The transcription factor nuclear factor κB (NF-κB)/p65 is the master regulator of inflammation in Duchenne muscular dystrophy (DMD). Disease severity is reduced by NF-κB inhibition in the mdx mouse, a murine DMD model; however, therapeutic targeting of NF-κB remains problematic for patients because of its fundamental role in immunity. In this investigation, we found that the therapeutic effect of NF-κB blockade requires hepatocyte growth factor (HGF) production by myogenic cells. We found that deleting one allele of the NF-κB subunit p65 (p65+/−) improved the survival and enhanced the anti-inflammatory capacity of muscle-derived stem cells (MDSCs) following intramuscular transplantation. Factors secreted from p65+/− MDSCs in cell cultures modulated macrophage cytokine expression in an HGF-receptor-dependent manner. Indeed, we found that following genetic or pharmacologic inhibition of basal NF-κB/p65 activity, HGF gene transcription was induced in MDSCs. We investigated the role of HGF in anti-NF-κB therapy in vivo using mdx;p65+/− mice, and found that accelerated regeneration coincided with HGF upregulation in the skeletal muscle. This anti-NF-κB-mediated dystrophic phenotype was reversed by blocking de novo HGF production by myogenic cells following disease onset. HGF silencing resulted in increased inflammation and extensive necrosis of the diaphragm muscle. Proteolytic processing of matrix-associated HGF is known to activate muscle stem cells at the earliest stages of repair, but our results indicate that the production of a second pool of HGF by myogenic cells, negatively regulated by NF-κB/p65, is crucial for inflammation resolution and the completion of repair in dystrophic skeletal muscle. Our findings warrant further investigation into the potential of HGF mimetics for the treatment of DMD.
The transcription factor nuclear factor-κB (NF-κB) is highly activated in the skeletal muscle (henceforth simply termed ‘muscle’) of patients suffering from Duchenne muscular dystrophy (DMD).1 In this fatal neuromuscular disease, absence of the cytoskeletal protein dystrophin results in muscle membrane instability, ongoing muscle degeneration and chronic inflammation. During early childhood, at the onset of disease, muscle is able to effectively repair. In early adolescence, however, tissue regeneration rapidly declines, and patients usually expire in their 20s.1, 2 It is well established from animal models of DMD, such as the dystrophin-deficient mdx mouse, that the dystrophic phenotype is exacerbated by NF-κB activation. Genetic or pharmacologic strategies blocking p65, the classical NF-κB DNA-binding subunit, or its upstream activator, IκB kinase β (IKKβ), have been found to reduce inflammation and accelerate muscle regeneration.1 This type of treatment approach is problematic for DMD patients, however, given the broad role of this transcription factor, particularly in immunity.3
NF-κB suppression is thought to improve muscle regeneration by acting directly on immune cells and muscle progenitor cells to reduce inflammation and promote muscle differentiation, respectively.4, 5 We previously reported that NF-κB negatively influences the myogenic potential of muscle-derived stem cells (MDSCs),6 a highly myogenic cell population with stem cell-like characteristics, including multilineage differentiation and self-renewal.7, 8 When compared with committed muscle precursor cells, or myoblasts, MDSCs demonstrate a higher intramuscular engraftment capability in both the skeletal and cardiac muscle.9 The improved regenerative potential of MDSCs may be related to stress resistance10, 11 and the release of soluble factors such as vascular endothelial growth factor (VEGF).12, 13 Of note, many secreted factors are NF-κB target genes, suggesting that its blockade might have broader implications than promoting myogenic lineage progression. This is suggested by our earlier work, in which we unexpectedly observed that intramuscular injection of donor MDSCs haploinsufficient for p65 reduced wild-type (WT) recipient muscle necrosis and CD14+ cell infiltration significantly more than WT MDSCs.6 This suggests that enhanced differentiation in mdx skeletal muscle may not account for all of the benefit of NF-κB blockade, and perhaps may offer a new strategy to reduce inflammation without compromising host immunity.
We found that loss of one p65 allele improved the anti-inflammatory properties of MDSCs in a macrophage hepatocyte growth factor (HGF) receptor-, Met, dependent manner. In muscle, the processing of HGF sequestered in the extracellular matrix is responsible for the activation and migration of satellite cells following injury.14, 15 However, an active role for HGF/Met in the remaining stages of muscle regeneration and inflammation resolution has yet to be identified.16, 17 Herein, we investigated the importance of HGF in mediating the beneficial effect of NF-κB/p65 blockade in dystrophic muscle using mdx;p65+/− mice, a previously described genetic model of NF-κB blockade in DMD.1 We found that enhanced muscle regeneration in mdx;p65+/− mice coincided with significant HGF upregulation. To examine the role of HGF produced by muscle cells during repair, we blocked de novo HGF expression following the onset of the mdx pathology using a musculotropic adeno-associated viral (AAV) vector carrying HGF shRNA. HGF silencing resulted in significantly increased inflammation and necrosis in the mdx;p65+/− diaphragm (DIA), thus reversing the beneficial effect of p65 haploinsufficiency. Our findings identify a critical role for HGF during inflammation resolution and provide new mechanistic insight into how modulation of NF-κB/p65 attenuates muscular dystrophy. With HGF mimetics currently in phase II clinical trials for treating myocardial infarction and kidney dysfunction, our results suggest that these drugs might also be used to control chronic inflammation in muscular dystrophy and other inflammatory myopathies without compromising host immunity.
P65 haploinsufficiency enhances MDSC anti-inflammatory properties
We previously reported that compared with WT cells, intramuscular engraftments of donor p65+/− MDSCs resulted in significantly reduced necrosis and inflammation in recipient tissue.6 To explore the mechanism behind this finding in vitro, we compared the ability of WT- and p65+/− MDSC-conditioned medium (CM) to modulate the expression of prototypical cytokines in a murine macrophage cell line (RAW264.7; RAW). Briefly, RAW cells were exposed to lipopolysaccharide (LPS) in WT- or p65+/−-CM for 24 h. Exposure to WT- or p65+/−-CM was associated with reduced tumor necrosis factor-α (Tnfα), interleukin-1β (Il1β) and interleukin-6 (Il6) transcription (Figure 1a, left). Interestingly, we found that it was the RAW cells stimulated in p65+/−-CM that demonstrated the greatest suppression of Il6 (a 10-fold decrease in p65+/−-CM versus WT-CM, P<0.05) (Figure 1a). As Il6 is a secondary response gene, we suspected that earlier events in the cytokine cascade were modulated by MDSC-secreted factors. Therefore, we continued these experiments at an earlier time point and under serum-free (SF) conditions. We found that at 3 h, RAW cells stimulated with LPS in p65+/−-CM demonstrated a significant induction of Il6, in contrast to the decrease we had observed at 24 h. Additionally, we observed induction of the anti-inflammatory factor interleukin-10 (Il10) (Figures 1b and c; P<0.05). WT-CM had a similar effect, but to a significantly smaller degree (Figures 1b and c; P<0.05). In contrast, LPS alone in the fresh medium did not induce Il10 at 3 h (P=0.11). Of note, the accelerated induction of both Il6 and Il10 may explain the decrease in Il6 we observed at 24 h. These results demonstrate that immunomodulatory factors regulated by NF-κB/p65 are secreted by MDSCs under basal conditions.
