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Semperula wallacei (Mollusca, Veronicellidae) um hospedeiro natural recém-descoberto de Angiostrongylus cantonensis (Nematoda, Angiostrongylidae) na Bacia do Pacífico

Published online by Cambridge University Press:  16 January 2024

C.L.F. Mendonça*
Affiliation:
Coleção de Malacologia Médica, Instituto René Rachou/FIOCRUZ, Brazil Laboratório de Helmintologia e Malacologia Médica, Instituto René Rachou/FIOCRUZ, Brazil Instituto de Ciências Biológicas e da Saúde, Pontifícia Universidade Católica de Minas Gerais, Brazil
R.L. Caldeira
Affiliation:
Coleção de Malacologia Médica, Instituto René Rachou/FIOCRUZ, Brazil Laboratório de Helmintologia e Malacologia Médica, Instituto René Rachou/FIOCRUZ, Brazil
O.S. Carvalho
Affiliation:
Laboratório de Helmintologia e Malacologia Médica, Instituto René Rachou/FIOCRUZ, Brazil
S. D’ávila
Affiliation:
Museu de Malacologia Prof. Maury Pinto de Oliveira, Universidade Federal de Juiz de Fora, Brazil
S.R. Gomes
Affiliation:
Laboratório de Malacologia, Instituto Oswaldo Cruz/FIOCRUZ, Brazil
*
Corresponding author: C.L.F. Mendonça; Email: [email protected]
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Abstract

Semperula wallacei (Issel, 1874) is a species of terrestrial slug that occurs in southeast China and the Pacific Basin and is the only species of its genus that occurs beyond the Oriental region and to the east of Wallace’s line in the Australian region, where it has probably been introduced. In this study, we report for the first time S. wallacei as an intermediate host for Angiostrongylus cantonensis (Chen, 1935) based on histological and molecular analyses of slugs from Tuamasaga, Samoa, deposited at the Medical Malacological Collection (Fiocruz-CMM). DNA was obtained from the deparafinized tissues scraped from specimen slides. Polymerase chain reaction and restriction fragment length polymorphism (PCR-RFLP) targeted to the internal transcribed spacer 2 (ITS2) region were carried out using the restriction enzyme Cla I. The RFLP profile observed for our larval specimen of S. wallacei was identical to the profile previously established for A. cantonensis, demonstrating that S. wallacei can be naturally infected with A. cantonensis and is likely to be an intermediate host for this parasitic nematode species in the field. The potential for geographical range expansion of S. wallacei in the Pacific Basin, its small size, and the general role of veronicellids as crop pests and hosts of nematodes, indicate the significance of S. wallacei as an invasive species in the Pacific Basin. Our work also highlights the importance of biological collections for investigating the environmental impact of invasive species on agriculture, public health, and biodiversity conservation.

Type
Short Communication
Copyright
© The Author(s), 2024. Published by Cambridge University Press

Introduction

Angiostrongylus cantonensis (Chen, 1935) is one of the main etiological agents of eosinophilic meningitis in humans (Eamsobhana, Reference Eamsobhana2014). This metastrongyloid is endemic in Asia and the Pacific Basin, where most cases of human infection have occurred, although now it is reported from most parts of the world (Cowie, Reference Cowie2013; Eamsobhana, Reference Eamsobhana2014; Jarvi et al., Reference Jarvi, Quarta, Jacquier, Howe, Bicakci, Dasalla, Lovesy, Snook, McHugh and Niebuhr2017). Currently, A. cantonensis has been reported from Taiwan and other parts of Southeast Asia (Thailand, Malaysia), numerous Pacific islands, including New Caledonia, Vanuatu, Fiji, Guam, Saipan, Chuuk, Pohnpei, Marshall Islands, Tahiti, Cook Islands, Hawaii, Papua New Guinea, Western Samoa, and American Samoa, as well as Okinawa and mainland Japan, Indonesia, the Philippines, Australia, Sri Lanka, India, Réunion, Mauritius, Ivory Coast, Egypt, South Africa, Madagascar, Cuba, Jamaica, Puerto Rico, Haiti, Dominican Republic, Ecuador, Brazil, the Canary Islands, and the southeastern United States (Gomes & Thomé, Reference Gomes and Thomé2001; Hirano et al., Reference Hirano, Yamazaki, Uchida, Saito and Chiba2019; Thiengo et al., Reference Thiengo, Ramos-de-Souza, Silva, Fernandez, Silva, Sousa, Rodrigues, Mattos, Costa and Gomes2022; Cowie et al., Reference Cowie, Ansdell, Panosian and Rollins2022). Additionally, an increasing number of cases have been recorded in locations where A. cantonensis is not considered to be naturally present, including various European countries and the northern United States (Cowie, Reference Cowie2013; Nguyen et al., Reference Nguyen, Rossi, Argy, Baker, Nickel, Marti, Zarrouk, Houzé, Fantin and Lefort2017; Ansdell & Wattanagoon, Reference Ansdell and Wattanagoon2018; Federspiel et al., Reference Federspiel, Skovmand and Skarphedinsson2020; Cowie et al., Reference Cowie, Ansdell, Panosian and Rollins2022), mostly in people returning from regions believed to be within its native biogeographical range.

