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Lissonema sicki, an emerging air sac nematode of European owls: introduction, host switching and rapid establishment on a Mediterranean island

Published online by Cambridge University Press:  30 September 2024

Sebastià Jaume-Ramis*
Affiliation:
Mediterranean Parasitology and Ecoepidemiology Research Group, University of the Balearic Islands, Mallorca, Spain
Sofía Delgado-Serra
Affiliation:
Mediterranean Parasitology and Ecoepidemiology Research Group, University of the Balearic Islands, Mallorca, Spain
Jordi Miquel
Affiliation:
Secció de Parasitologia, Departament de Biologia, Sanitat i Medi Ambient, Facultat de Farmàcia i Ciències de l'Alimentació, Universitat de Barcelona, Barcelona, Spain Institut de Recerca de la Biodiversitat (IRBio), Universitat de Barcelona, Barcelona, Spain
Nieves Negre
Affiliation:
Consortium for the Recovery of Wildlife of the Balearic Islands (COFIB), Mallorca, Spain
Ugo Mameli
Affiliation:
Consortium for the Recovery of Wildlife of the Balearic Islands (COFIB), Mallorca, Spain
Carles Feliu
Affiliation:
Secció de Parasitologia, Departament de Biologia, Sanitat i Medi Ambient, Facultat de Farmàcia i Ciències de l'Alimentació, Universitat de Barcelona, Barcelona, Spain
Claudia Paredes-Esquivel*
Affiliation:
Mediterranean Parasitology and Ecoepidemiology Research Group, University of the Balearic Islands, Mallorca, Spain CIBER Enfermedades Infecciosas CIBERINFEC-MICINN-ISCIII, Madrid, Spain
*
Corresponding authors: Sebastià Jaume-Ramis; Email: sebastia.jaume@uib.cat; Claudia Paredes-Esquivel; Email: claudia.paredes@uib.es
Corresponding authors: Sebastià Jaume-Ramis; Email: sebastia.jaume@uib.cat; Claudia Paredes-Esquivel; Email: claudia.paredes@uib.es

Abstract

In recent years, air sac parasitic helminths have been reported to cause severe disease in birds. In addition, various species appear to be expanding and infecting new avian hosts in various regions worldwide. In this context, an air sac nematode was initially detected in 2014 infecting the Eurasian scops owl, hospitalized in the local wildlife hospital in Mallorca (Balearic Islands, Spain). Years later, the parasite was detected in 2 other owl species. Air sac nematodes had never been reported in the Mallorcan Strigiformes before. A comprehensive molecular and morphological characterization analysis, including scanning electron microscopy, was required for species confirmation. The species was identified as Lissonema sicki, a parasite infrequently reported in South American owls. Since its first introduction to Mallorca, it has dramatically increased in prevalence in hospitalized birds, being highly prevalent in the Eurasian scops owl (41%), in the long-eared owl (11%) and in the barn owl (4%). The introduction pathway of this parasite to Europe remains unknown. This discovery underscores the expanding range and impact of L. sicki, emphasizing the importance of ongoing surveillance and research to comprehend and manage the implications of its emergence in new territories.

Type
Research Article
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), 2024. Published by Cambridge University Press

Introduction

Parasitic infections have the potential to cause severe disease outbreaks in birds. Although mild infections tend to be asymptomatic (Höfle et al., Reference Höfle, Krone, Blanco and Pizarro2003; Liptovszky et al., Reference Liptovszky, Majoros and Perge2012; Galosi et al., Reference Galosi, Heneberg, Rossi, Sitko, Magi and Perrucci2019), high parasitic loads can negatively impact hosts' population dynamics by decreasing body mass, nesting success, fecundity and clutch size, increasing nestling mortality (Hamilton and Marlene, Reference Hamilton and Marlene1982; Møller et al., Reference Møller, Allander and Dufva1990, Reference Møller, Merino, Soler, Antonov, Badás, Calero-Torralbo, De Lope, Eeva, Figuerola, Flensted-Jensen, Garamszegi, González-Braojos, Gwinner, Hanssen, Heylen, Ilmonen, Klarborg, Korpimäki, Martínez, Martínez-de La Puente, Marzal, Matthysen, Matyjasiak, Molina-Morales, Moreno, Mousseau, Nielsen, Pap, Rivero-De Aguilar, Shurulinkov, Slagsvold, Szép, Szöllosi, Török, Vaclav, Valera and Ziane2013; Loye and Zuk, Reference Loye and Zuk1991; Marzal et al., Reference Marzal, De Lope, Navarro and Møller2005; Brym et al., Reference Brym, Henry and Kendall2018). Helminth parasites are generally considered to be less pathogenic than protozoans; however, virulence varies widely depending on the parasite group and the specific interaction with their hosts (Gutiérrez et al., Reference Gutiérrez, Piersma and Thieltges2019).

In birds, global change is directly impacting the dynamics of parasitic infections (Hakalahti et al., Reference Hakalahti, Karvonen and Valtonen2006; Garamszegi, Reference Garamszegi2011). Climatic variations can induce alterations of migration routes, resulting in the introduction of new parasites into previously unoccupied regions (Harvell et al., Reference Harvell, Mitchell, Ward, Altizer, Dobson, Ostfeld and Samuel2002; Cattadori et al., Reference Cattadori, Haydon and Hudson2005; Brooks and Hoberg, Reference Brooks and Hoberg2007). Furthermore, episodes of parasite host switching, which appear to be widespread, are believed to be influenced by global change (Brooks and Hoberg, Reference Brooks and Hoberg2007; Hoberg and Brooks, Reference Hoberg and Brooks2008). These changes in susceptible host species may eventually result in vulnerable or endemic birds contracting novel parasites, which can lead to population declines or even extinctions (Fuller et al., Reference Fuller, Bensch, Müller, Novembre, Pérez-Tris, Ricklefs, Smith and Waldenström2012). Therefore, having a comprehensive understanding of the parasites circulating among endemic and migrant birds is crucial to assess the potential for outbreaks. In Europe, long-term monitoring of bird populations has revealed a steady decline in species diversity (European Environment Agency, 2020), along with changes in bird dynamics (Zalakevicius, Reference Zalakevicius2000; Crick, Reference Crick2004), which may also have a negative impact on helminth diversity (Sitko and Heneberg, Reference Sitko and Heneberg2020b, Reference Sitko and Heneberg2021). Moreover, the observation of uncommon bird species has become increasingly frequent in the Balearic Islands (Garcia-Febrero et al., Reference Garcia-Febrero, Méndez and Escandell2011; López-Jurado et al., Reference López-Jurado, McMinn, González, Triay, Moss and Llabrés2020).

