The plasmid encoding HSP47 enhances collagen expression and promotes skin wound healing in an alloxan-induced diabetic model

The objective of this work was initially to investigate the effects on skin wound healing process by local injection of HSP47 recombinant plasmid in an alloxan-induced diabetic rat model and assess the possibility and utility of gene therapy based on HSP47 plasmid to improve the diabetic skin wound healing. Rats were injected intraperitoneally with alloxan (120 mg/kg) to induce diabetes. The fragment containing the rat 47 kDa heat shock protein (HSP47) gene lacking its own promoter was cloned into plasmids containing a promoter and green fluorescent protein (GFP). The resulting gene constructs were first tested in vitro using 3T3 fibroblast cell line and subsequently in vivo after inducing wounds with alloxan in diabetic rats. Immunohistochemistry, quantitative fluorescent RT-PCR, and Western blotting 3-5 days after plasmid injection were performed to measure the expression changes of HSP47 and collagen I. The results demonstrate an increase of HSP47 levels in vitro in 3T3 fibroblast cells and in vivo in diabetic rat after treatment with plasmids expressing HSP47. The level of collagen I around the wound during the repair process was higher in the treated group than that in the control group, indicating that the constructs may have use in human gene therapy in cases of impaired skin wound healing in diabetes.     

Serum exosomes accelerate diabetic wound healing by promoting angiogenesis and ECM formation

Nonhealing wounds in diabetes remain a global clinical and research challenge. Exosomes are primary mediators of cell paracrine action, which are shown to promote tissue repair and regeneration. In this study, we investigated the effects of serum derived exosomes (Serum-Exos) on diabetic wound healing and its possible mechanisms. Serum-Exos were isolated from blood serum of normal healthy mice and identified by transmission electron microscopy and western blot. The effects of Serum-Exos on diabetic wound healing, fibroblast growth and migration, angiogenesis and extracellular matrix (ECM) formation were investigated. Our results showed that the isolated Serum-Exos exhibited a sphere-shaped morphology with a mean diameter at 150 nm, and expressed classical markers of exosomes including HSP70, TSG101, and CD63. Treatment with Serum-Exos elevated the percentage of wound closure and shortened the time of healing in diabetic mice. Mechanistically, Serum-Exos promoted granulation tissue formation and increased the expression of CD31, fibronectin and collagen-ɑ in diabetic mice. Serum-Exos also promoted the migration of NIH/3T3 cells, which was associated with increased expression levels of PCNA, Ki67, collagen-α and fibronectin. In addition, Serum-Exos enhanced tube formation in human umbilical vein endothelial cells and induced the expression of CD31 at both protein and messenger RNA levels. Collectively, our results suggest that Serum-Exos may facilitate the wound healing in diabetic mice by promoting angiogenesis and ECM formation, and show the potential application in treating diabetic wounds.     

Carnosine enhances diabetic wound healing in the db/db mouse model of type 2 diabetes

Diabetes mellitus (DM) is a progressive disorder with severe late complications. Normal wound healing involves a series of complex and well-orchestrated molecular events dictated by multiple factors. In diabetes, wound healing is grossly impaired due to defective, and dysregulated cellular and molecular events at all phases of wound healing resulting in chronic wounds that fail to heal. Carnosine, a dipeptide of alanine and histidine and an endogenous antioxidant is documented to accelerate healing of wounds and ulcers. However, not much is known about its role in wound healing in diabetes. Therefore, we studied the effect of carnosine in wound healing in db/db mice, a mice model of Type 2 DM. Six millimeter circular wounds were made in db/db mice and analyzed for wound healing every other day. Carnosine (100?mg/kg) was injected (I.P.) every day and also applied locally. Treatment with carnosine enhanced wound healing significantly, and wound tissue analysis showed increased expression of growth factors and cytokines genes involved in wound healing. In vitro studies with human dermal fibroblasts and microvascular-endothelial cells showed that carnosine increases cell viability in presence of high glucose. These effects, in addition to its known role as an antioxidant and a precursor for histamine synthesis, provide evidence for a possible therapeutic use of carnosine in diabetic wound healing.     