The life cycle of A. cantonensis occurs mainly in molluscs and rodents. The increasing spread of these intermediate and definitive hosts, respectively, due to globalization, are among the reasons for the currently wide distribution of this species of nematode (Kim et al., Reference Kim, Hayes, Yeung and Cowie2014). The molluscs that act as intermediate hosts have been transported around the world either intentionally or accidentally through various pathways, notably the agricultural and horticultural industries (Cowie et al., Reference Cowie, Hayes, Tran and Meyer2008).

The parasite A. cantonensis can use numerous species of terrestrial, and some aquatic molluscs as intermediate hosts (Valente et al., Reference Valente, Robles and JI2020). Species of Veronicellidae are well known for their public health importance as intermediate hosts for nematodes (Bonetti & Graeff-Teixeira, Reference Bonetti and Graeff-Teixeira1998; Laitano et al., Reference Laitano, Genro, Fontoura, Branco, Maurer, Graeff-Teixeira, Milanez, Chiaradia and Thomé2001; Ohlweiler et al., Reference Ohlweiler, Takahashi, Guimaraes, Gomes and Kawano2010; Carvalho et al., Reference Carvalho, Scholte, Mendonça, Passos and Caldeira2012; Valente et al., Reference Valente, Robles and JI2020; Modrý et al., Reference Modrý, Fecková, Putnová, Manalo and Otranto2021) and for being important agricultural pests (Robinson & Hollingsworth, Reference Robinson and Hollingsworth2005; Ramos et al., Reference Ramos, Gomes, Gutierrez, Ramos-Rodriguez and Uzeda2021). These molluscs are a diverse group that includes endemic species as well as more widespread species that have recently expanded beyond their original native ranges (Gomes & Thomé, Reference Gomes and Thomé2004).

Semperula wallacei (Issel, 1874) is a small veronicellid, having a body length of approximately 40 mm and width of approximately 20 mm. This species can be identified based on both its reproductive system characteristics and molecular markers (Gomes & Thomé, Reference Gomes and Thomé2001; Schilthuizen & Liew, Reference Schilthuizen and Liew2008; Gomes et al., Reference Gomes, Britto da Silva, Mendes, Thomé and Bonatto2010). Semperula wallacei occurs in Australia, China, Fiji, Sarawak, Sulawesi, Sumatra, Samoa, Vanuatu (Gomes & Thomé, Reference Gomes and Thomé2001), American Samoa (Kim et al., Reference Kim, Hayes, Yeung and Cowie2016), and Japan (Hirano et al., Reference Hirano, Yamazaki, Uchida, Saito and Chiba2019). This species is the only member of the genus Semperula found beyond the Oriental region and to the east of Wallace’s line in the Australian region.

In the present study, we report the occurrence of S. wallacei from Tuamasaga, Samoa, infected with larvae of A. cantonensis, using molecular identification of DNA recovered from larval specimens found in histological slides of the snail host.