Among bird helminths, those that infect air sacs have been historically overlooked, because they have not been associated with major health issues (Cooper, Reference Cooper1969). Furthermore, their correct identification is challenging given the scarcity of updated and available keys as well as the limited number of species studied using a molecular approach. Although these parasites tend to cause asymptomatic infections, an increasing number of reports have shown that they can also cause severe clinical manifestations and even lead to death (Dronen et al., Reference Dronen, Greiner, Ialeggio and Nolan2009; Galosi et al., Reference Galosi, Heneberg, Rossi, Sitko, Magi and Perrucci2019; Díaz et al., Reference Díaz, Donoso, Mosquera, Ramírez-Villacís, González, Zapata and Cisneros-Heredia2022). Some of these helminths appear to be expanding their distribution or infecting new avian hosts. One clear example is the nematode Serratospiculum tendo (Nitzsch, 1819) of the family Diplotriaenidae which has recently been reported in Peru and Argentina and is expanding across South America among Austral peregrine falcons (Order Falconiformes, Falco peregrinus Tunstall, 1771) (Gomez-Puerta et al., Reference Gomez-Puerta, Ospina, Ramirez and Cribillero2014; Ibarra et al., Reference Ibarra, Sierra, Neira, Ibaceta and Saggese2019) and the diplotriaenid nematode Serratospiculoides amaculata (Wehr, 1938) which has been also increasing its geographic range and switched host to passerines (Abdu et al., Reference Abdu, Eisenring, Zúniga, Alarcón-Nieto, Schmid, Aplin, Brandl and Farine2023). In the USA, there has been a growing number of reports of air sac trematodes from the family Cyclocoelidae in zoos (Dronen et al., Reference Dronen, Greiner, Ialeggio and Nolan2009). In Europe, a comprehensive spatiotemporal study in the common blackbird (Passeriformes, Turdus merula Linnaeus, 1758) showed that the cyclocoelid air sac trematode Morishitium polonicum (Machalska, 1980) was absent in this bird species prior 1990 and its prevalence has increased, reaching 19% in recent years (Sitko and Heneberg, Reference Sitko and Heneberg2020a). This same species was reported from the air sacs of a song thrush (Passeriformes, Turdus philomelos Brehm, 1831) in the Balearic Islands (Jaume-Ramis and Pinya, Reference Jaume-Ramis and Pinya2018).

The primary objective of this study was to conduct a comprehensive morphological, ultrastructural and molecular characterization of nematodes infecting the air sacs of strigiform birds that entered the wildlife hospital and to analyse prevailing trends in their prevalence. Furthermore, we engage in a critical evaluation of their role as emerging pathogens within the affected bird population.

Materials and methods

The Balearic archipelago consists of 4 main islands (Mallorca, Menorca, Ibiza and Formentera) and several uninhabited islets located at the Western Mediterranean Basin. The archipelago constitutes an important nesting place for birds including migratory and sedentary species (Arcos, Reference Arcos2011). Birds included in this study were hospitalized at the Consortium for the Recovery of Wildlife of the Balearic Islands (herein COFIB hospital), between 2010 and 2022. Most birds were admitted due to injuries caused by electrocution, cranial trauma or collisions with cars or fences. Necropsies were performed at the COFIB hospital on dead or euthanized individuals. Among the birds with air sac nematodes, some specimens were collected manually and stored in 70% alcohol for further investigations.

Morphological identification of parasites

Morphological identification was conducted using both, light and scanning electron microscopy (SEM). Specimens were slide-mounted in Amann lactophenol and subsequently examined and identified under a light microscope (Euromex iScope, The Netherlands) at 100× and 400× magnifications. A morphometric analysis was conducted in well-preserved specimens (26 females and 11 males). The analysis included measurements of the total body length and maximum width, the length of the oesophagus, the length of spicules (for males), as well as measurements of eggs, ovejector and distance from the vulva to the anterior end (for females). Parasites were identified using generic and specific dichotomous keys and species descriptions (Skrjabin and Schikhobalova, Reference Skrjabin and Schikhobalova1936; Anderson and Chabaud, Reference Anderson and Chabaud1958; Chabaud et al., Reference Chabaud, Anderson and Brygoo1959; Anderson and Bain, Reference Anderson, Bain, Anderson, Chabaud and Willmott1976).

Some specimens (5 males and 3 females) were preserved for SEM examination to better observe characters which are often difficult to visualize with light microscopy examination. To achieve this, the nematodes initially fixed in 70% ethanol underwent dehydration in an ethanol series and critical point drying with carbon dioxide in an Emitech K850X (Quorum Technologies Ltd., Laughton, East Sussex, UK). Subsequently, the specimens were mounted on stubs with conductive adhesive tape and colloidal silver, coated with carbon in an Emitech K950X (Quorum Technologies Ltd.) evaporator, and examined using a field emission SEM JSM-7001F (Jeol Ltd., Tokyo, Japan) at 10 kV in the ‘Centres Científics i Tecnològics’ of the University of Barcelona' (CCiTUB).

Molecular characterization

Eleven nematodes (including males and females) were randomly selected and stored in 96% ethanol, at −20°C for further molecular analysis. These belonged to the 3 affected strigiform bird species hospitalized in different years (2016, 2018 and 2021). Whole specimens were processed using the NZY Tissue gDNA Isolation Kit (Nzytech, Lisboa, Portugal). The specifications of the manufacturer were followed except for the pre-lysis step, where samples were incubated 24 h at 56°C instead of 1–3 h as specified, and the final elution step, where only 40 μL elution buffer was used instead of 100 μL to increase DNA yield. Molecular characterization was conducted in at least 1 nematode per bird species and year, when possible.

DNA obtained was estimated through a NanoDrop 2000 spectrophotometer (Thermo Scientific, Wilmington, USA). We amplified and sequenced the cytochrome c oxidase I (COI) barcode region and the small ribosomal subunit (18S). The polymerase chain reaction (PCR) was performed using a Veriti Thermal Cycler (Applied Biosystems, Foster City, USA). For the COI amplification, PCR was performed using a pair of primers LCO1490: 5′-GGTCAACAAATCATAAAGATATTGG-3′, and HCO2198: 5′-TAAACTTCAGGGTGACCAAAAAATCA-3′ (Folmer et al., Reference Folmer, Black, Hoeh, Lutz and Vrijenhoek1994), which theoretically results in a 710 bp amplicon. If amplification was not possible, we used the following primers: COI F: 5′-TTTTTTGGGCATCCTGAGGTTTAT-3′ and COI R: 5′-TAAAGAAAGAACATAATGAAAATG-3′ (Monte et al., Reference Monte, Simes, Oliveira, Novaes, Thiengo, Silva, Estrela and Júnior2012), in which case, the resulting amplicon is a 394 bp fragment. For the 18S region, the primers NEMFG1: 5′-TCTCCGATTGATTCTGTCGGCGATTATATG-3′ and CRYPTOR: 5′-GCTTGATCCTTCTGCAGGTTCACCTAC-3′ (Bimi et al., Reference Bimi, Freeman, Eberhard, Ruiz-Tiben and Pieniazek2005) were used, which theoretically results in an amplicon around 1700 bp.

The reactions were carried out in a final volume of 50 μL. The PCR mix contained 2 μL 10 μm of each primer, 2 μL of the sample's DNA, 25 μL of the Supreme NZYtaq II 2× Green Master Mix (Nzytech, Lisboa, Portugal), 17 μL of MilliQ water and 2 μL of MgCl2 50 mm. For the COI region amplification, PCR was performed under the following conditions: initial denaturation step at 95°C for 3 min followed by 35 cycles at 95°C for 30 s, 50°C for 30 s, 72°C for 1 min and a final extension step at 72°C for 10 min. For the 18S region, the PCR was performed with an initial denaturation step at 95°C for 15 min followed by 35 cycles at 94°C for 30 s, 60°C for 30 s, 72°C for 90 s and a final extension step at 72°C for 10 min.

PCR products were then visualized on a 2% agarose gel stained with Pronasafe nucleic acid solution (Conda Laboratories, Madrid, Spain). Before sequencing, PCR products were purified using the NZY Gelpure kit (Nzytech, Lisboa, Portugal) according to the manufacturer's instructions except for the final step, where the samples were eluted in 30 μL MilliQ water instead of 50 μL elution buffer. Purified PCR products were sent to Sistemas Genómicos S.L. (Spain) and Macrogen (Spain) for bi-directional Sanger sequencing.

