- Email: [email protected]
Oxidative Stress and “Senescent” Fibroblasts in Non-Healing Wounds as Potential Therapeutic Targets
commentary
GLI signal transduction is predominantly mediated by GLI2. Cancer Res 64:7724–31 Reifenberger J, Wolter M, Knobbe CB, Kohler B, Schonicke A, Scharwachter C et al. (2005) Somatic mutations in the PTCH, SMOH, SUFUH and TP53 genes in sporadic basal cell carcinomas. Br J Dermatol 152:43–51 Shah S, Islam MN, Dakshanamurthy S, Rizvi I, Rao M, Herrell R et al. (2006) The molecular basis of vitamin D receptor and beta-catenin crossregulation. Mol Cell 21:799–809 Tlsty TD (1990) Normal diploid human and rodent cells lack a detectable frequency of gene amplification. Proc Natl Acad Sci USA 87:3132–6 Tlsty TD, Margolin BH, Lum K (1989) Differences in the rates of gene amplification in nontumorigenic and tumorigenic cell lines as measured by Luria–Delbruck fluctuation analysis. Proc Natl Acad Sci USA 86:9441–5 Tojo M, Mori T, Kiyosawa H, Honma Y, Tanno Y, Kanazawa KY et al. (1999) Expression of sonic hedgehog signal transducers, patched and smoothened, in human basal cell carcinoma. Pathol Int 49:687–94 van Dam RM, Huang Z, Giovannucci E, Rimm EB, Hunter DJ, Colditz GA et al. (2000) Diet and basal cell carcinoma of the skin in a prospective cohort of men. Am J Clin Nutr 71:135–41 Wakabayashi Y, Mao JH, Brown K, Girardi M, Balmain A (2007) Promotion of Hras-induced squamous carcinomas by a polymorphic variant of the Patched gene in FVB mice. Nature 445:761–5 Wang TT, Tavera-Mendoza LE, Laperriere D, Libby E, MacLeod NB, Nagai Y et al. (2005) Large-scale in silico and microarray-based identification of direct 1,25-dihydroxyvitamin D3 target genes. Mol Endocrinol 19:2685–95 Weinstock MA, Stampfer MJ, Lew RA, Willett WC, Sober AJ (1992) Case–control study of melanoma and dietary vitamin D: implications for advocacy of sun protection and sunscreen use. J Invest Dermatol 98:809–11 Wood RD, Mitchell M, Sgouros J, Lindahl T (2001) Human DNA repair genes. Science 291:1284–9 Xie Z, Komuves L, Yu QC, Elalieh H, Ng DC, Leary C et al. (2002) Lack of the vitamin D receptor is associated with reduced epidermal differentiation and hair follicle growth. J Invest Dermatol 118:11–6 Ziegler A, Leffell DJ, Kunala S, Sharma HW, Gailani M, Simon JA et al. (1993) Mutation hotspots due to sunlight in the p53 gene of nonmelanoma skin cancers. Proc Natl Acad Sci USA 90:4216–20 Ziegler A, Jonason AS, Leffell DJ, Simon JA, Sharma HW, Kimmelman J et al. (1994) Sunburn and p53 in the onset of skin cancer. Nature 372:773–6 Zinser GM, Sundberg JP, Welsh J (2002) Vitamin D(3) receptor ablation sensitizes skin to chemically induced tumorigenesis. Carcinogenesis 23:2103–9
See related article on pg 2526
Oxidative Stress and “Senescent” Fibroblasts in Non-Healing Wounds as Potential Therapeutic Targets Richard A.F. Clark1 In chronic wounds, fibroblast dysfunctions, such as increased apoptosis, premature senescence, senescence-like phenotype, or poor growth response in the absence of senescence markers, have been reported. Some of these differential dysfunctions may be secondary to differences in patient age or sex, ulcer size or duration, edge versus base sampling, or culture technique. Nevertheless, the entire spectrum of fibroblast dysfunction may exist and be secondary to, or a response to, different amounts of oxidative stress. Journal of Investigative Dermatology (2008), 128, 2361–2364. doi:10.1038/jid.2008.257
In their article entitled “Fibroblast dysfunction is a key factor in the nonhealing of chronic venous leg ulcers,” Wall et al. (2008, this issue) demonstrate that a telomere-independent fibroblast abnormality occurs in chronic venous leg ulcers and posit that oxidative stress underlies this dysfunctional behavior. Although it is dysfunctional, the authors have clearly emphasized both here and in a previous publication (Stephens et al., 2003) that the chronic wound fibroblast phenotype observed by them does not represent the replicative senescence-like phenotype as has been reported for chronic wound fibroblasts by a number of other investigators (Agren et al., 1999; Mendez et al., 1998; Stanley and Osler, 2001; Stanley et al., 1997; Vande Berg et al., 1998, 2005). However, Stephens’s group isolated their chronic wound fibroblasts from biopsy specimens that come from the ulcer base while all other groups harvested chronic wound fibroblasts from the ulcer edge. Given the heterogeneity in growth response and other functions among human fibroblasts derived from either papillary or reticular dermis (Harper and Grove, 1979; Sorrell et al., 2008; Sorrell and Caplan, 2004), it is not surprising that Stephens’s
group has identified a different chronic wound fibroblast phenotype from the ulcer bed than the previously described fibroblast phenotype from the ulcer margin. Nevertheless, the fibroblast phenotypes reported by all groups of investigators are consistent with the variety of functional changes that can be induced by oxidative stress on fibroblasts (Wlaschek and Scharffetter-Kochanek, 2005). As pointed out by Wall et al. (2008), the oxidative effects on fibroblast phenotype and function depend on the level and length of exposure to reactive oxygen species (ROS). Low-level, chronic exposure to ROS accelerates telomere shortening (von Zglinicki, 2002), whereas high levels of ROS induce telomere-independent premature senescence (Song et al., 2005). Another important aspect of the cell “senescence” response to oxidative stress is cell age; aged human dermal fibroblasts demonstrate increased entrance into a senescent state compared with their younger counterparts when exposed to oxidative stress (Gurjala et al., 2005). Furthermore, depending on the physiologic state of the cell, oxidative stress can induce apoptosis rather than senescence (Chen
