Update of Dicrocoeliidae (Digenea) parasitizing rodents from the Americas with a description of a new <i>Platynosomoides</i> species from Argentina

MARTINS, NATALIA B. GUERREIRO; PANISSE, GUILLERMO; ROBLES, MARÍA DEL ROSARIO; DIAZ, JULIA I.; NAVONE, GRACIELA T.

doi:10.1590/0001-3765202220211430

Abstract

Digeneans are common parasites of small mammals. Dicrocoeliidae is a family with a cosmopolitan distribution, with 18 genera previously recorded from mammals in the Americas, six of them parasitizing rodents in Argentina. In this study, an updated compilation is provided of Dicrocoeliidae from rodents in the Americas. Also, a new Platynosomoides species is described parasitizing the cricetid rodent Akodon montensis of the Atlantic Forest in Argentina. Digital repositories were used to search for Dicrocoeliidae from rodents in the Americas. Rodents were collected in four localities of the Atlantic Forest, Argentina. Digeneans were removed from the rodent’s bile duct, and conventional studies were used for the morphological description. A total of 15 Dicrocoeliidae species were found parasitizing 18 rodent species from eight countries in the Americas. The new species of Platynosomoides from Akodon montensis differs from the other two species of genus by the size of body, testes, ovary, cecum length and position and length of the vitelline bands. Dicrocoeliidae show growing diversity, and the compilation of species in a rodent host base allows a clearer comparison and identification of new taxa in the future.

Key words
Akodon montensis; Argentina; Cricetidae; Dicroceliidae; Platynosomoides; Sigmodontinae

INTRODUCTION

The family Dicrocoeliidae Looss 1899, has a worldwide distribution, being composed of more than 400 species included in 48 genera, parasitizing the bile ducts and gall bladders of birds and placental mammals and, more rarely, reptiles and marsupials. Their life cycles usually involve snails and arthropods as first and second intermediate hosts, respectively (Yamaguti 1971YAMAGUTI S. 1971. Synopsis of digenetic trematodes of vertebrates. Tokyo: Keigaku Publishing Co., 1074 p., Pojmańska 2008POJMAŃSKA T. 2008. Family Dicrocoeliidae Loos, 1899. In: Bray RA, Gibson DI & Jones A (Eds), Keys to the Trematoda. Vol. III. London: CAB International and Natural History Museum, p. 233-260.). To date, 29 genera within this family were recorded in mammals, 18 of them distributed in the Americas. Among these, 11 genera have been previously registered in rodents, six of them in Argentina (Pojmańska 2008POJMAŃSKA T. 2008. Family Dicrocoeliidae Loos, 1899. In: Bray RA, Gibson DI & Jones A (Eds), Keys to the Trematoda. Vol. III. London: CAB International and Natural History Museum, p. 233-260., Fernandes et al. 2015FERNANDES BMM, JUSTO MCN, CARDENAS MQ & COHEN SC. 2015. South American trematodes parasites of birds and mammals. Rio de Janeiro: Oficina de Livros, 516 p., Panisse et al. 2017PANISSE G, ROBLES MR, DIGIANI MC, NOTARNICOLA J, GALLIARI C & NAVONE GT. 2017. Description of the helminth communities of sympatric rodents (Muroidea: Cricetidae) from the Atlantic Forest in northeastern Argentina. Zootaxa 4337(2): 243-262., Guerreiro Martins et al. 2019bGUERREIRO MARTINS NB, ROBLES MDR, DIAZ JI, PANISSE G & NAVONE GT. 2019b. Digenean parasites of Sigmodontinae rodents from Argentina: a list of species, new host, and geographical records. Acta Parasitol 65(1): 97-107.).

Regarding dicrocoelids, the diagnosis of the genera is based on a combination of morphological characters, such as location of genital pore, testes, vitelline bands, and size of the ventral sucker (Pojmańska 2008POJMAŃSKA T. 2008. Family Dicrocoeliidae Loos, 1899. In: Bray RA, Gibson DI & Jones A (Eds), Keys to the Trematoda. Vol. III. London: CAB International and Natural History Museum, p. 233-260.). In the last revision of this family, Pojmańska (2008)POJMAŃSKA T. 2008. Family Dicrocoeliidae Loos, 1899. In: Bray RA, Gibson DI & Jones A (Eds), Keys to the Trematoda. Vol. III. London: CAB International and Natural History Museum, p. 233-260. distinguished four subfamilies based on the relative position of gonads, vitelline bands, and uterus. However, molecular phylogeny does not support this proposal (Tkach et al. 2018TKACH VV, ACHATZ TJ, HILDEBRAND J & GREIMAN SE. 2018. Convoluted history and confusing morphology: Molecular phylogenetic analysis of dicrocoeliids reveals true systematic position of the Anenterotrematidae Yamaguti, 1958 (Platyhelminthes, Digenea). Parasitol Int 67(4): 501-508., Hildebrand et al. 2019HILDEBRAND J, PYRKA E, SITKO J, JEŻEWSKI W, ZALEŚNY G, TKACH VV & LASKOWSKI Z. 2019. Molecular phylogeny provides new insights on the taxonomy and composition of Lyperosomum Looss, 1899 (Digenea, Dicrocoeliidae) and related genera. Int J Parasitol Parasites Wildl 9: 90-99.).

Despite several representative taxa of Dicrocoeliidae being included in molecular studies, only three species parasitic of American rodents have sequences available in GenBank (Martínez-Ibeas et al. 2011MARTÍNEZ-IBEAS AM, MARTÍNEZ-VALLADARES M, GONZÁLEZ-LANZA C, MIÑAMBRES B & MANGA-GONZÁLEZ MY. 2011. Detection of Dicrocoelium dendriticum larval stages in mollusk and ant intermediate hosts by PCR, using mitochondrial and ribosomal internal transcribed spacer (ITS-2) sequences. Parasitology 138(14): 1916-1923., Pinto et al. 2018PINTO HA, PULIDO-MURILLO EA, BRAGA RR, MATI VL, MELO AL & TKACH VV. 2018. DNA sequences confirm low specificity to definitive host and wide distribution of the cat pathogen Platynosomum illiciens (= P. fastosum) (Trematoda: Dicrocoeliidae). Parasitol Res 117(6): 1975-1978., Hildebrand et al. 2019HILDEBRAND J, PYRKA E, SITKO J, JEŻEWSKI W, ZALEŚNY G, TKACH VV & LASKOWSKI Z. 2019. Molecular phylogeny provides new insights on the taxonomy and composition of Lyperosomum Looss, 1899 (Digenea, Dicrocoeliidae) and related genera. Int J Parasitol Parasites Wildl 9: 90-99.). Several taxonomic keys have compiled digenean diversity around the world, with few of them mentioning the species (Yamaguti 1971YAMAGUTI S. 1971. Synopsis of digenetic trematodes of vertebrates. Tokyo: Keigaku Publishing Co., 1074 p., Gibson et al. 2002GIBSON DI, JONES A & BRAY RA. 2002. Keys to the Trematoda. Vol. I. London: CAB International & Natural History Museum, 544 p., Jones et al. 2005JONES A, BRAY RA & GIBSON DI. 2005. Keys to the Trematoda. Vol. II. London: CAB International & Natural History Museum, 768 p., Bray et al. 2008BRAY RA, GIBSON DI & JONES A. 2008. Keys to the Trematoda. Vol. III. London: CAB International and Natural History Museum, 848 p.). The cricetid rodents deserve greater attention as hosts of these parasites, since in recent years there has been a growing diversity of genera and species not yet registered (Panisse et al. 2017PANISSE G, ROBLES MR, DIGIANI MC, NOTARNICOLA J, GALLIARI C & NAVONE GT. 2017. Description of the helminth communities of sympatric rodents (Muroidea: Cricetidae) from the Atlantic Forest in northeastern Argentina. Zootaxa 4337(2): 243-262., Guerreiro Martins et al. 2019aGUERREIRO MARTINS NB, ROBLES MDR, DIAZ JI, KINSELLA JM & NAVONE GT. 2019a. Cladorchis pyriformis (Diesing, 1838) (Digenea, Cladorchiidae): new rodent host and geographic records in Argentina. Check List 15(4): 645-650., b, Preisser & Falcón-Ordaz 2019PREISSER WC & FALCÓN-ORDAZ J. 2019. A checklist of the parasitic helminths of cricetid and heteromyid rodents in Mexico. Therya 10(3): 329-341.).

