Acanthoparyphium spinulosum Johnston
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publication ID |
https://doi.org/10.11646/zootaxa.4711.3.3 |
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publication LSID |
lsid:zoobank.org:pub:85D81C2D-0B66-4C0D-B708-AAF1DAD6018B |
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DOI |
https://doi.org/10.5281/zenodo.5665012 |
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persistent identifier |
https://treatment.plazi.org/id/EF6AD377-8944-8B26-FF39-FF10FB65FAA9 |
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treatment provided by |
Plazi (2019-12-20 06:36:05, last updated 2024-11-26 08:02:28) |
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scientific name |
Acanthoparyphium spinulosum Johnston |
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Acanthoparyphium spinulosum Johnston
(5. Acsp; Figs. 1 View FIGURE 1 , 19–22 View FIGURES 19–22 )
Diagnosis: Parthenitae. Colony comprised of active rediae, densely concentrated in snail gonad region. Rediae translucent orange, yellow, or colorless; redial gut often yellow; ~ 400–900 µm long, ovoid to oblong (length:width typically <3.5:1), with collar and posterior appendages that are often not pronounced.
Cercaria . Body translucent colorless, often with opaque and refringent white granules in distinctive, pinnately branched excretory system; non-oculate; with oral and ventral sucker; with two lateral pinnately branched excretory ducts; body ~ 320 µm long, ~equal in length to tail; tail simple.
Cercaria behavior: Fresh, emerged cercariae remain in water column, swim ~continuously, lashing tail back and forth.
Similar species: The Acsp cercaria is readily separated from the other himasthlids by its pronounced pinnatelybranched excretory system. It is readily distinguished from Hisb [7] by lacking a tail fin; Acsp is also often smaller than Hisb, but there is overlap, so this is not a consistently reliable distinguishing trait. Acsp’s collar spine count of 23 is also diagnostic, but seeing this requires mounting at the compound scope.
Remarks: Martin and Adams (1961) document the life cycle. They described miracidia, rediae, cercariae, and metacercariae from experimentally infected horn snails, and adults from experimentally infected young domestic chickens. They identified the adults as Acanthoparyphium spinulosum , which was originally described from adults naturally occurring in Australian birds, indicating A. spinulosum likely represents a broadly distributed species complex.
There are almost certainly at least two cryptic species subsumed within A. spinulosum of California horn snails, but we have not yet determined clear morphological traits to distinguish them. Martin (1972) included two Acanthoparyphium species in his key: A. spinulosum and “ Acanthoparyphium sp.”, which he reported as having smaller cercaria than A. spinulosum and as forming metacercariae within polychaetes and snail feces. Similarly, we have regularly noted natural and experimental infections of Acanthoparyphium metacercariae in both bivalves, horn snails, and polychaetes (but never in feces) ( Hechinger et al. 2007; Nguyen et al. 2015; Hechinger, unpublished data). This disparate host use may reflect one or more cryptic species, each of which would have more restricted host use. Additionally, DNA sequence data indicates the existence of cryptic Acanthoparyphium spp. in California horn snails ( Nguyen et al. 2015; Miura, Torchin, & Hechinger, unpublished data). However, the sequence data has not been connected to specimens suitable for morphological examination, and results of experimental infections have been ambiguous ( Nguyen et al. 2015; Hechinger, unpublished data). Hence, research is called for to resolve the existence of, morphological differences of, and host use by cryptic species of A. spinulosum .
This species almost certainly corresponds to the “small echinostome” of Martin (1955).
Mature, ripe colonies comprise ~20% the soft-tissue weight of an infected snail (summer-time estimate derived from information in [ Hechinger et al. 2009]).
Acsp infection causes (stolen) snail bodies to grow over 1.5x faster than uninfected snails ( Hechinger 2010).
This species has a caste of soldier rediae ( Garcia-Vedrenne et al. 2016).
Nadakal (1960b) presents information on the pigments of the rediae and cercariae of this species (as his “small echinostome”).
As part of one of the first studies documenting the syncytial nature of trematode integuments, Bils and Martin (1966) examined the fine structure and development of the tegument for the rediae and cercariae (and metacercariae and adults) of this species.
Koprivnikar et al. (2010) performed laboratory experiments to examine the effects of salinity, temperature, and pH on survivorship and activity of Acsp cercariae from Bolinas Lagoon (central California).