Final sequences were uploaded to GenBank and subjected individually for BLAST searches in the NCBI database (https://blast.ncbi.nlm.nih.gov). For phylogenetic reconstruction we retrieved the first 100 hits and manually added sequences from other members of the order Spirurida. All sequences were aligned using MUSCLE (Edgar, Reference Edgar2004) and manually checked for inconsistences. Phylogenetic trees based on maximum-likelihood were constructed for both COI and 18S sequences using MEGA11 software (Tamura et al., Reference Tamura, Stecher and Kumar2021). The best substitution models (Kimura 2-parameter + G + I and Tamura–Nei + G for 18S and COI, respectively) were determined using MEGA 11 software. A bootstrap test with 1000 replicates was used to determine robustness. Sequences of the trichurid Trichuris trichiura (Linnaeus, 1771) were included in the analysis as an outgroup, in both COI and 18S trees.

Prevalence trends

Statistical analyses were conducted with R software version 4.3.2 (R Core Team, 2023). The prevalence for each host species and year was calculated as the percentage of positive necropsies over the total number of necropsies conducted. Prevalence was calculated for the whole period (2010–2022) as well as for each year. Prevalence trends were plotted with the ‘ggplot2’ R package (Wickham, Reference Wickham2016). Prevalences 95% confidence intervals (CIs) were calculated by the Clopper–Pearson method using the ‘binom’ R package (Dorai-Raj, Reference Dorai-Raj2022). As we considered each bird species independently, the years previous to the first detection (before 2014) were removed from the analyses. To evaluate the trend of infection, a generalized linear model (GLM) per host was run with the raw output of each necropsy (1 = infected; 0 = not infected). A binomial distribution with link logit was used as a family. The variable Year was used as a predictor of infection. The models were evaluated with the ‘DHARMa’ R package (Hartig, Reference Hartig2022). A variable was considered statistically significant when the P value was ⩽0.05. The data and the code used in the analysis can be found in the Supplementary materials.

Results

Host data

In total, 641 Strigiformes belonging to 3 species (173 Eurasian scops owls, Otus scops (Linnaeus, 1758); 212 long-eared owls, Asio otus (Linnaeus, 1758) and 256 barn owls, Tyto alba (Scopoli, 1769)) were necropsied at the COFIB hospital between 2010 and 2022. The 3 bird species are listed as Least Concern according to the IUCN Red List of Threatened Species with a decreasing global population trend in all but T. alba, which keeps a stable global population trend (BirdLife International, 2019, 2021a, 2021b). The owls entered the COFIB hospital due to different causes; the most typical being collisions with vehicles, collisions with fences, malnutrition or unknown trauma, among others. The birds necropsied were the ones for which rehabilitation was not possible. No reports of air sac nematodes were reported in any bird species prior to 2014.

Morphological identification of the parasites

The nematodes (Fig. 1A) found in the air sacs of A. otus, O. scops and T. alba were morphologically identified as Lissonema sicki (Strachan, Reference Strachan1957) (Aproctidae). The nematodes were found free mainly in the thoracic and clavicular air sacs. The taxonomy of L. sicki is complex as many synonyms exist in the literature. This taxon was first described as Thelazia sicki by Strachan (Reference Strachan1957) and later included in the genus Squamofilaria Schmerling, 1925, following a redescription of the species by Anderson and Chabaud (Reference Anderson and Chabaud1958). In the present study, we adhered to the generic diagnosis provided by Bain and Mawson (Reference Bain and Mawson1981), in which Squamofilaria sicki was classified within the genus Lissonema Linstow, 1903, a group known to have Strigiformes as their definitive hosts. The present specimens possessed a funnel-shaped buccal capsule and an oesophagus with no differentiation between the muscular and glandular regions (Fig. 1B). The cephalic end had 2 trilobed elevations, 4 pairs of cephalic papillae (the posterior papilla of each pair was bigger) and a pair of amphids (Fig. 2B and C). The morphometric analysis showed that female nematodes were larger, being 29.12 ± 3.8 mm long and 559 ± 96 μm width (Table 1), with a well-defined vulva, located near the anterior end (Figs 1C and 2A). Thick-shelled eggs were observed in all female specimens. Male specimens were 12.54 ± 1.5 mm long and 370 ± 84 μm wide, with a short, curved and rounded tail. The spicules were equal in length and shape (Table 1). The proximal extremity of the spicules was massive and the distal extremity bluntly rounded, flattened and membranous (Figs 1D and 3A). Males exhibited 3 pairs of postcloacal papillae (not always visible with a light microscope), 1 pair of precloacal papillae situated near to the anterior margin of the cloaca and an unpaired precloacal papilla (Figs 1D and 3B). The 2 phasmids were located posterior to the last pair of postcloacal papillae (Fig. 3B). All morphoanatomical features observed in our specimens matched those redescribed for L. sicki by Anderson and Chabaud (Reference Anderson and Chabaud1958).

Figure 1. Photographs of Lissonema sicki found infecting Strigiformes in this study. (A) Nematodes found free mainly in the thoracic and clavicular air sacs during necropsies. (B) Anterior end of L. sicki, showing the buccal capsule (arrow). (C) Female with the vulva (v) near the cephalic end. (D) Male caudal region. Note the 2 almost equal spicules. Arrows indicate the 3 pairs of postcloacal papillae characteristic of this species.

Figure 2. SEM of the anterior end of L. sicki (A and B, female; C, male). v, vulva; am, amphids; *, **, anterior and posterior papillae of the 4 pairs of cephalic papillae; arrows, 2 trilobed lateral elevations.

Table 1. Comparative morphometry of the air sac nematode Lissonema sicki found in the Strigiformes of this study vs the original redescription and the morphometry of Lissonema noctuae (a closely related species).

All measurements are given in μm.

Figure 3. SEM of the posterior end of a male of L. sicki. (A) General view of the posterior end; (B) details showing the distribution of cloacal papillae in ventral view. sp, spicules; ph, phasmids; arrows, cloacal papillae.

Molecular characterization

We obtained 11 COI and 4 18S sequences from individual specimens. In the case of COI, none of the specimens could be amplified with primers by Folmer et al. (Reference Folmer, Black, Hoeh, Lutz and Vrijenhoek1994); however, they were successfully amplified and sequenced using the primers developed by Monte et al. (Reference Monte, Simes, Oliveira, Novaes, Thiengo, Silva, Estrela and Júnior2012). All sequences were submitted to GenBank with the following accession numbers: OQ941465–OQ941475 (COI sequences) and PP838209–PP838212 (18S sequences). The resulting alignments were 355–394 and 1539 bp in length, for COI and 18S respectively. The BLAST resulted with our sequences being >12 and >7% distant with the closest ones for COI and 18S, respectively, therefore, species identity could not be determined using this approach.

Both phylogenetic trees place L. sicki within the Spirurida (Figs 4 and 5). However, L. sicki does not appear in the Aproctidae clade (represented by members of the Aprocta genus). Instead, it appears in the same clade as members of the Onchocercidae family (bootstrap support <50%) in the 18S tree (Fig. 5). The phylogenetic tree using the COI gene region (Fig. 4) is less informative because sequences of other members of the Aproctidae could not be retrieved from GenBank. Furthermore, the number of sequences from representatives of the Spirurida was limited for this gene. Bootstrap values were low in both cases.