In this study, an updated compilation is provided of Dicrocoeliidae from rodents in the Americas. Also, a new Platynosomoides species is described based on morphological characteristics, parasitizing the cricetid rodent Akodon montensis Thomas 1913 of the Atlantic Forest in Argentina.

The ZooBank Life Science Identifier (LSID) of this publication is: urn:lsid:zoobank.org:pub:058703F3-DDC4-42CF-8648-9EEF8548391F.

MATERIALS AND METHODS

The compilation of species data of Dicrocoeliidae from American rodents was performed using the digital repositories Scielo, Redalyc, Scopus, Dialnet, Pubmed, and Google Academic. Reports were found using the descriptor words: Dicrocoeliidae, Platynosomoides sp., and Rodentia.

A total of 190 Akodon montensis specimens were collected by several collaborators (see Acknowledgments) between 2009 and 2013 in Misiones Province, Argentina: 80 from Campo Anexo M. Belgrano, INTA (26º 02’54.21”S; 53º 46’32.40”W); 82 from Parque Provincial Urugua-í (25º51’25.58”S; 54º09’59.87”W); 4 from Sendero de la Gruta, Parque Provincial Moconá (27°9’23.52”S; 53°54’10.26”W); and 24 from Reserva de Vida Silvestre Urugua-í, Fundación Vida Silvestre (25º58’32.29”S; 54º 07’00.08”W).

The research has been conducted according to Argentine laws. Sample collection was carried out during fieldwork under official permits granted by Ministerio de Ecología, RNR y Turismo, Provincia de Misiones (authorization #23 and #27. Guía Tránsito 000316, 000685 and 000699), in accordance with the recommendations in the Guide for the Care and Use of Laboratory Animals of the National Institutes of Health. Rodent specimens were collected following the procedures and protocols approved by national laws (Animal Protection National law 14.346 and references in the provincial permits) and Ethics Committee for Research on Laboratory Animals, Farm and Obtained from Nature of National Council of Scientific and Technical Research (CONICET). No endangered species were involved in this study.

Dicrocoelids were removed from the rodent’s bile duct, subsequently fixed in 10% formalin, preserved in 70% ethanol, stained with hydrochloric carmine, dehydrated through an alcohol series, cleared in eugenol, and studied by light microscopy (Leica MZ6® and Olympus BX51®). Drawings were made with the aid of a drawing tube. One specimen was dried using the critical point method, examined using the scanning electron microscope (JEOL/JSMT 6360 LV®). Family and generic identification were made following the keys of Yamaguti (1971)YAMAGUTI S. 1971. Synopsis of digenetic trematodes of vertebrates. Tokyo: Keigaku Publishing Co., 1074 p. and Bray et al. (2008)BRAY RA, GIBSON DI & JONES A. 2008. Keys to the Trematoda. Vol. III. London: CAB International and Natural History Museum, 848 p..

Prevalence (P), mean intensity (MI), and mean abundance (MA) were calculated according to Bush et al. (1997)BUSH AO, LAFFERTY KD, LOTZ JM & SHOSTAK AW. 1997. Parasitology meets ecology on its own terms: Margolis et al. revisited. J Parasitol 83: 575-583.. In the description, measurements of specimens are presented as follows: mean, standard deviation, and range in parentheses. All measurements are given in millimeters (mm) unless otherwise indicated. The scales of figures are given in micrometers (μm).

The nomenclatural acts have been registered in ZooBank, the online registration system for the ICZN. Type specimens were deposited in the helminthological collection of Museo de La Plata (MLP-He), La Plata, Buenos Aires, and hosts in the mammalogy collection of Centro Nacional Patagónico (CNP), Puerto Madryn, Chubut.

RESULTS

An updated compilation of Dicrocoeliidae species parasitizing rodents in the Americas is provided in Table I. A total of 14 species were recorded from 18 host species in eight countries.

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Table I
Morphological features and measurements (mm) of Dicrocoeliidae species from rodents in the Americas.

A total of 47 dicrocoelid specimens were found in the bile duct of 10 Akodon montensis and were identified as a new species of Platynosomoides described below.

Platynosomoides lunaschiae sp. nov. (Table II, Figs. 1-2)

Description (based on 15 complete stained specimens): Plagiorchiida: Dicrocoeliidae. Fusiform body (Fig. 1a), 2.18 ± 0.33 (1.79-2.84) long by 1.16 ± 0.21 (0.92-1.59) wide. Tegument unspined covered by papillae (Figs. 2a-b). Oral sucker rounded, 0.31 ± 0.05 (0.19-0.39) long by 0.29 ± 0.06 (0.21-0.38) wide. Ventral sucker rounded, 0.38 ± 0.06 (0.29-0.48) long by 0.34 ± 0.06 (0.23-0.44) wide. Pharynx, 0.13 ± 0.01 (0.11-0.15) long by 0.12 ± 0.01 (0.9-0.13) wide. Esophagus short. Cecal bifurcation in the forebody, just anterior to the ventral sucker. Long ceca, extending up to three-quarters of the body (Fig. 1a). Rounded testis located immediately posterolateral to the ventral sucker. Right testis 0.16 ± 0.03 (0.07-0.20) long by 0.15 ± 0.03 (0.06-0.18) wide; left testis 0.14 ± 0.03 (0.06-0.18) long by 0.13 ± 0.02 (0.05-0.15) wide (Fig. 1a). Cirrus sac short, located between the ventral sucker and the cecal bifurcation, 0.22 long by 0.1 wide. Genital pore at level of pharynx (Fig. 1b). Ovary rounded, 0.14 ± 0.03 (0.11-0.2) long by 0.12 ± 0.02 (0.09-0.18) wide, located posterior to the right or left testis (Fig. 1c). Uterus intercecal, occupying the entire hindbody (Fig. 1a). Vitelline bands extracecal, extending from the level of the ventral sucker up to 2/3 of the body length, not overlapping the end of the ceca (Fig. 1a). Eggs 32.43 ± 1.69 (29.04-34.98) µm long by 17.62 ± 2.02 (14.51-20.8) µm wide.

Figure 1
Drawing of Platynosomoides lunaschiae sp. nov. a) Complete adult specimen, ventral view. b) Detail of cirrus sac, with internal seminal vesicle (isv) and cirrus (ci). c) Detail of the ovarian complex, showing ovary (ov), oviduct (ovd), seminal receptacle (sr) and ootype (oo).

Figure 2
SEM images of Platynosomoides lunaschiae sp. nov. a), b) Details of tegument papillae, lateral view.

Taxonomic summary

Type host: Akodon montensis Thomas 1913

Symbiotype: with collection number in process, field numbers: CG 159. Other hosts: CNP 3724, 4069, 5191, 5255, 5274

Site of infection: Bile duct

Type locality: Parque Provincial Urugua-í, Misiones province, Argentina (25º51’25.58” S; 54º09’59.87” W)

Other localities: Campo Anexo M. Belgrano, Parque Provincial Moconá and Reserva de Vida Silvestre Urugua-í, Misiones province, Argentina

Specimens deposited: Holotype (No. 7324), Paratype (No. 7709) and a total of three Voucher specimens (Nos. 7573, 7710, 7711) were deposited at MLP-He

Host-parasite data: P=5.26%, IM=4.7 and AM=0.25. The values of P, MI, and MA in the different sampling areas were: Campo Anexo M. Belgrano P=1.2% (1/80), IM=5, and AM-0.1; Parque Provincial Urugua-í P=7.3% (6/82), IM=5.2, and AM=0.4; Sendero La Gruta, Parque Provincial Moconá P=25% (1/4), IM=2, and AM= 0.5; and Reserva de Vida Silvestre Urugua-í P=8.3% (2/24), IM=4.5, and AM=0.4

Etymology: to Dr. Lía I. Lunaschi in recognition of her work in the helminthological collection of Museo de La Plata and valuable contributions to knowledge of the digenean

