Hox D3 expression in normal and impaired wound healing

BACKGROUND: We have previously shown that Hox D3 and Hox B3 can promote angiogenesis. As angiogenesis is essential for wound healing, we examined expression of these genes in the vasculature following wounding in normal and genetically diabetic adult mice with impaired healing. METHODS: In situ hybridization was performed on tissues taken 0, 1, 4, 7, and 14 days following administration of linear wounds in wild-type and genetically diabetic mice. Expression of Hox D3 and Hox B3, angiogenesis, and synthesis of type I collagen were assessed in the wound. RESULTS: Hox B3 was expressed in endothelial cells (ECs) of both medium and small vessels in unwounded tissue, whereas little Hox D3 was detected in resting ECs. Hox D3 expression was significantly upregulated by 1 day after wounding in ECs of vessels immediately adjacent to the wound site, and expression was maintained for at least 7 days. In the diabetic mice, expression of Hox B3 was similar to that of wild-type mice. In contrast, expression of Hox D3 in ECs was significantly lower and delayed during wound repair in diabetic mice. In cultured microvascular ECs, Hox D3 selectively induced high levels of collagen I mRNA expression. Hox D3-deficient wounds of diabetic animals also displayed a reduction in expression and deposition of type I collagen. CONCLUSIONS: These results suggest that reduced angiogenesis and type I collagen in diabetic mice with impaired wound healing may be related to deficient Hox D3 expression, and restoring Hox D3 expression may enhance angiogenesis and wound repair.     

Diabetes enhances mRNA levels of proapoptotic genes and caspase activity, which contribute to impaired healing

We previously reported that after a bacteria-induced wound in the scalp, type 2 diabetic (db/db) mice had higher levels of apoptosis of fibroblasts and bone-lining cells that are critical for healing compared with normoglycemic controls. To investigate mechanisms by which this might occur, RNA profiling and caspase activity was measured after inoculation of Porphyromonas gingivalis. Diabetes caused a more than twofold induction of 71 genes that directly or indirectly regulate apoptosis and significantly enhanced caspase-8, -9, and -3 activity. The functional significance of diabetes-induced apoptosis was studied by treating diabetic mice with a pancaspase inhibitor, z-VAD-fmk (N-benzyloxycarbonyl-Val-Ala-Asp-fluoromethylketone). Inhibiting apoptosis significantly improved several parameters of healing, including fibroblast density, enhanced mRNA levels of collagen I and III, and increased matrix formation. Improvements were also noted in bone, with an increase in the number of bone-lining cells and new bone formation. Thus, diabetes-enhanced apoptosis represents an important mechanism through which healing is impaired, and this can be explained, in part, by diabetes-increased expression of proapoptotic genes and caspase activity.     

Human bone marrow-derived cells: An attractive source to populate dermal substitutes

We have previously shown the importance of dermal fibroblasts within skin substitutes for promoting the emergence of a functional neodermis after grafting in humans. However, the use of fibroblasts from sources other than the dermis needs to be evaluated for patients with extensive skin loss. Here we examined the capacity of human bone marrow-derived cells (BMDCs), selected for their ability to adhere to plastic culture dishes, to behave like human dermal fibroblasts when incorporated within a 3D in vitro reconstructed tissue that promotes dermal fibroblast differentiation. Like dermal fibroblasts, BMDCs contracted a collagen matrix and were growth regulated by the matrix environment. They had the same shape and their nuclei had the same form factor as dermal fibroblasts. In addition, both cell types expressed desmin and vimentin but not α-smooth muscle actin. BMDCs deposited collagen types I and III, and fibrillin-1 with similar efficiency to dermal fibroblasts. In addition, BMDCs have the potential to regulate this deposition, as they produced metalloproteinases (MMP1, MMP2, and MMP9) and metalloproteinase inhibitors (TIMP1) very similarly to dermal fibroblasts. BMDCs can thus be induced to express functions resembling those of dermal fibroblasts, including those involved in the wound healing process.     