P65+/− MDSC engraftments accelerate healing in injured muscle when compared with WT MDSC engraftments
Although we previously reported that reduced numbers of CD14+ cells were associated with p65+/− MDSC engraftments at 1 week postinjection,6 a time-course analysis was required to determine if this finding was reflective of accelerated inflammation resolution. Thus, we used a similar cell transplant model to monitor recipient inflammation up to 7 days following intramuscular injection of WT or p65+/− MDSCs. Briefly, the gastrocnemius (GAS) muscle was injured with cardiotoxin (CTX), and 24 h later, MDSCs retrovirally labeled with nuclear-localized red fluorescent protein (RFP) were delivered intramuscularly. Immunofluorescent staining of tissue sections revealed that p65+/− cell engraftments were associated with significantly less CD68+ cells at day 7, but not at days 1 and 3 (Figures 2a and c). Nearly all CD68+ cells coexpressed CD11b (data not shown); therefore, CD68 was used as a macrophage marker in subsequent experiments. Staining for the embryonic isoform of myosin heavy chain (eMyHC) identified regenerating fibers local to donor cell engraftments at day 7 (Figure 2b). p65+/− MDSC engraftments demonstrated a trend (P=0.12) towards being associated with more eMyHC+ myofibers (Figure 2d). This demonstrates that inflammation resolution, likely coupled with regeneration, was accelerated by p65+/− MDSC engraftment.
Improved survival of donor p65+/− MDSCs in injured WT muscle at 3 and 7 days postinjection
As evident in Figure 2, and confirming our previous investigation, engraftments of p65+/− MDSCs appeared larger than those of WT cells.6 Indeed, the number of WT cells declined rapidly from days 1 to 3 (Figures 3a and b; P<0.05). It is unlikely that the higher number of p65+/− cells was because of proliferation, as staining for Ki-67 indicated no difference between groups (Figures 3a and c). This was surprising because in vitro, p65+/− MDSCs demonstrate higher proliferation than WT cells.6 To further determine how inflammation might affect the expansion of the donor MDSCs, we cocultured MDSCs with RAW cells in vitro (ratio of 1 : 10). We determined MDSC population doubling time (PDT) using a previously validated model of cell population growth.18 In the absence of LPS, p65+/− MDSCs were more proliferative compared with WT cells (Figure 3d).6 However, the addition of LPS extended the PDT of p65+/− cells, but not WT cells, indicating a decrease in p65+/− cell proliferation. Thus, decreased proliferation, in addition to paracrine modulation of the inflammatory microenvironment, may represent a mechanism through which p65+/− MDSCs are protected from cell death following transplantation to injured muscle.
Inhibition of IKKβ in MDSCs induces Hgf expression
We next endeavored to identify anti-inflammatory factors differentially expressed by p65+/− MDSCs. We began with a number of candidate genes known to have immunomodulatory properties, including transforming growth factor β1 (Tgfb), Vegf, Hgf, interleukin-4 (Il4), Il10 and inducible nitric oxide synthase (Inos).19 Of these factors, only Hgf was significantly upregulated (Figure 4a, P⩽0.05). Il4 and Il10 transcripts were detected in neither WT nor p65+/− MDSCs (data not shown). Under basal conditions, proliferating myogenic cells display a relatively high level of NF-κB activity.20 To verify a relationship between Hgf expression and NF-κB activity, we treated WT and p65+/− cells with an inhibitor of IKKβ (IKK-2 inhibitor IV, IKKi) and examined gene expression after 2 and 24 h. By 24 h, Hgf was upregulated ~+3.5-fold (P⩽0.05) in IKKi-treated WT MDSCs (Figure 4b). p65+/− MDSCs demonstrated a small increase (+1.67-fold, P⩽0.05) after 2 h, but at 24 h this did not significantly differ from the vehicle alone (P=0.46). These experiments confirm a negative relationship between Hgf and IKKβ/NF-κB in MDSCs.
P65+/−-CM modulation of Il10 and Il6 expression in RAW cells depends on the HGF receptor, Met
To verify the functional significance of increased HGF transcription, we examined the activation of its receptor, Met, in RAW cells exposed to CM. Strikingly, phosphorylated Met (p-Met) was detectable at 5 min following exposure to p65+/−-CM, but not WT-CM (Figure 4c, right, middle). Stimulating cells with LPS and CM in the presence of the Met inhibitor, SU11274 (Sigma, St. Louis, MO, USA), significantly decreased the induction of Il6 and Il10 by p65+/− CM observed after 3 h (Figures 4d, P⩽0.05), demonstrating that MDSC modulation of RAW cell gene transcription occurs downstream of Met. Il6 induction by WT-CM was not significantly changed. Il10 induction did decrease, although to a lesser degree than that of the p65+/− CM group (Figures 4e, P<0.05).
HGF/Met has been reported to modulate cytokine production by the inactivation of glycogen synthase kinase 3β (GSK3β).21 Under basal conditions, GSK3β sequesters transcription factors that are required for the induction of anti-inflammatory genes. For example, Il10 is induced following inactivation of GSK3β via phosphorylation on serine 9 (pS9-GSK3β).22 By western blot, we found that at 30 min, RAW cells activated in p65+/−-CM demonstrated a striking +3.5-fold (P⩽0.05) increase in pS9-GSK3β, which remained elevated (+2.9-fold, P⩽0.05) up to 24 h. In contrast, when activated in WT-CM or fresh medium, pS9-GSK3β increased to a significantly smaller degree and then declined (Figures 5a and b). Moreover, GSK3β phosphorylation 30 min postexposure to LPS in p65+/−-CM was abrogated by treatment with SU11274 (Sigma) (Figure 5c and d). Collectively, these results suggest that HGF released from p65+/− MDSCs modulates cytokine gene expression in activated macrophages via inactivation of macrophage GSK3β.