Departments of Biomedical Engineering, Dermatology, and Medicine, Stony Brook University, Stony Brook, New York, USA
1
Correspondence: Dr Richard A.F. Clark, Center for Tissue Engineering, Department of Biomedical Engineering, Stony Brook University, HSC T-16, Room 060, Stony Brook, New York 11794-8165, USA. E-mail: [email protected]
www.jidonline.org 2361
commentary
R
+
Lipid radical
H2 O
R
•OH Initiation
•
Propagation Lipid peroxide
O2
R
R
OOH
M(n + 1)+ − SOD + O2− → Mn+ − SOD + O2
|
Oxidative stress affects fibroblast phenotype.
Mn+ − SOD + O2− + 2H+ → M(n + 1)+ − SOD + H2O2
R
H
Because of its relatively long life span, H2O2 can act as an effector in signal transduction pathways (Wulf, 2002). Examples of genes induced by ROS (probably primarily H2O2) include peroxyredoxin I (a thioredoxin
peroxide molecule (H2O2) from two superoxide molecules (O2−) by the following reactions, where M is a transition metal that oscillates between its oxidized and reduced state:
+ OO• Termination Lipid peroxyl radical
Figure 1. Lipid peroxidation refers to the oxidative degradation of lipids. It is the process whereby free radicals “steal” electrons from the lipids in cell membranes, resulting in cell damage. This process proceeds by a free radical chain reaction mechanism. It most often affects polyunsaturated fatty acids, because they contain multiple double bonds between which lie reactive hydrogens. As with any radical reaction, the reaction consists of three major steps: initiation, propagation, and termination. (From “Lipid peroxidation,” Wikipedia, http://en.wikipedia.org/ wiki/Lipid_peroxidation, with permission.)
et al., 2000). Because chronic wounds demonstrate findings that indicate the presence of increased ROS (Wlaschek and Scharffetter-Kochanek, 2005), it is certainly possible that the dysfunctional fibroblast phenotypes reported at ulcer margins and the ulcer base are both attributable to oxidative stress. ROS can be generated by a variety of sources, including H2O2 during purine catabolism (xanthine and hypoxanthine oxidase) and superoxide (O2−) during mitochondrial metabolism in all cells or the respiratory burst associated with microbiocidal activity in phagocytes (Wlaschek and Scharffetter-Kochanek, 2005; Wulf, 2002). Importantly, according to Wall et al. (2008), chronic wound fibroblasts generate elevated levels of ROS compared with normal dermal fibroblasts, setting up a positive feedback system for wound degeneration. To understand the mechanisms of ROS-induced alteration and damage to cells, it is important to know that hydroxyl (OH·) and peroxy radicals (OOH·) are generated from O2− and H2O2 via superoxide dismutase (SOD) and the Fenton reaction, respectively (Wulf, 2002). SOD generates one oxygen molecule and one hydrogen
The Fenton reaction converts H2O2 to hydroxyl and peroxy radicals via the following reactions: Fe2+ + H2O2 → Fe3+ + OH· + OH− Fe3+ + H2O2 → Fe2+ + OOH· + H+
peroxidase that is protective against oxidative stress and apoptosis), heme oxygenase-1 (HO-1), and the cystine transporter xc–. The redox control of the HO-1 gene is one of the best-studied models of redox regulation. For example, in dermal fibroblasts HO-1 induction may serve as an inducible defense pathway to remove oxidant-liberated heme, which is extremely toxic when free (Kumar and Bandyopadhyay, 2005). Interestingly, heme toxicity probably is attributable in large part to its iron core, which, when released in great abundance, overwhelms the iron-binding capacity in blood and tissue (i.e., ferritin) and therefore can act as a catalyst in the Fenton reaction to generate more ROS. Because HO-1 mRNA is inducible in many tissues and its expression
In the Fenton reaction, the transition metal is iron, which oscillates between its reduced and oxidized states. Hydrogen peroxide (H2O2) is relatively long-lived in the cell until it is reduced by catalase in the perioxisome or by glutathione peroxidase in the cytoplasm by the following reactions, respectively, where GSH is reduced glutathione and GSSG is oxidized glutathione: 2H2O2 → 2H2O + O2 (catalase mediated) 2GSH + H2O2 → GSSG + 2H2O (glutathione peroxidase mediated)
a
R
b
H
N H H
CH3
R
O
R
O
H N
HO•
O
HO 2HO•
NH
H N
• O
R
O
H3C
N H
CH3
H3C
O
H
+
Unsaturated lipid
NH
CH2OH
O
H3C
NH
Valine side chain
Figure 2. Protein oxidation by free radicals. (a) Hydrogen atom elimination at the α-carbon of the protein backbone, resulting in backbone fragmentation, or (b) hydrogen atom elimination at side chains, resulting in different products, including peroxides, alcohols, and carbonyls. As with lipid perioxidation, protein peroxides are unstable and propagate further reactions. (Modified from the presentation “Protein Oxidation: Concepts, Mechanisms and New Insights,” by M.J. Davies, Heart Research Institute, Sydney, Australia, with permission.)
