1. Shell fish Parasitic
disease
Term paper
Parasitic disease of fin fish and shell fish (AAH-
502)
To- Proff. K. Riji. John
Head of the department
Department of Aquatic Animal Health
management
FC&RI
By – Harapriya Behera
Id no- I-17-TN-03-002-M-F-048
-
3. 1.Cotton shrimp disease
.
Such microsporidian-infected
prawns are known as ‘cotton
shrimp’, ‘milky white’ or ‘chalky
white’ prawns.
These diseases are highly
pathogenic and cause epizootics in
feral crustacean populations
5. Pathology:
• Forms opaque white patches along
dorsal midline
• Spores may fill haemocoel, destroy
the gonad.
• Abdominal muscle fibres by spores.
• Opaqueness of skeletal muscle.
7. Prevention:
• Affected animals should be destroyed and buried with lime away from the
farms. After harvesting, the pond bottom should be throughly dried to kill
the spores of the microsporadia.
• Control : Not known
9. Aetiology
• Enterocytozoon hepatopenaei
• Genus Enterocytozoonidae
• It has ovoid spores and size of approximately 0.7–1.1 mm that shows 5–6 internal coils of the
filament.
10. Host range : Enterocytozoon hepatopenaei is a microsporidian causes
disease in:-
Penaeus (Penaeus) monodon
Litopenaeus vannamei
Marsupenaeus japonicus
Geographic distribution:
EHP was first detected in P. monodon inThailand in 2004,
Vietnam
Australia
Indonesia
India
11. Pathology
• Retarded growth(10-40%) in the
• Absence of other gross signs of disease,
• Do not feed due to damage of hp tubules.
• White feces
• Hp tubule epithelial cells show the presence of cytoplasmic, basophilic inclusions
containing clusters of elliptical to somewhat ovoid spores of 1.1 ± 0.2 by 0.6-0.7 ±
0.1 µm.
• Sometimes free spores released from lysed cells may be seen in the tubule lumens;
14. Prevention& control:-
1. Disinfection by chloric acid 200ppm.
2. Avoid of live feeding. If given then pasteurization of feed at 70˚c for 15 min
should be done.
3. SPF broodstock should be taken.
4. Disinfection all the equipment NaOH at 2.5% solution for 3hrs.
5. Pond bottom should treated with Calcium oxide (CaO) (6tons/ha)
6. No chemotherapeutics
15. 3)Milky blood disease
Hematodinium infection may spread more easily
within these polyculture ponds,
In china causing severe economic loss.
16. Host range:-
1. Chinese swimming crabs (portunus trituberculatus)
2. Mud crabs (scylla serrata)
3. Ridgetail white prawn (exopalaemon carinicauda)
4. Clams
Geographical distribution:-
1. China
2. Europe
3. America
Outbreaks:-
salinities above 15 ppt
water temperatures (above 20°C for at least 1 month)
17. Pathology:
Diseased shrimp were lethargic
The carapaces showed the typical “cooked” color of shrimps or crabs,
the whitish muscle in walking legs and claws.
The hemolymph appeared milky and failed to clot
.Three forms of the parasite were frequently observed in the hemolymph,
18. whitish dicolouration of the gills (g) and opaque
haemolymph (h) pooled in the carapace of a specimen
heavily infected with Hematodinium sp. (top specimen) in
comparison to an uninfected crab.
The specimen at the top of the image was
heavily infected with Hematodinium sp. and
the other specimen was not infected with
this parasite.
19. (a) an transparent hemolymph
(b) of healthy shrimp.
B, Uninucleate trophonts. C, Multinucleate sporonts. D, Motile dinospores in an
aquarium holding disease shrimps thay recently sporulated.
20. Effect of parasite on host:
. necrosis or loss of epithelial cells and trabecular cells Of gill.
Gill lamellae were distended and filled with parasites
The hemal spaces among hepatopancreatic tubules were filled with large
number of parasites..
In crabs, the myocardium was devoid of spongy connective tissue and filled
with parasites.
21. Histopathology of ridgetail white prawns Exopalaemon carinicauda infected with Hematodinium sp.
A, Gill stem were enlarged, and filaments filled with massive number of parasites.
B,The hemal space among hepatopancreatic tubules were enlarged and filled with parasite cells.
C,Tissues in the myocardium were devoid of spongy connective tissue, the heart muscle lost its normal dense
appearance due to invasion of parasite cells.
