Maturational alterations in gap junction expression and associated collagen synthesis in response to tendon function.
Abstract: Energy-storing tendons including the equine superficial digital flexor tendon (SDFT) contribute to energetic efficiency of locomotion at high-speed gaits, but consequently operate close to their physiological strain limits. Significant evidence of exercise-induced microdamage has been found in the SDFT which appears not to exhibit functional adaptation; the degenerative changes have not been repaired by the tendon fibroblasts (tenocytes), and are proposed to accumulate and predispose the tendon to rupture during normal athletic activity. The anatomically opposing common digital extensor tendon (CDET) functions only to position the digit, experiencing significantly lower levels of strain and is rarely damaged by exercise. A number of studies have indicated that tenocytes in the adult SDFT are less active in collagen synthesis and turnover than those in the immature SDFT or the CDET. Gap junction intercellular communication (GJIC) is known to be necessary for strain-induced collagen synthesis by tenocytes. We postulate therefore that expression of GJ proteins connexin 43 and 32 (Cx43; Cx32), GJIC and associated collagen expression levels are high in the SDFT and CDET of immature horses, when the SDFT in particular grows significantly in cross-sectional area, but reduce significantly during maturation in the energy-storing tendon only. The hypothesis was tested using tissue from the SDFT and CDET of foetuses, foals, and young adult Thoroughbred horses. Cellularity and the total area of both Cx43 and Cx32 plaques/mm(2) of tissue reduced significantly with maturation in each tendon. However, the total Cx43 plaque area per tenocyte significantly increased in the adult CDET. Evidence of recent collagen synthesis in the form of levels of neutral salt-soluble collagen, and collagen type I mRNA was significantly less in the adult compared with the immature SDFT; procollagen type I amino-propeptide (PINP) and procollagen type III amino-propeptide (PIIINP) levels per mm(2) of tissue and PINP expression per tenocyte also decreased with maturation in the SDFT. In the CDET PINP and PIIINP expression per tenocyte increased in the adult, and exceeded those in the adult SDFT. The level of PINP per mm(2) was greater in the adult CDET than in the SDFT despite the higher cellularity of the latter tendon. In the adult SDFT, levels of PIIINP were greater than those of PINP, suggesting relatively greater synthesis of a weaker form of collagen previously associated with microdamage. Tenocytes in monolayers showed differences in Cx43 and Cx32 expression compared with those in tissue, however there were age- and tendon-specific phenotypic differences, with a longer time for 50% recovery of fluorescence after photobleaching in adult SDFT cells compared with those from the CDET and immature SDFT. As cellularity reduces following growth in the SDFT, a failure of the remaining tenocytes to show a compensatory increase in GJ expression and collagen synthesis may explain why cell populations are not able to respond to exercise and to repair microdamage in some adult athletes. Enhancing GJIC in mature energy-storing tendons could provide a strategy to increase the cellular synthetic and reparative capacity.
Publication Date: 2009-05-27 PubMed ID: 19481603DOI: 10.1016/j.matbio.2009.05.002Google Scholar: Lookup
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- Journal Article
- Research Support
- Non-U.S. Gov't
Summary
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The research study aims to understand how changes in gap junction expression and collagen synthesis during the maturation of tendons, particularly the superficial digital flexor tendon (SDFT) in horses, may contribute to tendon injury. The focus is on energy-storing tendons that experience high levels of strain. The research suggests that there are declines in tendon cell activity and collagen turnover as the tendon matures, reducing its ability to repair microdamage, potentially making it more prone to injury.
Research Context and Hypothesis
- The study’s central hypothesis is that expression of gap junction proteins, cell-to-cell communication, and associated collagen expression levels are high in immature tendons but decrease during maturation.
- Two tendons in horses were considered in this study: the superficial digital flexor tendon (SDFT), which is constantly under high strain, and the common digital extensor tendon (CDET), which experiences significantly lower levels of strain.
Methodology
- Tissue from both tendons was collected from foetuses, foals, and young adult Thoroughbred horses, studying the maturation process.
- The researchers examined the levels of cellularity and the total area of gap junction proteins connexin 43 and 32 (Cx43 and Cx32) plaques per mm² of tissue, parameters related to the tendon’s maturity.
- They also gauged collagen synthesis by looking at the levels of neutral salt-soluble collagen, and collagen type I mRNA. Procollagen type I and type III amino propeptides were also considered as indicators of collagen synthesis.
Findings
- The data indicated decreases in cellularity and Cx43 and Cx32 plaques per mm² of tissue in both tendons as they matured.
- However, the total area of Cx43 plaques per cell significantly increased in the adult CDET.
- There was a considerable decline in evidence of new collagen synthesis in the adult compared to the immature SDFT.
- Interestingly, the adult CDFT showed increased procollagen expression despite a decline in cellularity, suggesting a compensatory mechanism that’s not present in adult SDFT.
- Examination of tendon cells in monolayers exhibited age- and tendon-specific differences in Cx43 and Cx32 expression.
- Critical discovery was that tenocytes (cells within tendons) in mature SDFT didn’t show a compensatory increase in gap junction expression and collagen synthesis as cellularity reduced following growth.
