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Experimentally Induced Glochidiosis in Smallmouth Bass (Micropterus dolomieu)

Abstract

Necropsy was performed on 2 smallmouth bass (Micropterus dolomieu) that died 8 days after experimental gill inoculation with Actinonaias pectorosa glochidia. The salient feature at necropsy was ragged gills containing multiple petechial hemorrhages and numerous white, iridescent dust-like particles easily confirmed as glochidia in squash preparations of the gill filaments. Microscopically, the gills contained multiple rounded glochidia encysted at the tips or along the length of the filaments. Parasitized filaments were thickened, blunted, and often fused. Lamellae were extensively fused and obliterated, with proliferation of the epithelial cells giving the filament a smooth outline. Sometimes glochidia were associated with necrosis and/or hemorrhage. These fish most likely died due to asphyxia associated with the severe branchial lesions caused by the glochidia.

Key words: Actinonaias pectorosa; branchitis; fish; gills; glochidia; glochidiosis; Micropterus dolomieu; mussels.

The Unionoida, commonly known as freshwater mussels, naiads, or unionids, is a diverse order of bivalved mollusks whose larvae are parasitic, generally on fish.⁴ Three families within the order, the Unionidae, Margaritiferidae, and Hyriidae, have glochidium-type parasitic larvae.⁴ Glochidia are small, bivalved larvae that invade and encyst in the gills and fins of fishes and then metamorphize into to a free-living juvenile with adult internal organs. Juvenile mussels then excyst, drop off the host, and settle to the bottom to develop into mature mussels. Although hosts of most mussels are unknown, glochidia of some mussels are species specific, whereas others can use a wide variety of fish as hosts.^3,5,8

Freshwater mussels play an important role in an aquatic ecosystem, and their presence or absence provides clues about water quality and environmental health. Typically, infection with glochidia is subclinical, but if gill infection is severe enough, asphyxiation can occur. Mortality has been reported in both natural and experimental glochidial infections in salmonids.^1,7,9,10 Because glochidial infections are rarely described in the literature, the purpose of this report is to heighten awareness of glochidia in fish and to describe the lesions associated with infection with glochidia of Actinonaias pectorosa in smallmouth bass (Micropterus dolomieu).

Two 7-cm long smallmouth bass died 8 days after inoculation with an unknown quantity of glochidia of the freshwater mussel A. pectorosa. To prepare the inoculum, gravid female mussels, collected from streams in Virginia, USA, were placed in crystalizing dishes half filled with water and the marsupia (gills containing glochidia) punctured with a scalpel and perfused with water from a pipette to expel glochidia into the dish. Glochidia from several females were mixed and a few drops collected in a pipette and placed onto the host fish's gills.

At necropsy, the fish were covered by white slime and had petechial hemorrhages in the skin and reddening of the skin at the base of the tail. The fins were ragged and livers pale. However, the most striking changes were in the gills. The gills were ragged and contained multiple petechial hemorrhages, as well as numerous white, iridescent dust-like particles.

Squash preparations of gill filaments contained numerous thin-shelled organisms compatible with glochidia (Figs. 1, 2). The organisms were composed of 2 nearly symmetrical, rounded (referred to as subelliptical in the glochidia literature⁶) valves, 242 to 247 µm (246 ± 2.5 µm, n = 4) in length and 247 to 258 µm in height (251 ± 5.32 µm, n = 4), joined by a hinge (the dorsal margin) that was apparent when organisms were seen on edge.

View larger version (120K): [in this window] [in a new window]   Fig. 1. Gill; smallmouth bass. Squash preparation of gill filaments parasitized by glochidia of Actinonaias pectorosa. Note numerous glochidia that are roughly round when viewed sagitally. A single organism is seen on edge revealing its hinged bivalve nature (single-headed arrow). One organism is used to demonstrate the dorsal margin (arrowhead), which is the hinged margin, height (dorsal to ventral, thicker double-headed arrow), and length (anterior to posterior, thinner double-headed arrow). Bar = 250 µm.

View larger version (148K): [in this window] [in a new window]   Fig. 2. Gill; smallmouth bass. Squash preparation of gill filament. Note attachment of 2 glochidia along the length of a filament (F). The arrows point to the ventral margin of the glochidia where they have grasped the filament for attachment. Bar = 250 µm.

View larger version (141K): [in this window] [in a new window]   Fig. 3. Gill; smallmouth bass. Two gill filaments have a glochidium of Actinonaias pectorosa at the tip that is encysted by a single layer of host cells (arrows). Internal structures seen are adductor muscle (M) and mantle (small arrows). Filaments are smooth in outline due to lamellar fusing and epithelial hyperplasia. HE stain. Bar = 130 µm.

View larger version (94K): [in this window] [in a new window]   Fig. 4. Gill; smallmouth bass. Five encysted glochidia of Actinonaias pectorosa along the gill filaments that have extensively fused lamellae. Glochidia are encysted by single (arrows) and multiple (arrowhead) layers of epithelium. HE stain. Bar = 250 µm.

View larger version (180K): [in this window] [in a new window]   Fig. 5. Gill; smallmouth bass. Centrally, 4 filaments are fused encysting 3 glochidia of Actinonaias pectorosa (shorter arrow). Many filaments have extensive fusing of lamellae, resulting in a smooth filament outline and epithelial hyperplasia that is sometimes extensive (arrowhead). A filament with multiple areas of necrosis (longer arrow) is shown at higher magnification in Fig. 6. HE stain.

View larger version (71K): [in this window] [in a new window]   Fig. 6. Gill; smallmouth bass. The filament at the longer arrow in Fig. 5, in addition to having fused lamellae and epithelial hyperplasia, has multiple foci of necrosis (N) and hemorrhage (H). HE stain.