The role of iNOS in wound healing

BACKGROUND: We have previously shown that the blockade of nitric oxide (NO) synthesis impairs wound healing, in particular collagen synthesis. Conversely, impaired wound healing is accompanied by decreased wound NO synthesis. Fibroblast collagen synthesis, proliferation, and fibroblast-mediated matrix contraction are critical to wound healing. We examined the wound healing-related phenotypic changes that are induced by the loss of inducible nitric oxide synthase (iNOS) gene function in fibroblasts. METHODS: Dermal fibroblasts were obtained from 8- to 12-week-old iNOS--knock out (KO; C57BL/Ai-[KO] Nos2 N5) and wild type mice by an explant technique and used after 1 to 3 passages. Proliferation ([(3)H]-thymidine incorporation) and collagen synthesis ([(3)H]-proline incorporation into collagenase-sensitive protein) were studied after stimulation with 10% fetal bovine serum. Matrix remodeling was assessed by the measurement of the contraction of fibroblast-populated collagen lattices. RESULTS: iNOS-KO fibroblasts proliferated more slowly, synthesized less collagen, and contracted fibroblast-populated collagen lattices more slowly than wild-type fibroblast. Collagen synthesis was restored to normal in KO fibroblasts in response to NO donors (s-nitroso-N-acetylpenicillamine). CONCLUSIONS: iNOS deficiency causes significant impairment in wound healing-related properties of fibroblasts, which suggests that NO plays an important role in wound healing.     

Exogenous calreticulin improves diabetic wound healing

A serious consequence of diabetes mellitus is impaired wound healing, which largely resists treatment. We previously reported that topical application of calreticulin (CRT), an endoplasmic reticulum chaperone protein, markedly enhanced the rate and quality of wound healing in an experimental porcine model of cutaneous repair. Consistent with these in vivo effects, in vitro CRT induced the migration and proliferation of normal human cells critical to the wound healing process. These functions are particularly deficient in poor healing diabetic wounds. Using a genetically engineered diabetic mouse (db/db) in a full‐thickness excisional wound healing model, we now show that topical application of CRT induces a statistically significant decrease in the time to complete wound closure compared with untreated wounds by 5.6 days (17.6 vs. 23.2). Quantitative analysis of the wounds shows that CRT increases the rate of reepithelialization at days 7 and 10 and increases the amount of granulation tissue at day 7 persisting to day 14. Furthermore, CRT treatment induces the regrowth of pigmented hair follicles observed on day 28. In vitro, fibroblasts isolated from diabetic compared with wild‐type mouse skin and human fibroblasts cultured under hyperglycemic compared with normal glucose conditions proliferate and strongly migrate in response to CRT compared with untreated controls. The in vitro effects of CRT on these functions are consistent with CRT's potent effects on wound healing in the diabetic mouse. These studies implicate CRT as a potential powerful topical therapeutic agent for the treatment of diabetic and other chronic wounds.     

Full‐thickness splinted skin wound healing models in db/db and heterozygous mice: Implications for wound healing impairment

The excisional dorsal full‐thickness skin wound model with or without splinting is widely utilized in wound healing studies using diabetic or normal mice. However, the effects of splinting on dermal wound healing have not been fully characterized, and there are limited data on the direct comparison of wound parameters in the splinted model between diabetic and normal mice. We compared full‐thickness excisional dermal wound healing in db/db and heterozygous mice by investigating the effects of splinting, semi‐occlusive dressing, and poly(ethylene glycol) treatment. Two 8‐mm full‐thickness wounds were made with or without splinting in db/db and heterozygous mice. Body weights, splint maintenance, wound contraction, wound closure, and histopathological parameters including reepithelialization, wound bed collagen deposition, and inflammation were compared between groups. Our results show that silicone splint application effectively reduced wound contraction in heterozygous and db/db mice. Splinted wounds, as opposed to nonsplinted wounds, exhibited no significant differences in wound closure between heterozygous and db/db mice. Finally, polyethylene glycol and the noncontact dressing had no significant effect on wound healing in heterozygous or db/db mice. We believe these findings will help investigators in selection of the appropriate wound model and data interpretation with fully defined parameters.     