Figure 4. Maximum-likelihood phylogenetic tree inferred from COI sequences showing the position of L. sicki in relation to other species of the order Spirurida. Bootstrap values (1000 replicates) lower than 50 are not shown.

Figure 5. Maximum-likelihood phylogenetic tree inferred from the 18S sequences showing the position of L. sicki in relation to other species of the order Spirurida. Bootstrap values (1000 replicates) lower than 50 are not shown.

Trends in prevalence and clinical information

The first detection of the air sac nematode L. sicki occurred in 2014 in O. scops, while the detections in A. otus and T. alba occurred in 2015 and 2017, respectively. Since then, the prevalence of L. sicki has increased in all 3 species, reaching its maximum peak in 2018 in O. scops and showing a slight decrease in 2022 in all hosts. Throughout the period of the first detection of the nematode to 2022, the overall prevalence of air sac nematodes on necropsied owls was 40.8% (CI 31.2–50.9%) in O. scops, 9.3% (CI 5.1–15.5%) in A. otus and 2.4% (CI 0.6–6%) in T. alba (Fig. 6). The GLM models indicate a significantly increasing trend in prevalence only in O. scops (GLM, P value = 0.014, slope = 1.21), while in the rest of the bird species this increment was not statistically significant (A. otus GLM, P value = 0.120, slope = 1.18; T. alba GLM, P value = 0.193, slope = 1.36). Slope is presented as the e estimate.

Figure 6. Prevalence of L. sicki in necropsied Strigiformes per year during this study (2010–2022). Graphic created with ‘ggplot2’ R package. Error bars represent the 95% CIs according to the Clopper–Pearson method. Numbers on the upper error bars show the total number of birds necropsied per year and species (Asio otus, Otus scops and Tyto alba, respectively).

All infected birds were adults, except for 2 juvenile O. scops specimens. Parasite intensities ranged from 2 to >80 nematodes per infected bird. As the examined birds were hospitalized and later died due to severe injuries (such as collisions or fractures), the clinical severity related to the presence of air sac nematodes could not be assessed.

Discussion

In recent years, air sac helminths have been reported as emerging pathogens of birds of prey in various regions worldwide (Gomez-Puerta et al., Reference Gomez-Puerta, Ospina, Ramirez and Cribillero2014; Ibarra et al., Reference Ibarra, Sierra, Neira, Ibaceta and Saggese2019). Although most infections are typically mild, severe and fatal cases caused by these parasites have been documented (Galosi et al., Reference Galosi, Heneberg, Rossi, Sitko, Magi and Perrucci2019; Díaz et al., Reference Díaz, Donoso, Mosquera, Ramírez-Villacís, González, Zapata and Cisneros-Heredia2022). This study introduces L. sicki, an air sac nematode that since its initial detection in the island of Mallorca in 2014 has shown an increase in prevalence among both mostly sedentary (A. otus and T. alba) and migratory (O. scops) owls on the island. Although sporadically documented only in South America, the first detection of L. sicki in Europe has prompted a comprehensive characterization of its morphology, molecular identity and ultrastructure to facilitate future detections and enhance our understanding of the impact L. sicki has on susceptible hosts.

The members of the Aproctidae are known to be parasites inhabiting the cervical air sacs, nasal cavities, orbits and incidentally the subcutaneous tissue of birds (Anderson and Bain, Reference Anderson, Bain, Anderson, Chabaud and Willmott1976; Anderson, Reference Anderson and Anderson2000). The taxonomy of the members of this family remains poorly explored (Vanstreels et al., Reference Vanstreels, Yabsley, Swanepoel, Stevens, Carpenter-Kling, Ryan and Pistorius2018). In this context, the identification of our specimens was challenging and laborious. Light microscopy showed that our specimens' morphology matched those of the South American parasite L. sicki and Lissonema noctuae (Spaul, Reference Spaul1927), a species found in North Africa (Spaul, Reference Spaul1927), Japan (Yoshino et al., Reference Yoshino, Hama, Onuma, Takagi, Sato, Matsui, Hisaka, Yanai, Ito, Urano, Osa and Asakawa2014) and China (Zhang et al., Reference Zhang, Liu and Zhang2012). The differentiation between L. sicki and L. noctuae relied mainly on the number and arrangement of postcloacal papillae [3 pairs in L. sicki (Anderson and Chabaud, Reference Anderson and Chabaud1958) and from 0 to 1 pair in L. noctuae (Spaul, Reference Spaul1927; Zhang et al., Reference Zhang, Liu and Zhang2012; Yoshino et al., Reference Yoshino, Hama, Onuma, Takagi, Sato, Matsui, Hisaka, Yanai, Ito, Urano, Osa and Asakawa2014)], which are difficult to differentiate with light microscopy (Table 1). However, based on SEM analysis, we were able to confirm the presence of 3 postcloacal pairs of papillae in the present specimens (Fig. 3). Other members of the genus were not considered given their different morphology and host range.

This study provides the first molecular characterization (18S and COI) of L. sicki, potentially contributing to the early detection of this species in other regions. Additionally, it increases the dataset for the Aproctidae, given that so far, only 1 previous study has molecularly characterized the members of this family (Niedringhaus et al., Reference Niedringhaus, Dumbacher, Dunker, Medina, Lawson, Fenton, Higley, Haynes and Yabsley2023).

Despite the low bootstrap values obtained, which prevent drawing firm conclusions, the phylogenetic reconstruction of members of the Spirurida using the 18S gene suggests that L. sicki may be more closely related to Onchocercidae than previously stated (Fig. 5). However, as previously reported for this order, the limited number of available sequences may provide misleading results and should be interpreted cautiously (Nadler et al., Reference Nadler, Carreno, Mejía-Madrid, Ullberg, Pagan, Houston and Hugot2007). According to Bain et al. (Reference Bain, Mutafchiev, Junker and Schmidt-Rhaesa2014), morphological characters in adults of the order Spirurida have little phylogenetic value because they are formed late during development and are thus subject to homoplasy. We strongly recommend carrying out further molecular-based studies to not only clarify the taxonomic position of L. sicki but also that of other taxa within this order.

This study represents the first report of L. sicki in Europe, outside of its little known native Neotropical region. Before 2014, no air sac nematode species had been observed in Mallorcan strigiform birds. To our knowledge, L. sicki had only been previously reported in Brazil, where it was found infecting the ocular region of an unidentified Asio sp. (Strachan, Reference Strachan1957) and later in Bolivia (Garvin et al., Reference Garvin, Bates and Kinsella1997), infecting the nasal cavity of an Otus choliba (Vieillot, 1817). Similar to other members of the superfamily Aproctoidea, L. sicki is likely transmitted through the ingestion of insects of the orders Orthoptera or Coleoptera (Anderson and Bain, Reference Anderson, Bain, Anderson, Chabaud and Willmott1976; Anderson, Reference Anderson and Anderson2000), which are known to play a crucial role in the diets of O. scops (Marchesi and Sergio, 2005), T. alba (De Pablo, Reference De Pablo2000) and A. otus (Trujillo et al., Reference Trujillo, Díaz and Moreno1989).

