Skin healing and scale regeneration in fed and unfed sea bream, Sparus auratus

Vieira, Florbela A.; Gregório, Sílvia F.; Ferraresso, Serena; Thorne, Michael A. S.; Costa, Rita A.; Milan, Massimo; Bargelloni, Luca; Clark, Melody S.; Canário, Adelino V.M.; Power, Deborah M.

doi:10.1186/1471-2164-12-490

Cited by 58 publications

(53 citation statements)

References 81 publications

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“…Transcriptional responses to damage have also been studied in non-mollusc species. In a microarray experiment investigating scale regeneration (a type of biomineralisation) in sea bream, Vieira et al (2011) found 769 differentially expressed genes after 3 days but only 21 differentially expressed after 7 days. Taken together with the results of the present study, damage-repair experiments emphasise the importance of timing in biomineralisation studies.…”

Section: Experiments One: Transcriptional Profiling Of Damage Responsementioning

confidence: 99%

Transcriptomic response to shell damage in the Antarctic clam, Laternula elliptica: Time scales and spatial localisation

2015

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Mollusc shell is built-up by secretion from the mantle and is the result of a controlled biological process termed biomineralisation. In general mollusc shells are well characterised however, the molecular mechanisms used by molluscs to produce shell remain largely unknown. One tractable method to study molecular biomineralisation mechanisms are shell damage-repair experiments, which stimulate calcification pathways. The present study used the Antarctic clam (Laternula elliptica) as a model to better understand when and where molecular biomineralisation events occur in the mantle. Two approaches were used: one experiment used high-throughput RNA-sequencing to study molecular damage-repair responses over a 2 month time series, and a second experiment used targeted semi-quantitative PCR to investigate the spatial location of molecular mechanisms in response to damage. Shell repair in L. elliptica was slow, lasting at least 2 months, and expression results revealed different biological processes were important at varying time scales during repair. A spatial pattern in relation to a single drilled hole was revealed for some, but not all, candidate genes suggesting the mantle may be functionally zoned and can respond to damage both locally and ubiquitously across the mantle. Valuable data on the temporal and spatial response of shell damage-repair provide a baseline not only for future studies in L. elliptica, but also other molluscs.

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Section: Experiments One: Transcriptional Profiling Of Damage Responsementioning

confidence: 99%

Transcriptomic response to shell damage in the Antarctic clam, Laternula elliptica: Time scales and spatial localisation

2015

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“…Keratocytes can cover fish skin wound surfaces with a new protective layer of cells within hours after wounding by rapid migration from the surrounding wound margins [66,67]. In addition to their migratory activity, different cell types present in fish epidermis are shown to internalize particular matter such as bacteria and other particles.…”

Section: Teleost Skinmentioning

confidence: 99%

An Overview of the Immunological Defenses in Fish Skin

2012

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The vertebrate immune system is comprised of numerous distinct and interdependent components. Every component has its own inherent protective value, and the final combination of them is likely to be related to an animal's immunological history and evolutionary development. Vertebrate immune system consists of both systemic and mucosal immune compartments, but it is the mucosal immune system which protects the body from the first encounter of pathogens. According to anatomical location, the mucosa-associated lymphoid tissue, in teleost fish is subdivided into gut-, skin-, and gill-associated lymphoid tissue and most available studies focus on gut. The purpose of this paper is to summarise the current knowledge of the immunological defences present in skin mucosa as a very important part of the fish immune system, serving as an anatomical and physiological barrier against external hazards. Interest in defence mechanism of fish arises from a need to develop health management tools to support a growing finfish aquaculture industry, while at the same time addressing questions concerning origins and evolution of immunity in vertebrates. Increased knowledge of fish mucosal immune system will facilitate the development of novel vaccination strategies in fish.

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“…Fish skin differs in several aspects from mammalian skin and the functional divergence between skin in a terrestrial and aquatic environment is presumably underpinned by significant divergence in molecular and cellular processes. While in human skin the primary physical barrier that confers protection is the stratified epidermis that is composed of dead keratinized cells, in fish the epidermis is composed of metabolically active cells with little keratinization [5–8]. Goblet cells and club cells produce mucous rich in proteases, mucins, immunoglobulins and antimicrobial peptides (AMPs) that protect the living epidermis of the fish integument.…”

Section: Introductionmentioning

confidence: 99%

Evolution of the angiopoietin-like gene family in teleosts and their role in skin regeneration

2017

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BackgroundThe skin in vertebrates is a protective barrier and damage is rapidly repaired to re-establish barrier function and maintain internal homeostasis. The angiopoietin-like (ANGPTL) proteins are a family of eight secreted glycoproteins with an important role in skin repair and angiogenesis in humans. In other vertebrates their existence and role in skin remains largely unstudied. The present study characterizes for the first time the homologues of human ANGPTLs in fish and identifies the candidates that share a conserved role in skin repair using a regenerating teleost skin model over a 4-day healing period.ResultsHomologues of human ANGPTL1-7 were identified in fish, although ANGPTL8 was absent and a totally new family member designated angptl9 was identified in fish and other non-mammalian vertebrates. In the teleost fishes a gene family expansion occurred but all the deduced Angptl proteins retained conserved sequence and structure motifs with the human homologues. In sea bream skin angptl1b, angptl2b, angptl4a, angptl4b and angptl7 transcripts were successfully amplified and they were differentially expressed during skin regeneration. In the first 2 days of skin regeneration, re-establishment of the physical barrier and an increase in the number of blood vessels was observed. During the initial stages of skin regeneration angptl1b and angptl2b transcripts were significantly more abundant (p < 0.05) than in intact skin and angptl7 transcripts were down-regulated (p < 0.05) throughout the 4-days of skin regeneration that was studied. No difference in angptl4a and angptl4b transcript abundance was detected during regeneration or between regenerating and intact skin.ConclusionsThe angptl gene family has expanded in teleost genomes. In sea bream, changes in the expression of angptl1b, angptl2b and angptl7 were correlated with the main phases of skin regeneration, indicating the involvement of ANGPTL family members in skin regeneration has been conserved in the vertebrates. Exploration of the fish angptl family in skin sheds new light on the understanding of the molecular basis of skin regeneration an issue of importance for disease control in aquaculture.Electronic supplementary materialThe online version of this article (doi:10.1186/s12862-016-0859-x) contains supplementary material, which is available to authorized users.

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Skin healing and scale regeneration in fed and unfed sea bream, Sparus auratus

Cited by 58 publications

References 81 publications

Transcriptomic response to shell damage in the Antarctic clam, Laternula elliptica: Time scales and spatial localisation

Transcriptomic response to shell damage in the Antarctic clam, Laternula elliptica: Time scales and spatial localisation

An Overview of the Immunological Defenses in Fish Skin

Evolution of the angiopoietin-like gene family in teleosts and their role in skin regeneration

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