The possible mechanism of action of ciclopirox olamine in the yeast Saccharomyces cerevisiae

Ciclopirox olamine is a synthetic antifungal agent with a high affinity for trivalent metal cations. Ciclopirox olamine can be used to synchronize mammalian cells, but its mechanism of action is not understood well. In this study, we investigated the effect of ciclopirox olamine in yeast cells and used a genetic approach to identify potential ciclopirox olamine targets in yeast. Wild type strains of the yeast Saccharomyces cerevisiae were weakly sensitive to ciclopirox olamine, but high concentrations of the drug arrested their growth at many different stages. MMS-mutagenized yeast clones were screened for increased sensitivity to ciclopirox olamine. Fourteen mutants, cos101-cos114, were identified and characterized. The targets of ciclopirox olamine in S. cerevisiae appear to include multiple proteins that participate in various components of cellular metabolism, including DNA replication, DNA repair, and cellular transport. Three genes were cloned: a Fe/Cu reductase (FRE1/COS107), an oxidative stress response gene (YAP1/COS110), and a gene involved in signal transduction (YBR203W/COS111). These results suggest that CPO inhibits multiple aspects of cell growth and metabolism, possibly via multiple targets.     

糖尿病伤口愈合的分子机制

伤口愈合不良是糖尿病的一个并发症,严重时可能导致截肢,已成为糖尿病患者住院率最高的疾病,但是其确切的分子机制尚不清楚。目前研究发现糖尿病发生时有多种分子和细胞功能受损,如生长因子、一氧化氮、活性氧分子、基质金属蛋白酶、m icroRNA、内皮祖细胞等,最终导致糖尿病伤口愈合不良。本文将就其近年研究的相关分子机制予以详述。     

Initiation and pattern of angiogenesis in wound healing in the rat.

The object of this study was to examine the initiation and pattern of capillary growth associated with wound healing. Collagen sponges were implanted subcutaneously in the hind limbs of adult male rats to stimulate the formation of granulation tissue. Blood vessels of the hind limbs of euthanized rats were perfused with Mercox (an acrylic monomer) via the abdominal aorta at selected periods of time following sponge implantation. When the perfusate was completely cured, the sponge and parajacent tissues were excised and subsequently macerated by alternating immersion in 40% KOH and distilled water. Cast replicas of the vascular lumina were coated with gold and imaged by scanning electron microscopy. At 6 hr, punctate depressions at the periphery of the replicas of vein and venule lumina were noted. The depressions represented sites of leukocyte margination. By 24 hr, the depressions increased numerically, indicating a great increase in the sites of leukocyte margination. The number of these depressions decreased by 48 hr. Concomitantly, the depressions representing endothelial cell nuclei became more pronounced, indicating nuclear hypertrophy of these cells. In addition, capillary bud formation was initiated. At 72 hr, capillary buds were quite apparent and arose solely from venules. Between 7 and 14 days, replicas of capillary lumina were longer and formed an elaborate network, presumably by end-to-end, side-to-side, and end-to-side anastomoses. The network was formed circumferential to the sponge and then capillary sprouts entered the sponge's interstitial spaces.     

Monotropein promotes angiogenesis and inhibits oxidative stress‐induced autophagy in endothelial progenitor cells to accelerate wound healing

Attenuating oxidative stress‐induced damage and promoting endothelial progenitor cell (EPC) differentiation are critical for ischaemic injuries. We suggested monotropein (Mtp), a bioactive constituent used in traditional Chinese medicine, can inhibit oxidative stress‐induced mitochondrial dysfunction and stimulate bone marrow‐derived EPC (BM‐EPC) differentiation. Results showed Mtp significantly elevated migration and tube formation of BM‐EPCs and prevented tert‐butyl hydroperoxide (TBHP)‐induced programmed cell death through apoptosis and autophagy by reducing intracellular reactive oxygen species release and restoring mitochondrial membrane potential, which may be mediated viamTOR/p70S6K/4EBP1 and AMPK phosphorylation. Moreover, Mtp accelerated wound healing in rats, as indicated by reduced healing times, decreased macrophage infiltration and increased blood vessel formation. In summary, Mtp promoted mobilization and differentiation of BM‐EPCs and protected against apoptosis and autophagy by suppressing the AMPK/mTOR pathway, improving wound healing in vivo. This study revealed that Mtp is a potential therapeutic for endothelial injury‐related wounds.     

Placenta mesenchymal stem cell accelerates wound healing by enhancing angiogenesis in diabetic Goto-Kakizaki (GK) rats