Features of wound healing shown by fibroblasts obtained from the superficial and deep dermis

Dermal fibroblasts (DF) obtained from the superficial dermal layer and those from the deep dermal layer have different cellular functions. These differences are often associated with excessive scarring; they also influence early wound healing. We therefore investigated the differences between superficial and deep dermal fibroblasts with special emphasis on their contractile properties, and ability to produce connective tissue. We investigated their proliferation kinetics, ability to contract collagen lattices, and chronological mRNA expression of eight genes associated with wound healing. To estimate the changes in the differences between them during the early phase of wound healing, we investigated mRNA expression in bFGF supplemented medium because bFGF is a representative cytokine that is familiar to clinicians. Superficial DF proliferate faster than deep DF in culture, whereas deep DF are better at contracting collagen lattices than superficial ones. In realtime analysis of polymerase chain reaction, the expression of type I and III collagen, fibronectin, TGF β1 and β3, and connective tissue growth factor were higher in deep DF than in superficial DF, while the expression of TGF β2 was higher in superficial DF. After bFGF supplementation, the relative dominance of mRNA expression between superficial and deep DF remained constant except for the expression of collagenase. According to our analysis, deep DF are superior to superficial DF at promoting wound healing (particularly contraction and production of connective tissue). The intradermal distribution of DF is appropriate for efficient wound healing.     

Comparison of human umbilical cord blood‐derived mesenchymal stem cells with healthy fibroblasts on wound‐healing activity of diabetic fibroblasts

Various types of skin substitutes composed of fibroblasts and/or keratinocytes have been used for the treatment of diabetic ulcers. However, the effects have generally not been very dramatic. Recently, human umbilical cord blood‐derived mesenchymal stromal cells (hUCB‐MSCs) have been commercialised for cartilage repair as a first cell therapy product using allogeneic stem cells. In a previous pilot study, we reported that hUCB‐MSCs have a superior wound‐healing capability compared with fibroblasts. The present study was designed to compare the treatment effect of hUCB‐MSCs with that of fibroblasts on the diabetic wound healing in vitro. Diabetic fibroblasts were cocultured with healthy fibroblasts or hUCB‐MSCs. Five groups were evaluated: group I, diabetic fibroblasts without coculture; groups II and III, diabetic fibroblasts cocultured with healthy fibroblasts or hUCB‐MSCs; and groups IV and V, no cell cocultured with healthy fibroblasts or hUCB‐MSCs. After a 3‐day incubation, cell proliferation, collagen synthesis levels and glycosaminoglycan levels, which are the major contributing factors in wound healing, were measured. As a result, a hUCB‐MSC‐treated group showed higher cell proliferation, collagen synthesis and glycosaminoglycan level than a fibroblast‐treated group. In particular, there were significant statistical differences in collagen synthesis and glycosaminoglycan levels (P = 0·029 and P = 0·019, respectively). In conclusion, these results demonstrate that hUCB‐MSCs may have a superior effect to fibroblasts in stimulating diabetic wound healing.     

Raxofelast, a hydrophilic vitamin E-like antioxidant, stimulates wound healing in genetically diabetic mice

