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Modulation of caspase activity regulates skeletal muscle regeneration and function in response to vasopressin and tumor necrosis factor

PLoS ONE (2009) 4(5)
DOI: 10.1371/journal.pone.0005570
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Abstract

Muscle homeostasis involves de novo myogenesis, as observed in conditions of acute or chronic muscle damage. Tumor Necrosis Factor (TNF) triggers skeletal muscle wasting in several pathological conditions and inhibits muscle regeneration. We show that intramuscular treatment with the myogenic factor Arg8-vasopressin (AVP) enhanced skeletal muscle regeneration and rescued the inhibitory effects of TNF on muscle regeneration. The functional analysis of regenerating muscle performance following TNF or AVP treatments revealed that these factors exerted opposite effects on muscle function. Principal component analysis showed that TNF and AVP mainly affect muscle tetanic force and fatigue. Importantly, AVP counteracted the effects of TNF on muscle function when delivered in combination with the latter. Muscle regeneration is, at least in part, regulated by caspase activation, and AVP abrogated TNF-dependent caspase activation. The contrasting effects of AVP and TNF in vivo are recapitulated in myogenic cell cultures, which express both PW1, a caspase activator, and Hsp70, a caspase inhibitor. We identified PW1 as a potential Hsp70 partner by screening for proteins interacting with PW1. Hsp70 and PW1 co-immunoprecipitated and co-localized in muscle cells. In vivo Hsp70 protein level was upregulated by AVP, and Hsp70 overexpression counteracted the TNF block of muscle regeneration. Our results show that AVP counteracts the effects of TNF through cross-talk at the Hsp70 level. Therefore, muscle regeneration, both in the absence and in the presence of cytokines may be enhanced by increasing Hsp70 expression. © 2009 Moresi et al.