We hypothesize that the invasion of L. sicki may have occurred through at least 3 possible routes: (1) introduction through illegally traded infected birds, (2) co-introduction with invasive intermediate hosts and (3) introduction through North African birds via migratory routes (Fig. 7). The first hypothesis is grounded in the occurrence of the illegal trade of O. choliba, its host in South America. This bird species ranks among the most trafficked bird species in South American countries (WCS Colombia, 2021). Previous studies have demonstrated that trafficked birds harbour parasites, and due to their compromised immune status, they often harbour high parasitic burdens (Arbetman et al., Reference Arbetman, Meeus, Morales, Aizen and Smagghe2013). Despite this, to the best of our knowledge, there are no reports of the introduction of O. choliba specimens in Europe. However, it is worth noticing that some eggs from this species were confiscated in 2008 in Portugal (Ortiz-von Halle, Reference Ortiz-von Halle2018). The second hypothesis is rooted in the establishment of several insect species in the Balearic Islands (Torres et al., Reference Torres, Jordà, De Vílchez, Vaquer-Sunyer, Rita, Canals, Cladera, Escalona and Miranda2021). The phenomenon of insects carrying pathogens from their native range is well-documented (Vilcinskas, Reference Vilcinskas2019), with some native host populations from invaded territories showing higher infection rates than the invasive hosts (Arbetman et al., Reference Arbetman, Meeus, Morales, Aizen and Smagghe2013). Finally, the difficulties observed in differentiating Lissonema species using light microscopy, coupled with the scarcity of new studies in these species may imply that L. noctuae from North Africa could be conspecific with L. sicki. This would imply L. sicki to be a synonym of the first described L. noctuae. However, further molecular studies comparing samples of both species and other members of this family should be performed to clarify the taxonomy of this group of nematodes. Notably, this region is part of the Mediterranean migration route of O. scops (Barriocanal et al., Reference Barriocanal, Robson and Gargallo2021). Migratory birds are known to harbour a wide variety of parasites, and the close phylogenetic relationships between hosts facilitate cross-species transmission (Ishtiaq and Renner, Reference Ishtiaq and Renner2020).

Figure 7. Schematic figure representing the possible entry routes of L. sicki to Mallorca (Balearic Islands, Spain). (1) Introduction through illegally traded infected birds, (2) co-introduction with invasive intermediate hosts and (3) introduction through North African birds via migratory routes if L. sicki is a synonym of Lissonema noctuae.

The increase in L. sicki prevalence observed in Mallorcan owls, reaching peaks of 71.43% in O. scops, 22.22% in A. otus and 15.38% in T. alba, shows that the Mediterranean basin has optimal conditions for the completion of the life cycle of this parasite. It is worth noting that data on prevalence presented in this study should be interpreted carefully, as it pertains solely to necropsied birds from the COFIB hospital and may not represent the real prevalence of the parasite in nature. Santoro et al. (Reference Santoro, Tripepi, Kinsella, Panebianco and Mattiucci2010) reported a high (80.6%) prevalence of the air sac nematode S. tendo in F. peregrinus in Italy with a higher severity of the clinical signs been directly related to parasite load. The high infection burden (>80 nematodes/host) reported in this study may indicate that L. sicki has the potential to severely impair birds' fitness. The only 2 reports of L. noctuae indicate that this parasite causes low parasitaemia, with only 1–3 nematodes per host (Spaul, Reference Spaul1927; Yoshino et al., Reference Yoshino, Hama, Onuma, Takagi, Sato, Matsui, Hisaka, Yanai, Ito, Urano, Osa and Asakawa2014). Given that air sac nematodes have been associated with lethal infections in birds (Lavoie et al., Reference Lavoie, Mikaelian, Sterner, Villeneuve, Fitzgerald, Mclaughlin, Phane Lair and Martineau1999; Samour and Naldo, Reference Samour and Naldo2001), further studies should be conducted to assess the detrimental effect that L. sicki could have on owls.

The Eurasian scops owl, O. scops, is the only European species undertaking a lengthy migratory route, overwintering in the South of the Sahara Desert (Barriocanal et al., Reference Barriocanal, Robson and Gargallo2021). The significantly higher prevalence observed in O. scops, in comparison to other owl species from Mallorca, may indicate a higher specificity of L. sicki for O. scops. Given that O. scops is present in various parts of the continent, the spread of the parasite to other regions is likely to occur. In this context, Mediterranean islands have served as gateways for several emerging parasitic helminths in Europe, subsequently reported in continental territories (Salas-Coronas et al., Reference Salas-Coronas, Bargues, Lozano-Serrano, Artigas, Martínez-Ortí, Mas-Coma, Merino-Salas and Abad Vivas-Pérez2021; Paredes-Esquivel et al., Reference Paredes-Esquivel, Foronda, Dunavan and Cowie2023). We speculate whether islands can be used for the early detection of emerging pathogens on the continent, given their susceptibility to the establishment of invasive species (Reaser et al., Reference Reaser, Meyerson, Cronk, De Poorter, Eldrege, Green, Kairo, Latasi, Richard, Mauremootoo, O'Dowd, Orapa, Sastroutomo, Saunders, Shine, Thrainsson and Vaiutu2007). Under the current scenario of global change, vigilance over emerging pathogens that may affect bird populations is imperative, as it has a direct influence on phenomena such as host switching and trophic dynamics.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0031182024000805.

Data availability statement

The authors confirm that the data supporting the findings of this study are available within the article (and/or its supplementary materials).

Acknowledgements

We thank all members of the COFIB hospital involved in the study. We acknowledge the Department of Biology of the University of the Balearic Islands for providing equipment for parasite identification and the Biomedicine area for the DNA quantification equipment. We wish to thank the staff of the ‘Centres Científics i Tecnològics de la Universitat de Barcelona (CCiTUB)’ for their assistance in the preparation of samples. J. M. is a member of the 2021-SGR-00359 research group. Finally, we thank Joan Díaz-Calafat, Andreu Rotger and Marcia Raquel Pegoraro for their support and advice with the statistics and the phylogenetic analysis.

Author contributions

S. Jaume-Ramis: data curation, formal analysis, investigation, methodology, validation, visualization, writing – original draft, writing – review and editing. S. Delgado-Serra: data curation, methodology, writing – review and editing. J. Miquel: data curation, formal analysis, validation, visualization, writing – review and editing. N. Negre: data curation, methodology, writing – review and editing. U. Mameli: data curation, writing – review and editing. C. Feliu: validation, writing – review and editing. C. Paredes-Esquivel: conceptualization, formal analysis, funding acquisition, methodology, project administration, resources, supervision, validation, visualization, writing – review and editing.

Financial support

This work has been partially sponsored and promoted by the Comunitat Autònoma de les Illes Balears through the Servei de Recerca i Desenvolupament and the Conselleria d'Educació i Universitats with funds from the Tourist Stay Law, Hisenda I Innovació via Plans complementaris del Pla de Recuperació, Transformació i Resiliència (PRTR-C17-I1) and by the European Union – Next Generation UE (BIO014). Nevertheless, the views and opinions expressed are solely those of the author or authors, and do not necessarily reflect those of the European Union or the European Commission. Neither the European Union nor the European Commission is to be held responsible.

Competing interests

None.