Multipotent mesenchymal stem cells have recently emerged as an attractive cell type for the treatment of diabetes-associated wounds. The purpose of this study was to examine the potential biological function of human placenta-derived mesenchymal stem cells (PMSCs) in wound healing in diabetic Goto-Kakizaki (GK) rats. PMSCs were isolated from human placenta tissue and characterized by flow cytometry. A full-thickness circular excisional wound was created on the dorsum of each rat. Red fluorescent CM-DiI-labeled PMSCs were injected intradermally around the wound in the treatment group. After complete wound healing, full-thickness skin samples were taken from the wound sites for histological evaluation of the volume and density of vessels. Our data showed that the extent of wound closure was significantly enhanced in the PMSCs group compared with the no-graft controls. Microvessel density in wound bed biopsy sites was significantly higher in the PMSCs group compared with the no-graft controls. Most surprisingly, immunohistochemical studies confirmed that transplanted PMSCs localized to the wound tissue and were incorporated into recipient vasculature with improved angiogenesis. Notably, PMSCs secreted comparable amounts of proangiogenic molecules, such as VEGF, HGF, bFGF, TGF-β and IGF-1 at bioactive levels. This study demonstrated that PMSCs improved the wound healing rate in diabetic rats. It is speculated that this effect can be attributed to the PMSCs engraftment resulting in vascular regeneration via direct de novo differentiation and paracrine mechanisms. Thus, placenta-derived mesenchymal stem cells are implicated as a potential angiogenesis cell therapy for repair-resistant chronic wounds in diabetic patients.     

Occlusion following laser resurfacing promotes reepithelialization and wound healing

One of the critical parameters that has not been examined carefully following laser skin resurfacing is the effect of eschar on the wound healing process. Because occlusive dressings minimize the occurrence of eschar, the present study was undertaken to evaluate the effect of occlusion following laser resurfacing. It is clear that CO2 lasers promote epidermal cell loss and variable amounts of dermal injury. To characterize the wound repair process after laser treatment, biopsy specimens were obtained 2 to 4 days after treatment. Specimens from 15 patients were examined; the preauricular biopsy specimens were paired such that one specimen was from skin that had been occluded and the other specimen (from the same patient) was from skin treated without occlusion. Skin specimens were examined by indirect immunofluorescence using antibodies to specific epidermal and dermal antigens. The results indicate that the keratinocytes that repopulate the epidermis migrate from the hair follicles and express keratin 17, an intermediate filament protein expressed in keratinocytes during the early stages of wound healing. The migration of keratin 17-expressing cells begins 48 hours following laser resurfacing in skin treated with occlusion, whereas cell migration from the follicles of skin treated without occlusion is delayed. In summary, occlusion promotes enhanced cell migration and diminished eschar formation, resulting in more rapid healing.     

Investigating a simple model of cutaneous wound healing angiogenesis

A simple model of wound healing angiogenesis is presented, and investigated using numerical and asymptotic techniques. The model captures many key qualitative features of the wound healing angiogenic response, such as the propagation of a structural unit into the wound centre. A detailed perturbative study is pursued, and is shown to capture all features of the model. This enables one to show that the level of the angiogenic response predicted by the model is governed to a good approximation by a small number of parameter groupings. Further investigation leads to predictions concerning how one should select between potential optimal means of stimulating cell proliferation in order to increase the level of the angiogenic response.     

Regulation of angiogenesis: wound healing as a model

Normal tissue function requires adequate supply of oxygen through blood vessels. Understanding how blood vessels form is a challenging objective because angiogenesis is vital to many physiological and pathological processes. Unraveling mechanisms of angiogenesis would offer therapeutic options to ameliorate disorders that are currently leading causes of mortality and morbidity, including cardiovascular diseases, cancer, chronic inflammatory disorders, diabetic retinopathy, excessive tissue defects, and chronic non-healing wounds. Restoring blood flow to the site of injured tissue is a prerequisite for mounting a successful repair response, and wound angiogenesis represents a paradigmatic model to study molecular mechanisms involved in the formation and remodeling of vascular structures. In particular, repair of skin defects offers an ideal model to analyze angiogenesis due to its easy accessibility to control and manipulate this process. Most of those growth factors, extracellular matrix molecules, and cell types, recently discovered and considered as crucial factors in blood vessel formation, have been identified and analyzed during skin repair and the process of wound angiogenesis. This article will review cellular and molecular mechanisms controlling angiogenesis in cutaneous tissue repair in light of recent reports and data from our laboratories. In this article we will discuss the contribution of growth factors, basement membrane molecules, and mural cells in wound angiogenesis. The article provides a rationale for targeting the angiogenic response in order to modulate the outcome of the healing response.     

