Histologic Findings in Captive American Horseshoe Crabs (<i>Limulus polyphemus</i>)

LaDouceur, Elise E B; Mangus, Lisa M.; Garner, Michael M.; Cartoceti, Andrew N.

doi:10.1177/0300985819859877

Cited by 7 publications

(17 citation statements)

References 16 publications

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“…Vibrio is commonly found in the microbiomes of aquatic organisms and some species have been identified as pathogens, commensals, and mutualists, yet, an understanding of the relationships between many Vibrio species and their hosts requires further research (Thompson et al, 2016). A histological analysis of Limulus identified several bacterial species associated with pathological conditions including Pseudomonas and Aeromonas (LaDouceur et al, 2019) which also appear to be major constituents of what we suspect is a pathological condition in our study, as well. A more comprehensive view of a core horseshoe crab microbiome awaits cultivation-independent surveys of other horseshoe crab species, and more individuals from different geographic and physicochemical environments (e.g., estuarine and marine).…”

Section: Discussionsupporting

confidence: 69%

“…Once the exoskeleton of the horseshoe crab has been breached (or degraded), it would then be susceptible to secondary infections and given that adults do not molt, the damage accumulated is irreparable. Previous studies have associated infections in captive lab horseshoe crab populations with eukaryotic parasites, algae, fungi, and bacteria (commonly Cyanobacteria and Gram-negative bacteria) (Leibovitz and Lewbart 2004, Smith 2006; Braverman et al, 2012, LaDouceur et al, 2019). We hypothesize that the appearance of these lesions could be due to dysbiosis of the horseshoe crab microbiome, resulting in an overall increase in the abundance of chitinolytic bacteria or the appearance of opportunistic pathogens capable of degrading chitin.…”

Section: Discussionmentioning

confidence: 99%

“…Additionally, several species of Pseudoalteromonas are widely discussed in the literature as symbionts, given their diverse metabolic potential and their ability to produce a variety of antibacterial, antifungal, algicidal, and antifouling compounds (Atencio et al 2018; Offret et al 2016). Fungi have been identified as possible chitinase containing pathogens that could be involved in this process (Tuxbury et al, 2014; LaDouceur et al, 2019). In our study, we excluded eukaryotic sequences from analysis and therefore were unable to document the fungal communities of our samples.…”

Section: Discussionmentioning

confidence: 99%

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Microbiome shifts associated with the introduction of wild Atlantic horseshoe crabs (Limulus polyphemus) into a touch-tank exhibit

Friel

Neiswenter

Seymour

et al. 2020

Preprint

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Section: Discussionsupporting

confidence: 69%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Microbiome shifts associated with the introduction of wild Atlantic horseshoe crabs (Limulus polyphemus) into a touch-tank exhibit

Friel

Neiswenter

Seymour

et al. 2020

Preprint

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“…This is in direct opposition to a study on cownose rays in touch tanks, which concluded that the transfer of human-associated taxa to the rays was negligible ( Kearns et al, 2017 ). Cultural analyses of hemolymph samples from captive Limulus resulted in the isolation of several bacterial species associated with pathological conditions, including Shewanella putrefaciens (formerly Pseudomonas putrefaciens ) and Aeromonas hydrophila ( Khashe and Janda, 1998 ; LaDouceur et al, 2019 ). We hypothesize that the unclassified species of Pseudomonas and Aeromonas that dominate our tank-acclimated population are involved somehow in the development of the diseased state in our study.…”

Section: Discussionmentioning

confidence: 99%

“…Once the exoskeleton of the horseshoe crab has been breached (or degraded), it would then be susceptible to secondary infections and given that adults do not molt, the damage accumulated is irreparable. Previous studies have associated infections in captive lab horseshoe crab populations with eukaryotic parasites, algae, fungi, and bacteria (commonly Cyanobacteria and Gram-negative bacteria) ( Leibovitz and Lewbart, 2003 ; Smith, 2007 ; Braverman et al, 2012 ; LaDouceur et al, 2019 ). We hypothesize that the appearance of these lesions could be due to shifts in the horseshoe crab microbiome, resulting in an overall increase in the abundance of chitinolytic bacteria or the appearance of opportunistic pathogens capable of degrading chitin.…”

Section: Discussionmentioning

confidence: 99%

Microbiome Shifts Associated With the Introduction of Wild Atlantic Horseshoe Crabs (Limulus polyphemus) Into a Touch-Tank Exhibit

et al. 2020

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The Atlantic horseshoe crab ( Limulus polyphemus ) is a common marine aquarium species and model organism for research. There is potential monetary and conservation value in developing a stable captive population of horseshoe crabs, however, one major impediment to achieving captivity is a lack of knowledge regarding captive diseases. We utilized 16S rRNA gene amplicon sequencing to track changes in the microbiomes of four body locations in three wild-caught (tracked over 14 months in captivity) and three tank-acclimated (>2 years in captivity) adult L. polyphemus in a touch tank at Shark Reef Aquarium at Mandalay Bay in Las Vegas, NV. The wild population hosted diverse and distinct microbiomes on the carapace (260 ± 96 amplicon sequence variants or ASVs), cloaca (345 ± 77 ASVs), gills (309 ± 36 ASVs), and oral cavity (359 ± 37 ASVs), which were dominated by classes Gammaproteobacteria , Bacteroidia , and Alphaproteobacteria . A rapid decline in richness across all body locations was observed within 1 month of captivity, with tank-acclimated (>2 years) animals having <5% of the initial microbiome richness and a nearly completely restructured microbial community. Tank-acclimated horseshoe crabs possessed distinct microbiomes that were highly uneven and low in species richness on the carapace (31 ± 7 ASVs), cloaca (53 ± 19 ASVs), gills (17 ± 2 ASVs), and oral cavity (31 ± 13 ASVs). The carapace, oral cavity, and gills of the tank-acclimated animals hosted abundant populations of Aeromonas (>60%) and Pseudomonas (>20%), both of which are known opportunistic pathogens of aquatic animals and can express chitinases, providing a plausible mechanism for the development of the carapace lesion pathology observed in this and other studies. The cloaca of the tank-acclimated animals was slightly more diverse than the other body locations with Aeromonas , Enterococcus , Shewanella , and Vagococcus dominating the community. These results provide an important baseline on the microbiomes of both wild and tank-acclimated horseshoe crabs and underscore the need to continue to investigate how native microbial populations may protect animals from pathogens.

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Horseshoe Crabs

Smith¹

2021

Invertebrate Medicine

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Histologic Findings in Captive American Horseshoe Crabs (Limulus polyphemus)

Cited by 7 publications

References 16 publications

Microbiome shifts associated with the introduction of wild Atlantic horseshoe crabs (Limulus polyphemus) into a touch-tank exhibit

Microbiome shifts associated with the introduction of wild Atlantic horseshoe crabs (Limulus polyphemus) into a touch-tank exhibit

Microbiome Shifts Associated With the Introduction of Wild Atlantic Horseshoe Crabs (Limulus polyphemus) Into a Touch-Tank Exhibit

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