2362 Journal of Investigative Dermatology (2008), Volume 128
commentary
is relatively stable, it is a useful marker for cellular oxidative stress. As previously stated, ROS can induce cell apoptosis, and this appears to be mediated by H2O2 through its activation of the c-Jun N-terminal kinase (JNK) pathway, a subgroup of the mitogen-activated protein kinase family (Shen and Liu, 2006). In general, JNK is activated by environmental stresses, including osmotic shock, UV radiation, heat shock, oxidative stress, and chemotherapeutic agents, as well as the cell death ligands FasL and tumor necrosis factor-α and pro inflammatory cytokines such as interleukin-1. Among these inducers of JNK, however, oxidative stress seems particularly important. Although activated JNK induces a large family of genes, its pro-apoptotic activity is more direct (Shen and Liu, 2006). In stressed cells activated JNK translocates to the mitochondria, where it phosphorylates and inhibits the anti-apoptotic factor Bcl-2 and phosphorylates and activates the pro-apoptotic agents Bax, Bim, and Bmf. The alteration in balance between pro- and anti-apoptotic factor activities results in the release of cytochrome c from the mitochondria into the cytoplasm. Subsequently, free cytoplasmic cytochrome c activates the downstream effectors of the intrinsic (mitochondrial) apoptosis pathway. Some years ago, it was thought that H2O2 was the primary positive effector of transcription factor NF-κB, a central regulator of immunity, inflammation, and cell survival, and that many of the negative effects of ROS were mediated through NF-κB, including expression of inflammatory cytokines such as IL-1, IL-6, IL-8, and tumor necrosis factor-α. However, new evidence demonstrates that NF-κB exerts negative control on ROS and JNK activities and may prevent apoptosis that ROS would otherwise induce through JNK (Bubici et al., 2006). Not all signal transduction proteins are positively regulated by H2O2. Interestingly, hypoxia-inducible factor 1 (HIF-1) is negatively regulated by this ROS. HIF-1α and HIF-1β genes are constitutively expressed, but under normoxic conditions HIF-1α is rapidly degraded by proteasomes in an ROS-dependent manner (Wulf, 2002).
Base
Base P
CH2
O
P
N
O
CH2
O
sugar
O P
O
CH2
sugar O
HO•
O
O
O
P
CH2
N
sugar P
O
O
-
O
Base O
N
O
Base O
N
sugar P
O
Figure 3. DNA single-strand breaks are the most common damage inflicted by ROS. The break results from collapse of the sugar that is illustrated in the process at the right. (Modified from the presentation “DNA Oxidation: A Simple Overview," by F.Q. Schafer, University of Iowa, with permission.)
