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Abstract
Two brachyurans of the varunid genus Hemigrapsus from the northwestern Pacific Ocean have invaded coastal regions of the north Atlantic – Hemigrapsus takanoi (sibling species of Hemigrapsus penicillatus) and Hemigrapsus sanguineus in Europe and the latter in the USA. Parasites are known from these crabs in their native habitats, but except for an undescribed larval nematode, none has been found in those examined from their new locations. These parasites include metacercariae of eight species of microphallid trematode, the rhizocephalan barnacles Polyascus polygenea, Sacculina nigra and Sacculina senta, and the obligate gut-inhabiting mesomycetozoan Enteromyces callianassae (potential parasite). The following have been identified in four of the other eight Pacific crabs within the genus (Hemigrapsus nudus and Hemigrapsus oregonensis, northern hemisphere; Hemigrapsus crenulatus and Hemigrapsus sexdentatus, southern hemisphere), none of which have been geographically displaced: metacercariae of two microphallid trematodes; cystacanths of three acanthocephalans Profilicollis antarcticus, Profilicollis botulus and Profilicollis novaezelandensis; larval nematode Ascarophis sp.; nematomorph Nectonema zealandica; entoniscid isopod Portunion conformis; mesomycetozoan Taeniella carcini; and nemertean egg predator Carcinonemertes epialti. The likelihood of the displaced species of shore crabs being rejoined with their native parasites or their susceptibility to becoming infected by similar parasites in their new locations is discussed. In future global displacements of parasitized Hemigrapsus species it is possible that their most serious parasites, rhizocephalans and entoniscid isopods, may infect previously uninfected species. For example, the two eastern Pacific species of Hemigrapsus (H. nudus and H. oregonensis) may be vulnerable to the rhizocephalans and may in turn be a source of entoniscids transported elsewhere.
Acknowledgements
I am grateful for the information provided by the following: April M. H. Blakeslee, Smithsonian Environmental Research Center, Edgewater, Maryland; Christopher B. Boyko, Dowling College, New York; Annette M. Brockerhoff and Colin L. McLay, University of Canterbury, New Zealand; Richard H. Heard and Robin M. Overstreet, Gulf Coast Research Laboratory, Ocean Springs, Mississippi; Ngan Kee Ng and Peter K. L. Ng, National University of Singapore; Robert Poulin, University of Otago, New Zealand; Akira Asakura, Kobe University, Japan; Tsunenori Koga, Wakayama University, Japan. My appreciation goes to Jason D. Williams, Hofstra University, New York for reviewing a draft of this paper. Franklin and Marshall College continues to aid and encourage my research.