<i>Collagen type XI α1</i> may be involved in the structural plasticity of the vertebral column in Atlantic salmon (<i>Salmo salar</i> L.)

Wargelius, Anna; Fjelldal, Per Gunnar; Nordgarden, Ulla; Grini, Ane; Krossøy, Christel; Grotmol, Sindre; Totland, Geir K.; Hansen, Tom

doi:10.1242/jeb.040022

Cited by 10 publications

(13 citation statements)

References 34 publications

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“…There appears to be a delay of several weeks between the induction and the development of a deformity (Wargelius et al., 2010a; Grini et al., 2011). The expression level of several genes is different in deformed compared to normal vertebrae; collagen type XI a1 gene is down‐regulated in the compact but not in the trabecular bone (Wargelius et al., 2010b) and MMP‐13 is up‐regulated in both compact and trabecular bone of compressed vertebrae (Wargelius et al., 2010b). Osteonectin (SPARC) gene, MMP‐9 and MMP‐13 are up‐regulated and collagen I, collagen X and osteocalcin genes are down‐regulated in completely fused vertebrae (Ytteborg et al., 2010b).…”

Section: Causes and Pathogenesis Of Vertebral Deformitiesmentioning

confidence: 99%

Vertebral deformities in farmed Atlantic salmon (Salmo salar L.) - etiology and pathology

Fjelldal

Hansen

Breck³

et al. 2012

Journal of Applied Ichthyology

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106

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Summary The present review sums up and discusses the current literature on occurrence, causation and pathology of vertebral deformities in farmed Atlantic salmon, and also gives a brief introduction into the normal ontogeny and anatomy of the vertebral column of Atlantic salmon. Skeletal development and growth are sensitive processes that can be affected by many factors. Many of these factors can be manipulated under farming conditions, and are thus regarded as risk factors. Several risk factors that relate to environmental conditions and to feed composition have been identified. Elevated temperatures and photoperiod manipulation to speed up growth are likely the most important environmental factors that cause skeletal deformities. Among the nutritional factors, optimal phosphorus nutrition during specific periods, for example after transfer to sea water, appears to be critical for development of deformity at later stages. More research is needed to understand the interdependency of genetics, development, aging, phosphorus nutrition, temperature and photoperiod, in order to establish the best practice procedures for salmon farming that improve fish welfare.

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Section: Causes and Pathogenesis Of Vertebral Deformitiesmentioning

confidence: 99%

Vertebral deformities in farmed Atlantic salmon (Salmo salar L.) - etiology and pathology

Fjelldal

Hansen

Breck³

et al. 2012

Journal of Applied Ichthyology

Self Cite

106

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“…Collagen XI α1 has been cloned in Atlantic salmon, where it is expressed in the osteoblasts and chordoblasts of the vertebral column (Wargelius et al . ). How the vitamin D system and bone of fish under continuous light responds to different dietary P levels when compared to fish under a short day has never been studied.…”

Section: Introductionmentioning

confidence: 97%

Continuous light induces bone resorption and affects vertebral morphology in Atlantic salmon (Salmo salarL.) fed a phosphorous deficient diet

Fjelldal

Lock²,

Hansen

et al. 2012

Aquacult Nutr

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This study investigated the combined effects of photoperiod and dietary P level on bone osteoclast and osteoblast activity, and morphology, as well as plasma vitamin D status in Atlantic salmon post‐smolts. The fish were reared under continuous light (LL) or 12 h light/dark (LD) per day, and fed diets with insufficient phosphorous (P) (4 g kg−1 available dietary P, LP) or sufficient P (8 g kg−1 available dietary P, HP) for 79 days in seawater. LL significantly increased plasma 25(OH)D3 level and bone tartrate resistant acid phosphatase (TRACP) activity, and decreased bone collagen XI α1 chain (col11a1) mRNA transcription. The LP diet significantly increased plasma 1,25(OH)2D3 level and bone alkaline phosphatase activity, but decreased bone TRACP activity and matrix metalloproteinase 13 (mmp13) mRNA transcription, and vertebral mineral content, stiffness and length/dorso‐ventral diameter (l/d) ratio. A significant interaction between light and P was only observed on the l/d ratio, and the LP‐LL group was the only group that developed vertebrae with a compressed morphology (significantly lowest l/d ratio). In practical terms, these results show that Atlantic salmon post‐smolts under continuous light may need P supplemented diets to support normal bone development.

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“…However, cellular and molecular events during pathological bone development in salmon have been little described and only a few studies have been published (e.g. Wargelius et al., 2010a,b; Ytteborg et al., 2010a,b,c). Our group recently finished a comprehensive study on temperature induced vertebral fusions in Atlantic salmon, where we described various stages of pathological development using molecular tools.…”

Section: Introductionmentioning

confidence: 99%

Four stages characterizing vertebral fusions in Atlantic salmon

Ytteborg

Torgersen

Bæverfjord

et al. 2012

Journal of Applied Ichthyology

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Summary Until recently, the molecular development of spinal deformities in fish has received relatively little attention and most studies have been largely descriptive. Due to economical matters of the industry, previous deformity studies were primarily based on radiographic findings, histological staining and field studies to reveal factors inducing deformities. Consequently, few deformities have been explored beyond the level of association with particular causative factors. However, accumulated studies on intensive production regimes and incidence of deformities have been followed by more advanced studies on vertebral development and bone biology. A better understanding of cellular and molecular events during bone development in teleosts should enable us to better characterize the pathology, define particular requirements and enable us to minimize the occurrence of bone disorders. In this review, four hallmarks in the cellular and molecular development of vertebral fusions in Atlantic salmon (Salmosalar) are described.

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Collagen type XI α1 may be involved in the structural plasticity of the vertebral column in Atlantic salmon (Salmo salar L.)

Cited by 10 publications

References 34 publications

Vertebral deformities in farmed Atlantic salmon (Salmo salar L.) - etiology and pathology

Vertebral deformities in farmed Atlantic salmon (Salmo salar L.) - etiology and pathology

Continuous light induces bone resorption and affects vertebral morphology in Atlantic salmon (Salmo salarL.) fed a phosphorous deficient diet

Four stages characterizing vertebral fusions in Atlantic salmon

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