Pathologic Cuticular Changes of Winter Impoundment Shell Disease Preceding and During Intermolt in the American Lobster, <i>Homarus americanus</i>

Smolowitz, Roxanna; Bullis, Robert A.; Abt, D. A.

doi:10.2307/1542411

Cited by 69 publications

(79 citation statements)

References 10 publications

(12 reference statements)

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“…Although shell disease results from bacterial invasion of the carapace (hess 1937;Rosen 1970;Malloy 1978;Stewart 1980;Getchell 1989;Smolowitz et al 1992Smolowitz et al ,2002Smolowitz et al ,2005Chistoserdov et al 2005), reasons for the increased ability of bacteria to penetrate the carapace are unknown. our results show that there is no evidence that the destruction of the cuticle leads to systematic infection by organisms associated with the cuticular lesion.…”

Section: Discussionmentioning

confidence: 99%

“…It is characterised by an erosion of the cuticle surface (Fisher et al 1978;Malloy 1978;Stewart 1980;Getchell 1989;Young 1991;Smolowitz et al 1992Smolowitz et al , 2002 and progressive chitinolysis and necrosis of the exoskeleton (Rosen 1970;Getchell 1989;Sindermann 1989). Histo-pathologic symptoms of shell diseases are necrotic lesions with bacteria first penetrating and breaking down the first layer of the exoskeleton (epicuticle), followed by necrosis of underlying tissue.…”

Section: Introductionmentioning

confidence: 99%

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Internal organ pathology of wild American lobster (Homarus americanus) from eastern Canada affected with shell disease

Comeau

Benhalima

2009

New Zealand Journal of Marine and Freshwater Research

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For the first time in decades, multiple lesions on the exoskeleton of wild caught American lobsters (Homarus americanus) were observed in eastern Canada in 2005 and 2006. These lesions were similar to those observed since the mid 1990s in the eastern United States. Of the 12 lobsters examined, 8 were males. Scanning electron microscopy showed a dense population of rod-shaped bacteria associated with the breakdown of the first layer of cuticle. However, the ability of bacteria to fully penetrate the carapace is unknown. The shell disease did not seem to be immediately fatal and was often associated with alterations in the histoarchitecture of several internal organs (i.e., testis, vas deferens, hepatopancreas, and gills). For instance, follicle cells responsible for spermatogenesis were damaged, resulting in deformed and non-viable spermatozoa in the testis and vas deferens. In contrast, the female reproductive organ did not show any abnormalities. R-cells responsible for the storage of lipids and glycogen in the hepatopancreas were severely damaged or destroyed, indicating stress and starvation. Beside necrosis and calcification of gill filaments, debris between the gill filaments was also observed that would limit ion exchange and cause metabolic exhaustion. It does not seem that shell disease was the causative agent or a vector for the pathological conditions of internal organs, but one of the symptoms of a common agent affecting the internal organs. Although shell disease was observed in several areas in eastern Canada, its prevalence M07111;

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Internal organ pathology of wild American lobster (Homarus americanus) from eastern Canada affected with shell disease

Comeau

Benhalima

2009

New Zealand Journal of Marine and Freshwater Research

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“…Shell disease is a common term for many different melanization of necrotic lesions, erosions, and disintegrations in crustaceans such as classical or endemic shell disease (Smolowitz et al, 1992;Sindermann, 1979) and epizootic shell disease (Shields, 2013;Smolowitz et al, 2005). The proximate causes are thereby a dysbiosis of different chitinolytic and lipolytic bacteria such as Plesiomonas, Vibrio and Aquimarina (Cipriani et al, 1980;Feinmann et al, 2017;Getchell, 1989;Meres et al, 2012;Rosen, 1967).…”

Section: Introductionmentioning

confidence: 99%

“…The proximate causes are thereby a dysbiosis of different chitinolytic and lipolytic bacteria such as Plesiomonas, Vibrio and Aquimarina (Cipriani et al, 1980;Feinmann et al, 2017;Getchell, 1989;Meres et al, 2012;Rosen, 1967). These pathogens are common in marine environments Fisher et al, 1978;Hock, 1940;Malloy, 1978;Smolowitz et al, 1992) and are also present on the cuticle of healthy crustaceans (Rosen, 1967), in this case without any impact on the host. Under stressful environmental conditions (ultimate causes e.g.…”