Hypoxia decreases the ROS-mediated degradation of HIF-1α and thereby enhances the formation of the hetero dimeric complex leading to HIF-1dependent gene regulation. Many of the gene targets of HIF-1 are important positive regulators of wound healing. In particular, HIF-1 increases the transcription of key factors for blood flow, including vascular endothelial growth factor, HO-1, and both endothelial and inducible nitric oxide synthase (Hellwig-Bürgel et al., 2005). Thus, in the presence of oxidative stress these HIF-1-inducible genes will remain repressed. Parenthetically, it should be pointed out that nitric oxide, a reactive nitrogen species, is also a potent mediator of signal transduction systems, but a discussion of this important topic is beyond the scope of this Commentary. Hydroxyl and peroxy radicals, in contrast to H2O2, are extremely short lived and essentially react with the first susceptible molecule with which they collide. Thus, these so-called free radicals damage cells directly by lipid peroxidation (Figure 1), protein oxidation (Figure 2), and scission of DNA single strands (Figure 3), although the figures oversimplify the actual processes. For example, hydroxyl radials can attack purines and pyrimidines, leading to gene mutations as well as the deoxyribosyl sugar in the DNA backbone (Wulf, 2002). It is important to emphasize that telomeres are
particularly sensitive to DNA breaks because they have no DNA repair enzyme system (Wulf, 2002). Another important example of the biologic consequences of ROS-generated free radicals is hydroxyl radical attack on endothelial cell membranes. In addition to compromising the membrane itself, hydroxyl radicals appear to directly activate intracellular calciumdependent adhesion molecule on the membrane, which makes the endothelium “stickier” for leukocytes passing in the circulation (Sellak et al., 1994). This both slows blood flow through the wound’s microvascular circulation and leads to an influx of inflammatory cells into the wound. Given all the adverse consequences of elevated ROS levels on cell machinery, it is no wonder that fibroblasts isolated from ROS-rich chronic wounds have a dysfunctional phenotype. These ongoing pathobiologic events in chronic wounds raise the question of how drug therapy can attenuate the impact of excessive ROS generation. Logically, the main target should be one or more of the pathways that generate ROS rather than dysfunctional chronic wound fibroblasts. If the hypothesis of Wall et al. (2008) is correct, relieving oxidative stress in chronic wounds will ameliorate fibroblast dysfunction. Here, clinicians and patients are fortunate to have a readily available drug that appears to attenuate oxidative stress in chronic wounds. www.jidonline.org 2363
commentary
Pentoxifylline has been used for patients with venous leg ulcers for two decades, and a recent meta-analysis by the Cochrane Collaborative Group found that pentoxifylline was effective with a high level of certainty (Jull et al., 2007). Although the mechanisms of action of this drug have not been rigorously defined, they include scavenging hydroxyl radicals (Freitas and Filipe, 1995), inhibiting xanthine oxidase (Hammerman et al., 1999), and reducing circulating levels of tumor necrosis factor-α (Fernandes et al., 2008; Zeni et al., 1996). Surprisingly, no other antioxidants have been tested in wellcontrolled clinical trials for efficacy in venous leg ulcer disease. CONFLICT OF INTEREST
The author states no conflict of interest.
References
Agren MS, Steenfos HH, Dabelsteen S, Hansen JB, Dabelsteen E (1999) Proliferation and mitogenic response to PDGF-BB of fibroblasts isolated from chronic venous leg ulcers is ulcer-age dependent. J Invest Dermatol 112:463–9 Bubici C, Papa S, Dean K, Franzoso G (2006) Mutual cross-talk between reactive oxygen species and nuclear factor-kappa B: molecular basis and biological significance. Oncogene 25:6731–48 Chen QM, Liu J, Merrett JB (2000) Apoptosis or senescence-like growth arrest: influence of cell-cycle position, p53, p21 and bax in H2O2 response of normal human fibroblasts. Biochem J 347:543–51 Fernandes JL, de Oliveira RT, Mamoni RL, Coelho OR, Nicolau JC, Blotta MH et al. (2008) Pentoxifylline reduces pro-inflammatory and increases anti-inflammatory activity in patients with coronary artery disease—a randomized placebo-controlled study. Atherosclerosis 196:434–42 Freitas JP, Filipe PM (1995) Pentoxifylline.
