Project description:Seventy-two female Sprague-Dawley rats underwent a 5 mm critical-sized femoral segmental defect followed by stabilization with a custom-made unilateral external fixator. Following femoral defect generation, absorbable type I bovine collagen sponges were loaded either with 50 ug GDF5wt or 50 ug GDF5N445T, dissolved in dilution buffer (10 mM HCl), and placed into the defect. The control group was treated with collagen sponges soaked with dilution buffer. For analysis of the early healing phase, 48 rats (n = 4 rats/group & time point) were sacrificed at day 3, 5, 7 and 14 post-operation and the callus tissue between the two inner pins was harvested and immediately flash frozen in liquid nitrogen for RNA extraction. Tissue was subsequently pulverized and total RNA was isolated using Trifast reagent and RNeasy Mini Kit. The total RNA from 3 animals per group and time point were pooled prior to hybridization on an Affymetrix GeneChip Rat Gene 1.0 ST Array.

Project description:The purpose of this project is to determine changes in proteins and signaling pathways in injured tendons of C57BL/6j and MRL/MpJ mice. The MRL.MpJ mice have been reported to have a strong repair ability compared to that of C57BL/6j mice. Identifying signaling pathways in MRL/MpJ tendons that are distinct from C57BL/6j tendons will help us understand the molecular mechanisms underlying the better healing ability of MRL/MpJ mice. The samples include normal and injured Achilles tendons 4 weeks after tenotomy surgery obtained from male and female C57BL/6j and MRL/MpJ. The Achilles injury surgery was performed at 12 weeks of age. Normal tendons were obtained age, sex and strain-matched mice without surgery. The collected normal and inured tendons were subjected to proteomics.

Project description:Tendon ruptures heal by forming a mechanically inferior scar. We have shown that male Murphy Roths large (MRL/MpJ) mice exhibit improved tendon healing, suggesting that they can inform biological mechanisms that lead to effective tendon healing. As sex impacts healing, we assessed the effect of sex on tendon healing in MRL/MpJ and normal healer C57BL/6 (B6) mice and compared the associated biological environment with identify genes that may be integral to the improved healing outcome. We hypothesized that (a) male MRL/MpJ mice will heal with improved mechanical properties compared to females; and (b) that regenerative tendon healing will be associated with decreased fibrotic pathways, decreased inflammation, and increased activity of matrix metalloproteinases (MMPs). A midsubstance punch was introduced, and tendons were harvested after (a) 1 or 7 days for profiling of 84 genes; (b) 7 or 14 days for the assessment of MMP-2 and MMP-9 activity; and (c) 6 weeks for mechanical assessment. MRL/MpJ tendons healed with the better restoration of mechanical properties than B6 tendons. Sex did not affect the mechanical properties of healing B6 or MRL/MpJ tendons. Comparison of the gene expression profiles in the context of the mechanical outcome revealed several differences between MRL/MpJ and B6 tendon healing, including, lower inflammation, an earlier higher expression of TGF-β-related genes that diminish by 7 days, and genes associated with enhanced cell migration in MRL/MpJ in comparison to B6 tendons. We expect that the timecourse and expression levels of these genes in scarless MRL/MpJ tendon healing represent the balanced environment that leads to improved tendon healing.

Project description:Tendon injury during limb motion is common. Damaged tendons heal poorly and frequently undergo unpredictable ruptures or impaired motion due to insufficient innate healing capacity. By basic fibroblast growth factor (bFGF) or vascular endothelial growth factor (VEGF) gene therapy via adeno-associated viral type-2 (AAV2) vector to produce supernormal amount of bFGF or VEGF intrinsically in the tendon, we effectively corrected the insufficiency of the tendon healing capacity. This therapeutic approach (1) resulted in substantial amelioration of the low growth factor activity with significant increases in bFGF or VEGF from weeks 4 to 6 in the treated tendons (p < 0.05 or p < 0.01), (2) significantly promoted production of type I collagen and other extracellular molecules (p < 0.01) and accelerated cellular proliferation, and (3) significantly increased tendon strength by 68-91% from week 2 after AAV2-bFGF treatment and by 82-210% from week 3 after AAV2-VEGF compared with that of the controls (p < 0.05 or p < 0.01). Moreover, the transgene expression dissipated after healing was complete. These findings show that the gene transfers provide an optimistic solution to the insufficiencies of the intrinsic healing capacity of the tendon and offers an effective therapeutic possibility for patients with tendon disunion.