Recorded in URN as: urn:lsid:zoobank.org:act:E3261D6F-09DC-45E2-B4FD-87253620B7F1

Remarks: Only two nominal species are located in Platynosomoides: P. muris (Shcherbakova 1942) and P. verschureni (Baer 1901) (Pojmańska 2008POJMAŃSKA T. 2008. Family Dicrocoeliidae Loos, 1899. In: Bray RA, Gibson DI & Jones A (Eds), Keys to the Trematoda. Vol. III. London: CAB International and Natural History Museum, p. 233-260.) (Table II). Platynosomoides lunaschiae sp. nov. is distinguished from these two species by the body length (1.79-2.84 vs. 3.27-3.41; 3-4.5, respectively), length and width of testis (0.06-0.20 x 0.05-0.18 vs. 0.24-0.41 x 0.25-0.36; 0.32 x 0.23, respectively). The ovary in the new species is smaller than in P. muris (0.09-0.18 vs. 0.23-0.24). Also, in the new species the ovary and testis have similar size, whereas in P. muris the testes are larger than the ovary. In addition, P. lunaschiae sp. nov. has ceca and vitelline bands extending to three-quarters of the body, while in P. muris the ceca extend to the end of the body and the vitelline bands reach up to two-thirds of the body, and in P. verschureni the ceca and vitelline bands extend up to the middle of the body.

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Table II
Morphological features and measurements (mm) of Platynosomoides species.

DISCUSSION

Dicrocoeliidae shows a high morphological diversity with 18 genera parasitizing mammals of the Americas, 11 of them in rodents (McIntosch 1939MCINTOSCH A. 1939. A new dicrocoeliid trematode, Furytrema komareki n. sp., from a white footed mouse. Proc Helminthol Soc Wash 6(1): 18-19., Neidert & Ralph 1968NEIDERT CM & RALPH WM. 1968. Concinnum peromysci sp. n. (Trematoda: Dicrocoeliidae) from Peromyscus maniculatus in Oregon. Am Midl Nat 79(2): 525-528., Lamothe-Argumedo et al. 2005LAMOTHE-ARGUMEDO R, FALCÓN-ORDAZ J, GARCÍA-PRIETO L & FERNÁNDEZ-FERNÁNDEZ J. 2005. A new dicrocoeliid (Digenea: Dicrocoeliinae) parasite of rodents from Tlaxcala, Mexico. J Parasitol 91(6): 1410-1412., Pojmańska 2008POJMAŃSKA T. 2008. Family Dicrocoeliidae Loos, 1899. In: Bray RA, Gibson DI & Jones A (Eds), Keys to the Trematoda. Vol. III. London: CAB International and Natural History Museum, p. 233-260., Fernandes et al. 2015FERNANDES BMM, JUSTO MCN, CARDENAS MQ & COHEN SC. 2015. South American trematodes parasites of birds and mammals. Rio de Janeiro: Oficina de Livros, 516 p., Panisse et al. 2017PANISSE G, ROBLES MR, DIGIANI MC, NOTARNICOLA J, GALLIARI C & NAVONE GT. 2017. Description of the helminth communities of sympatric rodents (Muroidea: Cricetidae) from the Atlantic Forest in northeastern Argentina. Zootaxa 4337(2): 243-262.). Nine of these genera were registered from the Neotropical region: Athesmia Looss 1899, Caballerolecythus Lamothe-Argumedo, Falcón-Ordaz, García-Prieto & Fernandez-Fernandez 2005, Canaania Travassos 1944, Conspicuum Bhalerao 1936, Dicrocoelium Dujardin 1845, Platynosomoides Yamaguti 1971YAMAGUTI S. 1971. Synopsis of digenetic trematodes of vertebrates. Tokyo: Keigaku Publishing Co., 1074 p., Platynosomum Looss 1907, Yungasicola Gardner & Pérez-Ponce de Leon 2002, and Zonorchis Travassos 1944.

Dicrocoelids of American rodents are distributed in five host families: Cricetidae, Echimyidae, Heteromyidae, Muridae, and Myocastoridae, the first being the most frequent (Sutton 1983SUTTON CA. 1983. Contribución al conocimiento de la fauna parasitológica argentina XI. Digeneos en roedores bonaerenses. Neotropica 29: 19-26., Sutton & Damborenea 1996SUTTON CA & DAMBORENEA MC. 1996. Colección Helmintológica del Museo de La Plata: I. Catálogo de preparaciones microscópicas, material tipo y no tipo. Seria Técnica y Didáctica Museo de La Plata 35: 1-20., Navone et al. 2009NAVONE GT, NOTARNICOLA J, NAVA S, ROBLES MDR, GALLIARI C & LARESCHI M. 2009. Arthropods and helminthes assemblage in sigmodontine rodents from wetlands of the Río de la Plata, Argentina. Mastozool Neotrop 16: 121-133., Fernandes et al. 2015FERNANDES BMM, JUSTO MCN, CARDENAS MQ & COHEN SC. 2015. South American trematodes parasites of birds and mammals. Rio de Janeiro: Oficina de Livros, 516 p., Panisse et al. 2017PANISSE G, ROBLES MR, DIGIANI MC, NOTARNICOLA J, GALLIARI C & NAVONE GT. 2017. Description of the helminth communities of sympatric rodents (Muroidea: Cricetidae) from the Atlantic Forest in northeastern Argentina. Zootaxa 4337(2): 243-262., Guerreiro Martins et al. 2019bGUERREIRO MARTINS NB, ROBLES MDR, DIAZ JI, PANISSE G & NAVONE GT. 2019b. Digenean parasites of Sigmodontinae rodents from Argentina: a list of species, new host, and geographical records. Acta Parasitol 65(1): 97-107.). Six dicrocoelid species (Canaania obesa Travassos 1944, Conspicuum minor Mañé-Garzón & Holcman-Spector 1975, Conspicuum pulchrum (Travassos 1919), Platynsomoides sp., Yungasicola travassosi Gardner & Pérez-Ponce de León 2002, Zonorchis oxymycterae Sutton 1983SUTTON CA. 1983. Contribución al conocimiento de la fauna parasitológica argentina XI. Digeneos en roedores bonaerenses. Neotropica 29: 19-26.) were recorded parasitizing Akodontini rodents (Cricetidae) (Travassos et al. 1969TRAVASSOS L, FREITAS JF & KOHN A. 1969. Trematódeos do Brasil. Mem Inst Oswaldo Cruz 67(1): 1-886., Sutton 1983SUTTON CA. 1983. Contribución al conocimiento de la fauna parasitológica argentina XI. Digeneos en roedores bonaerenses. Neotropica 29: 19-26., Sutton 1998SUTTON CA. 1998. Primer registro y redescripción de Conspicuum minor Mañé-Garzón y Holcman-Spector, 1975 (Digenea, Dicrocoelidae) en Argentina. Gayana Zool 62: 221-224., Maldonado Junior et al. 2010 Panisse et al. 2017PANISSE G, ROBLES MR, DIGIANI MC, NOTARNICOLA J, GALLIARI C & NAVONE GT. 2017. Description of the helminth communities of sympatric rodents (Muroidea: Cricetidae) from the Atlantic Forest in northeastern Argentina. Zootaxa 4337(2): 243-262.).