Accelerated regeneration in p65+/− skeletal muscle is accompanied by elevated HGF and macrophage pS9-GSK3β
To determine whether the macrophage HGF/Met/GSK3β pathway is activated during muscle regeneration in vivo, we conducted CTX injury experiments on 4- to 5-week-old p65+/− and WT mice. In uninjured p65+/− muscles, higher levels of Hgf mRNA were detected but this was not statistically significant (Figures 6a, P=0.09). Similarly, uninjured p65+/− muscle had a modest increase in total HGF protein (Figure 6c). We found Hgf expression was significantly higher in p65+/− muscle after 3 days (Figure 6a). This coincided with de novo fiber formation, visible by H&E staining of tissue sections (Figure 6b, middle panel, arrows). Consistent with the findings of Archaryya and co-workers1 regarding accelerated muscle regeneration in p65+/− mice, muscle inflammation was reduced at 5 days postinjury (Figure 6b). Immunohistochemical staining revealed that compared with WT muscle, HGF-positive mononuclear cells occupied a greater area in p65+/− muscle at 1 and 3 days postinjury (Supplementary Figure S1A). We next isolated macrophage and myoblast populations from WT and p65+/− hindlimb muscles at day 3 postinjury. Not only were significantly less macrophages identified as F4/80+ cells, collected from p65+/− muscle (Supplementary Figure S1B), but also ex vivo analysis demonstrated no difference in Hgf expression and only a small, nonsignificant difference in HGF secretion (Supplementary Figure S1C). In contrast, TNFα stimulation of primary p65+/− myoblasts resulted in stronger induction of Hgf expression compared with WT myoblasts (Supplementary Figure S1D). Collectively, these data indicate that myogenic progenitor cells are the likely source of elevated Hgf in CTX-injured p65+/− muscle.
We next stained tissue sections for CD68 and pS9-GSK3β (Figure 6d). Compared with WT muscle, a substantially higher number of pS9-GSK3β macrophages was found in p65+/− muscle at all three time points tested (Figure 6e, P⩽0.05). Ex vivo analysis of macrophages isolated on day 3 postinjury revealed that p65+/− macrophages expressed higher levels of both Il6 and Il10 compared with WT cells (Supplementary Figure S2A), consistent with our in vitro results using RAW cells treated with p65+/− MDSC-CM (Figure 4). Higher secretion of IL-10 by p65+/− macrophages was further confirmed by ELISA (Supplementary Figure S2B). Of note, upon stimulation with an equal amount of HGF (±LPS), WT and p65+/−-resident peritoneal macrophages did not demonstrate any differences in the percentage of pS9-GSK3β-positive cells in vitro (Supplementary Figure S2C). These results indicate that p65 deficiency had no confounding effect on the HGF/Met/GSK3β pathway in native macrophages. Additionally, macrophage populations isolated from p65+/− muscles contained higher percentages of cells expressing resistin-like molecule-α (RELMα) or CD163, markers of a prohealing, regenerative phenotype (Supplementary Figure S2D).23, 24 Taken together, these results demonstrate that the accelerated regeneration of p65+/− muscle correlates with HGF upregulation in myogenic progenitor cells, leading to the modulation of macrophage phenotype, likely via a Met/GSK3β pathway.
HGF is upregulated in mdx;p65+/− skeletal muscle during regeneration
Based on our findings with the CTX injury model, we hypothesized that elevation of HGF contributes to the beneficial effects of NF-κB blockade in dystrophic muscle. To investigate this, we used mdx;p65+/− mice, a genetic model of NF-κB/p65 inhibition, which has been reported to have a significantly attenuated dystrophic phenotype.1 We examined HGF expression in the GAS muscles of mdx;p65+/− and mdx;p65+/+(mdx) littermates during both the degenerative (~4 weeks) and regenerative phases (~6 weeks) of muscle pathology. Strikingly, HGF was upregulated +5.7-fold in mdx;p65+/− mice at 4 weeks of age compared with WT mice (Figures 7a, P<0.05). In contrast, HGF expression in mdx GAS only increased +2.7-fold. At this time, H&E staining of mdx:p65+/− GAS revealed a reduced mononuclear cell infiltrate and significantly enhanced regeneration compared with mdx littermates (Figures 7b (P<0.05) and Supplementary Figure S3). By 6 weeks, we detected no significant differences in Hgf expression or regenerating fibers between mdx and mdx;p65+/− GAS (Figures 7a and b). Importantly, we found no differences in Hgf expression in muscle tissues of presymptomatic, 1-week-old mice (Figure 7a). This demonstrated that upregulation of Hgf occurs following the onset of muscle degeneration and was associated with the regenerative stage of the mdx pathology, which was accelerated by ~2 weeks in mdx;p65+/− mice.
In vivo silencing of skeletal muscle-derived HGF reversed the ameliorated phenotype of mdx;p65+/− mice
We hypothesized that HGF upregulation precedes and subsequently promotes muscle regeneration. To investigate this, we designed a musculotropic recombinant AAV vector25 carrying the ZsGreen reporter gene and shRNA targeting HGF (HGF-shRNA). Five-day-old mdx;p65+/− and mdx littermates received intraperitoneal injections of HGF-shRNA or control vector with scrambled shRNA (ct-shRNA). With this approach, the matrix reservoir of pro-HGF produced during development will be present until muscle degeneration begins, at ~3 weeks of age.15 Muscle-derived HGF produced during repair, however, will be targeted by our vector. Based on reporter gene expression, we observed high gene transfer efficiency in the limb and DIA muscles (Supplementary Figure S4A). Regenerating fibers exhibited ZsGreen expression, indicating that muscle progenitor cells were successfully transduced (Figure 7c, arrows). CD68 and ZsGreen did not colocalize, demonstrating that myeloid cells (red) were not transduced (Figure 7c). Finally, transduction of the liver and spleen was minimal, attesting to the musculotropic nature of our vector (Supplementary Figure S4B). These observations indicate that we preferentially transduced muscle fibers and progenitor cells using this approach.
HGF-shRNA reduced Hgf transcript by ~−2- and −4-fold in mdx;p65+/− DIA and GAS, respectively (P⩽0.05) (Figure 7d). Paradoxically, Hgf in mdx DIA or GAS muscles was not significantly decreased by HGF-shRNA (P=0.80 and P=0.20, respectively). This may be because of a low level of Hgf in mdx muscles, relative to those of mdx;p65+/− mice. HGF-shRNA-treated muscle demonstrated striking morphological changes compared with ct-shRNA-treated muscle. Transduction was highest in the DIA (Supplementary Figure S4A, data not shown); therefore, we focused on this muscle for our subsequent analysis. Increased degeneration of the DIA indicated a reversal of the histological improvements associated with p65 haploinsufficiency, as shown in Figure 7e (top). Although the decrease in Hgf was not statistically significant in the mdx group, we still detected histological changes in treated muscle (Figures 7e and f). HGF-shRNA significantly increased the necrotic/inflammatory lesion area of mdx;p65+/− DIA, such that the size of lesions (percent area) resembled those of mdx mice (Figure 7f). Similarly, the necrotic/inflammatory lesion area of mdx DIA increased following HGF-shRNA treatment. To distinguish between necrosis and inflammation, we identified necrotic fibers and infiltrating macrophages by mouse IgG and CD68 immunostaining, respectively. HGF silencing significantly increased both inflammatory and necrotic lesions of mdx;p65+/− DIA (P⩽0.05) (Figures 8a and c). In contrast, only the IgG+ area was significantly increased in HGF-shRNA-treated mdx mice (P⩽0.05) (Figure 8c). Based on our results, HGF produced by muscle cells during repair is essential for the completion of regeneration. More importantly, these results indicate that HGF is critical for the beneficial effects of NF-κB/p65 blockade on dystrophic muscle.