Project description:While most mammalian tissue regeneration is limited, the Murphy Roths Large (MRL/MpJ) mouse has been identified to regenerate several tissues, including tendon. Recent studies have indicated that this regenerative response is innate to the tendon tissue and not reliant on a systemic inflammatory response. Therefore, we hypothesized that MRL/MpJ mice may also exhibit a more robust homeostatic regulation of tendon structure in response to mechanical loading. To assess this, MRL/MpJ and C57BL/6J flexor digitorum longus tendon explants were subjected to stress-deprived conditions in vitro for up to 14 days. Explant tendon health (metabolism, biosynthesis, and composition), matrix metalloproteinase (MMP) activity, gene expression, and tendon biomechanics were assessed periodically. We found a more robust response to the loss of mechanical stimulus in the MRL/MpJ tendon explants, exhibiting an increase in collagen production and MMP activity consistent with previous in vivo studies. This greater collagen turnover was preceded by an early expression of small leucine-rich proteoglycans and proteoglycan-degrading MMP-3, promoting efficient regulation and organization of newly synthesized collagen and allowing for more efficient overall turnover in MRL/MpJ tendons. Therefore, mechanisms of MRL/MpJ matrix homeostasis may be fundamentally different from that of B6 tendons and may indicate better recovery from mechanical microdamage in MRL/MpJ tendons. We demonstrate here the utility of the MRL/MpJ model in elucidating mechanisms of efficient matrix turnover and its potential to shed light on new targets for more effective treatments for degenerative matrix changes brought about by injury, disease, or aging.

Project description:To better understand the molecular mechanisms of tendon healing, we investigated the Murphy Roth's Large (MRL) mouse, which is considered a model of mammalian tissue regeneration. We show that compared to C57Bl/6J (C57) mice, injured MRL tendons have reduced fibrotic adhesions and cellular proliferation, with accelerated improvements in biomechanical properties. RNA-seq analysis revealed that differentially expressed genes in the C57 healing tendon at 7 days post injury were functionally linked to fibrosis, immune system signaling and extracellular matrix (ECM) organization, while the differentially expressed genes in the MRL injured tendon were dominated by cell cycle pathways. These gene expression changes were associated with increased α-SMA+ myofibroblast and F4/80+ macrophage activation and abundant BCL-2 expression in the C57 injured tendons. Transcriptional analysis of upstream regulators using Ingenuity Pathway Analysis showed positive enrichment of TGFB1 in both C57 and MRL healing tendons, but with different downstream transcriptional effects. MRL tendons exhibited of cell cycle regulatory genes, with negative enrichment of the cell senescence-related regulators, compared to the positively-enriched inflammatory and fibrotic (ECM organization) pathways in the C57 tendons. Serum cytokine analysis revealed decreased levels of circulating senescence-associated circulatory proteins in response to injury in the MRL mice compared to the C57 mice. These data collectively demonstrate altered TGFB1 regulated inflammatory, fibrosis, and cell cycle pathways in flexor tendon repair in MRL mice, and could give cues to improved tendon healing.

Project description:Tendon rupture can occur at any age and is commonly treated nonoperatively, yet can result in persisting symptoms. Thus, a need exists to improve nonoperative treatments of injured tendons. Photobiomodulation (PBM) therapy has shown promise in the clinic and is hypothesized to stimulate mitochondrial-related metabolism and improve healing. However, the effect of PBM therapy on mitochondrial function during tendon maturation and healing are unknown, and its effect on tendon structure and function remain unclear. In this study, near-infrared light (980:810 nm blend, 2.5 J/cm2 ) was applied at low (30 mW/cm2 ) or high (300 mW/cm2 ) irradiance to unilateral Achilles tendons of CD-1 mice during postnatal growth (maturation) as well as adult mice with bilateral Achilles tenotomy (healing). The chronic effect of PBM therapy on tendon structure and function was determined using histology and mechanics, and the acute effect of PBM therapy on mitochondrial-related gene expression was assessed. During maturation and healing, collagen alignment, cell number, and nuclear shape were unaffected by chronic PBM therapy. We found a sex-dependent effect of PBM therapy during healing on mechanical outcomes (eg, increased stiffness and Young's modulus for PBM-treated females, and increased strain at ultimate stress for PBM-treated males). Mitochondria-related gene expression was marginally influenced by PBM therapy for both maturation and healing studies. This study was the first to implement PBM therapy during both growth and healing of the murine tendon. PBM therapy resulted in marginal and sex-dependent effects on the murine tendon. Clinical significance: PBM may be beneficial for tendon healing because functional remodeling improves without adverse effects.