The iridescent dust-like particles seen grossly in the gills of these fish were glochidia, and their identity was easily confirmed by squash preparations of the gill filaments. In fact, these organisms were much easier to identify in squash preparations than in histologic sections. Glochidia of various species vary in size and may be rounded (as A. pectorosa), rectangular, or triangular.³ There are problems with identification to the species level using light microscopy, and scanning electron microscopy may be needed to identify such features as protuberances to differentiate species within a genus.¹¹

Because branchial lesions in these fish were severe and contained numerous encysted glochidia, asphyxia was most likely the immediate cause of death. Although bacteria were not seen in the viscera, the presence of petechial hemorrhages suggests that sepsis may have been a complicating factor. However, it is uncertain if any of the isolated bacteria are significant. Secondary fungal infections are relatively common in salmonids infected, either experimentally or naturally, with glochidia of Margaritifera margaritifera,^7,9 so invading or exiting parasites may provide a portal of entry for secondary invaders, such as bacteria and fungi.

The histologic changes in the gills of these fish were similar to those described for infection of salmonids with glochidia of M. margaritifera.⁷ Microscopic findings in salmonids infected with M. margaritifera glochidia suggest that once glochidia attach to the gill by biting or grasping, they are encysted by epithelial proliferation and lamellar fusion.^2,9 The microscopic appearance of the gill filaments and glochidia cysts in this report would support a similar mechanism of cyst formation for the glochidia of A. pectorosa. Necrosis and hemorrhage in parasitized filaments as seen in these fish have not been described for other glochidia, and their cause is uncertain. It may have been the result of vascular damage caused by the sheer number of parasitizing glochidia. The glochidia had not metamorphized to the juvenile form, so this was not a manifestation of excystment, which is due to the juvenile mussel breaking the wall with its foot.⁷

Susceptibility to a particular glochidium may vary with host fish. For example, when 6 species of salmonids were infected with M. margaritifera glochidia, a range of susceptiblity was observed. Chinook salmon were the most susceptible, with mortality occurring even at low doses, whereas coho salmon were relatively resistant.⁷ Length of infection and lesions also may vary depending on host susceptibility.⁷ In highly susceptible chinook, parasites were retained for 12 weeks through complete metamorphosis to the juvenile form, but histologically there was little hyperplasia in the gills. On the other hand, relatively resistant coho sloughed glochidia in about 5 days and infection was associated with a severe hyperplastic response in the gills. Similar differences in encapsulation and gill tissue reactions and length of infection have been seen with Lampsilis radiata siliquoidea infections in walleye (Stizostedion vitreum vitreum), a suitable host, versus common carp (Cyprinus carpio), a resistant host.¹²

Although most natural infections of glochidia go undetected, this report demonstrates the potential for lethal glochidia infections. Introduction of the zebra mussel, an aggressive, nonglochidia-forming species, demonstrates the potential for introduction of glochidia-producing mussels that might out compete and replace native mussel species. Susceptibility of native fishes to exotic mussel glochidia could vary substantially from native mussel species, and the potential for exotic glochidia to cause lethal disease in certain species needs to be recognized.

References

1. Davis HS. Glochidia of freshwater mussels. In: Culture and Diseases of Game Fishes 201–203,University of California Press, Berkeley, CA. 1953
2. Fustish CA, Millemann RE. Glochidiosis of salmonid fishes. II. Comparison of tissue response of coho and chinook salmon to experimental infection with Margaritifera margaritifera (L.) (Pelecypoda: Margaritanidae). J Parasitol 64:155–157, 1978[CrossRef][Medline]
3. Gordon ME, Layzer JB. Mussels (Bivalvia°Unionoidea) of the Cumberland river: review of life histories and ecological relationships. Biological report 89(15) U.S. Department of the Interior, Fish and Wildlife Service, Research and Development, Washington, DC. 1989
4. Graf DL. A phylogenetic perspective on the evolution of the Unionoida (Mollusca Bivalvia Palaeoheterodonta): using pattern to test hypotheses of macroevolutionary process [dissertation] University of Michigan, Ann Arbor, MI. 2001
5. Hoggarth MA. An examination of the glochidia-host relationships reported in the literature for North American species of Unionacea (Mollusca: Bivalvia). Malacology Data Net 3:1–30, 1992
6. Hoggarth MA. Descriptions of some of the glochidia of the unionidae (Mollusca°Bivalvia). Malacologia 41: 1–118, 1999
7. Karna DW, Millemann RE. Glochidiosis of salmonid fishes. III. Comparative susceptiblity to natural infection with Margaritifera magaritifera (L.) (Pelecypoda: Margaritanida) and associated histopathology. J Parasitol 64:528–537, 1978[CrossRef][Medline]
8. Keller AE, Ruessler DS. Determination and verification of host fishes for nine species of unionid mussels. Am Midl Nat 138: 402–407, 1997[CrossRef]
9. Meyers TR, Millemann RE. Glochidiosis of salmonid fishes. 1. Comparative susceptibility to experimental infection with Margaritifera margaritifera (L.) (Pelecypoda: Margaritanidae). J Parasitol 63:728–733, 1977[CrossRef][Medline]
10. Murphy G. Relationship of the freshwater mussel to trout in the Truckee river. Calif Fish Game 28:89–102, 1942
11. Rand TG, Wiles M. Species differentiation of the glochidia of Anodonta cataracta Say, 1817 and Anodonta implicata Say, 1829 (Mollusca: Unionidae) by scanning electron microscopy. Can J Zool 60:1722–1727, 1982
12. Waller DL, Mitchell LG. Gill tissue reactions in walleye Stizostedion vitreum vitreum and common carp Cyprinus carpio to glochidia of the freshwater mussel Lampsilis radiata siliquoidea. Dis Aquatic Org 6:81–87, 1989

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