus macrorchis, which has testes larger than ventral sucker and very short vitellaria, and from Prosthogonimus limani with a differently structured uterus.

According to Skrjabin's (Reference Skrjabin and Skrjabin1961) division, F. falconis would belong to the subgenus Macrogenotrema Skrjanin & Basakov, Reference Skrjabin and Baskakow1925 in which P. cuneatus was assigned as type species. This subgenus combines species with well-developed reproductive organs and a uterus that forms lopes only posterior to the ventral sucker and these lopes overlay blind-ending caeca. Five species – namely, Prosthogonimus hyperabadensis Jaiswal, 1957, Prosthogonimus indicus Srivastava, 1938, Prosthogonimus ketupi Jaiswal, 1957, Prosthogonimus macroacetabulus Chauhan, 1940 and Prosthogonimus singhi Jaiswal, 1957 – were described from India as a country relatively close to the UAE. From other countries close to the UAE, P. cuneatus was found in Falco tinnunculus (Mohammed, Reference Momammed1999) and recently, Saeed et al. (Reference Saeed, Das Sanjota, Ghazi and Khan2019) reported a new species, Prosthogonimus jonesae found in Vanellus indicus in Pakistan. Sadaf et al. (Reference Sadaf, Javid and Hussain2021) claimed that they found eggs of P. ovatus and P. macrorchis in faecal smears of domestic birds in Punjab, Pakistan in a prevalence of 12.1% and 9.1%, respectively. A curious finding of P. macrorchis in the albumen of an egg was described by Naem & Golpayegani (Reference Naem and Golpayegani2003) in Iran. The other species reported from Iran was P. ovatus, found in P. Pica in a prevalence of 11.3% (Halajian et al., Reference Halajian, Eslami, Mobedi, Amin, Mariaux, Mansoori and Tavakol2011).

All the named species here are morphologically different from P. falconis (table 2).

Table 2. Morphology of Prosthogonimus species described from India, Pakistan and Kazakhstan in comparison to Prosthogonimus falconis (measurements are in mm unless stated otherwise).

Prosthogonimus hyperabadensis, P. indicus and P. macrorchis differ as they have an elongated body size. The dimensions of P. ketupi are considerably larger, those of P. macrorchis smaller than those of P. falconis. Tegumental spines of P. indicus and P. macorchis are shorter and not reported for P. jonesae. In P. hyperabadensis, P. indicus, P. macrorchis and P. jonesae relation of ventral to oral suckers are >1:2 and eggs of P. ketupi, P. singhi and Prosthogonimus putschkovski are larger than those of F. falconis.

Our newly determined gene sequences showed the highest similarity to those of P. cuneatus. However, percent identity between compared sequences ranged from 84.2% to 98.5%, overcoming intraspecies variation within P. cuneatus and suggesting that our sample belongs to a different species. In addition, phylogenetic dendrograms that were constructed according to ITS2, cox1 and ND1 sequences, designated our sample as a separate species. However, we cannot be sure if it represents a new Prosthogonimus species or one of the existing species that was described only based on morphological criteria, but without molecular confirmation. Therefore, future studies on Prosthogonimus spp. should also include sequencing data in order to corroborate the validity of morphological identification and avoid any bias in species identification.

Since members of the genus Prosthogonimus have a semiaquatic life cycle with prosobranch snails as first and dragon- and damselflies as second intermediate hosts, prosthogonimosis was more often diagnosed in water birds with water as natural habitat (Anseriformes, Ralliformes, Charadriformes, Lariformes), but also in birds of the orders Passerifomes and Galliformes. Only very few infections of birds of prey have been recorded so far from Poland (Falco subbuteo by von Siebold, Reference von Siebold1836; Accipiter nissus and F. subbuteo by Sulgostowska & Czaplinska, Reference Sulgostowska and Czaplinska1987), Russia (F. tinnunculus and Falco vespertinus by Skrjabin & Baskakow, Reference Skrjabin and Baskakow1925), Iraq (F. tinnunculus Moammed, Reference Momammed1999), the Netherlands (F. subbuteo by Borgsteede et al., Reference Borgsteede, Okulewicz, Zoun and Okulewicz2003) and Czech Republic (F. subbuteo by Heneberg et al., Reference Heneberg, Sitko and Bizoz2015).

Unfortunately, neither information on the origin nor on the history of the infected peregrine falcon could be obtained. Birds become infected by ingesting dragonflies or damselflies or their larval stages. According to a survey by Lambret et al. (Reference Lambret, Boudot, Chelmick, De Knijf, Durand, Judas and Stoquert2017), some of the genera of damselflies, hawkers and skimmers that can act as second intermediate hosts are present in the UAE.