References

Abdu, S, Eisenring, M, Zúniga, D, Alarcón-Nieto, G, Schmid, H, Aplin, LM, Brandl, HB and Farine, DR (2023) The presence of air sac nematodes in passerines and near-passerines in southern Germany. International Journal for Parasitology: Parasites and Wildlife 21, 174178.Google ScholarPubMed
Anderson, RC (2000) 7.9 The superfamily Aproctoidea. In Anderson, RC (ed.), Nematode Parasites of Vertebrates: Their Development and Transmission. New York: CABI Publishing, pp. 533534.CrossRefGoogle Scholar
Anderson, RC and Bain, O (1976) Spirurida: Diplotriaenoidea, Aproctoidea and Filarioidea. In Anderson, RC, Chabaud, AG and Willmott, S (eds), Keys to the Nematode Parasites of Vertebrates: Archival Volume. Wallingford, UK: CABI, pp. 59116.Google Scholar
Anderson, R and Chabaud, A (1958) Taxonomy of the filarian worm Squamofilaria sicki (Strachan 1957) n. comb. and placement of the genus Squamofilaria (Schmerling, 1925) in the subfamily Aproctinae. Annales de Parasitologie Humaine et Comparée 33, 254266.Google Scholar
Arbetman, MP, Meeus, I, Morales, CL, Aizen, MA and Smagghe, G (2013) Alien parasite hitchhikes to Patagonia on invasive bumblebee. Biological Invasions 15, 489494.CrossRefGoogle Scholar
Arcos, JM (2011) International species action plan for the Balearic shearwater, Puffinus mauretanicus. SEO/BirdLife and BirdLife International, 1–51.Google Scholar
Bain, O and Mawson, P (1981) On some oviparous filarial nematodes mainly from Australian birds. Records of the South Australian Museum 18, 265284.Google Scholar
Bain, O, Mutafchiev, Y and Junker, K (2014) 7.21 Order Spirurida. In Schmidt-Rhaesa, A (ed.), Volume 2 Nematoda. Berlin, Boston: De Gruyter, pp. 661732Google Scholar
Barriocanal, C, Robson, D and Gargallo, G (2021) Migration of the Eurasian scops-owl (Otus scops) over the Western Mediterranean. AIRO 29, 1522.Google Scholar
Bimi, L, Freeman, AR, Eberhard, ML, Ruiz-Tiben, E and Pieniazek, NJ (2005) Differentiating Dracunculus medinensis from D. insignis, by the sequence analysis of the 18S rRNA gene. Annals of Tropical Medicine and Parasitology 99, 511517.CrossRefGoogle Scholar
BirdLife International (2019) Tyto alba (amended version of 2016 assessment). The IUCN Red List of Threatened Species 2019: e.T22688504A155542941. https://dx.doi.org/10.2305/IUCN.UK.2019-3.RLTS.T22688504A155542941.en (accessed 19 December 2023).CrossRefGoogle Scholar
BirdLife International (2021a) Otus scops. The IUCN Red List of Threatened Species 2021: e.T155019854A206523296. https://dx.doi.org/10.2305/IUCN.UK.2021-3.RLTS.T155019854A206523296.en (accessed 19 December 2023).CrossRefGoogle Scholar
BirdLife International (2021b) Asio otus. The IUCN Red List of Threatened Species 2021: e.T22689507A201150685. https://dx.doi.org/10.2305/IUCN.UK.2021-3.RLTS.T22689507A201150685.en (accessed 19 December 2023).CrossRefGoogle Scholar
Brooks, DR and Hoberg, EP (2007) How will global climate change affect parasite–host assemblages? Trends in Parasitology 23, 571574.CrossRefGoogle ScholarPubMed
Brym, MZ, Henry, C and Kendall, RJ (2018) Elevated parasite burdens as a potential mechanism affecting northern bobwhite (Colinus virginianus) population dynamics in the rolling plains of West Texas. Parasitology Research 117, 16831688.CrossRefGoogle ScholarPubMed
Cattadori, IM, Haydon, DT and Hudson, PJ (2005) Parasites and climate synchronize red grouse populations. Nature 433, 737741.CrossRefGoogle Scholar
Chabaud, AG, Anderson, RC and Brygoo, ER (1959) Sept filaries d'Oiseaux Malgaches. Annales de Parasitologie Humanie et Comparée 34, 88109.CrossRefGoogle Scholar
Cooper, JE (1969) Some diseases of birds of prey. Veterinary Record 84, 454457.CrossRefGoogle ScholarPubMed
Crick, HQP (2004) The impact of climate change on birds. Ibis 146, 4856.CrossRefGoogle Scholar
De Pablo, F (2000) Alimentación de la Lechuza Común (Tyto alba) en Menorca. Botlletí de la Societat d'Història Natural de les Balears 43, 1526.Google Scholar
Díaz, EA, Donoso, G, Mosquera, JD, Ramírez-Villacís, DX, González, G, Zapata, S and Cisneros-Heredia, DF (2022) Death by massive air sac fluke (Trematoda: Bothriogaster variolaris) infection in a free-ranging snail kite (Rostrhamus sociabilis). International Journal for Parasitology: Parasites and Wildlife 19, 155160.Google Scholar
Dorai-Raj, S (2022) binom: Binomial Confidence Intervals for Several Parameterizations. R package version 1.1-1.1. Available at https://CRAN.R-project.org/package=binomGoogle Scholar
Dronen, NO, Greiner, EC, Ialeggio, DM and Nolan, TJ (2009) Circumvitellatrema momota n. gen., n. sp. (Digenea: Cyclocoelidae: Cyclocoelinae) from a captive-hatched blue-crowned motmot, Momotus momota (Momotidae). Zootaxa 2161, 6068.CrossRefGoogle Scholar
Edgar, RC (2004) MUSCLE: multiple sequence alignment with high accuracy and high throughput. Nucleic Acids Research 32, 1792.CrossRefGoogle ScholarPubMed
European Environment Agency (2020) Bird populations: latest status and trends. Available at https://www.eea.europa.eu/themes/biodiversity/state-of-nature-in-the-eu/bird-populations-what-are-the (accessed 4 November 2022).Google Scholar
Folmer, O, Black, M, Hoeh, W, Lutz, R and Vrijenhoek, R (1994) DNA primers for amplification of mitochondrial cytochrome c oxidase subunit I from diverse metazoan invertebrates. Molecular Marine Biology and Biotechnology 5, 294299.Google Scholar
Fuller, T, Bensch, S, Müller, I, Novembre, J, Pérez-Tris, J, Ricklefs, RE, Smith, TB and Waldenström, J (2012) The ecology of emerging infectious diseases in migratory birds: an assessment of the role of climate change and priorities for future research. EcoHealth 9, 8088.CrossRefGoogle Scholar
Galosi, L, Heneberg, P, Rossi, G, Sitko, J, Magi, GE and Perrucci, S (2019). Air sac trematodes: Morishitium polonicum as a newly identified cause of death in the common blackbird (Turdus merula). International Journal for Parasitology: Parasites and Wildlife 9, 7479.Google ScholarPubMed
Garamszegi, LZ (2011) Climate change increases the risk of malaria in birds. Global Change Biology 17, 17511759.CrossRefGoogle Scholar
Garcia-Febrero, O, Méndez, X and Escandell, R (2011) Noves aportacions al coneixement de les aus nidificants a Menorca (Illes Balears) 1997–2011. Anuari Ornitològic de les Balears: Revista d'observació estudi i conservació dels aucells 26, 3756.Google Scholar
Garvin, MC, Bates, JM and Kinsella, JM (1997) Field techniques for collecting and preserving helminth parasites from birds, with new geographic and host records of parasitic nematodes from Bolivia. Ornithological Monographs 48, 261266.CrossRefGoogle Scholar
Gomez-Puerta, LA, Ospina, PA, Ramirez, MG and Cribillero, NG (2014) Primer registro del nemátodo Serratospiculum tendo para el Perú. Revista Peruana de Biología 21, 111114.CrossRefGoogle Scholar
Gutiérrez, JS, Piersma, T and Thieltges, DW (2019) Micro- and macroparasite species richness in birds: the role of host life history and ecology. Journal of Animal Ecology 88, 12261239.CrossRefGoogle ScholarPubMed
Hakalahti, T, Karvonen, A and Valtonen, ET (2006) Climate warming and disease risks in temperate regions – Argulus coregoni and Diplostomum spathaceum as case studies. Journal of Helminthology 80, 9398.CrossRefGoogle ScholarPubMed
Hamilton, WD and Marlene, Z (1982) Heritable true fitness and bright birds: a role for parasites? Science (New York, N.Y.) 218, 384387.CrossRefGoogle Scholar
Hartig, F (2022) DHARMa: Residual Diagnostics for Hierarchical (Multi-Level/Mixed) Regression Models. R package version 0.4.6. Available at https://CRAN.R-project.org/package=DHARMaGoogle Scholar
Harvell, CD, Mitchell, CE, Ward, JR, Altizer, S, Dobson, AP, Ostfeld, RS and Samuel, MD (2002). Climate warming and disease risks for terrestrial and marine biota. Science (New York, N.Y.) 296, 21582162.CrossRefGoogle ScholarPubMed
Hoberg, EP and Brooks, DR (2008) A macroevolutionary mosaic: episodic host-switching, geographical colonization and diversification in complex host–parasite systems. Journal of Biogeography 35, 15331550.CrossRefGoogle Scholar
Höfle, U, Krone, O, Blanco, JM and Pizarro, M (2003) Chaunocephalus ferox in free-living white storks in central Spain. Avian Diseases 47, 506512.CrossRefGoogle ScholarPubMed
Ibarra, J, Sierra, RLM, Neira, G, Ibaceta, DEJ and Saggese, MD (2019) Air sac nematode (Serratospiculum tendo) infection in an Austral peregrine falcon (Falco peregrinus cassini) in Argentina. Journal of Wildlife Diseases 55, 179182.Google Scholar
Ishtiaq, F and Renner, SC (2020) Bird migration and vector-borne parasite transmission. In Santiago-Alarcon D and Marzal A (eds), Avian Malaria and Related Parasites in the Tropics: Ecology, Evolution and Systematics. Cham: Springer, pp. 513526. doi: 10.1007/978-3-030-51633-8_16CrossRefGoogle Scholar