Bils, R. F. & Martin, W. E. (1966) Fine Structure and Development of the Trematode Integument. Transactions of the American Microscopical Society, 85, 78 - 88. https: // doi. org / 10.2307 / 3224777
Garcia-Vedrenne, A. E., Quintana, A. C. E., DeRogatis, A. M., Martyn, K., Kuris, A. M. & Hechinger, R. F. (2016) Social Organization in Parasitic Flatworms-Four Additional Echinostomoid Trematodes Have a Soldier Caste and One Does Not. Journal of Parasitology, 102, 11 - 20. https: // doi. org / 10.1645 / 15 - 853
Hechinger, R. F., Lafferty, K. D., Huspeni, T. C., Brooks, A. & Kuris, A. M. (2007) Can parasites be indicators of free-living diversity? Relationships between the species richness and abundance of larval trematodes with that of local fishes and benthos. Oecologia, 151, 82 - 92. https: // doi. org / 10.1007 / s 00442 - 006 - 0568 - z
Hechinger, R. F., Lafferty, K. D., Mancini III, F. T., Warner, R. R. & Kuris, A. M. (2009) How large is the hand in the puppet? Ecological and evolutionary factors affecting body mass of 15 trematode parasitic castrators in their snail host. Evolutionary Ecology, 23, 651 - 667. https: // doi. org / 10.1007 / s 10682 - 008 - 9262 - 4
Hechinger, R. F. (2010) Mortality affects adaptive allocation to growth and reproduction: field evidence from a guild of body snatchers. BMC Evolutionary Biology, 10 (136), 1 - 14. https: // doi. org / 10.1186 / 1471 - 2148 - 10 - 136
Koprivnikar, J., Lim, D., Fu, C. & Brack, S. H. M. (2010) Effects of temperature, salinity, and pH on the survival and activity of marine cercariae. Parasitology Research, 106, 1167 - 1177. https: // doi. org / 10.1007 / s 00436 - 010 - 1779 - 0
Martin, W. E. (1955) Seasonal infections of the snail, Cerithidea californica Haldeman, with larval trematodes. In: Essays in Natural Science in Honor of Captain Alan Hancock on the occasion of his birthday. University of Southern California Press, Los Angeles, California, pp. 203 - 210.
Martin, W. E. & Adams, J. E. (1961) Life Cycle of Acanthoparyphium spinulosum Johnston, 1917 (Echinostomatidae: Trematoda). The Journal of Parasitology, 47, 777 - 782. https: // doi. org / 10.2307 / 3275470
Martin, W. E. (1972) An annotated key to the cercariae that develop in the snail Cerithidea californica. Bulletin of the Southern California Academy of Sciences, 71, 39 - 43.
Nadakal, A. M. (1960 b) Types and sources of pigments in certain species of larval trematodes. Journal of Parasitology, 46, 777 - 786. https: // doi. org / 10.2307 / 3275532
Nguyen, A. T., Kuwata, C. & Kuris, A. M. (2015) A synthetic workflow for coordinated direct observation and genetic tagging applied to a complex host-parasite interaction. Parasitology Research, 114, 2015 - 2021. https: // doi. org / 10.1007 / s 00436 - 015 - 4437 - 8
FIGURE 1. General characteristics of the parthenitae and cercariae of the trematodes infecting Cerithideopsis californica as first intermediate host. Species numbers and codes follow Table 1 and species accounts. Cercariae are all to scale, with additional magnified views of six small species (indicated by dashed lines). Note the oral stylets (presented in right lateral view) for Pruc and Smmi. Parthenitae are not to scale. Scale bars consistently indicate 100 µm.
FIGURES 19–22. Acanthoparyphium spinulosum (Acsp). 19, Overview of a colony in a freshly deshelled, infected horn snail in sea water. The arrow indicates the colony, which is localized in the gonadal region. Note the prominent white areas, which are masses of cercariae that have left the orange rediae. Scale bar = 1 cm. Base photo credit: Todd Huspeni. 20, Reproductive rediae, live, with developing cercariae, under coverslip pressure. Scale bar = 100 µm. 21, Soldier redia, live. Scale bar = 100 µm. Base photo credit: Ana Garcia-Vedrenne. 22, Cercariae, live, under coverslip pressure. Scale bar = 100 µm. Base photo credit: Todd Huspeni.
No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.
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