D,The intact structure of muscle fiber in claws wa distorted because of infiltration of parasite cells.
22. Electron microscopy of Hematodinium sp. infecting ridgetail white prawn Exopalaemon carinicauda.
A, General ultrastructure of Hematodinium-like parasites in hemolymph. Scale
bar=4 μm.
B, Ultrastructures ofuninucleate,multinucleate sporonts, and dinospores in hemolymph.Note the
flagellum(arrow)of dinospores and the typical “9+2” pattern (insert) of the
flagellum. Scale bar=3 μm..
23. Control :-
• Culling heavily infected crabs
• Proper disposal of infected crabs
• Culling or removing dead animals
• Limiting transportation of live animals
• Avoid polyculture
24. 4)Perkinus spp.
It is similar to a dinoflagellate. Of 2 to
4 micrometers long
It is known as a prevalent pathogen of oysters, causing
massive mortality.
Dermo or perkinsosis.
Characterized by the degradation of oyster tissues.
it share features with both dinoflagellates and
apicomplexans, be assigned to the phylum Perkinsozoa
25. Chesapeake Bay
a) Puerto Rico,
b) Cuba
c) Brazil.
d) East coast of N. America
e) Pacific coast of mexico
American oyster Crassostrea virginica
Blue mussel Mytilus edulis
Mangrove oyster Crassostrea rhizophorae
Pacific oyster Crassostrea gigas
Sand gaper mussel Mya arenaria
Geographical distribution:- Host range:-
27. a) grow and develop a
cytoplasmic vacuole
(b). Mature trophozoites
(c) Dividing tropozoites
develops into a large
prezoosporangium
(d, mother tropozoites with
(e) daughter tropozoites
(f). On liberation into the
marine environment, the
prezoosporangium
develops a discharge tube
(g) and undergoes
palintomy
(h), resulting in the
formation of numerous
biflagellated zoospores
(i) capable of initiating a
new infection
28. Host–parasite relationships
Gross signs of ‘dermo’ low-oxygen “dead zones”
emaciation ,gapping,
pale appearance of the digestive gland,
shrinkage of the mantle away from the outer edge of the shell,
inhibition of gonadal development,
abscesses
30. Prevention and control
Cyclohexamide (1 μg/ml/week for 45 days
However, chemical treatment is impractical in the field.
Control of the disease depends on isolation and manipulation of seed stock
and recommended the following procedures: avoid use of infected seed
stocks;
Ray’s fluid thioglycollate medium (RFTM) . For disinfection prior culture.
Harvest early if beds become infected; and
fallow beds after harvest to allow all infected oysters to die before replanting
31. 5)Grey crab disease
Paramoebidae are significant pathogens of
shellfish.
Host range:-
• blue crab (C. sapidus).
• sea urchins (Strongylocentrotus droebachiensis).
• American lobsters
Aetology:-
P. perniciosa is round to elongate, with linguiform
lobopodia central endosome and a ‘second nucleus
.
32. Clinical signs and diagnosis of infection
In blue crabs, signs of infection include :-
• greyish discoloration of the ventral exoskeleton.
• General sluggishness,
• absence of clotting of the haemolymph &
Characteristic signs of paramoebiasis in sea urchins included:-
• Muscle necrosis,
• general infiltration of coelomocytes,
• Reddish-brown discoloration &
• poor attachment
33.
34. Pathogenesis
tissue displacement of connective tissues and haemal spaces, occurs
along the infections midgut, antennal gland andY organ in light.
lysis of haemocytes;
anoxia and nutrient deficiency.
35. 6)Aber disease
Marteilia refringens is a haplosporidum protozoan parasite.
Geographical distribution
1. Europe (from Greece to the Netherlands).
2. North Africa (Morocco).
3. Florida,
4. USA
Europe, especially along the Atlantic coast
of France, , commonly known
as Aber disease or digestive-gland disease.
American oyster Crassostrea virginica
European flat oyster* (Ostrea edulis)
Rock oyster (Saccostrea cuccullatta
Argentinian flat oyster Ostrea puelchana
Common cockle Cardium edule
Host range
36. Pathogenesis:-
.
• Sporangia are observed free in the lumen
of the digestive tract.
• Refringent granules appear in the course
of sporulation.