Material and methods

The results presented below are based on the analysis of four specimens originally from the collection of terrestrial molluscs of the United States of Department of Agriculture (USDA), which were donated to the Collection of the Medical Malacology Research Center René of the Instituto René Rachou/Fiocruz/Minas in the state of Minas Gerais, Brazil. The specimens were collected from the district of Tuamasaga on the island of Upolu, Samoa.

To identify the specimens, three specimens were dissected under a stereomicroscope, starting with a posterior to anterior longitudinal central incision, following the methodology of Thomé & Lopes-Pitoni (Reference Thomé and Lopes-Pitoni1973). The anatomical characteristics of the genus and species were compared with those described by Gomes & Thomé (Reference Gomes and Thomé2001, Reference Gomes and Thomé2004).

For histological analysis, one specimen preserved in 70% ethanol was analyzed. A cross-sectional sample of the slug’s body was clipped, dehydrated in an ethanol series, and then infiltrated with paraffin. Serial cross sections of the paraffin-embedded block of tissue were stained with hematoxylin-eosin (HE) and examined by bright field microscopy. The slides were photographed using a stereoscopic microscope coupled to a camera and captured using the LAS V4.9 software.

For the molecular identification of A. cantonensis, the same histological slides were placed in glass containers containing xylol for 48 h, followed by 10 consecutive washes in absolute alcohol and distilled water. Deparaffinized tissues were scraped from the slides and placed in 1.5 ml Eppendorf tubes containing 600 μl of nuclear lysis solution (Wizard Genomic DNA Purification, Promega). Five μl of proteinase K (125 mg/ml) were added to the lysate and then incubated for 24 h at 55°C. Afterwards, DNA extraction was undertaken using the DNA Wizard Genomic Purification kit (Promega, Madison, USA), according to the manufacturer’s instructions. The resulting pellet was treated with 50 μl DNA dehydration solution for 30 min at 65°C and stored at –20°C (Magalhães et al., Reference Magalhães, Jannotti-Passos, Caldeira, Berne, Muller, Carvalho and Lenzi2008).

For comparison, other nematode species were also included in the study: A. cantonensis and A. costaricensis, which had been stored at –70ºC. Polymerase chain reaction and restriction fragment length polymorphism (PCR-RFLP) directed to the internal transcribed spacer 2 (ITS2) region were carried out using the restriction enzyme Cla I (Caldeira et al., Reference Caldeira, Carvalho, Mendonça, Graeff-Teixeira, Silva, Ben, Maurer, Lima and Lenzi2003).

Results and discussion

Our results demonstrate that the larva present in the fibromuscular layer of the integument of S. wallacei (Figure 1) belongs to A. cantonensis because the molecular profile of the samples analyzed were identical to the profile previously established for this metastrongylid species (Figure 2). This observation was possible because of the efficiency of the method of DNA extraction of A. cantonensis from formalin-fixed, paraffin-embedded, HE-stained histological sections. Using this same methodology, our group was also previously able to detect the liver fluke Fasciola hepatica (Plagiorchiida: Fasciolidae) in the freshwater snail Lymnaea viatrix d’Orbigny, 1835 (Gastropoda: Lymnaeidae) in histological sections using multiplex-PCR (Magalhães et al., Reference Magalhães, Jannotti-Passos, Caldeira, Berne, Muller, Carvalho and Lenzi2008). The wide geographical distribution of S. wallacei in the Pacific Basin and its known proximity to human habitations suggest that it may be a potentially important intermediate host of A. cantonensis. Schilthuizen & Liew (Reference Schilthuizen and Liew2008) mentioned that, although the holotype of S. wallacei is from Sarawak and was collected during a period when alien species introductions resulting from anthropogenic activity were still relatively rare, this species appears not to be native to Borneo because it is only found in disturbed vegetation near human habitation, being present in and around most towns and cities of Sabah, as well as more widely in Southeast Asia and the Pacific islands.

Figure 1. Hematoxylin-eosin-stained histological section showing a larva of the nematode Angiostrongylus cantonensis (arrow) in the fibromuscular layer of the integument of Semperula wallacei.