A hydroxyl radical scavenger. Biol Trace Element Res 47:307–11 Gurjala AN, Liu WR, Mogford JE, Procaccini PS, Mustoe TA (2005) Age-dependent response of primary human dermal fibroblasts to oxidative stress: cell survival, pro-survival kinases, and entrance into cellular senescence. Wound Repair Regen 13:565–75 Hammerman C, Goldschmidt D, Caplan MS, Kaplan M, Schimmel MS, Eidelman AI et al. (1999) Amelioration of ischemia–reperfusion injury in rat intestine by pentoxifyllinemediated inhibition of xanthine oxidase. J Pediatr Gastroenterol Nutr 29:69–74 Harper RA, Grove G (1979) Human skin fibroblasts derived from papillary and reticular dermis: differences in growth potential in vitro. Science 204:526–7 Hellwig-Bürgel T, Stiehl DP, Wagner AE, Metzen E, Jelkmann W. (2005) Hypoxia-inducible factor-1 (HIF-1): a novel transcription factor in immune reactions. J Interferon Cytokine Res 25:297–310 Jull A, Arroll B, Parag V, Waters J (2007) Pentoxifylline for treating venous leg ulcers (review). Cochrane Collaboration 2007:1–30 Kumar S, Bandyopadhyay U (2005) Free heme toxicity and its detoxification systems. Toxicol Lett 175:175–88 Mendez MV, Stanley A, Park HY, Shon K, Phillips T, Menzoian JO (1998) Fibroblasts cultured from venous ulcers display cellular characteristics of senescence. J Vasc Surg 28:876–83 Sellak H, Franzini E, Hakim J, Pasquier C (1994) Reactive oxygen species rapidly increase endothelial ICAM ability to bind neutrophils without detectable upregulation. Blood 83:2669–77 Shen H-M, Liu Z (2006) JNK signaling pathway is a key modulator in cell death mediated by reactive oxygen and nitrogen species. Free Radical Biol Med 40:928–39 Song YS, Lee BY, Hwang ES (2005) Dinstinct ROS and biochemical profiles in cells undergoing DNA damage-induced senescence and apoptosis. Mech Ageing Dev 126:580–90 Sorrell JM, Caplan AI (2004) Fibroblast heterogeneity: more than skin deep. J Cell Sci 117:667–75
2364 Journal of Investigative Dermatology (2008), Volume 128
Sorrell JM, Baber MA, Caplan AI (2008) Human dermal fibroblast subpopulations; differential interactions with vascular endothelial cells in coculture: nonsoluble factors in the extracellular matrix influence interactions. Wound Repair Regen 16:300–9 Stanley A, Osler T (2001) Senescence and the healing rates of venous ulcers. J Vasc Surg 33:1206–11 Stanley AC, Park HY, Phillips TJ, Russakovsky V, Menzoian JO (1997) Reduced growth of dermal fibroblasts from chronic venous ulcers can be stimulated with growth factors. J Vasc Surg 26:994–9; discussion 999–1001 Stephens P, Cook H, Hilton J, Jones CJ, Haughton MF, Wyllie FS et al. (2003) An analysis of replicative senescence in dermal fibroblasts derived from chronic leg wounds predicts that telomerase therapy would fail to reverse their disease-specific cellular and proteolytic phenotype. Exp Cell Res 283:22–35 Vande Berg JS, Rudolph R, Hollan C, HaywoodReid PL (1998) Fibroblast senescence in pressure ulcers. Wound Repair Regen 6:38–49 Vande Berg JS, Rose MA, Haywood-Reid PL, Rudolph R, Payne WG, Robson MC (2005) Cultured pressure ulcer fibroblasts show replicative senescence with elevated production of plasmin, plasminogen activator inhibitor-1, and transforming growth factorbeta1. Wound Repair Regen 13:76–83 von Zglinicki T (2002) Oxidative stress shortens telomeres. Trends Biochem Sci 27:339–44 Wall IB, Moseley R, Baird DM, Kipling D, Giles P, Laffafian I et al. (2008) Fibroblast dysfunction is a key factor in the non-healing of chronic venous leg ulcers. J Invest Dermatol 128:2526–40 Wlaschek M, Scharffetter-Kochanek K (2005) Oxidative stress in chronic venous leg ulcers. Wound Repair Regen 13:452–61 Wulf D (2002) Free radicals in regulation of physiological functions. Physiol Rev 82:47–95 Zeni F, Pain P, Vindimian M, Gay JP, Gery P, Bertrand M et al. (1996) Effects of pentoxifylline on circulating cytokine concentrations and hemodynamics in patients with septic shock: results from a doubleblind, randomized, placebo-controlled study. Crit Care Med 24:207–14
GLI signal transduction is predominantly mediated by GLI2. Cancer Res 64:7724–31 Reifenberger J, Wolter M, Knobbe CB, Kohler B, Schonicke A, Scharwachter C et al. (2005) Somatic mutations in the PTCH, SMOH, SUFUH and TP53 genes in sporadic basal cell carcinomas. Br J Dermatol 152:43–51 Shah S, Islam MN, Dakshanamurthy S, Rizvi I, Rao M, Herrell R et al. (2006) The molecular basis of vitamin D receptor and beta-catenin crossregulation. Mol Cell 21:799–809 Tlsty TD (1990) Normal diploid human and rodent cells lack a detectable frequency of gene amplification. Proc Natl Acad Sci USA 87:3132–6 Tlsty TD, Margolin BH, Lum K (1989) Differences in the rates of gene amplification in nontumorigenic and tumorigenic cell lines as measured by Luria–Delbruck fluctuation analysis. Proc Natl Acad Sci USA 86:9441–5 Tojo M, Mori T, Kiyosawa H, Honma Y, Tanno Y, Kanazawa KY et al. (1999) Expression of sonic hedgehog signal transducers, patched and smoothened, in human basal cell carcinoma. Pathol Int 49:687–94 van Dam RM, Huang Z, Giovannucci E, Rimm EB, Hunter DJ, Colditz GA et al. (2000) Diet and basal cell carcinoma of the skin in a prospective cohort of men. Am J Clin Nutr 71:135–41 Wakabayashi Y, Mao JH, Brown K, Girardi M, Balmain A (2007) Promotion of Hras-induced squamous carcinomas by a polymorphic variant of the