Fin healing and regeneration in sturgeon

Allen, Peter J.; Baumgartner, Wes; Brinkman, Erin; DeVries, R. J.; Stewart, Heather A.; Aboagye, Daniel L.; Ramee, Shane W.; Ciaramella, Michael A.; Culpepper, Charlie M.; Petrie‐Hanson, Lora

doi:10.1111/jfb.13794

Cited by 8 publications

(8 citation statements)

References 65 publications

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“…In addition, Allen et al. (2018a) confirmed that the complete regeneration of the pectoral fin ray in juvenile Atlantic Sturgeon was achieved after 12 months of healing. With specific reference to Lake Sturgeon (the focus of our study), a recent mark–recapture study from the Winnipeg River (wherein all juvenile Lake Sturgeon captured had fin rays removed for aging) produced annual survival estimates of 0.99 (McDougall et al.…”

Section: Discussionmentioning

confidence: 94%

Identification of Hatchery‐Reared Lake Sturgeon Using Natural Elemental Signatures and Elemental Marking of Fin Rays

Loeppky

McDougall²,

Anderson

2020

N American J Fish Manag

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Stock enhancement programs often involve the introduction of hatchery‐reared fish into wild environments, with the goal of increasing the abundance of a particular stock. To measure the success of stocking efforts for depressed populations, hatchery‐reared individuals must be distinguishable from naturally spawned fish, potentially many years after release. Biological tags are attractive due to their ability to batch‐mark whole cohorts in a cost‐effective manner, with minimal disruption to hatchery procedures and reduced handling stress inflicted on individuals during the marking process. Elemental marking may occur naturally or via deliberate manipulation of the concentration of specific elements to create recognizable elemental signatures in the hard structures of fish (e.g., fin rays and otoliths). In this study, elemental signatures in the fin rays of known hatchery‐released Lake Sturgeon Acipenser fulvescens (ages 1–7) were quantified via laser ablation (LA) inductively coupled plasma–mass spectrometry (ICP‐MS) to assess whether the ambient water chemistry in a groundwater‐fed hatchery would create an elemental signature that facilitated discrimination of hatchery‐reared individuals from those naturally spawned in the wild. The concentrations of divalent trace elements, particularly Mn, within the first growth band of hatchery‐reared fish were significantly different from those of wild conspecifics, allowing us to accurately classify hatchery‐ versus wild‐spawned individuals with 99% success. In addition, we conducted a preliminary experiment to test the validity of two separate 24‐h immersions in 86Sr and 137Ba (immersions were conducted 30 d apart) to induce multiple combination marks in the fin rays of juvenile Lake Sturgeon. Fin rays collected 60 d after the second immersion were analyzed for isotopic ratios via LA ICP‐MS, and results indicated that elemental marking at both time points was achieved with 100% success. Induction of a combination of isotopic signatures could enable hatcheries to track the success of families or stocking groups within a single year‐class or across multiple year‐classes.

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Section: Discussionmentioning

confidence: 94%

Identification of Hatchery‐Reared Lake Sturgeon Using Natural Elemental Signatures and Elemental Marking of Fin Rays

Loeppky

McDougall²,

Anderson

2020

N American J Fish Manag

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“…The dermal fin folds are useful during swimming, but due to their fine structure, they can get easily injured, therefore, the capacity to regenerate them has clear adaptive value. Exoskeletal regeneration has been described in many Actinopterygian species, (e.g., sturgeon (Acipenser oxyrinchus) [35], short-lived killifish (Nothobranchius furzeri) [36], sailfin molly (Poecilia latipinna) [37], mexican cavefish (Astyanax mexicanus) [38], medaka (Oryzias latipes) [39], loach (Paramisgurnus dabryanu) [40] and several others [41]), suggesting that this is an ancestral trait of ray-finned fishes.…”

Section: Discussionmentioning

confidence: 99%

No Correlation between Endo- and Exoskeletal Regenerative Capacities in Teleost Species

Pápai

Kagan

Csikós

et al. 2019

Fishes

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The regeneration of paired appendages in certain fish and amphibian lineages is a well established and extensively studied regenerative phenomenon. The teleost fin is comprised of a proximal endoskeletal part (considered homologous to the Tetrapod limb) and a distal exoskeletal one, and these two parts form their bony elements through different ossification processes. In the past decade, a significant body of literature has been generated about the biology of exoskeletal regeneration in zebrafish. However, it is still not clear if this knowledge can be applied to the regeneration of endoskeletal parts. To address this question, we decided to compare endo- and exoskeletal regenerative capacity in zebrafish (Danio rerio) and mudskippers (Periophthalmus barbarous). In contrast to the reduced endoskeleton of zebrafish, Periophthalmus has well developed pectoral fins with a large and easily accessible endoskeleton. We performed exo- and endoskeletal amputations in both species and followed the regenerative processes. Unlike the almost flawless exoskeletal regeneration observed in zebrafish, regeneration following endoskeletal amputation is often impaired in this species. This difference is even more pronounced in Periophthalmus where we could observe no regeneration in endoskeletal structures. Therefore, regeneration is regulated differentially in the exo- and endoskeleton of teleost species.