Figures

  • Figure 1. TNF and AVP differentially regulate myogenic differentiation in vitro. A) The L6 cell line was induced to differentiate in the continuous presence of PBS (CTR), AVP, TNF, or TNF and AVP combined (TNF+AVP). Myosin (red) was immunostained to assess cell differentiation. Nuclei were detected with DAPI (blue). Scale bar = 100 micron. B) Quantitative analysis of myogenic differentiation (% FUSION) of L6 cells. ** = p,0.04 vs TNF; * = p,0.05 vs CTR, by Student’s t test. Data are the means6SEM of values from three independent experiments performed in triplicate. C) Myosin (MHC) and a-tubulin levels detected by western blot in cells treated as described above. TNF blocks whereas AVP promotes myogenic differentiation. In the presence of TNF, AVP rescues myogenic differentiation to the level of the control. Data are representative of three independent experiments. doi:10.1371/journal.pone.0005570.g001
  • Figure 2. Hsp70 and PW1 are coexpressed and colocalize in L6 cells. A) Immunofluorescence analysis of PW1 expression in L6 cells in growth medium (GM) and following 5 d of differentiation (DM). PW1 (green) displays nuclear and cytoplasmic localizations in both conditions. DAPI-stained nuclei are blue. Panels on the left represent a negative control incubated without primary Ab (No I Ab). Embedded in the panels is the mean percentage of PW1-expressing cells6SEM, resulting from three independent experiments performed in triplicate. Scale bar = 100 micron. B) Immunofluorescence analysis of Hsp70 (red) and PW1 (green) expression in L6 cells cultured in GM subjected or not subjected to heat shock treatment (HS), as described in the Materials and Methods. Nuclei were visualized by DAPI staining (blue). The lowest panels represent merged images. The panels on the left represent a negative control incubated without primary Ab (No I Ab). PW1 and Hsp70 are expressed in the same cells, both in basal conditions and following heat shock treatment, which upregulates Hsp70 expression. PW1 and Hsp70 colocalize in both the cell nucleus and cytoplasm. Data are representative of six independent experiments. Scale bar = 100 micron. C) Immunofluorescence analysis of PW1 expression in L6 cells overexpressing Hsp70. PW1 staining (green) was performed on cells transfected with an expression vector for Hsp70. Transfected cells were identified by coexpression of red fluorescent protein (RFP, red). Nuclei are counterstained with DAPI (blue) and tricolour, merged images are shown. All the possible combinations were observed, with cells expressing or not expressing PW1 in the presence of RFP and Hsp70 expression. The percentage of PW1 positive cells among the cells transfected with either pCDNA and RFP or Hsp70 and RFP was evaluated in 10 randomly chosen fields for each sample. Shown is the mean6SEM of three replicate experiments. Hsp70 and PW1 are both expressed in muscle cells and Hsp70 expression levels do not affect PW1 expression. doi:10.1371/journal.pone.0005570.g002
  • Figure 3. Hsp70 and PW1 physically associate. A) Co-immunoprecipitation of PW1 and Hsp70 in myogenic cells. Equal amounts of L6 whole cell extracts (E) were subjected to immunoprecipitation (IP) of endogenous PW1 or endogenous Hsp70 proteins using an anti-PW1 antibody or an anti-Hsp70 antibody, respectively. The presence of PW1 and Hsp70 was assessed by Western blot on whole cell extracts and on the immunoprecipitated products. B) Co-immunoprecipitation of Hsp70 and ectopically expressed PW1. HEK293 cells were transiently co-transfected with an expression vector containing the HA-tagged exon 9 region of PW1 (HA-PW1 EX9), a full-length PW1 construct (PW1 FL) or the empty vector (pcDNA), by the calcium phosphate method. 48 h after transfection, equal amounts of whole cell extract (500 mg) were subjected to immunoprecipitation of PW1 or Hsp70 as indicated, by using a mouse monoclonal antibody against HA tag or against Hsp70, or a polyclonal antibody against PW1 (IP). The pellets of the immunoprecipitation or an aliquot of the whole extract were analyzed by Western blot using an antiPW1 antibody. In C the reciprocal experiment is shown, where HEK293 cells were transiently co-transfected with an expression vector for HA-tagged PW1 (HA-PW1 EX9), or a full-length PW1 construct (PW1 FL). Cell extracts were subjected to immunoprecipitation of PW1 or Hsp70 as indicated, by
  • Figure 4. Hsp70 overexpression reduces TNF-mediated caspase activation. A) L6 cells were transfected with SNAP-GFP and an excess of Hsp70 expression vector or empty vector. Overexpression of Hsp70 was assessed by Western Blot analysis of cell lysates normalized for tubulin expression. The cells, transfected as indicated, were treated for 16 h with TNF, and floating and adherent cells (detached by trypsin) were pooled. B) Caspase activity (red) was detected with CaspGLOW while transfected cells were detected by the expression of SNAP-GFP (green). Puromycin-treated, apoptotic cells incubated or not incubated with CaspGLOW were used as a positive (Pos ctrl) and negative (Neg ctrl) control for the caspase assay, respectively. From left to right, the panels show phase contrast, green channel, red channel and merged images (the latter with increased contrast to highlight both signals). Only the apoptotic cell (arrowhead), characterized by a condensed nucleus, shows a bright fluorescence due to intense caspase activation. TNF-treated cells display a weaker fluorescence than apoptotic cells. C) The percentage of mock transfected cells that displayed caspase activity was evaluated by counting 10 randomly chosen fields in triplicate experiments. Shown is the mean6SEM of values from three independent experiments. Hsp70 overexpression reduces the percentage of cells displaying active caspases in the presence of TNF. doi:10.1371/journal.pone.0005570.g004
  • Figure 5. AVP counteracts TNF inhibition of muscle regeneration. A) WB analysis on extracts from adult (UNINJURED) and regenerating Tibialis anterior injected with PBS (C), AVP (A), , TNF (T) or TNF and AVP combined (T+A) and analyzed at 4.5 days following injury. The levels of Pax7 and desmin proteins were used as markers of satellite cell activation, while the levels of tubulin were the loading control. AVP increases satellite cell
  • Table 1. Functional analysis of skeletal muscle after one week of regeneration.
  • Figure 6. AVP counteracts TNF inhibition of muscle function. A) AVP and TNF differentially affect muscle performance. The Tibialis anterior muscle was subjected to freeze injury, injected with PBS (CTR), AVP, TNF, or TNF and AVP combined (TNF+AVP) 2 and 4 days later, and analyzed 1 week following injury. One week after injury, the TNF-treated muscle generates a tetanic force that is significantly lower than that achieved with all other treatments. Data obtained from 6,n,7, for each experimental condition, are shown as mean6SEM; * p,0.05 vs. CTR by Student’s t test. B) Principal Components Analysis (PCA) was performed using the multiple parameters from the functional data sets obtained both 1 and 2 weeks following injury, as described in the Materials and Methods. One example of a data set included in the PCA are the specific force recordings described in A. The centroids represent the mean values obtained from single measurements on the muscles of each of the 6 treatment groups (uninjured; CTRL 24 h; CTRL; AVP; TNF; AVP+TNF). The centroids were plotted in the bidimensional space defined by the 1st and 2nd principal component functions shown in Table 3. The differences in behaviour between the injured muscles and uninjured muscles vary significantly depending on the treatments: the TNF-treated muscle exhibits the greatest difference from uninjured muscle and is closest to freshly injured muscle (CTRL 24 h, i.e. a time gap that is not sufficient for functional recovery to occur), which indicates that TNF hampers functional recovery of damaged muscle, whereas AVP rescues this phenomenon. doi:10.1371/journal.pone.0005570.g006
  • Table 2. Functional analysis of skeletal muscles after two weeks of regeneration.

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Moresi, V., Garcia-Alvarez, G., Pristerà, A., Rizzuto, E., Albertini, M. C., Rocchi, M., … Coletti, D. (2009). Modulation of caspase activity regulates skeletal muscle regeneration and function in response to vasopressin and tumor necrosis factor. PLoS ONE, 4(5). https://doi.org/10.1371/journal.pone.0005570

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