Numerous studies suggest that chronic inflammation accounts for a significant portion of muscle damage in DMD. The transcription factor NF-κB is central to inflammation and has been found to be dysregulated in muscular dystrophy.26 In an earlier investigation by Archaryya and co-workers,1 the phenotype of mdx mice was found to be significantly attenuated by deletion of one p65 allele. By conditional knockout of IKKβ in either myeloid cells or muscle, they attributed this improvement to reduced inflammation and enhanced myogenesis, respectively. Indeed, p65 potently suppresses myogenic progenitor cell differentiation.1, 4, 5, 6 In this study, we further investigated effector mechanisms of anti-NF-κB therapy and found that the alleviation of muscular dystrophy in mdx;p65+/− mice depends in large part on HGF. Based on our results and summarized in Figure 8d, we propose that in addition to promoting myogenesis, NF-κB blockade increases HGF expression by myogenic cells during repair, which acts locally to modulate inflammation and increase cell survival.
A regenerative role for HGF has been reported in a number of diverse adult tissues, such as liver, kidney and bone.27, 28, 29 Secreted in a proform, HGF requires cleavage by proteases to produce two chains, which bind to form the active HGF heterodimer.30, 31 In muscle, pro-HGF is stored in the extracellular matrix and is crucial for the activation of satellite cells following injury.16, 32 Unlike the models put forth by others, our work suggests that HGF is also important for the completion of regeneration. We found significantly higher Hgf expression in mdx;p65+/− muscle at 4 weeks of age, correlating with reduced leukocyte infiltration and increased muscle fiber formation. The phenotypic improvements of mdx;p65+/− muscle were reversed by silencing HGF preferentially in myogenic cells, resulting in significant degeneration of the DIA. Thus, stimulation of the HGF/Met pathway may be a viable strategy for treating inflammatory myopathies, such as DMD.
Notably, p65 haploinsufficiency improved the survival and engraftment of donor MDSCs in host muscle. We have previously reported that the engraftment of myoblasts was improved by retroviral gene transfer of the anti-inflammatory mediator IL-1 receptor antagonist.33 Thus, it is reasonable to suggest that the local anti-inflammatory effects of HGF might be responsible for improved survival of donor cells. Further experiments will be required to investigate this point. The anti-inflammatory effect of HGF/Met in target cells appears to be mediated through inactivation of the ubiquitously expressed kinase, GSK3β. Constitutively active under basal conditions, GSK3β suppresses the anti-inflammatory factor IL-10.22, 30, 34 In line with these previous reports, our work suggests that RAW cell Il6 and Il10 expression is modulated by p65+/−-CM through an HGF/Met/GSK3β pathway.
During normal muscle repair, inflammatory macrophages transition to a proregenerative, or ‘M2’ phenotype.35 This has been reported to involve AMP-activated protein kinase (AMPK).36 Recently, AMPK has been found to be negatively regulated by GSK3β.37 Interestingly, GSK3β activity has been reported to be elevated in a canine model of DMD, implicating it in muscular dystrophy.38 As we found that macrophages collected from injured p65+/− muscle had higher percentages of cells bearing M2 markers (Supplementary Figure S2D), it is tempting to speculate that HGF/Met/GSK3β might be involved in macrophage phenotype switching and inflammation resolution in dystrophic muscle. It is worthy to consider however, that the mechanisms governing macrophage phenotype switching may differ between regeneration associated with acute versus chronic injuries. Future studies will be required to determine whether HGF/Met might have a role in this process.
The current DMD treatment, corticosteroid therapy, reduces inflammation, but comes with many unwanted side effects, including cataracts, growth impairment and reduction in bone density.39 An anti-NF-κB therapy can only be temporary, at best, given the ubiquitous nature of this transcription factor, especially in immunity. Based on this investigation, the beneficial effect of anti-NF-κB therapy might also be achieved by targeting HGF/Met. Phase II clinical trials using HGF mimetics for treating heart attack and delayed kidney graft function are currently in progress, suggesting that such an approach to DMD may well be feasible and safe.40, 41 Based on our findings, HGF/Met might be a new target for reducing inflammation, prolonging fiber integrity and delaying disease progression in dystrophic muscle.
Materials and Methods
C57Bl/6 (WT) mice and C57BL/10ScSn-Dmdmdx/J (mdx) mice were purchased from the Jackson laboratory (Bar Harbor, ME, USA). P65+/− mice on a C57Bl/6 background, originally characterized by Beg et al.,42 were bred with mdx mice to produce mdx:p65+/− and mdx:p65+/+ mice. P65 heterozygotes were backcrossed into an mdx background for a minimum of 10 generations. Genotyping was carried out by PCR analysis of tail samples. Mice ranged in age from 5 days to 12 weeks. Specific ages for each experiment are described below. All animal protocols used for these experiments were approved by the University of Pittsburgh’s Institutional Animal Care and Use Committee.
Primary WT and p65+/− MDSCs and myoblasts (i.e. committed myogenic progenitor cells) were obtained from 5-month-old WT and p65+/− mice using the modified preplate method, as described previously.8 MDSCs and myoblasts were cultured in proliferation medium (PM) containing 10% fetal bovine serum (FBS), 10% horse serum, 1% penicillin–streptomycin (P/S) and 0.5% chick embryo extract in DMEM. Freshly isolated myoblasts were minimally expanded ex vivo for 3 days and then treated with TNFα (10 ng/ml) for 0, 3, 6, 18, or 24 h. Cell pellets were immediately collected for RNA extraction. RAW264.7 cells, a murine macrophage-like cell line (ATCC, Manassas, VA, USA), were maintained and expanded in 10% FBS and 1% P/S in DMEM. Resident peritoneal macrophages were collected by lavage of the peritoneal cavity of unmanipulated mice and cultured in complete medium for 1 day before experiments. Primary macrophages were isolated from CTX-injured hindlimb muscles of WT (n=3) or p65+/− (n=4) mice at 3 days postinjury, as reported previously.43 Cells were cultured in vitro for 3 days in DMEM supplemented with 10% FBS and 1% P/S on non-tissue culture-treated petri dishes. Primary macrophages were then removed from dishes by Versene solution for real-time RT-PCR or seeded for subsequent experiments. To block NF-κB activation, WT MDSCs were treated with the reversible ATP-competitive inhibitor of IKKβ, IKKi (EMD Millipore, Billerca, MA, USA) at 5 μM. Recombinant mouse HGF was used at a concentration of 100 ng/ml (Pepro Tech, Rocky Hill, NJ, USA).