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“…Similarly, telemetry is often an inviable option when working with endangered species, as capture, surgery, and transmitter application may be harmful (Nielsen 1998;Godfrey et al 2003). Trace elements have been demonstrated to be a useful technique for identifying life history traits in sturgeons (Allen et al 2009(Allen et al , 2018a.…”

Section: Introductionmentioning

confidence: 99%

“…These techniques were found to be useful when identifying the spawning location, age determination, and growth of A. oxyrinchus oxyrinchus (Atlantic Sturgeon) (Stevenson and Secor 2000;Balazik et al 2012) and in A. brevirostrum (Shortnose Sturgeon) (Altenritter et al 2015). Strontium (Sr) isotopes, are also used to identify natal spawning areas of freshwater fishes (Hobbs et al 2007;Hobbs et al 2010), and contemporary studies have used them to distinguish freshwater movements of juvenile Gulf Sturgeon in the Choctawhatchee River System (Allen et al 2018a). Trace element and Sr isotopes analysis are potentially useful for other river systems occupied by Gulf Sturgeon, such as the Pearl River System in Louisiana and Mississippi where little is known of movements and habitat use of juveniles.…”

Section: Introductionmentioning

confidence: 99%

“…Identifying trace elements and strontium isotope gradients has the potential to provide useful baseline information for application to fisheries conservation within the Pearl River Watershed. Based on a contemporary study on the Choctawhatchee River System (Allen et al 2018a), it is anticipated that trace element and 87 Sr/ 86 Sr isotope ratios in calcified structures of fishes will be beneficial for life history reconstruction within the Pearl River System. This information is beneficial for resource managers for use in assessing changes within watersheds and identifying ontogenetic patterns, anadromous movements, and life history characteristics of Gulf Sturgeon and other fishes.…”

Section: Introductionmentioning

confidence: 99%

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Spatial changes in trace element and strontium isotope water chemistry in a temperate river system with application to sturgeon movement

Gunn

Moran

Pracheil

et al. 2019

Journal of Freshwater Ecology

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Understanding patterns in trace element concentrations and water quality within river systems provides a foundation to evaluate retrospective movements and habitat use of fish. Because trace elements are incorporated into calcified structures of fishes relative to water concentrations, baseline maps have application for fisheries management, including for rare species such as sturgeons. Therefore, trace elements [strontium (Sr), barium (Ba), manganese (Mn), zinc (Zn), and magnesium (Mg)], strontium isotopes ( 87 Sr/ 86 Sr), dissolved oxygen and salinity were measured in the Pearl River and Lake Pontchartrain watersheds, within Mississippi and Louisiana, USA for application in assessing riverine use by Gulf Sturgeon Acipenser oxyrinchus desotoi. Water samples were collected during the summerfall period when juvenile Gulf Sturgeon were anticipated to be present and analyzed by solution and multi-collector inductively coupled plasma mass spectrometry. Trace element to calcium (Ca) ratios in Sr, Ba, Zn, and Mg were distinguishable between the upper Pearl River and the Bogue Chitto River tributary, and the upper Pearl River and lower Pearl River. For most trace elements and 87 Sr/ 86 Sr, there was a gradual increase from upper river regions to lower river regions, and large differences between freshwater and saline areas. Lake Pontchartrain watershed rivers were not easily differentiated, but regions of low dissolved oxygen concentrations in the lower reaches suggest available Gulf Sturgeon habitat may be seasonally limited. Therefore, maps of water microchemistry in the Pearl River watershed allow for retrospective analyses of fish watershed use.

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Fin healing and regeneration in sturgeon

Cited by 8 publications

References 65 publications

Identification of Hatchery‐Reared Lake Sturgeon Using Natural Elemental Signatures and Elemental Marking of Fin Rays

Identification of Hatchery‐Reared Lake Sturgeon Using Natural Elemental Signatures and Elemental Marking of Fin Rays

No Correlation between Endo- and Exoskeletal Regenerative Capacities in Teleost Species

Spatial changes in trace element and strontium isotope water chemistry in a temperate river system with application to sturgeon movement

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