Four dicrocoelid species have been recorded parasitizing the genus Akodon: C. obesa from A. azarae, Akodon cursor (Winge 1887) and A. montensis in Argentina and Brazil; Platynosomoides sp. from A. montensis in Argentina (Maldonado Junior et al. 2010 Panisse et al. 2017PANISSE G, ROBLES MR, DIGIANI MC, NOTARNICOLA J, GALLIARI C & NAVONE GT. 2017. Description of the helminth communities of sympatric rodents (Muroidea: Cricetidae) from the Atlantic Forest in northeastern Argentina. Zootaxa 4337(2): 243-262., Guerreiro Martins et al. 2019bGUERREIRO MARTINS NB, ROBLES MDR, DIAZ JI, PANISSE G & NAVONE GT. 2019b. Digenean parasites of Sigmodontinae rodents from Argentina: a list of species, new host, and geographical records. Acta Parasitol 65(1): 97-107.); Y. travassosi from Akodon fumeus Thomas 1902 in Bolivia (Gardner & Pérez-Ponce de Léon 2002GARDNER SL & PÉREZ-PONCE DE LÉON G. 2002. Yungasicola travassosi gen. n., sp. n. (Digenea: Dicrocoeliidae: Eurytrematinae) from two species of grass mice of the genus Akodon Meyen (Rodentia: Muridae) from the Yungas of Bolivia. Comp Parasitol 69(1): 51-58.); and Z. oxymycterae from A. azarae in Argentina (Sutton 1983SUTTON CA. 1983. Contribución al conocimiento de la fauna parasitológica argentina XI. Digeneos en roedores bonaerenses. Neotropica 29: 19-26.). Although Platynosomoides sp. was mentioned by Panisse et al. (2017)PANISSE G, ROBLES MR, DIGIANI MC, NOTARNICOLA J, GALLIARI C & NAVONE GT. 2017. Description of the helminth communities of sympatric rodents (Muroidea: Cricetidae) from the Atlantic Forest in northeastern Argentina. Zootaxa 4337(2): 243-262. as the first record of this genus in Cricetidae and in America, no description was provided. Notably, the genus Platynosomoides has been reported parasitizing only two families of rodents, Muridae from Asia, and Soricidae from Africa (Stcherbakova 1942STCHERBAKOVA E. 1942. Studies on helminth fauna of rodents from Armenia (in Russian). Bull Armenian Branch Acad Sci USSR 1: 159-173., Baer 1959BAER JG. 1959. Helminthes parasites. Exploration des Parcs Nationaux du Congo Belge. Fasc. 1. Mission J. G. Baer-W. Gerber (1958). Brussels, Belgium: Instituts des Parcs Nationals, Congo Belge, 163 p.).

The main morphological differences between P. lunaschiae sp. nov. and the other three dicrocoelid species reported from Akodon spp. are the distribution and length of the vitelline bands, and the position of the testes. The new species is distinguished from C. obesa and Z. oxymycterae by the size of the ventral and oral suckers. Platynosomoides lunaschiae sp. nov. is also differentiated from Y. travassosi by cecum length and the size of the uterus. Platynosomoides lunaschiae sp. nov. was found in four geographic localities of the Atlantic Forest in Misiones Province, with low prevalence similar to those recorded for other dicrocoelids in the Akodon species (Navone et al. 2009NAVONE GT, NOTARNICOLA J, NAVA S, ROBLES MDR, GALLIARI C & LARESCHI M. 2009. Arthropods and helminthes assemblage in sigmodontine rodents from wetlands of the Río de la Plata, Argentina. Mastozool Neotrop 16: 121-133., Maldonado Junior et al. 2010, Simões et al. 2011SIMÕES RO, SOUZA JGR, MALDONADO JR A & LUQUE JL. 2011. Variation in the helminth community structure of three sympatric Sigmodontine rodents from the coastal Atlantic Forest of Rio de Janeiro, Brazil. J Helminthol 85: 171-178.).

To date, few molecular studies have been performed on dicrocoelid species parasitizing rodents in the Americas (Table I). The only three species with data available in GenBank are Dicrocoelium dendriticum, Lyperosomum intermedium Denton & Kinsella 1972DENTON JF & KINSELLA JM. 1972. Lyperosomum intermedium sp. n. (Digenea: Dicrocoeliidae) from the rice rat, Oryzomys palustris, from southeastern salt marshes. J Parasitol 58(2): 226-228., and Platynosomum illiciens (Braun 1901) (Martínez-Ibeas et al. 2011MARTÍNEZ-IBEAS AM, MARTÍNEZ-VALLADARES M, GONZÁLEZ-LANZA C, MIÑAMBRES B & MANGA-GONZÁLEZ MY. 2011. Detection of Dicrocoelium dendriticum larval stages in mollusk and ant intermediate hosts by PCR, using mitochondrial and ribosomal internal transcribed spacer (ITS-2) sequences. Parasitology 138(14): 1916-1923., Pinto et al. 2018PINTO HA, PULIDO-MURILLO EA, BRAGA RR, MATI VL, MELO AL & TKACH VV. 2018. DNA sequences confirm low specificity to definitive host and wide distribution of the cat pathogen Platynosomum illiciens (= P. fastosum) (Trematoda: Dicrocoeliidae). Parasitol Res 117(6): 1975-1978., Hildebrand et al. 2019HILDEBRAND J, PYRKA E, SITKO J, JEŻEWSKI W, ZALEŚNY G, TKACH VV & LASKOWSKI Z. 2019. Molecular phylogeny provides new insights on the taxonomy and composition of Lyperosomum Looss, 1899 (Digenea, Dicrocoeliidae) and related genera. Int J Parasitol Parasites Wildl 9: 90-99.). Regarding the new species, despite extracting DNA, no molecular results were obtained, possibly due to inadequate conservation of the specimens. However, the morphological and morphometric comparison of the present specimens and the previously described species support the erection of a new species.

The taxonomy of the Dicrocoeliidae has been controversial, with many species being transferred from one genus to another. For example, Pojmańska (2008)POJMAŃSKA T. 2008. Family Dicrocoeliidae Loos, 1899. In: Bray RA, Gibson DI & Jones A (Eds), Keys to the Trematoda. Vol. III. London: CAB International and Natural History Museum, p. 233-260. suggested the synonymy of Zonorchis with Skrjabinus. However, considering the position of the reproductive organs and the morphology and size of the ventral sucker, the present study considers both genera as valid, following Sitko (2013)SITKO J. 2013. Redescription of Skrjabinus skrjabini and validity reassessment of selected species of Skrjabinus (Digenea, Dicrocoeliidae). Helminthologia 50(4): 281-286. and Hildebrand et al. (2019)HILDEBRAND J, PYRKA E, SITKO J, JEŻEWSKI W, ZALEŚNY G, TKACH VV & LASKOWSKI Z. 2019. Molecular phylogeny provides new insights on the taxonomy and composition of Lyperosomum Looss, 1899 (Digenea, Dicrocoeliidae) and related genera. Int J Parasitol Parasites Wildl 9: 90-99.. In turn, Nguyen & Pham (2004)NGUYEN TL & PHAM ND. 2004. On some trematoda species of three genera Dictyonograptus Travassos, 1919; Platynosomoides Yamaguti, 1971 and Skrjabinus (Bhalerao, 1936) (Dicrocoeliidae). Tap Chi Sinh Hoc 26(3): 1-4. suggested that Platynosomoides muris should be transferred to the genus Dictyonograptus. This paper does not follow that proposal, since that species presents diagnostic features of Platynosomoides that agree with Pojmańska (2008)POJMAŃSKA T. 2008. Family Dicrocoeliidae Loos, 1899. In: Bray RA, Gibson DI & Jones A (Eds), Keys to the Trematoda. Vol. III. London: CAB International and Natural History Museum, p. 233-260., such as vitelline bands extending from ventral sucker level to far beyond the ovary. Platynosomoides verschureni was originally described in the genus Platynosomum (Baer 1959BAER JG. 1959. Helminthes parasites. Exploration des Parcs Nationaux du Congo Belge. Fasc. 1. Mission J. G. Baer-W. Gerber (1958). Brussels, Belgium: Instituts des Parcs Nationals, Congo Belge, 163 p.), and Yamaguti (1971)YAMAGUTI S. 1971. Synopsis of digenetic trematodes of vertebrates. Tokyo: Keigaku Publishing Co., 1074 p. later suggested that it should be referred to as Platynosomoides. Pojmańska (2008)POJMAŃSKA T. 2008. Family Dicrocoeliidae Loos, 1899. In: Bray RA, Gibson DI & Jones A (Eds), Keys to the Trematoda. Vol. III. London: CAB International and Natural History Museum, p. 233-260. agrees with this proposal, including the geographic distribution of the two species within the Platynosomoides genus.