Retroviral vector construction and transduction of MDSCs
To label the cells before in vivo and coculture experiments, MDSCs were retrovirally transduced to express nuclear-localized RFP. The retroviral vector was constructed with a combined CMV and long terminal repeat promoter driving RFP followed by a nuclear localization sequence derived from an SV40 large T-antigen. Briefly, cells were plated at 40% confluence and transduced at an MOI of 5 in culture medium supplemented with polybrene (8 μg/ml; Sigma-Aldrich, Milwaukee, WI, USA). After transduction, cells were passaged approximately four times to ensure stable gene expression. Finally, transduced WT and p65+/− cells were selected by flow cytometry (FACSAria II, Bedford, MA, USA).
Measurement of cell proliferation
In triplicate, cells were plated in a 24-well collagen type I-coated plate. Using a previously described live cell imaging (LCI) system, x10 brightfield images were taken in 10-min intervals over a 72- h period.18 Our custom-built LCI includes a biobox incubator that sits atop a Nikon Eclipse TE 2000 U microscope stage, which is attached to a CCD camera (Kairos Instruments LLC, Pittsburgh, PA, USA). Three locations to be imaged were randomly chosen per well, giving nine fields of view per population, per experiment. LCI was used to measure proliferation over 60 h by counting the number of cells per field of view at 12 -h intervals using ImageJ software (NIH, Bethesda, MD, USA). For coculture experiments, RFPn expressing WT or p65+/− MDSCs were plated with murine RAW264.7 (ATCC) cells at a ratio of 1 : 10 and incubated overnight in PM. The following day, cells were activated by exposure to 100 ng/ml LPS (Sigma-Aldrich) in PM. Using LCI, we tracked the activity of RFP-expressing MDSCs over a 60- h period by capturing x10 brightfield and fluorescent images at 10-min intervals. PDT was calculated using a previously described model.44 For each field of view per population, the mean PDT was defined as the average of PDT measurements calculated at 48 and 60 h.
CTX muscle injury model and stem cell implantation
WT (8–12 weeks old) mice were injured by the injection of 30 μl of CTX (4μM; Sigma) into the GAS muscle, as described previously.45 Twenty four hours later, 300 × 105 RFPn-positive WT or p65+/− MDSCs were injected into the injured GAS muscle. At 24 h, 72 h and 7 days postinjection, the animals were killed and the hind limbs were harvested and frozen in 2-methylbutane, and then precooled in liquid nitrogen. The specimens were stored at −80 °C until 10-μm-thick cryosections were obtained at −25 °C. To examine muscle regeneration between genotypes, the GAS of 4- to 6-week-old p65+/− and WT mice were injured with CTX, killed at 1, 3 or 5 days postinjury and tissues were harvested and snap frozen as described above.
Immunofluorescence and histology
Cryosections were fixed with 5% formalin for 5 min and blocked with 10% donkey serum for 2 h. Slides were then incubated with one or more primary antibodies, including rabbit anti-RFP (1 : 200; Abcam, Cambridge, MA, USA), rabbit anti-mouse Ki-67 (1 : 200; Abcam), rabbit anti-phospho(S9)-GSK3β (1 : 50; Abcam) or rat anti-CD68 (1 : 200; Abcam) in 10% donkey or goat serum. Next, sections were incubated with secondary antibodies including 594-conjugated anti-rabbit or anti-rat IgG (1 : 500; Invitrogen, Grand Island, NY, USA) and 488-conjugated anti-rabbit or anti-rat IgG (1 : 500; Invitrogen) in PBS for 30 min. We stained sections for eMyHC using a mouse anti-mouse eMyHC antibody (1 : 50; Developmental Studies Hybridoma Bank, University of Iowa, Iowa City, IA, USA) with a Mouse-on-Mouse (M.O.M.) Staining Kit (Vector Labs, Burlingame, CA, USA) according to the manufacturer’s directions. To identify necrotic fibers, we used a biotinylated anti-mouse IgG antibody (1 : 300; Vector Labs) with the M.O.M. kit diluent, according to the manufacturer’s directions. Alternatively, cryosections were fixed with 2% paraformaldehyde and stained with goat anti-mouse HGF primary antibody (15 μg/ml; R&D Systems, Minneapolis, MN, USA) using the Cell & Tissue Staining HRP-DAB System (R&D Systems) according to the manufacturer’s instructions. For immunocytochemistry, cultured cells were fixed with 4% paraformaldehyde for 5 min, blocked with 10% donkey serum for 1 h and then incubated overnight at 4 °C with one or more primary antibodies, including rat anti-mouse F4/80 (1 : 250; AbD Serotec, Kidlington, UK), rabbit anti-mouse RELMα (1 : 100; Thermo Scientific Pierce, Waltham, MA, USA) or rabbit anti-mouse CD163 (1 : 100, Biorbyt, Cambridge, UK), followed by incubation with secondary antibodies 594-conjugated anti-rat (1 : 500; Invitrogen) or 488-conjugated anti-rabbit (1 : 500; Invitrogen) for 1 h at room temperature. Nuclei were stained with DAPI (1 : 1000; Invitrogen) for 5 min at room temperature. Histological analysis was carried out by hematoxylin and eosin staining (H&E), as described previously.46
Image acquisition and processing
Immunofluorescent or brightfield images were captured using an upright fluorescent microscope (Leica Microsystems Inc., Wetzlar, Germany) equipped with a digital Retiga camera (QImaging, Surrey, BC, Canada). Images were acquired using Northern Eclipse (Empix Imaging Inc., Cheektowaga, NY, USA) or QCapture (QImaging) and quantified using ImageJ software (NIH) or CellProfiler (Broad Institute, Cambridge, MA, USA). To analyze RFP, CD68, Ki-67 or eMyHC staining, x200 images were captured through the entire injury and engraftment area from the region of highest engraftment along the length of the muscle. To analyze CD68 and phospho(S9)-GSK3β staining, four x600 images were captured from the injured area of each muscle. To analyze IgG or CD68 staining on ZsGreen-transduced muscles, x200 fluorescent images were captured from three locations along the length of sections from the medial region of each muscle. The x100, x200 or x400 brightfield images were captured for H&E analysis, with the regions for imaging chosen in a similar manner as described above. Area was measured using Adobe Photoshop (Adobe Systems Inc., New York, NY, USA). Final images for figures were also prepared in Adobe Photoshop.