Jaume-Ramis, S and Pinya, S (2018) First record of Morishitium polonicum (Machalska, 1980) (Trematoda, Cyclocoelidae) parasitizing Turdus philomelos Brehm, 1831 in Mallorca (Balearic Islands, Spain). Bolletí de la Societat d'Història Natural de Balears 61, 115.Google Scholar
Lavoie, M, Mikaelian, I, Sterner, M, Villeneuve, A, Fitzgerald, G, Mclaughlin, JD, Phane Lair, S and Martineau, D (1999) Respiratory nematodiases in raptors in Quebec. Journal of Wildlife Diseases 35, 375380.CrossRefGoogle Scholar
Liptovszky, M, Majoros, G and Perge, E (2012) Cathaemasia hians in a black stork (Ciconia nigra) in Hungary. Journal of Wildlife Diseases 48, 809811.CrossRefGoogle Scholar
López-Jurado, C, McMinn, M, González, JM, Triay, R, Moss, J and Llabrés, X (2020) Observacions d'aus rares a les Balears al 2020. Anuari Ornitològic de les Balears 35, 86102.Google Scholar
Loye, JE and Zuk, M (1991) Bird–Parasite Interactions. Oxford Ornitology Series. Oxford: Oxford University Press.Google Scholar
Marchesi, L and Sergio, F (2005) Distribution, density, diet and productivity of the scops owl Otus scops in the Italian Alps. Ibis 147, 176187.CrossRefGoogle Scholar
Marzal, A, De Lope, F, Navarro, C and Møller, AP (2005) Malarial parasites decrease reproductive success: an experimental study in a passerine bird. Oecologia 142, 541545.CrossRefGoogle Scholar
Møller, AP, Allander, K and Dufva, R (1990) Fitness effects of parasites on passerine birds: a review. Population Biology of Passerine Birds 24, 269280.CrossRefGoogle Scholar
Møller, AP, Merino, S, Soler, JJ, Antonov, A, Badás, EP, Calero-Torralbo, MA, De Lope, F, Eeva, T, Figuerola, J, Flensted-Jensen, E, Garamszegi, LZ, González-Braojos, S, Gwinner, H, Hanssen, SA, Heylen, D, Ilmonen, P, Klarborg, K, Korpimäki, E, Martínez, J, Martínez-de La Puente, J, Marzal, A, Matthysen, E, Matyjasiak, P, Molina-Morales, M, Moreno, J, Mousseau, TA, Nielsen, JT, Pap, PL, Rivero-De Aguilar, J, Shurulinkov, P, Slagsvold, T, Szép, T, Szöllosi, E, Török, J, Vaclav, R, Valera, F and Ziane, N (2013) Assessing the effects of climate on host–parasite interactions: a comparative study of European birds and their parasites. PLoS ONE 8, 111. doi: 10.1371/journal.pone.0082886CrossRefGoogle ScholarPubMed
Monte, TCC, Simes, RO, Oliveira, APM, Novaes, CF, Thiengo, SC, Silva, AJ, Estrela, PC and Júnior, AM (2012) Phylogenetic relationship of the Brazilian isolates of the rat lungworm Angiostrongylus cantonensis (Nematoda: Metastrongylidae) employing mitochondrial COI gene sequence data. Parasites & Vectors 5, 248. doi: 10.1186/1756-3305-5-248CrossRefGoogle ScholarPubMed
Nadler, SA, Carreno, RA, Mejía-Madrid, H, Ullberg, J, Pagan, C, Houston, R and Hugot, JP (2007) Molecular phylogeny of clade III nematodes reveals multiple origins of tissue parasitism. Parasitology 134, 14211442.CrossRefGoogle ScholarPubMed
Niedringhaus, KD, Dumbacher, JP, Dunker, F, Medina, S, Lawson, B, Fenton, HMA, Higley, JM, Haynes, E and Yabsley, MJ (2023) Apparent prevalence, diversity, and associated lesions of periorbital nematodes in a population of barred owls (Strix varia) from northern California, USA. Journal of Wildlife Diseases 59, 299309.CrossRefGoogle Scholar
Ortiz-von Halle, B (2018) Bird's-eye View: Lessons from 50 Years of Bird Trade Regulation & Conservation in Amazon Countries. Cambridge, UK: TRAFFIC.Google Scholar
Paredes-Esquivel, C, Foronda, P, Dunavan, CP and Cowie, RH (2023) Neuroangiostrongyliasis: rat lungworm invades Europe. The American Journal of Tropical Medicine and Hygiene 108, 857.CrossRefGoogle ScholarPubMed
R Core Team (2023) R: A Language and Environment for Statistical Computing. Vienna, Austria: R Foundation for Statistical Computing.Google Scholar
Reaser, J, Meyerson, L, Cronk, Q, De Poorter, M, Eldrege, L, Green, E, Kairo, M, Latasi, P, Richard, N, Mauremootoo, J, O'Dowd, D, Orapa, W, Sastroutomo, S, Saunders, A, Shine, C, Thrainsson, S and Vaiutu, L (2007) Ecological and socioeconomic impacts of invasive alien species in island ecosystems. Environmental Conservation 34, 98111.CrossRefGoogle Scholar
Salas-Coronas, J, Bargues, MD, Lozano-Serrano, AB, Artigas, P, Martínez-Ortí, A, Mas-Coma, S, Merino-Salas, S and Abad Vivas-Pérez, JI (2021) Evidence of autochthonous transmission of urinary schistosomiasis in Almeria (southeast Spain): an outbreak analysis. Travel Medicine and Infectious Disease 44, 102165. doi: 10.1016/J.TMAID.2021.102165CrossRefGoogle ScholarPubMed
Samour, JH and Naldo, J (2001) Serratospiculiasis in captive falcons in the Middle East: a review. Journal of Avian Medicine and Surgery 15, 29.CrossRefGoogle Scholar
Santoro, M, Tripepi, M, Kinsella, JM, Panebianco, A and Mattiucci, S (2010) Helminth infestation in birds of prey (Accipitriformes and Falconiformes) in southern Italy. The Veterinary Journal 186, 119122.CrossRefGoogle ScholarPubMed
Sitko, J and Heneberg, P (2020a) Emerging helminthiases of song thrush (Turdus philomelos) in Central Europe. Helminthology 119, 41234134.Google ScholarPubMed
Sitko, J and Heneberg, P (2020b) Systemic collapse of a host–parasite trematode network associated with wetland birds in Europe. Parasitology Research 119, 935945.CrossRefGoogle ScholarPubMed
Sitko, J and Heneberg, P (2021) Long-term dynamics of trematode infections in common birds that use farmlands as their feeding habitats. Parasites & Vectors 14, 118.CrossRefGoogle ScholarPubMed
Skrjabin, KJ and Schikhobalova, NP (1936) Contribution au remaiement de la classification des nématodes de l'ordre des Filariata Skrjabin 1915. Annales de Parasitologie Humaine et Comparée 1, 6175.CrossRefGoogle Scholar
Sonin, MD (1966) Filariata of Animals and Man and Diseases Caused by them. Part 1. Aproctoidea. Principles of Nematodology, vol. 17. Moscow: Nauka.Google Scholar
Spaul, EA (1927) On a new species of the nematode genus Aprocta. Journal of Natural History 19, 584588.CrossRefGoogle Scholar
Strachan, A (1957) Eye worms of the family Thelaziidae from Brazilian birds. Canadian Journal of Zoology 35, 179187.CrossRefGoogle Scholar
Tamura, K, Stecher, G and Kumar, S (2021) MEGA11: molecular evolutionary genetics analysis version 11. Molecular Biology and Evolution 38, 30223027.CrossRefGoogle ScholarPubMed
Torres, C, Jordà, G, De Vílchez, P, Vaquer-Sunyer, R, Rita, J, Canals, V, Cladera, A, Escalona, JM and Miranda, (2021). Climate change and their impacts in the Balearic Islands: a guide for policy design in Mediterranean regions. Regional Environmental Change 21, 107. doi: 10.1007/s10113-021-01810-1Google ScholarPubMed
Trujillo, O, Díaz, G and Moreno, M (1989) Alimentación del búho chico (Asio otus canariensis) en gran Canaria (Islas Canarias). Ardeola 36, 193231.Google Scholar
Vanstreels, RET, Yabsley, MJ, Swanepoel, L, Stevens, KL, Carpenter-Kling, T, Ryan, PG and Pistorius, PA (2018) Molecular characterization and lesions associated with Diomedenema diomedeae (Aproctoidea: Desmidocercidae) from grey-headed albatrosses (Thalassarche chrysostoma) on Subantarctic Marion Island. International Journal for Parasitology: Parasites and Wildlife 7, 155.Google ScholarPubMed
Vilcinskas, A (2019) Pathogens associated with invasive or introduced insects threaten the health and diversity of native species. Current Opinion in Insect Science 33, 4348.CrossRefGoogle ScholarPubMed
WCS Colombia (2021) The Extraction of Animals from their Habitats. Wildlife Trafficking Impairs Health of Essential Ecosystems. New York: Wildlife Conservation Society. Available at https://colombia.wcs.org/en-us/WCS-Colombia/News/articleType/ArticleView/articleId/16301/the-extraction-of-animals-from-their-habitats-wildlife-trafficking-impairs-health-of-essential-ecosystem.aspx (accessed 19 December 2023).Google Scholar
Wickham, H (2016) ggplot2: Elegant Graphics for Data Analysis. New York: Springer-Verlag.CrossRefGoogle Scholar
Yoshino, T, Hama, N, Onuma, M, Takagi, M, Sato, K, Matsui, S, Hisaka, M, Yanai, T, Ito, H, Urano, N, Osa, Y and Asakawa, M (2014) Filarial nematodes belonging to the superorders Diplotriaenoidea and Aproctoidea from wild and captive birds in Japan. Journal of the Rakuno Gakuen University 38, 139148.Google Scholar
Zalakevicius, M (2000) Global Climate Change, Bird Migration and Bird Strike Problems. Amsterdam: International Bird Strike Committee.Google Scholar
Zhang, S-Q, Liu, B-C and Zhang, L-P (2012) Two species of Spirurid nematodes (Nematoda, Spirurida) from raptors in Beijing, China. Acta Zootaxonomica Sinica 37, 535541.Google Scholar
Figure 0