Patched gene in FVB mice. Nature 445:761–5 Wang TT, Tavera-Mendoza LE, Laperriere D, Libby E, MacLeod NB, Nagai Y et al. (2005) Large-scale in silico and microarray-based identification of direct 1,25-dihydroxyvitamin D3 target genes. Mol Endocrinol 19:2685–95 Weinstock MA, Stampfer MJ, Lew RA, Willett WC, Sober AJ (1992) Case–control study of melanoma and dietary vitamin D: implications for advocacy of sun protection and sunscreen use. J Invest Dermatol 98:809–11 Wood RD, Mitchell M, Sgouros J, Lindahl T (2001) Human DNA repair genes. Science 291:1284–9 Xie Z, Komuves L, Yu QC, Elalieh H, Ng DC, Leary C et al. (2002) Lack of the vitamin D receptor is associated with reduced epidermal differentiation and hair follicle growth. J Invest Dermatol 118:11–6 Ziegler A, Leffell DJ, Kunala S, Sharma HW, Gailani M, Simon JA et al. (1993) Mutation hotspots due to sunlight in the p53 gene of nonmelanoma skin cancers. Proc Natl Acad Sci USA 90:4216–20 Ziegler A, Jonason AS, Leffell DJ, Simon JA, Sharma HW, Kimmelman J et al. (1994) Sunburn and p53 in the onset of skin cancer. Nature 372:773–6 Zinser GM, Sundberg JP, Welsh J (2002) Vitamin D(3) receptor ablation sensitizes skin to chemically induced tumorigenesis. Carcinogenesis 23:2103–9
See related article on pg 2526
Oxidative Stress and “Senescent” Fibroblasts in Non-Healing Wounds as Potential Therapeutic Targets Richard A.F. Clark1 In chronic wounds, fibroblast dysfunctions, such as increased apoptosis, premature senescence, senescence-like phenotype, or poor growth response in the absence of senescence markers, have been reported. Some of these differential dysfunctions may be secondary to differences in patient age or sex, ulcer size or duration, edge versus base sampling, or culture technique. Nevertheless, the entire spectrum of fibroblast dysfunction may exist and be secondary to, or a response to, different amounts of oxidative stress. Journal of Investigative Dermatology (2008), 128, 2361–2364. doi:10.1038/jid.2008.257
In their article entitled “Fibroblast dysfunction is a key factor in the nonhealing of chronic venous leg ulcers,” Wall et al. (2008, this issue) demonstrate that a telomere-independent fibroblast abnormality occurs in chronic venous leg ulcers and posit that oxidative stress underlies this dysfunctional behavior. Although it is dysfunctional, the authors have clearly emphasized both here and in a previous publication (Stephens et al., 2003) that the chronic wound fibroblast phenotype observed by them does not represent the replicative senescence-like phenotype as has been reported for chronic wound fibroblasts by a number of other investigators (Agren et al., 1999; Mendez et al., 1998; Stanley and Osler, 2001; Stanley et al., 1997; Vande Berg et al., 1998, 2005). However, Stephens’s group isolated their chronic wound fibroblasts from biopsy specimens that come from the ulcer base while all other groups harvested chronic wound fibroblasts from the ulcer edge. Given the heterogeneity in growth response and other functions among human fibroblasts derived from either papillary or reticular dermis (Harper and Grove, 1979; Sorrell et al., 2008; Sorrell and Caplan, 2004), it is not surprising that Stephens’s
group has identified a different chronic wound fibroblast phenotype from the ulcer bed than the previously described fibroblast phenotype from the ulcer margin. Nevertheless, the fibroblast phenotypes reported by all groups of investigators are consistent with the variety of functional changes that can be induced by oxidative stress on fibroblasts (Wlaschek and Scharffetter-Kochanek, 2005). As pointed out by Wall et al. (2008), the oxidative effects on fibroblast phenotype and function depend on the level and length of exposure to reactive oxygen species (ROS). Low-level, chronic exposure to ROS accelerates telomere shortening (von Zglinicki, 2002), whereas high levels of ROS induce telomere-independent premature senescence (Song et al., 2005). Another important aspect of the cell “senescence” response to oxidative stress is cell age; aged human dermal fibroblasts demonstrate increased entrance into a senescent state compared with their younger counterparts when exposed to oxidative stress (Gurjala et al., 2005). Furthermore, depending on the physiologic state of the cell, oxidative stress can induce apoptosis rather than senescence (Chen
Departments of Biomedical Engineering, Dermatology, and Medicine, Stony Brook University, Stony Brook, New York, USA
1
Correspondence: Dr Richard A.F. Clark, Center for Tissue Engineering, Department of Biomedical Engineering, Stony Brook University, HSC T-16, Room 060, Stony Brook, New York 11794-8165, USA. E-mail: [email protected]
www.jidonline.org 2361
commentary
R
+
Lipid radical
H2 O
R
•OH Initiation
•
Propagation Lipid peroxide
O2
R
R
OOH
M(n + 1)+ − SOD + O2− → Mn+ − SOD + O2
|
Oxidative stress affects fibroblast phenotype.