Pathology:-
• Emaciation
• Discoloration of the digestive gland,
• Cessation of growth,
• Tissue necrosis and mortalities
38. Schematic drawing to scale of the sporulation process of Marteilia spp., sporangiosorus (or primary cell);
NS, nucleus of sporangiosorus; SP, sporangial primordium (or secondary cell); NSP, nucleus of sporangial
primordium; St, sporont; SpP, spore primordium (or tertiary cell); MSp, mature spore; R, refringent
bodies; N1, nucleus of outermost sporoplasm; N2, nucleus of middle
sporoplasm; N3, nucleus of innermost sporoplasm.
39. Control measures
• The primary method of control is by restriction of the movement of
infected animals to areas.
• To avoid the introduction of animals from an enzootic area to areas.
• During the summer, oysters were not planted in areas of risk
40. 7)BONAMIASIS
• commonly called a microcell
because of its small size(2-3μm); is a
lethal pathogen of flat oysters (O.
edulis), In which it causes a disease
called bonamiasis.
41. European flat oyster, Ostrea edulis.
Australian flat oyster Ostrea angasi
• In Europe, distribution of the parasite is along the
Atlantic coast from Spain to Denmark.
• In the USA it is found on the Atlantic coast in Maine
and the Pacific coast from California to
Washington. England, France, Ireland, Holland,
42. Pathology
Although many infected oysters
appear normal, others
Bonamia ostreae infects the granular
blood cells (haemocytes) of the native
oyster.
non-specific gill lesions which appear
as perforations, and a yellowing of the
tissues.
43. control and prevention
Resistant species, such as pacific oysters, are now being cultured in areas.
destruction of infected stocks
restricting movement of flat oysters.
measure must be taken as early as possible.
45. Pathology:-
• Nacreous blisters produced
• atrophy and detachment of the adductor muscle
• mud blisters in the shell
• yellowish abscesses in the adductor muscle
• mud blisters may interfere with shucking and this reduces the commercial
value of oysters to be served on the half-shell.
47. 9)Trematode
Host species
Sporocysts and cercariae in
• Mytilus edulis,
• Mytilus galloprovincialis
• bivalve species
• Gallo mussels
• Hooked mussels (Ischadium
recurvum).
• Brown mussel (perna perna
Geographic distribution
• Northwestern Europe
• Atlantic Canada.
• west coast of North America
• Usa
• Gulf of mexico
49. Pathology:-
• In mussels, sporocysts of Bucephalus mytili) occur in the vascular system.
• alteration in haemolymph components,
• reduction in growth rate
• weakness in respect of valve closure and attachment to the substrate
• sporocyst infiltrates in gonad.
• occlusion of the haemal sinuses and
• gradual destruction and replacement of molluscan tissue by the sporocyst
50.
51. 10)Phylum- Arthropoda
Bopyrus spp. Mytilicola spp.
These copepods have a direct life cycle.
Host range
• Japanese red prawns (Penaeopsis akayebi)
• Epipenaeon japonicus,
• grooved tiger prawns (Penaeus semisulcatus),
• bivalves
52. Pathology:-
• Slight decrease in host growth
• Small changes in the host’s secondary sexual characters
• Reduce reproductive capability of female prawn
• Reside in the intestinal tract of a widevariety of bivalves
53. Conclusion
A wide variety of parasites have been identified as causing significant
economic losses in shellfish production worldwide. Many of these
pathogens have the potential of causing significant losses either in endemic
areas or if they inadvertently become established in other areas.
In order to avoid future disasters, all movements o shellfish must be
conducted with caution Equally essential is the acquisition of information
on agents of disease, including parasites, such that risks associated with
impending movements and aquaculture practices can be accurately
assessed.This information should also prove useful for treating or
controlling a disease in the event that an accidental introduction occurs.
54. Reference
• Parasitic Diseases of Shellfish Susan M. Bower Fisheries and Oceans
Canada, Sciences Branch, Pacific Biological Station, Nanaimo, British
Columbia, CanadaV9T 6N7Aquatic Animal Disease
• Significant to Asia–Pacific Identification Field Guide
• Haplosporidian Diseases of Imported Oysters, Ostrea edulis, in Dutch
Estuaries PAUL van BANNIN
• Fisheries Research Services
• DFO - BucephalidTrematode Disease of Mussels
• www.dfo-mpo.gc.ca/science/aah-saa/diseases-maladies/bucephmu-
eng.html