Figure 1. Photographs of Lissonema sicki found infecting Strigiformes in this study. (A) Nematodes found free mainly in the thoracic and clavicular air sacs during necropsies. (B) Anterior end of L. sicki, showing the buccal capsule (arrow). (C) Female with the vulva (v) near the cephalic end. (D) Male caudal region. Note the 2 almost equal spicules. Arrows indicate the 3 pairs of postcloacal papillae characteristic of this species.

Figure 1

Figure 2. SEM of the anterior end of L. sicki (A and B, female; C, male). v, vulva; am, amphids; *, **, anterior and posterior papillae of the 4 pairs of cephalic papillae; arrows, 2 trilobed lateral elevations.

Figure 2

Table 1. Comparative morphometry of the air sac nematode Lissonema sicki found in the Strigiformes of this study vs the original redescription and the morphometry of Lissonema noctuae (a closely related species).

Figure 3

Figure 3. SEM of the posterior end of a male of L. sicki. (A) General view of the posterior end; (B) details showing the distribution of cloacal papillae in ventral view. sp, spicules; ph, phasmids; arrows, cloacal papillae.

Figure 4

Figure 4. Maximum-likelihood phylogenetic tree inferred from COI sequences showing the position of L. sicki in relation to other species of the order Spirurida. Bootstrap values (1000 replicates) lower than 50 are not shown.

Figure 5

Figure 5. Maximum-likelihood phylogenetic tree inferred from the 18S sequences showing the position of L. sicki in relation to other species of the order Spirurida. Bootstrap values (1000 replicates) lower than 50 are not shown.

Figure 6

Figure 6. Prevalence of L. sicki in necropsied Strigiformes per year during this study (2010–2022). Graphic created with ‘ggplot2’ R package. Error bars represent the 95% CIs according to the Clopper–Pearson method. Numbers on the upper error bars show the total number of birds necropsied per year and species (Asio otus, Otus scops and Tyto alba, respectively).

Figure 7

Figure 7. Schematic figure representing the possible entry routes of L. sicki to Mallorca (Balearic Islands, Spain). (1) Introduction through illegally traded infected birds, (2) co-introduction with invasive intermediate hosts and (3) introduction through North African birds via migratory routes if L. sicki is a synonym of Lissonema noctuae.

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