As far as it is known, prosobranch snails of the genus Bithynia (Bithynia tentaculta and Bithynia leachi complex) are known as first intermediate hosts. These snails are quite common in the northern Palearctic, and representatives of the genus Bithynia occur in central Asian republics, in Iran and India, but they are absent in the UAE (Feulner & Green, Reference Feulner and Green1999).

Since hunting with falcons is restricted in the UAE, many falconers go on hunting trips to Pakistan, Iran, Afghanistan and central Asian republics or to Morocco where they can find bigger concentrations of bustards, and it is quite possible that the infection was acquired in one of these countries. Maralbayeva & Akhmetov et al. (Reference Maralbayeva and Akhmetov2019) examined birds in Kazakhstan and detected only two members of the genus ProsthogonimusP. rarus and P. cuneatus – while Khasanova (Reference Khasanova2019) reported only P. ovatus for Uzbekistan.

Acknowledgements

The authors are grateful to Mrs Viertel from the Institute for Zoo and Wildlife Research, Berlin, for her excellent technical assistance for SEM. We thank Dr B. Neuhaus from Berliner Naturkundemuseum for sending copies of difficult-to-obtain historical references.

Financial support

This study was partially supported by the UAE University in Al Ain, UAE (grant numbers 31F095 and G00002877).

Conflicts of interest

None.

Ethical standards

The authors assert that all procedures contributing to this work comply with the ethical standards of the relevant national and institutional guides on the care and use of laboratory animals.