Digenean-host associations occur within a complex system of biotic and abiotic factors. Three types of life cycle have been suggested for the family Dicrocoeliidae (Pojmańska 2008POJMAŃSKA T. 2008. Family Dicrocoeliidae Loos, 1899. In: Bray RA, Gibson DI & Jones A (Eds), Keys to the Trematoda. Vol. III. London: CAB International and Natural History Museum, p. 233-260.). Ecological aspects of the Platynosomoides species, such as dispersal ability, survival conditions, and adequate hosts, have not yet been studied. However, considering that the host species are terrestrial and omnivorous, feeding mainly on green vegetation, leaves, fruit, seeds, and arthropods (Houemenou et al. 2014HOUEMENOU G, KASSA B & LIBOIS R. 2014. Ecologie, diversité spécifique et abondance des petits mammifères de la ville de Cotonou au Bénin (Afrique de l’Ouest). Int J Biol Chem Sci 8(3): 1202-1213., Latinne et al. 2014LATINNE A, GALAN M, WAENGSOTHORN S, ROJANADILOK P, EIAMAMPAI K, SRIBUAROD K & MICHAUX J. 2014. Diet analysis of Leopoldamys neilli, a cave-dwelling rodent in Southeast Asia, using next-generation sequencing from feces. J Caves Karst Stud 76: 139-145., Pardiñas et al. 2017PARDIÑAS UFJ, MYERS P, LEÓN-PANIAGUA L, ORDÓÑEZ GARZA N, COOK JA, KRYŠTUFEK B, HASLAUER R, BRADLEY RD, SHENBROT GI & PATTON JL. 2017. Family Cricetidae (true hamsters, voles, lemmings and New World rats and mice). In: Wilson DE, Lacher TE & Mittermeier RA (Eds), Handbook of the mammals of the world, Vol. 7. Rodents II. Lynx Editions, Barcelona, Spain, p. 204-279., Schlitter et al. 2021SCHLITTER D, VAN DER STRAETEN E, AMORI G, HUTTERER R, KRYŠTUFEK B, YIGIT N & MITSAINAS G. 2021. Apodemus sylvaticus (Linnaeus, 1758). The IUCN Red List of Threatened Species 2021: htps://doi.org/10.2305/IUCN.UK.2021-1.RLTS.T1904A197270811.en.), some invertebrates, such as mollusks and arthropods, may act as intermediate hosts of P. lunaschiae sp. nov. as occurs in other dicrocoelid species.

To date, Athesmia heterolecithodes (Braun 1899), Canaania obesa, Conspicuum minor, Dicrocoelium dendriticum (Rudolphi 1819), Platynosomoides lunaschiae sp. nov. and Zonorchis oxymycterae are the only Dicrocoellidae of rodents recorded from Argentina (Martínez & Binda 1992MARTÍNEZ FA & BINDA JL. 1992. Athesmia heterolecithodes (Braun, 1899) Looss, 1899 (Trematoda, Dicrocoeliidae) en Myocastor coypus. Vet Argent 9: 98-101., Sutton 1998SUTTON CA. 1998. Primer registro y redescripción de Conspicuum minor Mañé-Garzón y Holcman-Spector, 1975 (Digenea, Dicrocoelidae) en Argentina. Gayana Zool 62: 221-224., Martino et al. 2012MARTINO PE, RADMAN N, PARRADO E, BAUTISTA E, CISTERNA C, SILVESTRINI MP & CORBA S. 2012. Note on the occurrence of parasites of the wild nutria (Myocastor coypus, Molina, 1782). Helminthologia 49(3): 164-168., Panisse et al. 2017PANISSE G, ROBLES MR, DIGIANI MC, NOTARNICOLA J, GALLIARI C & NAVONE GT. 2017. Description of the helminth communities of sympatric rodents (Muroidea: Cricetidae) from the Atlantic Forest in northeastern Argentina. Zootaxa 4337(2): 243-262., Guerreiro Martins et al. 2019bGUERREIRO MARTINS NB, ROBLES MDR, DIAZ JI, PANISSE G & NAVONE GT. 2019b. Digenean parasites of Sigmodontinae rodents from Argentina: a list of species, new host, and geographical records. Acta Parasitol 65(1): 97-107.). The records show a growth in knowledge of the diversity of digeneans from rodents in recent years. This is encouraging, since it may indicate that this increase is related to greater interest of taxonomists in these less-explored groups of helminths. This study provides an updated compilation of dicrocoelid species parasitizing rodents in the Americas with the description of a new species of Platynosomoides from the Atlantic Forest, enlarging the host and geographic distribution for this family of Digenea.

ACKNOWLEDGMENTS

We thank Carlos Galliari, Ulyses Pardiñas, Marcela Lareschi, Juliana Notarnicola, Cecilia Ezquiaga, Juliana Sanchez, Ezequiel Palumbo, Jorge Barneche, Julio Torres for their essential help and cooperation in the ﬁeld tasks and host collections, mainly to the first four specialists mentioned, who were part of most of the samplings carried out; to Carlos Galliari and Ulyses Pardiñas for the identification of the hosts, to Patricia Sarmiento for the SEM photographs. The work in Misiones province was authorized by Ernesto Kraucsuk and Facundo Tejeda Cajas (Dirección de Biodiversidad) and Mónica Schroder (Dirección Áreas Naturales Protegidas), both from Ministerio de Ecología y Recursos Naturales Renovables de la Provincia de Misiones. We thank Mariano Chudi by kindness and assistance in P.P.Urugua-í at Seccional Uruzú; Luis Marmelicz, Hugo Fassola and Martín Pinazo for their hospitality and support during the field work at the Campo Anexo Manuel Belgrano-INTA Montecarlo; Pablo Herrera, Manuel Jaramillo and Ariel Tombo for allowance to work at Reserva de Vida Silvestre Urugua-í.

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DENTON JF & KINSELLA JM. 1972. Lyperosomum intermedium sp. n. (Digenea: Dicrocoeliidae) from the rice rat, Oryzomys palustris, from southeastern salt marshes. J Parasitol 58(2): 226-228.
FERNANDES BMM, JUSTO MCN, CARDENAS MQ & COHEN SC. 2015. South American trematodes parasites of birds and mammals. Rio de Janeiro: Oficina de Livros, 516 p.
GARDNER SL & PÉREZ-PONCE DE LÉON G. 2002. Yungasicola travassosi gen. n., sp. n. (Digenea: Dicrocoeliidae: Eurytrematinae) from two species of grass mice of the genus Akodon Meyen (Rodentia: Muridae) from the Yungas of Bolivia. Comp Parasitol 69(1): 51-58.
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HOUEMENOU G, KASSA B & LIBOIS R. 2014. Ecologie, diversité spécifique et abondance des petits mammifères de la ville de Cotonou au Bénin (Afrique de l’Ouest). Int J Biol Chem Sci 8(3): 1202-1213.
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MALDONADO JUNIOR A, PINHEIRO J, SIMÕES R & LANFREDI RM. 2010. Canaania obesa (Platyhelminthes: Dicrocoeliidae): redescription and new hosts records. Zoologia 27: 789-794.
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Publication Dates

Publication in this collection
21 Nov 2022
Date of issue
2022

History

Received
23 Oct 2021
Accepted
6 Feb 2022

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] BAER JG. 1959. Helminthes parasites. Exploration des Parcs Nationaux du Congo Belge. Fasc. 1. Mission J. G. Baer-W. Gerber (1958). Brussels, Belgium: Instituts des Parcs Nationals, Congo Belge, 163 p.

[2] BRAY RA, GIBSON DI & JONES A. 2008. Keys to the Trematoda. Vol. III. London: CAB International and Natural History Museum, 848 p.

[3] BUSH AO, LAFFERTY KD, LOTZ JM & SHOSTAK AW. 1997. Parasitology meets ecology on its own terms: Margolis et al. revisited. J Parasitol 83: 575-583.

[4] DENTON JF & KINSELLA JM. 1972. Lyperosomum intermedium sp. n. (Digenea: Dicrocoeliidae) from the rice rat, Oryzomys palustris, from southeastern salt marshes. J Parasitol 58(2): 226-228.

[5] FERNANDES BMM, JUSTO MCN, CARDENAS MQ & COHEN SC. 2015. South American trematodes parasites of birds and mammals. Rio de Janeiro: Oficina de Livros, 516 p.