BACKGROUND. Impaired wound healing is a well-documented phenomenon in experimental and clinical diabetes. Emerging evidence favors the involvement of free radicals in the pathogenesis of diabetes-related healing deficit. This study assessed the effect of systemic administration of raxofelast, a protective membrane antioxidant agent, on wound healing by using healing-impaired (db/db) mice. METHODS. The wound healing effect of raxofelast was investigated by using an incisional skin-wound model produced on the back of female diabetic C57BL/KsJ db+/db+ mice and their healthy littermates (db+/+m). Animals were then randomized to the following treatment: raxofelast (15 mg/kg/d intraperitoneally) or its vehicle (dimethyl sulfoxide/sodium chloride 0.9%, 1:1, vol/vol). The animals were killed on different days, and the wounded skin tissues were used for histologic evaluation and for analysis of malondialdehyde (MDA) level and myeloperoxidase (MPO) activity, wound breaking strength, and collagen content. RESULTS. Diabetic mice showed delayed wound healing together with low collagen content, breaking strength, and increased MDA levels and MPO activity when compared with their healthy littermates. The administration of raxofelast did not modify the process of wound repair in healthy (db/+) mice, but significantly improved impaired wound healing in diabetic mice through the stimulation of angiogenesis, reepithelialization, synthesis, and maturation of extracellular matrix. Furthermore, raxofelast treatment significantly reduced MDA levels, MPO activity, and increased the breaking strength and collagen content of the wound. CONCLUSIONS. The current study provides evidence that raxofelast restores wound healing to nearly normal levels in experimental diabetes-impaired wounds and suggests that an increased lipid peroxidation in diabetic mice may have a role in determining a defect of wound repair.     

EGF increases short-term type I collagen accumulation during wound healing in diabetic rats

Continuous topical application of epidermal growth factor (EGF) to granulation tissue increases the rate of collagen accumulation. It is believed that the clinical use of growth factors, such as EGF, may become common in the treatment of impaired wound healing in the near future. Impairments in the production and degradation of wound collagens have been demonstrated in diabetes mellitus. We studied the effects of a single, local application of EGF on collagen content, collagenase activity, and the ratio of type III and type I collagens within granulation tissue using polytetrafluoroethylene (PTFE) wound cylinders in 48 streptozotocin-induced diabetic rats in order to determine potential benefits of EGF to wound healing in diabetics. Wound collagen content in EGF-treated diabetic animals was significantly higher than in diabetic controls during the first 10 days of wound healing (236% on day 5, P less than .001; 140% on day 10, P less than .01), but decreased to significantly lower levels by day 15 of healing (71% of diabetic controls, P less than .01; 47% of nondiabetic controls, P less than .01). An 18% increase in diabetic wound protease activity was observed following application of EGF (P less than .001). The ratio of type III collagen to total wound collagen within the granulation tissue was significantly reduced (P less than .001) following EGF application. We demonstrate that a single, topical application of EGF promotes early synthesis of type I collagen, thereby deranging the usual type III/total collagen ratio, and is associated with increased wound protease activity.     

血小板源伤口愈合因子促糖尿病大鼠伤口组织胶原合成机制的研究

目的 探讨外源性血小板源伤口愈合因子（PDWHF）促糖尿病大鼠伤口合成胶原与内源性转化生长因子-β（TGF-β1）基因表达的关系。方法 33只雄性SD大鼠,分为正常组（A组n＝9）、糖尿组（n＝24）。四氧嘧啶诱导糖尿病组大鼠血糖值大于1．8g/L1、2天后,在每组大鼠背部造成两块直径为1．8 cm的全层皮肤伤口。术后当天及以后连续6天,每天一次,糖尿病组大鼠一侧伤口局部应用PDWHF（100μg/伤口）作为治疗组（B组）,另一侧伤口作为对照组（C组）。斑点杂交法测定伤后不同天数伤口组织中TGF－β1、Ⅰ型（α1）前胶原mRNA水平量。结果 伤后5、7天,B组伤口组织TGF－β1mRNA水平量是C组的4倍和5．6倍,经统计学处理有非常显著性差异（P＜0．01）,但低于A组（P＜0．05）;伤后10天,三组间TGF-β1mRNA水平量无明显差异。伤后5、7天及10天,B组I型（α1）前胶原mRNA水平量明显高于C组,分别为2．1、1．8和2．3倍有非常显著性差异（P＜0．01）;但伤后5、7天仍明显低于A组（P＜0．05）,伤后10天,两组间差异消失。结论 PDWHF促进糖尿病大鼠伤口内源性TGF－β1基因表达是其增强I型（α1）前胶原合成的重要原因。     

Transient exposure to tumor necrosis factor-alpha inhibits collagen accumulation by cultured hypertrophic scar fibroblasts.