References

Borgsteede, FHM, Okulewicz, A, Zoun, PEF and Okulewicz, J (2003) The fauna of birds of prey (accipitriformes, falconiformes and strigiformes) in the Netherlands. Acta Parasitologica 48, 200207.Google Scholar
Braun, M (1902) Fascioliden der Vögel. Zoologische Jahrbücher 16, 1162.Google Scholar
Feulner, GR and Green, SA (1999) Freshwater snails of the UAE. Tribulus 9(1), 59.Google Scholar
Halajian, A, Eslami, A, Mobedi, I, Amin, O, Mariaux, J, Mansoori, J and Tavakol, S (2011) Gastrointestinal helminths of magpies (Pica pica), rooks (Corvus frugilegus) and carrion crows (Corvus corone) in Mazandaran Province, North of Iran. Iranien Journal of Parasitology 6, 3844.Google Scholar
Heneberg, R, Sitko, J and Bizoz, J (2015) Integrative taxonomy of central European parasitic flatworms of the family Prosthogonimidae Lühe, 1909 (Trematoda: Plagiorchiida). Parasitology International 64, 264273.CrossRefGoogle ScholarPubMed
Khasanova, TN (2019) The migration of helminthes between wild and domestic birds and regularity of their circulation in biocenosis. International Journal of Scientific and Research Publications 9, 658660.Google Scholar
Kumar, S, Stecher, G and Tamura, K (2016) MEGA7: molecular evolutionary genetics analysis version 7.0 for bigger datasets. Molecular Biology and Evolution 33, 18701874.CrossRefGoogle ScholarPubMed
Lambret, P, Boudot, JP, Chelmick, D, De Knijf, G, Durand, E, Judas, J and Stoquert, A (2017) Odonata surveys 2010–2016 in the United Arab Emirates and the sultanate of Oman, with emphasis on some regional heritage species. Odonatologica 46, 153212.Google Scholar
Lee, J-J, Jung, B-K, Lim, H, Lee, MY, Choi, S-Y, Shin, EH and Chai, J-Y (2012) Comparative morphology of minute intestinal fluke eggs that can occur in human stools in the Republic of Korea. Korean Journal of Parasitology 50, 207213.Google ScholarPubMed
Looss, A (1899) Weitere Beiträge zur Trematodenfauna Aegyptens, zugleich der Versuch einer natuerlichen Gliederung des Genus Distoma Retzius. Zoologische Jahrbücher 12, 521784.CrossRefGoogle Scholar
Lühe, M (1899) Zur Kenntniss einiger Distomen. Zoologischer Anzeiger 22, 524529.Google Scholar
Maralbayeva, DG and Akhmetov, KT (2019) Features of the distribution of trematodes of the family Prosthogonimidae (Nicoll, 1924) in birds in North-Eastern Kazakhstan. Rossiskij Parazitologiceskij Zurnal 13, 6370 (in Russian).Google Scholar
Momammed, KM (1999) Helminths of the kestrel (Falco tinnunculus L., 1758) in Iraq. Bulletin of the Iraq National History Museum 9, 123129.Google Scholar
Naem, S and Golpayegani, MH (2003) Prosthogonimus macrorchis in the albumin of the egg from Sari, Iran. Iranian Journal of Veterinary Research 4(2), 160162.Google Scholar
Panin, VJ (1957) Variability of the morphological characters and its significance in the system of the trematodes of the genus Prosthogonimus Lühe, 1899. Trudy Instituta Zoologii Akademii Nauk Kazachskoj SSR 7, 170215 (in Russian).Google Scholar
Rudolphi, KA (1803) Fortsetzung über die Beobachtung von eingeweidewürmern. Archiv für Zoologie und Zootomie 3(2), 132.Google Scholar
Rudolphi, CA (1809) Entozoorum sive Vermium Intestinalum. Vol. 2. Amsterdam, Amstelaedami Sumtibus Librariae et Artium, p. 457.Google Scholar
Rudolphi, CA (1819) Entozoorum synopsis cui accedunt mantissa duplex et indices locupletissimi. Berlin, Berolini, Sumptibus A. Rückeri, p. 811Google Scholar
Sadaf, T, Javid, A, Hussain, A, et al. (2021) Studies on parasitic prevalence in pet birds from Punjab, Pakistan. Brazilian Journal of Biology 83, e246229.Google ScholarPubMed
Saeed, HA, Das Sanjota, N, Ghazi, RR and Khan, A (2019) New locality and host record of the genus Prosthogonimus Luhe, 1899 (Trematoda: Prosthogonimidae) from the Vanellus indicus (red wattled lapwing) in Larkana, Sindh, Pakistan. Pakistan Journal of Parasitology 67, 8591.Google Scholar
Shin, DH, Lim, D-S, Choi, K-J, et al. (2009) Scanning electron microscope study of ancient parasite eggs recovered from Korean mummies of the Joseon dynasty. Journal of Parasitology 95, 137145.CrossRefGoogle ScholarPubMed
Skrjabin, KI (1961) Family Prosthogonimidae Nicoll, 1924. pp. 5192 in Skrjabin, KI (Eds) Trematodes of animals and man – essentials in trematodology 14. Moscow, Izdatel'stvo Akademii Nauk SSSR.Google Scholar
Skrjabin, KI and Baskakow, WP (1925) Űber die Trematodengattung Prosthogonimus. (Versuch einer Monographie.) Zeitschrift für Infektionsktskheiten Parasitäre Krankrankheiten und Hygiene der Haustiere 28, 195212.Google Scholar
Stiles, C and Wardell, A (1902) Discussion of certain questions of nomenclature. Zoologische Jahrbücher 15, 157208.Google Scholar
Sulgostowska, T and Czaplinska, D (1987) Pasozyty ptakov – parasiti avium. Zesyt 1. Pierwotniaki i przywry. Protozoa et trematoda. p. 210 in Katalog fauny pasozytniczej polski. Warsaw, Wrocław, Panstwowe Wydawnictwo Naukowe.Google Scholar
von Linstow, OFB (1873) Einige neue distomen und bemerkungen über die weiblichen sexualorgane der trematoden. Archiv für Naturgeschichte 39, 95108.Google Scholar
von Siebold, CT (1836) Helminthologische beiträge. Archiv für Naturgeschichte 2(1), 105119.Google Scholar
Wedl, C (1858) Anatomische beobachtungen über trematoden. Sitzungsberichte der Mathematisch-Naturwissenschaftlichen Classe der Kaiserlichen Akademie der Wissenschaften 26, 241278.Google Scholar
Figure 0

Fig. 1. Prosthogonimus falconis. Scale bar: 0.5 mm.

Figure 1

Fig. 2. SEM micrographs of Prosthogonimus sp. from the peregrine falcon: (a) anterior end with oral sucker and cirrus tip – the rim of the oral sucker with rosette-like structures is spineless; (b) ventral sucker; (c) body spines in anterior body part; (d) sparse spination at the posterior end; (e) eggs with net-like structure on the egg shell.

Figure 2

Table 1. Morphology of four Prosthogonimus species according to Heneberg et al. (2015) and own data.

Figure 3

Fig. 3. ML analysis of Prosthogonimus spp. sequences from GenBank. (a) ITS2; (b) cox1; (c) ND1. Sequences generated from the specimens analysed in our study are bolded. The bar represents percentage of genetic variation.

Figure 4

Table 2. Morphology of Prosthogonimus species described from India, Pakistan and Kazakhstan in comparison to Prosthogonimus falconis (measurements are in mm unless stated otherwise).