In vitro inflammation assay
RAW264.7 cells were plated in a six-well plate with 105 cells per well, and then incubated for 48 h to achieve high density. CM was prepared by plating 106 MDSCs into a T-175 flask with 15 ml of medium. Following a 24 h incubation, the medium was collected and then filtered (0.22 μm). RAW264.7 cultures were washed with PBS and then cultured in CM with or without 100 ng/ml LPS for 30 min, 3 h or 24 h, at which time cell lysates were collected. To block Met, cells were pretreated with SU11274 (EMD Millipore; 448101) in DMEM supplemented with 1% P/S for 2 h before exposure to CM (SF) also supplemented with SU11274.
Cell and tissue lysates were prepared in RIPA buffer (Sigma) supplemented with protease and phosphatase inhibitors (nos. 2 and 3, 1 : 100; Sigma) and quantified using the Bio-Rad Protein Assay (500-0001; Bio-Rad, Hercules, CA, USA). Immunoblotting was performed as described previously.6 Membranes were incubated with monoclonal antibodies (1 : 1000; Cell Signaling, Danvers, MA, USA) to pS9-GSK3β, total GSK3β or polyclonal rabbit anti-HGF (1 : 100; Santa Cruz, Dallas, TX, USA) at 4 °C overnight in 5% milk or BSA in TBST. Ponceau S (Sigma) staining or probing with an HRP-conjugated antibody to GAPDH (1 : 8000; Abcam) was used to evaluate loading. For detection of total or phospho(Y1234/1235)-Met (1 : 1000; Cell Signaling), cells were lysed in RIPA with the above inhibitors with the addition of 0.2% SDS. Membranes probed for total or phospho-Met were washed for 30 min in high salt buffer (TBST supplemented with 0.5 M NaCl and 0.2% SDS) before detection.
Total RNA was isolated using TRI Reagent (Sigma) and reverse transcribed using Maxima First-Strand cDNA Synthesis Kit (Thermo Scientific, Waltham, MA, USA) according to the manufacturer’s protocols. Real-time PCR was carried out using the Maxima Syber Green Assay Kit (Thermo Scientific) with an iQ5 thermocycler (Bio-Rad), with β-actin serving as an endogenous control. Primers were designed using PRIMER-Blast (NCBI, Bethesda, MA, USA) and were as follows: β-actin, F: 5′-IndexTermCCACACCCGCCACCAGTTCG-3′ and R: 5′-IndexTermTACAGCCCGGGGAGCATCGT-3′; Interleukin 6, F: 5′-IndexTermTCTGCAAGAGACTTCCATCCAGTTGC-3′ and R: 5′-IndexTermAGCCTCCGACTTGTGAAGTGGT-3′; Interleukin 1, F: 5′-IndexTermAAGCCTCGTGCTGTCGGACC-3′ and R: 5′-IndexTermGCTTGGGATCCACACTCTCCAGC-3′; Interleukin 10, F: 5′-IndexTermGCATGGCCCAGAAATCAAGG-3′ and R: 5′-IndexTermAGGGGAGAAATCGATGACAGC-3′; tumor necrosis factor α, F: 5′-IndexTermAGCCCACGTCGTAGCAAACCAC-3′ and R: 5′-IndexTermCGGGGCAGCCTTGTCCCTTG-3′; vascular endothelial growth factor, F: 5′-IndexTermGGCTTTACTGCTGTACCTCC-3′ and R: 5′-IndexTermGCAGTAGCTTCGCTGGTAGA-3′; transforming growth factor β, F: 5′-IndexTermCTAATGGTGGACCGCAACAAC-3′ and R: 5′-IndexTermCACTGCTTCCCGAATGTCTGA-3′; Inos, F: 5′-IndexTermGCTGCCTTCCTGCTGTCGCA-3′ and R: IndexTermCCTGACCATCTCGGGTGCGG; hepatocyte growth factor, F: 5′-IndexTermTCATATCTTCTGGGAGCCAGATGCT-3′ and R: 5′-IndexTermGGTCCAAATTGACAATTGTAGGTGTAGT-3′.
To detect IL-10 and HGF secretion by primary macrophages, freshly isolated cells were cultured ex vivo for a total of 5 days. Cells were then washed two times and maintained in DMEM with 1% P/S (SF) for additional 24 h. Supernatants were then collected and stored at −80 °C; cells were collected and counted. ELISA was performed to detect IL-10 and HGF using the Mouse IL-10 ELISA Kit (Abcam) and the Mouse/Rat HGF Quantikine ELISA Kit (R&D Systems), respectively. The concentration of IL-10 and HGF was normalized per 105 cells.
Construction of HGF shRNA, AAV vector production and AAV administration
We designed two HGF-shRNAs, each based on previously reported siRNA sequences.47, 48 We first tested the efficiency of HGF knockdown in vitro using C2C12 mouse myoblasts (ATCC). We chose the most efficient sequence (>60% reduction by western blot) for our continued experiments. Our shRNA targeted the sense sequence 5′-IndexTermACGAAGTCTGTGACATTCCTC-3′ (position in gene sequence: nucleotide 718–738) and antisense sequence 5′-IndexTermGCGGAATGTCACAGACTTCGT-3′. The following oligos were synthesized by Invitrogen: IndexTermGATC-sense-IndexTermCTCGAG-antisense-IndexTermTTTTTTT-G (forward) and IndexTermAATTC-AAAAAAA-sense-IndexTermCTCGAG-antisense-G (reverse). We chose to use AAV serotype 9 because of its unique tropism towards muscles, which results in high gene transfer efficiency.25 We designed an AAV construct containing a dual cassette consisting of the human U6 promoter driving HGF-shRNA, followed by a CMV promoter driving the ZsGreen reporter gene as described previously.46 An AAV vector with scrambled shRNA was designed as a control (ct-shRNA). At 5 days of age, we performed intraperitoneal injection with 100 μl of virus titered at 5 × 1012 vg/ml. Four weeks later, animals were killed and the muscles and soft tissues were harvested. Each experimental and control group contained four to six mice.
Data are reported as mean±S.E.M. or mean±S.D., as indicated in figure legends. To compare two groups, a Student’s t-test was used to determine significance. To compare three or more groups, we used a one-way ANOVA followed by Tukey's post hoc analysis. A P-value <0.05 was considered significant.