Mn+ − SOD + O2− + 2H+ → M(n + 1)+ − SOD + H2O2
R
H
Because of its relatively long life span, H2O2 can act as an effector in signal transduction pathways (Wulf, 2002). Examples of genes induced by ROS (probably primarily H2O2) include peroxyredoxin I (a thioredoxin
peroxide molecule (H2O2) from two superoxide molecules (O2−) by the following reactions, where M is a transition metal that oscillates between its oxidized and reduced state:
+ OO• Termination Lipid peroxyl radical
Figure 1. Lipid peroxidation refers to the oxidative degradation of lipids. It is the process whereby free radicals “steal” electrons from the lipids in cell membranes, resulting in cell damage. This process proceeds by a free radical chain reaction mechanism. It most often affects polyunsaturated fatty acids, because they contain multiple double bonds between which lie reactive hydrogens. As with any radical reaction, the reaction consists of three major steps: initiation, propagation, and termination. (From “Lipid peroxidation,” Wikipedia, http://en.wikipedia.org/ wiki/Lipid_peroxidation, with permission.)
et al., 2000). Because chronic wounds demonstrate findings that indicate the presence of increased ROS (Wlaschek and Scharffetter-Kochanek, 2005), it is certainly possible that the dysfunctional fibroblast phenotypes reported at ulcer margins and the ulcer base are both attributable to oxidative stress. ROS can be generated by a variety of sources, including H2O2 during purine catabolism (xanthine and hypoxanthine oxidase) and superoxide (O2−) during mitochondrial metabolism in all cells or the respiratory burst associated with microbiocidal activity in phagocytes (Wlaschek and Scharffetter-Kochanek, 2005; Wulf, 2002). Importantly, according to Wall et al. (2008), chronic wound fibroblasts generate elevated levels of ROS compared with normal dermal fibroblasts, setting up a positive feedback system for wound degeneration. To understand the mechanisms of ROS-induced alteration and damage to cells, it is important to know that hydroxyl (OH·) and peroxy radicals (OOH·) are generated from O2− and H2O2 via superoxide dismutase (SOD) and the Fenton reaction, respectively (Wulf, 2002). SOD generates one oxygen molecule and one hydrogen
The Fenton reaction converts H2O2 to hydroxyl and peroxy radicals via the following reactions: Fe2+ + H2O2 → Fe3+ + OH· + OH− Fe3+ + H2O2 → Fe2+ + OOH· + H+
peroxidase that is protective against oxidative stress and apoptosis), heme oxygenase-1 (HO-1), and the cystine transporter xc–. The redox control of the HO-1 gene is one of the best-studied models of redox regulation. For example, in dermal fibroblasts HO-1 induction may serve as an inducible defense pathway to remove oxidant-liberated heme, which is extremely toxic when free (Kumar and Bandyopadhyay, 2005). Interestingly, heme toxicity probably is attributable in large part to its iron core, which, when released in great abundance, overwhelms the iron-binding capacity in blood and tissue (i.e., ferritin) and therefore can act as a catalyst in the Fenton reaction to generate more ROS. Because HO-1 mRNA is inducible in many tissues and its expression
In the Fenton reaction, the transition metal is iron, which oscillates between its reduced and oxidized states. Hydrogen peroxide (H2O2) is relatively long-lived in the cell until it is reduced by catalase in the perioxisome or by glutathione peroxidase in the cytoplasm by the following reactions, respectively, where GSH is reduced glutathione and GSSG is oxidized glutathione: 2H2O2 → 2H2O + O2 (catalase mediated) 2GSH + H2O2 → GSSG + 2H2O (glutathione peroxidase mediated)
a
R
b
H
N H H
CH3
R
O
R
O
H N
HO•
O
HO 2HO•
NH
H N
• O
R
O
H3C
N H
CH3
H3C
O
H
+
Unsaturated lipid
NH
CH2OH
O
H3C
NH
Valine side chain
Figure 2. Protein oxidation by free radicals. (a) Hydrogen atom elimination at the α-carbon of the protein backbone, resulting in backbone fragmentation, or (b) hydrogen atom elimination at side chains, resulting in different products, including peroxides, alcohols, and carbonyls. As with lipid perioxidation, protein peroxides are unstable and propagate further reactions. (Modified from the presentation “Protein Oxidation: Concepts, Mechanisms and New Insights,” by M.J. Davies, Heart Research Institute, Sydney, Australia, with permission.)