[6] GARDNER SL & PÉREZ-PONCE DE LÉON G. 2002. Yungasicola travassosi gen. n., sp. n. (Digenea: Dicrocoeliidae: Eurytrematinae) from two species of grass mice of the genus Akodon Meyen (Rodentia: Muridae) from the Yungas of Bolivia. Comp Parasitol 69(1): 51-58.

[7] GIBSON DI, JONES A & BRAY RA. 2002. Keys to the Trematoda. Vol. I. London: CAB International & Natural History Museum, 544 p.

[8] GUERREIRO MARTINS NB, ROBLES MDR, DIAZ JI, KINSELLA JM & NAVONE GT. 2019a. Cladorchis pyriformis (Diesing, 1838) (Digenea, Cladorchiidae): new rodent host and geographic records in Argentina. Check List 15(4): 645-650.

[9] GUERREIRO MARTINS NB, ROBLES MDR, DIAZ JI, PANISSE G & NAVONE GT. 2019b. Digenean parasites of Sigmodontinae rodents from Argentina: a list of species, new host, and geographical records. Acta Parasitol 65(1): 97-107.

[10] HILDEBRAND J, PYRKA E, SITKO J, JEŻEWSKI W, ZALEŚNY G, TKACH VV & LASKOWSKI Z. 2019. Molecular phylogeny provides new insights on the taxonomy and composition of Lyperosomum Looss, 1899 (Digenea, Dicrocoeliidae) and related genera. Int J Parasitol Parasites Wildl 9: 90-99.

[11] HOUEMENOU G, KASSA B & LIBOIS R. 2014. Ecologie, diversité spécifique et abondance des petits mammifères de la ville de Cotonou au Bénin (Afrique de l’Ouest). Int J Biol Chem Sci 8(3): 1202-1213.

[12] JONES A, BRAY RA & GIBSON DI. 2005. Keys to the Trematoda. Vol. II. London: CAB International & Natural History Museum, 768 p.

[13] KIFUNE T & UYEMA N. 1982. Report of the Fukuoka University Scientific Expedition to Peru, 1976. Part 3. Taxonomical studies on trematodes from marsupials and rodents with records of two crabs. Med Bull Fukuoka Univ 9(3): 241-256.

[14] LAMOTHE-ARGUMEDO R, FALCÓN-ORDAZ J, GARCÍA-PRIETO L & FERNÁNDEZ-FERNÁNDEZ J. 2005. A new dicrocoeliid (Digenea: Dicrocoeliinae) parasite of rodents from Tlaxcala, Mexico. J Parasitol 91(6): 1410-1412.

[15] LATINNE A, GALAN M, WAENGSOTHORN S, ROJANADILOK P, EIAMAMPAI K, SRIBUAROD K & MICHAUX J. 2014. Diet analysis of Leopoldamys neilli, a cave-dwelling rodent in Southeast Asia, using next-generation sequencing from feces. J Caves Karst Stud 76: 139-145.

[16] MALDONADO JUNIOR A, PINHEIRO J, SIMÕES R & LANFREDI RM. 2010. Canaania obesa (Platyhelminthes: Dicrocoeliidae): redescription and new hosts records. Zoologia 27: 789-794.

[17] MARTÍNEZ FA & BINDA JL. 1992. Athesmia heterolecithodes (Braun, 1899) Looss, 1899 (Trematoda, Dicrocoeliidae) en Myocastor coypus. Vet Argent 9: 98-101.

[18] MARTÍNEZ-IBEAS AM, MARTÍNEZ-VALLADARES M, GONZÁLEZ-LANZA C, MIÑAMBRES B & MANGA-GONZÁLEZ MY. 2011. Detection of Dicrocoelium dendriticum larval stages in mollusk and ant intermediate hosts by PCR, using mitochondrial and ribosomal internal transcribed spacer (ITS-2) sequences. Parasitology 138(14): 1916-1923.

[19] MARTINO PE, RADMAN N, PARRADO E, BAUTISTA E, CISTERNA C, SILVESTRINI MP & CORBA S. 2012. Note on the occurrence of parasites of the wild nutria (Myocastor coypus, Molina, 1782). Helminthologia 49(3): 164-168.

[20] MCINTOSCH A. 1939. A new dicrocoeliid trematode, Furytrema komareki n. sp., from a white footed mouse. Proc Helminthol Soc Wash 6(1): 18-19.

[21] NAVONE GT, NOTARNICOLA J, NAVA S, ROBLES MDR, GALLIARI C & LARESCHI M. 2009. Arthropods and helminthes assemblage in sigmodontine rodents from wetlands of the Río de la Plata, Argentina. Mastozool Neotrop 16: 121-133.

[22] NEIDERT CM & RALPH WM. 1968. Concinnum peromysci sp. n. (Trematoda: Dicrocoeliidae) from Peromyscus maniculatus in Oregon. Am Midl Nat 79(2): 525-528.

[23] NGUYEN TL & PHAM ND. 2004. On some trematoda species of three genera Dictyonograptus Travassos, 1919; Platynosomoides Yamaguti, 1971 and Skrjabinus (Bhalerao, 1936) (Dicrocoeliidae). Tap Chi Sinh Hoc 26(3): 1-4.

[24] PANISSE G, ROBLES MR, DIGIANI MC, NOTARNICOLA J, GALLIARI C & NAVONE GT. 2017. Description of the helminth communities of sympatric rodents (Muroidea: Cricetidae) from the Atlantic Forest in northeastern Argentina. Zootaxa 4337(2): 243-262.

[25] PARDIÑAS UFJ, MYERS P, LEÓN-PANIAGUA L, ORDÓÑEZ GARZA N, COOK JA, KRYŠTUFEK B, HASLAUER R, BRADLEY RD, SHENBROT GI & PATTON JL. 2017. Family Cricetidae (true hamsters, voles, lemmings and New World rats and mice). In: Wilson DE, Lacher TE & Mittermeier RA (Eds), Handbook of the mammals of the world, Vol. 7. Rodents II. Lynx Editions, Barcelona, Spain, p. 204-279.

[26] PINTO H, MATI V & MELO A. 2016. Can the same species of Platynosomum (Trematoda: Dicrocoeliidae) infect both mammalian and avian hosts? J Helminthol 90(3): 372-376.

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[28] POJMAŃSKA T. 2008. Family Dicrocoeliidae Loos, 1899. In: Bray RA, Gibson DI & Jones A (Eds), Keys to the Trematoda. Vol. III. London: CAB International and Natural History Museum, p. 233-260.

[29] PREISSER WC & FALCÓN-ORDAZ J. 2019. A checklist of the parasitic helminths of cricetid and heteromyid rodents in Mexico. Therya 10(3): 329-341.

[30] RIVILLAS C, CARO F, CARVAJAL H & VÉLEZ I. 2004. Conspicuum thatcheri n. sp. Rev Acad Colomb Cienc Exact Fis Nat 28(107): 275-280.

[31] SCHLITTER D, VAN DER STRAETEN E, AMORI G, HUTTERER R, KRYŠTUFEK B, YIGIT N & MITSAINAS G. 2021. Apodemus sylvaticus (Linnaeus, 1758). The IUCN Red List of Threatened Species 2021: htps://doi.org/10.2305/IUCN.UK.2021-1.RLTS.T1904A197270811.en.

[32] SIMÕES RO, SOUZA JGR, MALDONADO JR A & LUQUE JL. 2011. Variation in the helminth community structure of three sympatric Sigmodontine rodents from the coastal Atlantic Forest of Rio de Janeiro, Brazil. J Helminthol 85: 171-178.

[33] SITKO J. 2013. Redescription of Skrjabinus skrjabini and validity reassessment of selected species of Skrjabinus (Digenea, Dicrocoeliidae). Helminthologia 50(4): 281-286.

[34] STCHERBAKOVA E. 1942. Studies on helminth fauna of rodents from Armenia (in Russian). Bull Armenian Branch Acad Sci USSR 1: 159-173.

[35] SUTTON CA. 1983. Contribución al conocimiento de la fauna parasitológica argentina XI. Digeneos en roedores bonaerenses. Neotropica 29: 19-26.

