Perkinsus species are destructive parasites of commercial Manila clams, Venerupis philippinarum, in Japan, Korea, and Spain. However, in vitro parasite cultures from this important host clam are not available. Tissues of Manila clams collected during April 2002 in Gokasho Bay, Japan harbored Perkinsus sp. parasites at a 97% prevalence (28/29) of moderate- and high-intensity infections. Perkinsus sp. cells in tissue samples were enlarged in alternative Ray's fluid thioglycollate medium, before propagation in DME:Ham's F-12 Perkinsus sp. culture medium. Enlarged parasite hypnospores zoosporulated at high frequencies to release motile zoospores, which gave rise to continuous schizogonic cell lines that also zoosporulated continuously at low frequencies. Four Perkinsus sp. in vitro isolates comprising two distinct morphotypes were cryopreserved, cloned, and archived for public distribution. For three isolates of one morphotype, nucleotide sequences of the ribosomal DNA internal transcribed spacer region, of the large subunit rRNA gene, and of actin genes, were consistent with those reported for P. olseni. Similar sequences from one morphologically unique isolate differed from those of all described Perkinsus species. These results show that at least two Perkinsus spp. infect Japanese Manila clams, and that one represents a new species, Perkinsus honshuensis n. sp.
Declining Chesapeake Bay harvests of softshell clams, together with historical and emerging reports of epizootic diseases in Mya arenaria, prompted a survey in summer 2000 of the health status of selected commercial clam populations. All sampled populations (8 M. arenaria softshell clam, 2 Tagelus plebeius razor clam) were infected by Perkinsus sp. protozoans at prevalences ranging from 30 to 100% of sampled clams. Nucleotide sequences for the internal transcribed spacer (ITS) region of the rRNA gene complex were determined for clonal in vitro Perkinsus sp. isolates propagated from both M. arenaria and T. plebeius. Multiple polymorphic sequences were amplified from each isolate, but phylogenetic analysis placed all sequences into 2 clades of a monophyletic group, which included both recently described clam parasites P. chesapeaki and P. andrewsi. Sequences amplified from each clonal isolate were found in both sister clades, one containing P. andrewsi and the other P. chesapeaki. Most (7 of 8) M. arenaria samples were also affected with disseminated neoplasia (DN), at prevalences of 3 to 37%, but neither T. plebeius sample showed DN disease. Disease mortalities projected for sampled clam populations, especially those affected by both diseases, may further deplete subtidal commercial clam populations in mesohaline portions of Chesapeake Bay. KEY WORDS: Mollusc neoplasia · Disseminated neoplasia · Hemic neoplasia · Dermo disease · Perkinsus chesapeaki · Perkinsus andrewsi · Softshell clam · Razor clam Resale or republication not permitted without written consent of the publisherDis Aquat Org 50: [67][68][69][70][71][72][73][74][75][76][77][78] 2002 circulatory systems of affected clams, displacing normal hemocyte cells and their critical physiological functions. DN disease pathogenesis has been compared to that of vertebrate leukemia (Smolowitz et al. 1989), and it is fatal within 9 mo of experimental transmission (House et al. 1998). With prevalences of up to 58% reported in some Chesapeake Bay clam populations (Farley et al. 1991), mortalities from DN disease are estimated to be significant.Although the etiology and natural transmission mechanisms of DN disease remain unknown, it is mechanically transplantable between affected and healthy Mya arenaria, and is experimentally transmitted through the water column. However, it is not transmitted by injection of healthy clams with cell-free filtrates of affected clam hemolymph, or of filtered hemolymph cell lysates. Despite one report of wholesale DN disease transmission by injection of 0.45 µm-filtered DN cell lysates into healthy clams (Oprandy et al. 1981), consistent failure by later investigators to transmit the disease with cell-free filtrates has been interpreted as refuting the possibility of a viral agent (McLaughlin et al. 1992). Recent detection of retroviral reverse transcriptase activity in filtrates of tissue homogenates only from DN-affected clams suggests that a retroviral agent is present. However, the failure of reverse transcriptase-pos...