Implications and Recommendations
- This reduction of activity could be why cell populations are not able to respond to exercise and to repair microdamage in adult athletes, eventually causing tendon ruptures.
- The researchers suggest that enhancing gap junction intercellular communication (GJIC) in mature energy-storing tendons could be a strategy to increase their cellular synthetic and reparative capacity, possibly decreasing the risk of tendon injuries.
Cite This Article
APA
Young NJ, Becker DL, Fleck RA, Goodship AE, Patterson-Kane JC.
(2009).
Maturational alterations in gap junction expression and associated collagen synthesis in response to tendon function.
Matrix Biol, 28(6), 311-323.
https://doi.org/10.1016/j.matbio.2009.05.002 Publication
Researcher Affiliations
- Department of Veterinary Clinical Sciences, The Royal Veterinary College, Hawkshead Lane, North Mymms, Hertfordshire AL9 7TA, United Kingdom. nyoung@rvc.ac.uk
MeSH Terms
- Animals
- Collagen / genetics
- Collagen / metabolism
- Connexin 43 / metabolism
- Connexins / metabolism
- Gap Junctions / metabolism
- Horses
- Protein Isoforms / genetics
- Protein Isoforms / metabolism
- Tendons / cytology
- Tendons / embryology
- Tendons / growth & development
- Tendons / metabolism
Grant Funding
- BB/D524883/1 / Biotechnology and Biological Sciences Research Council
Citations
This article has been cited 15 times.- Peserico A, Barboni B, Russo V, Bernabò N, El Khatib M, Prencipe G, Cerveró-Varona A, Haidar-Montes AA, Faydaver M, Citeroni MR, Berardinelli P, Mauro A. Mammal comparative tendon biology: advances in regulatory mechanisms through a computational modeling.. Front Vet Sci 2023;10:1175346.
- Rampin A, Skoufos I, Raghunath M, Tzora A, Diakakis N, Prassinos N, Zeugolis DI. Allogeneic Serum and Macromolecular Crowding Maintain Native Equine Tenocyte Function in Culture.. Cells 2022 May 5;11(9).
- Yang Y, Wu Y, Zhou K, Wu D, Yao X, Heng BC, Zhou J, Liu H, Ouyang H. Interplay of Forces and the Immune Response for Functional Tendon Regeneration.. Front Cell Dev Biol 2021;9:657621.
- Yoon JY, Lee SY, Shin S, Yoon KS, Jo CH. Comparative Analysis of Platelet-rich Plasma Effect on Tenocytes from Normal Human Rotator Cuff Tendon and Human Rotator Cuff Tendon with Degenerative Tears.. Clin Shoulder Elb 2018 Mar;21(1):3-14.
- Baker LA, Kirkpatrick B, Rosa GJ, Gianola D, Valente B, Sumner JP, Baltzer W, Hao Z, Binversie EE, Volstad N, Piazza A, Sample SJ, Muir P. Genome-wide association analysis in dogs implicates 99 loci as risk variants for anterior cruciate ligament rupture.. PLoS One 2017;12(4):e0173810.
- Rothrauff BB, Lauro BB, Yang G, Debski RE, Musahl V, Tuan RS. Braided and Stacked Electrospun Nanofibrous Scaffolds for Tendon and Ligament Tissue Engineering.. Tissue Eng Part A 2017 May;23(9-10):378-389.
- Plotkin LI, Stains JP. Connexins and pannexins in the skeleton: gap junctions, hemichannels and more.. Cell Mol Life Sci 2015 Aug;72(15):2853-67.
- Vandenberg LN, Blackiston DJ, Rea AC, Dore TM, Levin M. Left-right patterning in Xenopus conjoined twin embryos requires serotonin signaling and gap junctions.. Int J Dev Biol 2014;58(10-12):799-809.
- Russo V, Mauro A, Martelli A, Di Giacinto O, Di Marcantonio L, Nardinocchi D, Berardinelli P, Barboni B. Cellular and molecular maturation in fetal and adult ovine calcaneal tendons.. J Anat 2015 Feb;226(2):126-42.
- Kuzma-Kuzniarska M, Yapp C, Pearson-Jones TW, Jones AK, Hulley PA. Functional assessment of gap junctions in monolayer and three-dimensional cultures of human tendon cells using fluorescence recovery after photobleaching.. J Biomed Opt 2014 Jan;19(1):15001.
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- Rich T, Henderson LB, Becker DL, Cornell H, Patterson-Kane JC. Indicators of replicative damage in equine tendon fibroblast monolayers.. BMC Vet Res 2013 Sep 11;9:180.
- Hieda K, Hayashi S, Kim JH, Murakami G, Cho BH, Matsubara A. Spatial relationship between expression of cytokeratin-19 and that of connexin-43 in human fetal kidney.. Anat Cell Biol 2013 Mar;46(1):32-8.
- Dakin SG, Dudhia J, Werling NJ, Werling D, Abayasekara DR, Smith RK. Inflamm-aging and arachadonic acid metabolite differences with stage of tendon disease.. PLoS One 2012;7(11):e48978.
- Waugh CM, Blazevich AJ, Fath F, Korff T. Age-related changes in mechanical properties of the Achilles tendon.. J Anat 2012 Feb;220(2):144-55.
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