BACKGROUND: Hypertrophic scars (HS) are frequent consequences of deep dermal injury, such as deep partial-thickness burns and abrasions, and are characterized by overproduction of collagen. In vitro studies have shown that cultured HS fibroblasts produce elevated levels of collagen and insulin-like growth factor-binding protein 3 (IGFBP-3). Additionally, histological studies have indicated HS contain fewer tumor necrosis factor alpha (TNF-alpha)-positive infiltrating cells and express lower levels of TNF-alpha mRNA, suggesting TNF-alpha, which can inhibit collagen expression in some systems, may function to deactivate the wound healing process in scars. HS also exhibit increased levels of transforming growth factor beta (TGF-beta), a factor that stimulates collagen and extracellular matrix deposition by fibroblasts and also stimulates IGFBP-3 expression. In some systems, IGFBP-3 mediates the effects of TGF-beta. The present study sought to determine the effects of continuous and transient TNF-alpha exposure on collagen and IGFBP-3 expression by cultured HS fibroblasts and to investigate the role of IGFBP-3 in collagen accretion by HS fibroblasts. MATERIALS AND METHODS: Superficial and deep dermal HS fibroblasts from four patients were cultured. Fibroblasts were cultured in serum-free medium and exposed to 0-2 ng/ml TNF-alpha for 0, 1, 4, or 72 h. After 72 h of culture, medium samples were processed for Western blot analysis of type I collagen accumulation or for ligand blot analysis of IGFBP-3 accumulation. The effects of an anti-IGFBP-3 neutralizing antibody on collagen accumulation were also assessed. RESULTS: Treatment of superficial and deep HS fibroblasts with TNF-alpha resulted in dose-dependent decreases in accumulation of both type I collagen and IGFBP-3 in the culture medium (P < 0.01). However, using the anti-IGFBP-3 neutralizing antibody, a causal relationship between decreased IGFBP-3 and decreased collagen accumulation could not be demonstrated. Transient exposure of cultured HS fibroblasts to TNF-alpha for as little as 1 h was as effective as continuous exposure to TNF-alpha for 72 h in inhibiting collagen accumulation. CONCLUSIONS: These results support the hypothesis that TNF-alpha functions as a wound healing deactivation signal that is deficient in HS. Although TNF-alpha inhibited accretion of both collagen and IGFBP-3, the role of IGFBP-3 in HS remains unresolved. This study suggests that transient TNF-alpha exposure may be used to inhibit collagen overaccumulation in HS and that the timing of TNF-alpha exposure following dermal injury may not be critical for this inhibition.     

汉防己甲素对成纤维细胞Ⅰ型胶原蛋白合成的影响

目的　探讨汉防己甲素预防和治疗增生性瘢痕的可行性。方法　对增生性瘢痕中的成纤维细胞进行培养 ,然后加入不同浓度的汉防己甲素 ,培养后继续观察成纤维细胞合成胶原蛋白的能力的变化。结果　汉防己甲素可以抑制成纤维细胞合成胶原蛋白。结论　汉防己甲素对成纤维细胞胶原蛋白的合成具有抑制作用 ,因此它可能对增生性瘢痕具有预防和治疗作用     

Hyperbaric oxygen therapy activates hypoxia‐inducible factor 1 (HIF‐1), which contributes to improved wound healing in diabetic mice

