Wound-healing defects in mice lacking fibrinogen

Drew, Angela F.

doi:10.1182/blood.v97.12.3691

Cited by 177 publications

(144 citation statements)

References 25 publications

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“…Although wound repair ultimately proceeds in a relatively normal manner in the absence of fibrin (ogen) or its biologically active fragments derived from proteolysis, the data show that fibrin(ogen) is important for appropriately directed cellular migration in a temporal and spatial manner within the wound space and to establish wound strength and stability. 52 We show in this report that matrix-FBG enhances both wound closure and cell proliferation to significantly shorten the time to wound closure in a dermal fibroblast model of tissue injury. Specific cell-binding domains on matrix-FBG are required to support accelerated wound closure.…”

Section: Org Frommentioning

confidence: 96%

“…During cutaneous wound healing, the FBGdeficient mice show an abnormal pattern of tissue repair, including misguided and hypertrophied epithelium, enhanced collagen deposition, delayed wound closure, and reduced wound tensile strength. 52 The most profound defect in tissue organization found in FBGdeficient mice is the inability of cells to efficiently organize and migrate into the wound space. Although wound repair ultimately proceeds in a relatively normal manner in the absence of fibrin (ogen) or its biologically active fragments derived from proteolysis, the data show that fibrin(ogen) is important for appropriately directed cellular migration in a temporal and spatial manner within the wound space and to establish wound strength and stability.…”

Section: Org Frommentioning

confidence: 99%

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Matrix-fibrinogen enhances wound closure by increasing both cell proliferation and migration

Rybarczyk

Lawrence

Simpson-Haidaris

2003

Blood

103

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Fibrinogen (FBG) assembles into matrix fibrils of fibroblasts, lung and mammary epithelial cells, but not endothelial cells. Furthermore, cryptic ␤ 15-21 residues are exposed in FBG fibrils with no evidence of thrombin or plasmin proteolysis. Herein, the effects of FBG on migration and proliferation of wounded dermal fibroblasts were investigated. FBG preassembled into matrix prior to scrape-wounding induced 3 Hthymidine incorporation 8-fold and shortened the time to wound closure 1.6-fold ؎ 0.1-fold. FBG added immediately after wounding did not enhance either response. Fibroblast growth factor-2/ platelet-derived growth factor (FGF-2/ PDGF) stimulated cell proliferation 2.2-fold for FGF-2 and 3.2-fold for PDGF and wound closure 1.5-fold ؎ 0.1-fold in the absence of matrix-FBG. Surprisingly, exogenous growth factors had negligible effect on wound closure and cell proliferation already enhanced by matrix-FBG. Matrix-FBG-enhanced wound closure required active assembly of an FBGfibronectin matrix, engagement of ␣v␤3, and FBG A␣-RGDS 572-575 integrin recognition sites; A␣-RGDF 95-98 sites were not sufficient for matrix-FBG assembly, enhanced wound closure, or cell proliferation. Although B␤ 1-42 was not necessary for matrix assembly, it was required for matrix-FBG-enhanced cell migration. These data indicate that FBG serves as an important matrix constituent in the absence of fibrin formation to enhance wound repair and implicate B␤ 1 IntroductionImmediately following disturbances in homeostasis, such as infection, tissue injury, or immunologic disorders, the host responds by activation of a conserved set of nonadaptive defense mechanisms that constitute the innate immune system. These nonadaptive defenses include cellular immunity via activated neutrophils and macrophages, activation of complement, and induction of the acute phase response (APR). 1 The APR is characterized by a series of local and systemic reactions that result in activation of various cell types to produce cytokines such as interleukin-1␤ (IL-1␤), IL-6, and tumor necrosis factor-␣ (TNF-␣). The cytokines in turn act on distant tissues and cells, resulting in fever, production of glucocorticoids, proliferation of cells of the immune system, and changes in synthesis of plasma proteins produced by the liver. Fibrinogen (FBG) is a well-characterized acute phase protein that is upregulated as part of the innate immune response to inflammation. 1 During coagulation, adhesive glycoproteins from plasma become incorporated into the fibrin clot by covalent cross-linking providing, in addition to the hemostatic plug, a scaffold for cell migration and proliferation; a reservoir for growth factors, proteases, and protease inhibitors; and a substrate for induction and modulation of cell function. 2 Although FBG is regarded primarily for its hemostatic role in platelet aggregation and fibrin clot formation, we have shown that expression of the FBG genes and production of the intact protein occurs in pulmonary alveolar epithelial cells in response to inflammation...

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Section: Org Frommentioning

confidence: 96%

Section: Org Frommentioning

confidence: 99%

Matrix-fibrinogen enhances wound closure by increasing both cell proliferation and migration

Rybarczyk

Lawrence

Simpson-Haidaris

2003

Blood

103

View full text Add to dashboard Cite

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“…These findings do however appear contradictory to the studies showing that fibrinogen-deficient mice are as susceptible to lung fibrosis as wild-type mice after bleomycin administration 60 -62 and are also able to produce granulation tissue and heal full-thickness skin wounds. 63,64 One explanation for this phenomenon is that fibrin(ogen) itself is not essential for collagen accumulation but that its persistence, or that of another component of the fibrin matrix, promotes and prolongs collagen accumulation. In addition, the type of fibrin matrix deposited at sites of tissue damage are likely to vary considerably in terms of composition, degree of crosslinking, mechanical stress, as well as cellularity, and these properties may influence the behavior of fibroblasts and the resultant amount of collagen formed.…”