Figure 2. Silver-stained 6% polyacrylamide gel showing the PCR-RFLP profiles of the ITS2 rDNA digested with the enzyme Cla I. Lane 1: L3 pool of Angiostrongylus costaricensis recovered from Sarasinula linguaeformis (Instituto Oswaldo Cruz, Fiocruz RJ); lanes 2–3: adult worm of Angiostrongylus cantonensis Department of Parasitology, Medical School, Akita University, Japan; lanes 4–6: larvae of A. cantonensis from a histological section of S. wallacei from Tuamasaga, Samoa (this study). Molecular size in base pairs is indicated on the left side of the figure.

The nonnative snail/slug faunas of many of the islands and archipelagos in the Pacific are often composed of cosmopolitan invasive species and contain a subset of this suite species. In many disturbed areas, for example in Hawaii, only nonnative species are present, and these include large species, such as Achatina fulica and other veronicellid slugs (Cowie, Reference Cowie2001).

In recent years, cases of human angiostrongyliasis have increased significantly in China due to increase of living standards and income and modern food consumption trends (Eamsobhana, Reference Eamsobhana2014). By the end of 2009, angiostrongyliasis cases/outbreaks had been reported from at least nine provinces in China, where 457 cases had been identified (Wang et al., Reference Wang, Wu, Wei, Owen and Lun2012).

Several species of gastropods, including terrestrial and freshwater species, can act to varying degrees as intermediate hosts for A. cantonensis (Valente et al., Reference Valente, Robles and JI2020). Of 37 mollusc species analyzed from the Hawaiian Islands, 16 tested positive for A. cantonensis (Kim et al., Reference Kim, Hayes, Yeung and Cowie2014). In Brazil, among 21 species of gastropods collected in 30 ports, four were found positive for A. cantonesis (Carvalho et al., Reference Carvalho, Scholte, Mendonça, Passos and Caldeira2012).

This finding reinforces the importance of health surveillance for eosinophilic meningitis in Samoa because there are already recorded cases of this zoonosis in the Pacific region and possibly in Samoa (Cowie et al., Reference Cowie, Ansdell, Panosian and Rollins2022). Also, there are other alien species of veronicellids reported in Samoa (Gomes & Thomé, Reference Gomes and Thomé2004) that has potential to act as intermediate hosts of nematodes of medical and veterinary importance, considering the historic of this family of slugs, such as Sarasinula plebeia (Fischer, 1868), Veronicella cubensis (Pfeiffer, 1840), and Laevicaulis alte (Férussac, 1822). The potential expanding geographical range of S. wallacei in the Pacific Basin through agriculture trade, its small size, and the generally known role of veronicellids as crop pests and hosts of nematodes, indicate the potential importance of S. wallacei as an invasive species in the Pacific Basin. Our work also highlights the importance of biological collections for investigating the environmental impact of invasive species on agriculture, public health and biodiversity conservation.

Acknowledgements

David Robinson, United States of Department of Agriculture (USDA) for donating specimens of S. wallacei. Dr. Luke Baton for revising the manuscript.

Financial support

This research received no specific grant from any funding agency or commercial or not-for-profit sectors.

Competing interest

The author(s) declare none.

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Figure 0

Figure 1. Hematoxylin-eosin-stained histological section showing a larva of the nematode Angiostrongylus cantonensis (arrow) in the fibromuscular layer of the integument of Semperula wallacei.

Figure 1

Figure 2. Silver-stained 6% polyacrylamide gel showing the PCR-RFLP profiles of the ITS2 rDNA digested with the enzyme Cla I. Lane 1: L3 pool of Angiostrongylus costaricensis recovered from Sarasinula linguaeformis (Instituto Oswaldo Cruz, Fiocruz RJ); lanes 2–3: adult worm of Angiostrongylus cantonensis Department of Parasitology, Medical School, Akita University, Japan; lanes 4–6: larvae of A. cantonensis from a histological section of S. wallacei from Tuamasaga, Samoa (this study). Molecular size in base pairs is indicated on the left side of the figure.