Hyperbaric oxygen (HBO) therapy has been used as an adjunctive therapy for diabetic foot ulcers, although its mechanism of action is not completely understood. Recently, it has been shown that HBO mobilizes the endothelial progenitor cells (EPCs) from bone marrow that eventually will aggregate in the wound. However, the gathering of the EPCs in diabetic wounds is impaired because of the decreased levels of local stromal‐derived factor‐1α (SDF‐1α). Therefore, we investigated the influence of HBO on hypoxia‐inducible factor 1 (HIF‐1), which is a central regulator of SDF‐1α and is down‐regulated in diabetic wounds. The effects of HBO on HIF‐1α function were studied in human dermal fibroblasts, SKRC7 cells, and HIF‐1α knock‐out and wild‐type mouse embryonic fibroblasts using appropriate techniques (Western blot, quantitative polymerase chain reaction, and luciferase hypoxia‐responsive element reporter assay). Cellular proliferation was assessed using H³‐thymidine incorporation assay. The effect of HIF in combination with HBOT was tested by inoculating stable HIF‐1α‐expressing adenovirus (Adv‐HIF) into experimental wounds in db/db mice exposed to HBO. HBO activates HIF‐1α at several levels by increasing both HIF‐1α stability (by a non‐canonical mechanism) and activity (as shown both by induction of relevant target genes and by a specific reporter assay). HIF‐1α induction has important biological relevance because the induction of fibroblast proliferation in HBO disappears when HIF‐1α is knocked down. Moreover, the local transfer of stable HIF‐1α‐expressing adenovirus (Adv‐HIF) into experimental wounds in diabetic (db/db mice) animals has an additive effect on HBO‐mediated improvements in wound healing. In conclusion, HBO stabilizes and activates HIF‐1, which contributes to increased cellular proliferation. In diabetic animals, the local transfer of active HIF further improves the effects of HBO on wound healing.     

Stromelysin-1-deficient fibroblasts display impaired contraction in vitro.

Targeted disruption of the stromelysin-1 gene in mice causes a delay in excisional wound healing due to a failure in wound contraction. Therefore, we postulated that stromelysin-1 activity is responsible for initiating contraction. To test this hypothesis, we compared the contractile capacity of fibroblasts from stromelysin-1 knockout mice (strom-1 KO) with that of normal fibroblasts using a collagen gel contraction model. Fibroblast cultures were established from explants of skin and lung parenchyma from strom-1 KO and wild-type mice, then transferred to the surface of collagen gels. The extent of contraction was determined by measuring greatest gel diameter. Results demonstrated that (1) all fibroblasts contracted collagen gels in a uniform concentric fashion, (2) skin fibroblasts from both sets of mice exhibited greater gel contraction than did lung fibroblasts, and (3) strom-1 KO fibroblasts demonstrated significantly less contraction (21-23%) than wild-type fibroblasts. These data support the hypothesis that absence of stromelysin-1 results in defective fibroblast contraction that may contribute to delayed wound healing.     

Altered ECM deposition by diabetic foot ulcer‐derived fibroblasts implicates fibronectin in chronic wound repair

Current chronic wound treatments often fail to promote healing of diabetic foot ulcers (DFU), leading to amputation and increased patient morbidity. A critical mediator of proper wound healing is the production, assembly, and remodeling of the extracellular matrix (ECM) by fibroblasts. However, little is known about how these processes are altered in fibroblasts within the DFU microenvironment. Thus, we investigated the capacity of multiple, primary DFU‐derived fibroblast strains to express, produce, and assemble ECM proteins compared to diabetic patient‐derived fibroblasts and healthy donor‐derived fibroblasts. Gene expression microarray analysis showed differential expression of ECM and ECM‐regulatory genes by DFU‐derived fibroblasts which translated to functional differences in a 3D in vitro ECM tissue model. DFU‐derived fibroblasts produced thin, fibronectin‐rich matrices, and responded abnormally when challenged with transforming growth factor‐beta, a key regulator of matrix production during healing. These results provide novel evidence that DFU‐derived fibroblasts contribute to the defective matrices of DFUs and chronic wound pathogenesis.