Hyaluronan oligosaccharides promote excisional wound healing through enhanced angiogenesis

The biological roles of hyaluronan (HA) fragments in angiogenesis acceleration have been investigated recently. Studies have confirmed that oligosaccharides of HA (o-HA) are capable of stimulating neovascularization in vitro and promoting blood flow or angiogenesis in animal models. However, few laboratories have studied the function of o-HA as an exogenous treatment in injured tissue repair in vivo. It is thought that o-HA may lose its activities when used topically in vivo due to its small size, which may be absorbed quickly by the surrounding tissues. In this study, we prepared a special slow-releasing gel that contains a mixture of defined size of o-HA and studied the healing effects of o-HA by topical application to an acute wound model. We report that o-HA complex promotes the repair of tissue injury of a murine excisional dermal wound. The therapy by o-HA was compared with high molecular weight HA (HMW-HA) and the known angiogenesis stimulator, VEGF. At days 6 to 8 after treatment, significant differences were seen in wound closure rates between o-HA and control or HMW-HA groups, in which o-HA showed an increased wound recovery. Histological analysis revealed that increased neo-blood and lymph vessels were formed in wounded tissues treated by o-HA. In addition, treatments of wounds with o-HA resulted in more granulation production, collagen deposition, and fibroblast proliferation. Analysis of gene expression by real-time RT-PCR demonstrated a significant up-regulation of some cytokines or adhesion molecules in o-HA-treated wounds, which corresponds with the increased granulation tissue in these wounds. Our findings suggested that o-HA therapy may be useful in acute wound repair.     

Blood microcirculation and angiogenesis in wound healing by first and second intentions

Local reaction of the microvascular bed and angiogenesis of closed and infected open wounds have been studied in 72 rats. Selective contrasting of the functioning microvessels was achieved by means of intravenous injection of peroxidases, as tracers. The dynamics of microcirculatory disorders and the periods of capillary circulation recovery in the wound within 1-20 days after the injury were described. The principal resemblance of the alterations of the microvascular bed in closed and infected open wounds was established.     

Connexins in wound healing; perspectives in diabetic patients

Skin lesions are common events and we have evolved to rapidly heal them in order to maintain homeostasis and prevent infection and sepsis. Most acute wounds heal without issue, but as we get older our bodies become compromised by poor blood circulation and conditions such as diabetes, leading to slower healing. This can result in stalled or hard-to-heal chronic wounds. Currently about 2% of the Western population develop a chronic wound and this figure will rise as the population ages and diabetes becomes more prevalent [1]. Patient morbidity and quality of life are profoundly altered by chronic wounds [2]. Unfortunately a significant proportion of these chronic wounds fail to respond to conventional treatment and can result in amputation of the lower limb. Life quality and expectancy following amputation is severely reduced. These hard to heal wounds also represent a growing economic burden on Western society with published estimates of costs to healthcare services in the region of $25B annually [3]. There exists a growing need for specific and effective therapeutic agents to improve healing in these wounds. In recent years the gap junction protein Cx43 has been shown to play a pivotal role early on in the acute wound healing process at a number of different levels [4-7]. Conversely, abnormal expression of Cx43 in wound edge keratinocytes was shown to underlie the poor rate of healing in diabetic rats, and targeting its expression with an antisense gel restored normal healing rates [8]. The presence of Cx43 in the wound edge keratinocytes of human chronic wounds has also been reported [9]. Abnormal Cx43 biology may underlie the poor healing of human chronic wounds and be amenable therapeutic intervention [7]. This article is part of a Special Issue entitled: The Communicating junctions, composition, structure and characteristics.     

Acute ethanol exposure impairs angiogenesis and the proliferative phase of wound healing

Acute ethanol exposure represents an increased risk factor for morbidity and mortality associated with surgical or traumatic injury. Despite clinical observations suggesting that ethanol exposure before injury alters tissue repair processes, little direct evidence about the mechanism by which ethanol affects the wound healing process is available. In this study, excisional wounds from female BALB/c mice with or without circulating ethanol levels of 100 mg/dl were used to assess wound closure, angiogenesis, and collagen content. Ethanol exposure resulted in a significant but transient delay in wound closure at day 2 postwounding (28 +/- 4% vs. 17 +/- 1%). In addition, total collagen content was significantly reduced by up to 37% in wounds from ethanol-treated mice compared with controls. The most significant effect of ethanol exposure on wounds was on vascularity because angiogenesis was reduced by up to 61% in wounds from ethanol-treated mice. The reduction in vessel density occurred despite near-normal levels of proangiogenic factors VEGF and FGF-2, suggesting a direct effect of ethanol exposure on endothelial cell function. Further evidence for a direct effect was observed in an in vitro angiogenesis assay because the exposure of endothelial cells to ethanol reduced angiogenic responsiveness to just 8.33% of control in a cord-forming assay. These studies provide novel information regarding the effect of a single dose of ethanol on multiple parameters of the wound healing process in vivo and suggest a potential mechanism by which ethanol impairs healing after traumatic injury.