[36] SUTTON CA. 1998. Primer registro y redescripción de Conspicuum minor Mañé-Garzón y Holcman-Spector, 1975 (Digenea, Dicrocoelidae) en Argentina. Gayana Zool 62: 221-224.

[37] SUTTON CA & DAMBORENEA MC. 1996. Colección Helmintológica del Museo de La Plata: I. Catálogo de preparaciones microscópicas, material tipo y no tipo. Seria Técnica y Didáctica Museo de La Plata 35: 1-20.

[38] TKACH VV, ACHATZ TJ, HILDEBRAND J & GREIMAN SE. 2018. Convoluted history and confusing morphology: Molecular phylogenetic analysis of dicrocoeliids reveals true systematic position of the Anenterotrematidae Yamaguti, 1958 (Platyhelminthes, Digenea). Parasitol Int 67(4): 501-508.

[39] TRAVASSOS L, FREITAS JF & KOHN A. 1969. Trematódeos do Brasil. Mem Inst Oswaldo Cruz 67(1): 1-886.

[40] YAMAGUTI S. 1971. Synopsis of digenetic trematodes of vertebrates. Tokyo: Keigaku Publishing Co., 1074 p.

Species	Athesmia heterolecithodes	Caballerolecythus ibunami	Canaania obesa ^a	Conspicuum minor ^b	Conspicuum pulchrum	Conspicuum thatcheri	Concinnum peromysci
Author	(Braun 1899) Looss 1899	Lamothe-Argumedo, Falcón-Ordaz, García-Prieto & Fernández-Fernández 2005	Travassos 1944	Mañé-Garzón & Holcman-Spector 1975	(Travassos 1919) Bhalerao 1936	Rivillas, Caro, Carvajal & Vélez 2004	Neidert & Macy 1968
Reference	Martínez & Binda 1992MARTÍNEZ FA & BINDA JL. 1992. Athesmia heterolecithodes (Braun, 1899) Looss, 1899 (Trematoda, Dicrocoeliidae) en Myocastor coypus. Vet Argent 9: 98-101.	Lamothe-Argumedo et al. 2005LAMOTHE-ARGUMEDO R, FALCÓN-ORDAZ J, GARCÍA-PRIETO L & FERNÁNDEZ-FERNÁNDEZ J. 2005. A new dicrocoeliid (Digenea: Dicrocoeliinae) parasite of rodents from Tlaxcala, Mexico. J Parasitol 91(6): 1410-1412.	Maldonado Junior et al. 2010, Guerreiro Martins et al. 2019aGUERREIRO MARTINS NB, ROBLES MDR, DIAZ JI, KINSELLA JM & NAVONE GT. 2019a. Cladorchis pyriformis (Diesing, 1838) (Digenea, Cladorchiidae): new rodent host and geographic records in Argentina. Check List 15(4): 645-650.	Sutton 1998SUTTON CA. 1998. Primer registro y redescripción de Conspicuum minor Mañé-Garzón y Holcman-Spector, 1975 (Digenea, Dicrocoelidae) en Argentina. Gayana Zool 62: 221-224.	Travassos et al. 1969TRAVASSOS L, FREITAS JF & KOHN A. 1969. Trematódeos do Brasil. Mem Inst Oswaldo Cruz 67(1): 1-886.	Rivillas et al. 2004RIVILLAS C, CARO F, CARVAJAL H & VÉLEZ I. 2004. Conspicuum thatcheri n. sp. Rev Acad Colomb Cienc Exact Fis Nat 28(107): 275-280.	Neidert & Ralph 1968NEIDERT CM & RALPH WM. 1968. Concinnum peromysci sp. n. (Trematoda: Dicrocoeliidae) from Peromyscus maniculatus in Oregon. Am Midl Nat 79(2): 525-528.
Synonymous	Distomum heterolecithodes	-	-	-	Eurytrema pulchrum	-	-
Host species	Myocastor coypus (Myocastoridae)	Liomys irroratus (Heteromyidae)	Akodon azarae, A. cursor, A. montensis, Nectomys squamipes, Oligoryzomys nigripes (Cricetidae)	Scapteromys aquaticus, S. tumidus (Cricetidae)	Oxymycterus quaestor (Cricetidae)	Melanomys caliginosus (Cricetidae)	Peromyscus maniculatus (Cricetidae)
Country	Argentina	Mexico	Argentina, Brazil	Argentina, Uruguay	Brazil	Colombia	United State
Site of infection	Bile duct	Bile duct	Bile ducts and the first part of small intestine	Bile duct	Bile duct	Liver	Pancreatic ducts and a few in the small intestine
Body length	6.95-7.50	6.00-6.90	2.20	0.83-1.62	3.00-3.80	1.12-2.66	2.66-3.19
Body width	1.77-1.96	0.26-0.40	1.30	0.35-0.63	1.50-20	0.49-1.13	0.86-1.10
Oral sucker diameter max	0.32	0.11-0.19	0.28	0.13-0.21	0.43-0.45	0.08-0.36	0.20-0.23
Oral sucker diameter min	0.32	0.10-0.16	0.22	0.13-0.20	0.43-0.45	0.13-0.37	0.19-0.23
Ventral sucker diameter max	0.36	0.10-0.19	0.84	0.24-0.44	0.62-0.70	0.15-0.63	0.23-0.32
Ventral sucker diameter min	0.36	0.09-0.19	0.73	0.23-0.35	0.62-0.70	0.28-0.69	0.23-0.30
Cirrus sac length	-	0.17-0.40	-	0.07-0.17	-	0.17-0.30	0.15-0.24
Cirrus sac width	-	0.04-0.10	-	0.07-0.09	-	0.10	0.06-0.10
Pharynx length	0.12	0.04-0.06	0.17	0.06-0.09	0.17-0.22	0.09-0.37	0.10-0.13
Pharynx width	-	0,04-0,07	-	0.08-0.12	0.17-0.22	0.07-0.38	0.10-0.13
Testes length	AT: 0.64-0.68 PT: 0.72-0.74	AT: 0.28-0.40; PT: 0.31-0.47	0.24-0.28	0.08-0.15	-	LT: 0.07-0.35; RT: 0.05-0.38	-
Testes width	-	AT: 0.16-0.25; PT: 0.18-0.28	0.31-0.33	0.06-0.09	-	LT: 0.06-0.22; RT: 0.05-0.24	-
Ovary length	0.21-0.36	0.21-0.28	0.26	0.06-0.10	-	0.12-0.17	0.11-0.16
Ovary width	-	0.15-0.20	0.33	0.04-0.11	-	0.12-0.17	0.13-0.21
Eggs length	0.031-0.036	0.024-0.030	0.02	0.027-0.034	0.041-0.045	0.030-0.038	0.05-0.06
Eggs width	0.020	0.013-0.017	0.03	0.016-0.020	0.018-0.022	0.013-0.019	0.033-0.039