Section: Discussionmentioning

confidence: 99%

Fibrin-Induced Skin Fibrosis in Mice Deficient in Tissue Plasminogen Activator

Giorgio-Miller

Bottoms

Laurent

et al. 2005

The American Journal of Pathology

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The deposition of fibrin is an integral part of the tissue repair process, but its persistence is also associated with a number of fibrotic conditions. This study addressed the hypothesis that reduced fibrinolysis and fibrin persistence are associated with an enhanced accumulation of collagen and the development of skin fibrosis. Decreased fibrinolysis was confirmed in fibrin gel cultures that contained human dermal fibroblasts plus the specific plasmin inhibitor ␣ 2 -antiplasmin or dermal fibroblasts isolated from plasminogen activator (PA)-deficient mice. Collagen accumulation was significantly increased in the presence of inhibitor and in tPA-deficient, but not uPAdeficient, fibroblasts compared with controls. These findings were also confirmed using a skin fibrosis model in which multiple injections of fibrin were given subcutaneously to PA-deficient mice. Injection sites from tPA-deficient mice displayed significantly increased collagen levels compared with uPA-deficient mice and wild-type controls. Up-regulation of fibroblast procollagen gene expression and reduced activation of pro-MMP-1 appeared to mediate the increase in collagen by human dermal fibroblasts in the presence of ␣2-antiplasmin. These findings suggest that persistent fibrin is associated with enhanced collagen accumulation that may result in the development of fibrotic skin disorders in which reduced fibrinolysis is a feature.

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“…However, we could not detect any increased mature blood vessel structures upon HIF-1α gene or VEGF protein delivery. Fibrin per se has wound healing properties [47] and it might be possible that fibrin masks the effect of wound revascularization after HIF-1α gene delivery. Nevertheless, the elevated levels of endothelial cells and α-SMA positive cells suggest that the wounds respond with a preliminary angiogenic response to the polymer-DNA condensates without forming increased mature blood vessels structures at the time points of analyzes.…”

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confidence: 99%

The angiogenic response to PLL-g-PEG-mediated HIF-1α plasmid DNA delivery in healthy and diabetic rats

et al. 2013

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Impaired angiogenesis is a major clinical problem and affects wound healing especially in diabetic patients. Improving angiogenesis is a reasonable strategy to increase diabetes-impaired wound healing. Recently, our lab described a system of transient gene expression due to pegylated poly-l-lysine (PLL-g-PEG) polymer-mediated plasmid DNA delivery in vitro. Here we synthesized peptide-modified PLL-g-PEG polymers with two functionalities, characterized them in vitro and utilized them in vivo via a fibrin-based delivery matrix to induce dermal wound angiogenesis in diabetic rats. The two peptides were 1) a TG-peptide to covalently bind these nanocondensates to the fibrin matrix (TG-peptide) for a sustained release and 2) a polyR peptide to improve cellular uptake of these nanocondensates. In order to induce angiogenesis in vivo we condensed modified and non-modified polymers with plasmid DNA encoding a truncated form of the therapeutic candidate gene hypoxia-inducible transcription factor 1 (HIF-1 ). HIF-1 is the primarily oxygen-dependent regulated subunit of the heterodimeric transcription factor HIF-1, which controls angiogenesis among other physiological pathways. The truncated form of HIF-1 lacks the oxygen-dependent degradation domain (ODD) and therefore escapes degradation under normoxic conditions. PLL-g-PEG polymer-mediated HIF-1 -ΔODD plasmid DNA delivery was found to lead to a transiently induced gene expression of angiogenesis-related genes Acta2 and Pecam1 as well as the HIF-1 target gene Vegf in vivo. Furthermore, HIF-1 gene delivery was shown to enhance the number endothelial cells and smooth muscle cells -precursors for mature blood vessels -during wound healing. We show that -depending on the selection of the therapeutic target gene -PLL-g-PEG nanocondensates are a promising alternative to viral DNA delivery approaches, which might pose a risk to health. AbstractImpaired angiogenesis is a major clinical problem and affects wound healing especially in diabetic patients. Improving angiogenesis is a reasonable strategy to increase diabetes-impaired wound healing. Recently, our lab described a system of transient gene expression due to pegylated poly-L-lysine (PLL-g-PEG) polymermediated plasmid DNA delivery in vitro. Here we synthesized peptide-modified PLLg-PEG polymers with two functionalities, characterized them in vitro and utilized them in vivo via a fibrin-based delivery matrix to induce dermal wound angiogenesis in diabetic rats. The two peptides were 1) a TG-peptide to covalently bind these nanocondensates to the fibrin matrix (TG-peptide) for a sustained release and 2) a polyR peptide to improve cellular uptake of these nanocondensates. In order to induce angiogenesis in vivo we condensed modified and non-modified polymers with plasmid DNA encoding a truncated form of the therapeutic candidate gene hypoxiainducible transcription factor 1α (HIF-1α). HIF-1α is the primarily oxygen-dependent regulated subunit of the hetero-dimeric transcription factor HIF-1, which controls angiogenesis...

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Wound-healing defects in mice lacking fibrinogen

Cited by 177 publications

References 25 publications

Matrix-fibrinogen enhances wound closure by increasing both cell proliferation and migration

Matrix-fibrinogen enhances wound closure by increasing both cell proliferation and migration

Fibrin-Induced Skin Fibrosis in Mice Deficient in Tissue Plasminogen Activator

The angiogenic response to PLL-g-PEG-mediated HIF-1α plasmid DNA delivery in healthy and diabetic rats

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