Duchenne muscular dystrophy
hepatocyte growth factor
muscle-derived stem cells
IκB kinase β
vascular endothelial growth factor
tumor necrosis factor-α
red fluorescent protein
embryonic isoform of myosin heavy chain
population doubling time
transforming growth factor β 1
inducible nitric oxide synthase
IKK-2 Inhibitor IV
glycogen synthase kinase 3β
- RELM α:
resistin-like molecule α
AMP-activated protein kinase
fetal bovine serum
10% horse serum
live cell imaging system
hematoxylin and eosin staining
high power field
Archaryya S, Villalta SA, Bakkar N, Bupha-Intr T, Janssen PM, Carathers M et al. Interplay of IKK/NF-kappaB signaling in macrophages and myofibers promotes muscle degeneration in Duchenne muscular dystrophy. J Clin Invest 2007; 117: 889–901.
Villalta SA, Nguyen HX, Deng B, Gotoh T, Tidball JG . Shifts in macrophage phenotypes and macrophage competition for arginine metabolism affect the severity of muscle pathology in muscular dystrophy. Hum Mol Genet 2009; 18: 482–496.
Karin M, Lin A . NF-kappaB at the crossroads of life and death. Nat Immunol 2002; 3: 221–227.
Wang H, Hertlein E, Bakkar N, Sun H, Acharyya S, Wang J et al. NF-kappaB regulation of YY1 inhibits skeletal myogenesis through transcriptional silencing of myofibrillar genes. Mol Cell Biol 2007; 27: 4374–4387.
Dahlman JM, Wang J, Bakkar N, Guttridge DC . The RelA/p65 subunit of NF-kappaB specifically regulates cyclin D1 protein stability: implications for cell cycle withdrawal and skeletal myogenesis. J Cell Biochem 2009; 106: 42–51.
Lu A, Proto JD, Guo L, Tang Y, Lavasani M, Tilstra JS et al. NF-kappaB negatively impacts the myogenic potential of muscle-derived stem cells. Mol Ther 2012; 20: 661–668.
Deasy BM, Gharaibeh BM, Pollett JB, Jones MM, Lucas MA, Kanda Y et al. Long-term self-renewal of postnatal muscle-derived stem cells. Mol Biol Cell 2005; 16: 3323–3333.
Gharaibeh B, Lu A, Tebbets J, Zheng B, Feduska J, Crisan M et al. Isolation of a slowly adhering cell fraction containing stem cells from murine skeletal muscle by the preplate technique. Nat Protoc 2008; 3: 1501–1509.
Payne TR, Oshima H, Sakai T, Ling Y, Gharaibeh B, Cummins J et al. Regeneration of dystrophin-expressing myocytes in the mdx heart by skeletal muscle stem cells. Gene Therapy 2005; 12: 1264–1274.
Urish KL, Vella JB, Okada M, Deasy BM, Tobita K, Keller BB et al. Antioxidant levels represent a major determinant in the regenerative capacity of muscle stem cells. Mol Biol Cell 2009; 20: 509–520.
Vella JB, Thompson SD, Bucsek MJ, Song M, Huard J . Murine and human myogenic cells identified by elevated aldehyde dehydrogenase activity: implications for muscle regeneration and repair. PLoS One 2011; 6: e29226.
Beckman SA, Chen WC, Tang Y, Proto JD, Mlakar L, Wang B et al. The beneficial effect of mechanical stimulation on the regenerative potential of muscle-derived stem cells is lost by inhibiting vascular endothelial growth factor. Arterioscler Thromb Vasc Biol 2013; 33: 2004–2012.
Payne TR, Oshima H, Okada M, Momoi N, Tobita K, Keller BB et al. A relationship between vascular endothelial growth factor, angiogenesis, and cardiac repair after muscle stem cell transplantation into ischemic hearts. J Am Coll Cardiol 2007; 50: 1677–1684.
Miller KJ, Thaloor D, Matteson S, Pavlath GK . Hepatocyte growth factor affects satellite cell activation and differentiation in regenerating skeletal muscle. Am J Physiol Cell Physiol 2000; 278: C174–C181.
Tatsumi R, Anderson JE, Nevoret CJ, Halevy O, Allen RE . HGF/SF is present in normal adult skeletal muscle and is capable of activating satellite cells. Dev Biol 1998; 194: 114–128.
Sisson TH, Nguyen MH, Yu B, Novak ML, Simon RH, Koh TJ et al. Urokinase-type plasminogen activator increases hepatocyte growth factor activity required for skeletal muscle regeneration. Blood 2009; 114: 5052–5061.
Galimi F, Cottone E, Vigna E, Arena N, Boccaccio C, Giordano S et al. Hepatocyte growth factor is a regulator of monocyte–macrophage function. J Immunol 2001; 166: 1241–1247.
Deasy BM, Jankowski RJ, Payne TR, Cao B, Goff JP, Greenberger JS et al. Modeling stem cell population growth: incorporating terms for proliferative heterogeneity. Stem Cells 2003; 21: 536–545.
Nauta AJ, Fibbe WE . Immunomodulatory properties of mesenchymal stromal cells. Blood 2007; 110: 3499–3506.
Lehtinen SK, Rahkila P, Helenius M, Korhonen P, Salminen A . Down-regulation of transcription factors AP-1, Sp-1, and NF-kappa B precedes myocyte differentiation. Biochem Biophys Res Commun 1996; 229: 36–43.
Steinbrecher KA, Wilson W 3rd, Cogswell PC, Baldwin AS . Glycogen synthase kinase 3beta functions to specify gene-specific, NF-kappaB-dependent transcription. Mol Cell Biol 2005; 25: 8444–8455.
Martin M, Rehani K, Jope RS, Michalek SM . Toll-like receptor-mediated cytokine production is differentially regulated by glycogen synthase kinase 3. Nat Immunol 2005; 6: 777–784.
Moestrup SK, Moller HJ . CD163: a regulated hemoglobin scavenger receptor with a role in the anti-inflammatory response. Ann Med 2004; 36: 347–354.
Mosser DM, Edwards JP . Exploring the full spectrum of macrophage activation. Nat Rev Immunol 2008; 8: 958–969.
Katwal AB, Konkalmatt PR, Piras BA, Hazarika S, Li SS, John Lye R et al. Adeno-associated virus serotype 9 efficiently targets ischemic skeletal muscle following systemic delivery. Gene Therapy 2013; 20: 930–938.
Monici MC, Aguennouz M, Mazzeo A, Messina C, Vita G . Activation of nuclear factor-kappaB in inflammatory myopathies and Duchenne muscular dystrophy. Neurology 2003; 60: 993–997.
Pediaditakis P, Lopez-Talavera JC, Petersen B, Monga SP, Michalopoulos GK . The processing and utilization of hepatocyte growth factor/scatter factor following partial hepatectomy in the rat. Hepatology 2001; 34: 688–693.