Species	Dicrocoelium dendriticum	Lyperosomum intermedium	Platynosomum illiciens	Platynosomum minutum	Yungasicola travassosi	Zonorchis komareki	Zonorchis oxymycterae ^c
Author	(Rudolphi 1819) Looss 1899	Denton & Kinsella 1972DENTON JF & KINSELLA JM. 1972. Lyperosomum intermedium sp. n. (Digenea: Dicrocoeliidae) from the rice rat, Oryzomys palustris, from southeastern salt marshes. J Parasitol 58(2): 226-228.	(Braun 1901) Kossak 1910	Kifune & Uyema 1982KIFUNE T & UYEMA N. 1982. Report of the Fukuoka University Scientific Expedition to Peru, 1976. Part 3. Taxonomical studies on trematodes from marsupials and rodents with records of two crabs. Med Bull Fukuoka Univ 9(3): 241-256.	Gardner & Pérez-Ponce de Léon 2002GARDNER SL & PÉREZ-PONCE DE LÉON G. 2002. Yungasicola travassosi gen. n., sp. n. (Digenea: Dicrocoeliidae: Eurytrematinae) from two species of grass mice of the genus Akodon Meyen (Rodentia: Muridae) from the Yungas of Bolivia. Comp Parasitol 69(1): 51-58.	(McIntosh 1939) Travassos 1944	Sutton 1983SUTTON CA. 1983. Contribución al conocimiento de la fauna parasitológica argentina XI. Digeneos en roedores bonaerenses. Neotropica 29: 19-26.
Reference	Martino et al. 2012MARTINO PE, RADMAN N, PARRADO E, BAUTISTA E, CISTERNA C, SILVESTRINI MP & CORBA S. 2012. Note on the occurrence of parasites of the wild nutria (Myocastor coypus, Molina, 1782). Helminthologia 49(3): 164-168.	Denton & Kinsella 1972DENTON JF & KINSELLA JM. 1972. Lyperosomum intermedium sp. n. (Digenea: Dicrocoeliidae) from the rice rat, Oryzomys palustris, from southeastern salt marshes. J Parasitol 58(2): 226-228.	Pinto et al. 2016PINTO H, MATI V & MELO A. 2016. Can the same species of Platynosomum (Trematoda: Dicrocoeliidae) infect both mammalian and avian hosts? J Helminthol 90(3): 372-376.	Kifune & Uyema 1982KIFUNE T & UYEMA N. 1982. Report of the Fukuoka University Scientific Expedition to Peru, 1976. Part 3. Taxonomical studies on trematodes from marsupials and rodents with records of two crabs. Med Bull Fukuoka Univ 9(3): 241-256.	Gardner & Pérez-Ponce de Léon 2002GARDNER SL & PÉREZ-PONCE DE LÉON G. 2002. Yungasicola travassosi gen. n., sp. n. (Digenea: Dicrocoeliidae: Eurytrematinae) from two species of grass mice of the genus Akodon Meyen (Rodentia: Muridae) from the Yungas of Bolivia. Comp Parasitol 69(1): 51-58.	McIntosch 1939MCINTOSCH A. 1939. A new dicrocoeliid trematode, Furytrema komareki n. sp., from a white footed mouse. Proc Helminthol Soc Wash 6(1): 18-19.	Sutton 1983SUTTON CA. 1983. Contribución al conocimiento de la fauna parasitológica argentina XI. Digeneos en roedores bonaerenses. Neotropica 29: 19-26., Guerreiro Martins et al. 2019aGUERREIRO MARTINS NB, ROBLES MDR, DIAZ JI, KINSELLA JM & NAVONE GT. 2019a. Cladorchis pyriformis (Diesing, 1838) (Digenea, Cladorchiidae): new rodent host and geographic records in Argentina. Check List 15(4): 645-650.
Synonymous	Distoma dendriticum,	-	Eurytrema fastosum, Platynosomum fastosum, P. concinnum	-	-	Eurytrema komareki	Skrjabinus oxymycterae
Host species	Myocastor coypus (Myocastoridae)	Oryzomys palustris (Cricetidae)	Mus musculus (Muridae)	Proechimys longicaudatus (Echimyidae)	Akodon fumeus (Cricetidae)	Peromyscus gossypinus (Cricetidae)	Akodon azarae; Oxymycterus rufus (Cricetidae)
Country	Argentina	United State	Brazil	Peru	Bolivia	United State	Argentina
Site of infection	Liver	Pancreas	Bile duct	Bile duct, gall bladder	Gall bladder and bile ducts	Liver	Bile duct and small intestine
Body length	5.00-12.00	1.65-4.20	2.23-4.98	1.88-2.74	1.97-3.33	2.82	1.77-3.68
Body width	1.00-2.50	0.33-0.42	0.86-1.72	0.58-0.86	0.71-1.45	0.80	0.66-0.78
Oral sucker diameter max	0.40	0.13-0.15	0.24-0.42	0.23-0.28	0.21-0.34	0.20	0.19-0.29
Oral sucker diameter min	0.30	0.12-0.14	0.24-0.35	0.22-0.26	0.19-0.36	0.20	0.13-0.24
Ventral sucker diameter max	0.45	0.21	0.20-0.43	0.27-0.34	0.19-0.34	0.37	0.49-0.66
Ventral sucker diameter min	0.40	0.16	0.24-0.39	0.27-0.34	0.18-0.34	0.32	0.49-0.61
Cirrus sac length	0.50-0.60	0.11-0.15	0.28-0.48	-	0.10-0.28	-	-
Cirrus sac width	-	0.05-0.65	0.10-0.17	-	0.02-0.07	-	-
Pharynx length	0.13	0.07	0.08-0.15	-	0.09-0.16	0.10	0.12-0.16
Pharynx width	0.12	0.06	0.07-0.14	-	0.07-0.14	0.10	0.13-0.16
Testes length	1.00	0.24	LT: 0.34-0.88; RT: 0.35-0.89	-	LT: 0.11-0.23; RT: 0.09-0.21	0.09-0.20	0.14-0.18
Testes width	0.70	0.11	LT: 0.24-0.58; RT: 0.23-0.54	-	LT: 0.09-0.19; RT: 0.11-0.18	0.09-0.20	0.16-0.19
Ovary length	0.25	0.06-0.14	0.10-0.29	-	0.05-0.13	0.13-0.14	0.11-0.14
Ovary width	0.35	0.07-0.15	0.17-0.39	-	0.62-0.13	0.13-0.14	0.11-0.16
Eggs length	0.038-0.045	0.04-0.05	-	0.03-0.04	0.019-0.031	0.030	0.02
Eggs width	0.022-0.030	0.02-0.027	-	0.02	0.012-0.020	0.023	0.02-0.04

Species	Platynosomoides muris	Platynosomoides verschureni	Platynosomoides lunaschiae sp. nov.
Author	(Stcherbakova 1942STCHERBAKOVA E. 1942. Studies on helminth fauna of rodents from Armenia (in Russian). Bull Armenian Branch Acad Sci USSR 1: 159-173.)	(Baer 1959BAER JG. 1959. Helminthes parasites. Exploration des Parcs Nationaux du Congo Belge. Fasc. 1. Mission J. G. Baer-W. Gerber (1958). Brussels, Belgium: Instituts des Parcs Nationals, Congo Belge, 163 p.)	This paper
Species hosts	Apodemus sylvaticus; Leopoldamys siporanus (Muridae)	Crocidura olivieri (Soricidae)	Akodon montensis (Cricetidae)
Country	Armenia; Russia; Malaysia	Democratic Republic of the Congo	Argentina
Continent	Asia	Africa	America
Site of infection	Liver	Bile duct	Bile duct
Body length	3.27-3.41	3.00-4.50	2.18 ± 0.33 (1.79-2.84)
Body width	1.22-1.80	0.71-0.90	1.16 ± 0.21 (0.92-1.59)
Oral sucker diameter max	0.23-0.27	0.25	0.31 ± 0.05 (0.19-0.39)
Oral sucker diameter min	0.22	0.23	0.29 ± 0.06 (0.21-0.38)
Ventral sucker diameter max	0.28	0.39-0.41	0.38 ± 0.06 (0.29-0.48)
Ventral sucker diameter min	0.25	-	0.34 ± 0.06 (0.23-0.44)
Cirrus sac length	0.23-0.28	0.23-0.26	0.22
Cirrus sac width	-	0.06-0.14	0.10
Pharynx length	-	0.14-0.15	0.13 ± 0.01 (0.11-0.15)
Pharynx width	-	0.12-0.14	0.12 ± 0.01 (0.09-0.13)
Right testis length	0.24-0.41	0.32	0.16 ± 0.03 (0.07-0.20)
Left testis length	0.24-0.41	0.32	0.14 ± 0.03 (0.06-0.18)
Right testis width	0.25-0.36	0.23	0.15 ± 0.03 (0.06-0.18)
Left testis width	0.25-0.36	0.23	0.13 ± 0.02 (0.05-0.15)
Ovary length	0.16-0.18	-	0.14 ± 0.03 (0.11-0.20)
Ovary width	0.23-0.24	0.18	0.12 ± 0.02 (0.09-0.18)
Eggs length	0.030-0.035	0.032-0.034	0.032 ± 0.001 (0.029-0.034)
Eggs width	0.018-0.020	0.018-0.021	0.017 ± 0.002 (0.014-0.020)

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