Project description:PurposeTendon tears are common injuries that heal with scar formation. Interestingly, MRL/MpJ mice heal without scar in several tissues, including tendon. Most hypotheses regarding scarless healing implicate the systemic environment. However, the tissue-specificity of this regenerative response and our previous findings showing regeneration of sub-rupture tendon injuries, which lack an overt systemic response, motivate a tissue-driven hypothesis. Our objective is to investigate the potential of the local tendon environment in driving scarless healing (1) by comparing the systemic response and the healing capacity associated with ear and tendon injuries in MRL/MpJ mice, and (2) by comparing intrinsic healing properties between MRL/MpJ and normal healer C57Bl/6 tendons.MethodsWe examined the systemic inflammatory and local structural environments of ear and tendon punch injuries in MRL/MpJ and C57Bl/6 mice. Systemic differences were analyzed to assess effects of different injuries on the inflammatory response. Correlations were assessed between MRL/MpJ ear and tendon injuries to compare the extent of healing between regenerative tissues.ResultsAnalysis showed similarities between the systemic environment in MRL/MpJ post ear or tendon injuries. However, comparable inflammatory responses did not translate into analogous healing between tissues, suggesting that the systemic environment is not the driver of regeneration. Supporting the regenerative role of the local environment, healing MRL/MpJ tendons exhibited improved matrix and cell alignment and a distinct composition of growth factors and Hyaluronan from C57Bl/6.ConclusionThese findings support the tissue-driven hypothesis for MRL/MpJ tendon regeneration and motivate further investigation regarding specific roles of extracellular factors in scarless healing.

Project description:Prolactin (PRL) plays an important role in modulating the immune response. In B cells, PRL enhances antibody production, including antibodies with self-specificity. In this study, our aims were to determine the level of PRL receptor expression during bone-marrow B-cell development and to assess whether the presence of high PRL serum concentrations influences absolute numbers of developing populations and disease outcome in lupus-prone murine models. We observed that the PRL-receptor is expressed in early bone-marrow B-cell; the expression in lupus-prone mice, which had the highest level of expression in pro-B cells and immature cells, differed from that in wild-type mice. These expression levels did not significantly change in response to hyperprolactinemia; however, populations of pro-B and immature cells from lupus-prone strains showed a decrease in the absolute numbers of cells with high PRL-receptor expression in response to PRL. Because immature self-reactive B cells are constantly being eliminated, we assessed the expression of survival factor BIRC5, which is more highly expressed in both pro-B and immature B-cells in response to PRL and correlates with the onset of disease. These results identify an important role of PRL in the early stages of the B-cell maturation process: PRL may promote the survival of self-reactive clones.

Project description:PurposeTo assess the biomechanical performance of different stitching methods using a suturing device by comparing the elongation, stiffness, failure load, and time to stitch completion in cadaveric semitendinosus tendons (STs) and quadriceps tendons (QTs).MethodsA total of 24 STs and 16 QTs were harvested from cadaveric knee specimens (N = 40). Samples were randomly divided into 2 groups: whipstitch (WS) and whip-lock (WL) stitch. Both tendon ends were clamped to a graft preparation stand, and a 2-part needle was used to place 5 stitches, each 0.5 cm apart. Stitching time was recorded. Samples were preconditioned and then underwent cyclic loading from 50 to 200 N at 1 Hz for 500 cycles, followed by load-to-failure testing at 20 mm/min. Stiffness (in newtons per millimeter), ultimate failure load (in newtons), peak-to-peak displacement (in millimeters), elongation (in millimeters), and failure displacement (in millimeters) were recorded.ResultsCompletion of the WS was significantly faster than the WL stitch in the ST (P < .001) and QT (P = .004). For the ST, the WL stitch exhibited higher ultimate failure loads and construct stiffness than the WS. Regarding the QT, the WL stitch showed higher stiffness and displacement than the WS; however, the ultimate failure load was higher for the WS in the QT. The ultimate failure load in the QT was higher than that in the ST for both stitches. In the ST, only 25% of WSs and 100% of WL stitches failed due to suture breakage. In the QT, suture breakage led to the failure of 100% of both the WL stitches and WSs.ConclusionsIn the ST, the WL stitch resulted in improved biomechanical performance through higher ultimate load and fewer failures from tissue damage compared with the WS. In the QT, both the WS and the WL stitch showed similar biomechanical performance with ultimate failure loads above established clinical failure thresholds.Clinical relevanceVarious types of ligament and tendon injuries require suturing to enable repair or reconstruction. The success of ligament or tendon surgery often relies on soft-tissue quality. It is important to investigate the biomechanical properties of stitching techniques that help preserve soft-tissue quality as a step to determining their clinical suitability.