2362 Journal of Investigative Dermatology (2008), Volume 128
commentary
is relatively stable, it is a useful marker for cellular oxidative stress. As previously stated, ROS can induce cell apoptosis, and this appears to be mediated by H2O2 through its activation of the c-Jun N-terminal kinase (JNK) pathway, a subgroup of the mitogen-activated protein kinase family (Shen and Liu, 2006). In general, JNK is activated by environmental stresses, including osmotic shock, UV radiation, heat shock, oxidative stress, and chemotherapeutic agents, as well as the cell death ligands FasL and tumor necrosis factor-α and pro inflammatory cytokines such as interleukin-1. Among these inducers of JNK, however, oxidative stress seems particularly important. Although activated JNK induces a large family of genes, its pro-apoptotic activity is more direct (Shen and Liu, 2006). In stressed cells activated JNK translocates to the mitochondria, where it phosphorylates and inhibits the anti-apoptotic factor Bcl-2 and phosphorylates and activates the pro-apoptotic agents Bax, Bim, and Bmf. The alteration in balance between pro- and anti-apoptotic factor activities results in the release of cytochrome c from the mitochondria into the cytoplasm. Subsequently, free cytoplasmic cytochrome c activates the downstream effectors of the intrinsic (mitochondrial) apoptosis pathway. Some years ago, it was thought that H2O2 was the primary positive effector of transcription factor NF-κB, a central regulator of immunity, inflammation, and cell survival, and that many of the negative effects of ROS were mediated through NF-κB, including expression of inflammatory cytokines such as IL-1, IL-6, IL-8, and tumor necrosis factor-α. However, new evidence demonstrates that NF-κB exerts negative control on ROS and JNK activities and may prevent apoptosis that ROS would otherwise induce through JNK (Bubici et al., 2006). Not all signal transduction proteins are positively regulated by H2O2. Interestingly, hypoxia-inducible factor 1 (HIF-1) is negatively regulated by this ROS. HIF-1α and HIF-1β genes are constitutively expressed, but under normoxic conditions HIF-1α is rapidly degraded by proteasomes in an ROS-dependent manner (Wulf, 2002).
Base
Base P
CH2
O
P
N
O
CH2
O
sugar
O P
O
CH2
sugar O
HO•
O
O
O
P
CH2
N
sugar P
O
O
-
O
Base O
N
O
Base O
N
sugar P
O
Figure 3. DNA single-strand breaks are the most common damage inflicted by ROS. The break results from collapse of the sugar that is illustrated in the process at the right. (Modified from the presentation “DNA Oxidation: A Simple Overview," by F.Q. Schafer, University of Iowa, with permission.)
Hypoxia decreases the ROS-mediated degradation of HIF-1α and thereby enhances the formation of the hetero dimeric complex leading to HIF-1dependent gene regulation. Many of the gene targets of HIF-1 are important positive regulators of wound healing. In particular, HIF-1 increases the transcription of key factors for blood flow, including vascular endothelial growth factor, HO-1, and both endothelial and inducible nitric oxide synthase (Hellwig-Bürgel et al., 2005). Thus, in the presence of oxidative stress these HIF-1-inducible genes will remain repressed. Parenthetically, it should be pointed out that nitric oxide, a reactive nitrogen species, is also a potent mediator of signal transduction systems, but a discussion of this important topic is beyond the scope of this Commentary. Hydroxyl and peroxy radicals, in contrast to H2O2, are extremely short lived and essentially react with the first susceptible molecule with which they collide. Thus, these so-called free radicals damage cells directly by lipid peroxidation (Figure 1), protein oxidation (Figure 2), and scission of DNA single strands (Figure 3), although the figures oversimplify the actual processes. For example, hydroxyl radials can attack purines and pyrimidines, leading to gene mutations as well as the deoxyribosyl sugar in the DNA backbone (Wulf, 2002). It is important to emphasize that telomeres are
particularly sensitive to DNA breaks because they have no DNA repair enzyme system (Wulf, 2002). Another important example of the biologic consequences of ROS-generated free radicals is hydroxyl radical attack on endothelial cell membranes. In addition to compromising the membrane itself, hydroxyl radicals appear to directly activate intracellular calciumdependent adhesion molecule on the membrane, which makes the endothelium “stickier” for leukocytes passing in the circulation (Sellak et al., 1994). This both slows blood flow through the wound’s microvascular circulation and leads to an influx of inflammatory cells into the wound. Given all the adverse consequences of elevated ROS levels on cell machinery, it is no wonder that fibroblasts isolated from ROS-rich chronic wounds have a dysfunctional phenotype. These ongoing pathobiologic events in chronic wounds raise the question of how drug therapy can attenuate the impact of excessive ROS generation. Logically, the main target should be one or more of the pathways that generate ROS rather than dysfunctional chronic wound fibroblasts. If the hypothesis of Wall et al. (2008) is correct, relieving oxidative stress in chronic wounds will ameliorate fibroblast dysfunction. Here, clinicians and patients are fortunate to have a readily available drug that appears to attenuate oxidative stress in chronic wounds. www.jidonline.org 2363
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Pentoxifylline has been used for patients with venous leg ulcers for two decades, and a recent meta-analysis by the Cochrane Collaborative Group found that pentoxifylline was effective with a high level of certainty (Jull et al., 2007). Although the mechanisms of action of this drug have not been rigorously defined, they include scavenging hydroxyl radicals (Freitas and Filipe, 1995), inhibiting xanthine oxidase (Hammerman et al., 1999), and reducing circulating levels of tumor necrosis factor-α (Fernandes et al., 2008; Zeni et al., 1996). Surprisingly, no other antioxidants have been tested in wellcontrolled clinical trials for efficacy in venous leg ulcer disease. CONFLICT OF INTEREST
The author states no conflict of interest.
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