Section: Introductionmentioning

confidence: 99%

Shell disease in Crangon crangon (Linnaeus, 1758): The interaction of temperature and stress response

Segelken-Voigt

Miller

Gerlach

2018

Journal of Experimental Marine Biology and Ecology

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A B S T R A C TThe prevalence of black spot shell disease is increasing among marine crustaceans worldwide. Rising seawater temperatures -often stressful for ectothermic species -are assumed to enhance the occurrence of shell disease. In the North Sea > 50% of local populations of the brown shrimp (Crangon crangon) are affected by the disease. While fisheries are suffering because diseased crustaceans are barely merchantable, the impact of shell disease on life history traits of crustaceans is little understood. To determine the role of temperature on the development of black spots and its implications for survival and physiology in the brown shrimp, a prolonged (3 months) thermal stress experiment was performed. We measured the increment of shell disease and the effect of molting in shrimps kept at control (15°C = equivalent to the seafloor temperature in the North Sea during sampling) and increased temperature (20°C = according to predictions for the end of the century). The resting metabolic rate was analyzed to determine the physiological state of diseased compared to non-diseased animals. In the present study, the warmer temperature in the range of 20°C did not increase the spot size of shell disease and no differences were observed between the two temperatures. The process of molting thereby seemed to diminish and in most of the cases even completely remove the signs of shell disease. At 15°C but not at 20°C, metabolic rate was reduced in diseased in contrast to healthy individuals. This study showed that shell disease might lead to a higher mortality rate and an impairment of the physiological state in C. crangon.

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“…Although the disease is not believed to be fatal in its initial stages, death is known to result from adhesion of successive moult shells at lesion sites leading to incomplete withdrawal from exuviate at moult (Smolowitz et al, 1992). Alterations in immune reactivity within invertebrates have been shown in response to various external and artificial stimuli, including changes in temperature and salinity, pollutants (Le Moullac and Haffner, 2000), and natural or artificially induced infections (Ford et al, 1993).…”

Section: Introductionmentioning

confidence: 99%

Shell disease of Neoepisesarma mederi crabs and its associated secondary infections

Sharmila¹,

Ravich²,

ran³

et al. 2013

Afr. J. Microbiol. Res.

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Shells of crabs are infected with a high prevalence of diseases than any other crustacean. Bacteria, viruses, fungi and several other pathogens influence higher percentage of shell disease in crabs. Infections in crab affected growth and metabolism and it may also lead to death. This work deals with the microscopic examination of shell diseased crabs with reference to its variation in hemocytes count, histopathology and biochemical estimation. The total heterotrophic bacterial (THB) population in normal shell was found to be 5.15 x 10 4 ± 0.09 Colony forming unit (CFU) ml -1 and THB load was noted to be slightly increased than in normal shell and the count was 5.95 x 10 4 ± 0.12 CFU ml -1 in the infected shell. The current findings suggest a positive correlation between bacterial shell disease and the secondary infection affecting hemolymph (total hemocyte count), proximate composition (protein, carbohydrate and lipid) and histopathology of the animal (gills, hepatopancreas and heart). The total hemocyte count and differential count were experimented which showed lower number of total hemocytes in infected crabs while no highly accountable difference was found in differential count. Hematology studies reported total hemocyte as 9.93 x10 6 ± 0.07 cells ml -1 in normal and 6.525 x 10 6 ± 0.12 cells ml -1 in shell diseased hemolymph. The level of protein, carbohydrate and lipid contents suffered a mild alteration in crabs with bacterial shell disease. Histopathology of gills had shown variations such as dilated lamellae and hemocyte accumulation (nodules), hepatopancreas showed mild difference with increased necrosis, appearance of hemocytic nodules in the hemal spaces and heart with very mere infection while no reportable changes were accomplished in muscle tissue.

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Pathologic Cuticular Changes of Winter Impoundment Shell Disease Preceding and During Intermolt in the American Lobster, Homarus americanus

Cited by 69 publications

References 10 publications

Internal organ pathology of wild American lobster (Homarus americanus) from eastern Canada affected with shell disease

Internal organ pathology of wild American lobster (Homarus americanus) from eastern Canada affected with shell disease

Shell disease in Crangon crangon (Linnaeus, 1758): The interaction of temperature and stress response

Shell disease of Neoepisesarma mederi crabs and its associated secondary infections

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