Diverse analytical and experimental results confirm that two protistan parasites, Perkinsus chesapeaki and Perkinsus andrewsi, described separately as parasites of Mya arenaria and Macoma balthica clams sympatric in Chesapeake Bay, USA, represent a single species. Ribosomal RNA (rRNA) internal transcribed spacer (ITS) regions, rRNA large subunit (LSU) gene, and actin gene sequences were obtained from clonal Perkinsus spp. cultured in vitro. Although multiple polymorphic sequences were found in DNA from clonal cultures at each locus, identical ITS region and actin gene sequences were found in the P. andrewsi holotype culture and in Perkinsus sp. clonal cultures from M. arenaria and Tagelus plebius. All sequences determined from cultures of P. chesapeaki and P. andrewsi at each locus grouped together in monophyletic clades with high support values in phylogenetic analyses. In vitro isolates of Perkinsus spp. from M. arenaria and M. balthica were reciprocally infective for each other's cognate host. Lesions and histozoic parasite cell morphologies were consistent with those described for the original host/parasite interactions. In vitro isolate cell cycles and cell types of both parasites were indistinguishable. In accordance with the International Code of Zoological Nomenclature rules of priority, P. andrewsi is declared a junior synonym of P. chesapeaki.
Oysters were collected from coastal locations in China from 1999-2006 for parasite analyses by molecular, culture, and histological techniques. Polymerase chain reaction-based assays targeting the internal transcribed spacer (ITS) region of the ribosomal RNA gene complex were performed to detect the presence of Perkinsus species. Sequencing and phylogenetic analysis of amplified Perkinsus sp. DNAs indicated that a novel Perkinsus sp. infects Crassostrea hongkongensis, Crassostrea ariakensis, and other bivalve hosts from Fujian to Guangxi provinces in southern China. Prevalence of this Perkinsus sp. reaches as high as 60% in affected oyster populations. Analyses of nucleotide sequences of the rRNA ITS region and of large subunit rRNA and actin genes, consistently confirmed the genus affiliation of this Perkinsus sp., but distinguished it from currently accepted Perkinsus species. Parasite cell types, such as signet ring trophozoites of 2-8 microm diameter, were observed by histology, and application of both genus Perkinsus and Perkinsus species-specific in situ hybridization probes consistently labelled the same Perkinsus sp. cells in histological sections from infected oyster tissues. Combined phylogenetic and histological results support the identity of a new parasite species, Perkinsus beihaiensis n. sp.
Perkinsus marinus and P. chesapeaki host ranges among wild Chesapeake Bay, USA, region bivalves were examined by surveying Crassostrea virginica oysters and members of several sympatric clam species from 11 locations. Perkinsus genus-and species-specific PCR assays were performed on DNA samples from 731 molluscs, and species-specific in situ hybridization assays were performed on a selected subset of histological samples whose PCR results indicated dual or atypical Perkinsus sp. infections. PCR assays detected P. marinus in 92% of oysters, but the P. chesapeaki PCR assay was positive for only 6% of oysters, and P. marinus was detected by PCR in only one clam. The very low prevalence of P. marinus infections in clams is noteworthy because all surveyed clams were sympatric with oyster populations showing high P. marinus infection prevalences. P. chesapeaki commonly infected Mya arenaria, Macoma balthica, and Tagelus plebeius clams, as well as the previously unreported P. chesapeaki host clams Mulinia lateralis, Rangia cuneata, and Cyrtopleura costata. Among 30 in vitro isolates propagated from surveyed hosts, 8 P. marinus isolates were exclusively from Crassostrea virginica oysters, and all 22 P. chesapeaki isolates were from clam hosts of 5 different species. Although both P. marinus and P. chesapeaki were previously both shown to be experimentally infective for oyster and clam hosts, this survey of wild bivalves in the Chesapeake Bay region reveals that P. marinus infections occur almost exclusively in oysters, and P. chesapeaki infections predominate among members of at least 6 clam species.
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