Zhou D, Tan RJ, Lin L, Zhou L, Liu Y . Activation of hepatocyte growth factor receptor, c-met, in renal tubules is required for renoprotection after acute kidney injury. Kidney Int 2013; 84: 509–520.
Nakase J, Kitaoka K, Matsumoto K, Tomita K . Facilitated tendon-bone healing by local delivery of recombinant hepatocyte growth factor in rabbits. Arthroscopy 2010; 26: 84–90.
Gong R, Rifai A, Ge Y, Chen S, Dworkin LD . Hepatocyte growth factor suppresses proinflammatory NFkappaB activation through GSK3beta inactivation in renal tubular epithelial cells. J Biol Chem 2008; 283: 7401–7410.
Mars WM, Zarnegar R, Michalopoulos GK . Activation of hepatocyte growth factor by the plasminogen activators uPA and tPA. Am J Pathol 1993; 143: 949–958.
Tatsumi R, Allen RE . Active hepatocyte growth factor is present in skeletal muscle extracellular matrix. Muscle Nerve 2004; 30: 654–658.
Qu Z, Balkir L, van Deutekom JC, Robbins PD, Pruchnic R, Huard J et al. Development of approaches to improve cell survival in myoblast transfer therapy. J Cell Biol 1998; 142: 1257–1267.
Coudriet GM, He J, Trucco M, Mars WM, Piganelli JD . Hepatocyte growth factor modulates interleukin-6 production in bone marrow derived macrophages: implications for inflammatory mediated diseases. PLoS One 2010; 5: e15384.
Arnold L, Henry A, Poron F, Baba-Amer Y, van Rooijen N, Plonquet A et al. Inflammatory monocytes recruited after skeletal muscle injury switch into antiinflammatory macrophages to support myogenesis. J Exp Med 2007; 204: 1057–1069.
Mounier R, Théret M, Arnold L, Cuvellier S, Bultot L, Göransson O et al. AMPKalpha1 regulates macrophage skewing at the time of resolution of inflammation during skeletal muscle regeneration. Cell Metab 2013; 18: 251–264.
Suzuki T, Bridges D, Nakada D, Skiniotis G, Morrison SJ, Lin JD et al. Inhibition of AMPK catabolic action by GSK3. Mol Cell 50, 2013: 407–419.
Feron M, Guevel L, Rouger K, Dubreil L, Arnaud MC, Ledevin M et al. PTEN contributes to profound PI3K/Akt signaling pathway deregulation in dystrophin-deficient dog muscle. Am J Pathol 174: 1459–1470.
Biggar WD, Harris VA, Eliasoph L, Alman B . Long-term benefits of deflazacort treatment for boys with Duchenne muscular dystrophy in their second decade. Neuromuscul Disord 2006; 16: 249–255.
Health, U. S. N. I. o. (2013) Study on delayed graft function using paired kidneys. Available at: 〈http://clinicaltrials.gov/ct2/show/NCT01561599?term=HGF+mimetic&rank=2〉 (last accessed 8 May 2012).
Health, U. S. N. I. o. (2012) Study to evaluate the safety and activity of BB3 to treat heart attack. Available at: 〈http://clinicaltrials.gov/ct2/show/NCT01539590?term=HGF+mimetic&rank=1〉 (last accessed 8 May 2012).
Beg AA, Sha WC, Bronson RT, Ghosh S, Baltimore D . Embryonic lethality and liver degeneration in mice lacking the RelA component of NF-kappa B. Nature 1995; 376: 167–170.
Villalta SA, Rinaldi C, Deng B, Liu G, Fedor B, Tidball JG et al. Interleukin-10 reduces the pathology of mdx muscular dystrophy by deactivating M1 macrophages and modulating macrophage phenotype. Hum Mol Genet 2011; 20: 790–805.
Deasy BM, Qu-Peterson Z, Greenberger JS, Huard J . Mechanisms of muscle stem cell expansion with cytokines. Stem Cells 2002; 20: 50–60.
Charge SB, Rudnicki MA . Cellular and molecular regulation of muscle regeneration. Physiol Rev 2004; 84: 209–238.
Yang Q, Tang Y, Imbrogno K, Lu A, Proto JD, Chen A et al. AAV-based shRNA silencing of NF-kappaB ameliorates muscle pathologies in mdx mice. Gene Ther 2012; 19: 1196–1204.
Bell LN, Cai L, Johnstone BH, Traktuev DO, March KL, Considine RV et al. A central role for hepatocyte growth factor in adipose tissue angiogenesis. Am J Physiol Endocrinol Metab 2008; 294: E336–E344.
Paranjpe S, Bowen WC, Bell AW, Nejak-Bowen K, Luo JH, Michalopoulos GK et al. Cell cycle effects resulting from inhibition of hepatocyte growth factor and its receptor c-Met in regenerating rat livers by RNA interference. Hepatology 2007; 45: 1471–1477.
We thank Dr. Dennis Guttridge for the original gift of p65+/− mice. We also thank Drs. Xuequin Gao, Danushka Seneviratne, and Liang-I-Kang for helpful discussions and technical suggestions, as well as Nick Oyster, Jessica Tebbets, Michelle Witt and Seth Thompson for their technical assistance. This project was funded, in part, by a Department of Defense grant (W81XWH-09-1-0658) and an NIH grant (1PO1AG043376-01A1) (awarded to JH), and the Henry J Mankin Endowed Chair at the University of Pittsburgh.
JDP designed and performed experiments, collected and analyzed the data and wrote the manuscript; AL designed and performed experiments, analyzed data and edited the manuscript; WC designed, performed and analyzed experiments; YT contributed to experimental design, managed mouse breeding and generated the AAV vectors; ES designed, performed and analyzed experiments; MP assisted in performing experiments; SAB contributed to experimental design and analyzed data; PDR and LJN contributed to experimental design and data interpretation; KI and TH assisted in tissue sectioning and data collection; WM designed experiment, contributed to data interpretation and edited the manuscript.
The authors declare no conflict of interest.
Edited by S Lavandero
Supplementary Information accompanies this paper on Cell Death and Disease website
About this article
Cite this article
Proto, J., Tang, Y., Lu, A. et al. NF-κB inhibition reveals a novel role for HGF during skeletal muscle repair. Cell Death Dis 6, e1730 (2015). https://doi.org/10.1038/cddis.2015.66
Muscle Precursor Cells Enhance Functional Muscle Recovery and Show Synergistic Effects With Postinjury Treadmill Exercise in a Muscle Injury Model in Rats
The American Journal of Sports Medicine (2021)
Frontiers in Molecular Neuroscience (2020)
Cell and Tissue Research (2019)
Canonical NF-κB signaling regulates satellite stem cell homeostasis and function during regenerative myogenesis
Journal of Molecular Cell Biology (2019)