The role of the Grb2–p38 MAPK signaling pathway in cardiac hypertrophy and fibrosis (original) (raw)
Cardiac pressure overload promotes Grb2 association with FAK. Previous work demonstrated that Grb2 is expressed in heart tissue and isolated cardiomyocytes. In addition, Grb2 is recruited by activated FAK in response to mechanical stress in cultured rat neonatal cardiomyocytes or in intact isolated rat hearts (8, 14). We investigated the ability of pressure overload to promote the association of FAK with Grb2 in murine cardiac tissue. TAC was performed on 12-week-old wild-type Grb2+/+ mice, and ventricular tissue was isolated 7 days after the surgical procedure. Anti-FAK immunoprecipitates derived from ventricular protein lysates were analyzed by anti-Grb2 immunoblotting; this revealed that Grb2 formed a complex with FAK in Grb2+/+ ventricular tissue after TAC, but not after a sham operation (Figure 1a).
Biochemical characterization of Grb2 and MAPK in murine cardiac tissue 7 days after TAC or sham operation. (a) Load-induced formation of a Grb2-FAK complex. Anti-FAK immunoprecipitates (IP) derived from ventricular lysates were separated by SDS-PAGE and analyzed by immunoblotting with an anti-Grb2 antibody (lower panel). Anti-FAK immunoprecipitates were also analyzed in parallel by immunoblotting with an anti-FAK antibody (upper panel). (b) Reduced Grb2 protein content in Grb2+/– cardiac tissue. Upper panel, ventricular lysates were analyzed by immunoblotting with an anti-Grb2 antibody. Lower panel, quantification of Grb2 protein levels by densitometric analysis of immunoreactive bands. (c) Analysis of p38 MAPK activation in Grb2+/– cardiac tissue. Ventricular lysates were analyzed by immunoblotting with an anti-phospho–p38 MAPK antibody (upper panel). Lysates were also analyzed in parallel by immunoblotting with an anti–p38 MAPK (lower panel) antibody to control for protein content. (d) Analysis of JNK activation in Grb2+/– cardiac tissue. Lysates were analyzed by immunoblotting with an anti–phospho-JNK antibody (upper panel). Lysates were also analyzed in parallel by immunoblotting with an anti-JNK (lower panel) antibody to control for protein content. (e) Analysis of ERK activity in Grb2+/– cardiac tissue. Anti-ERK immunoprecipitates derived from ventricular lysates were analyzed by in vitro kinase assay by use of Elk-1 protein as a substrate. Anti-phospho–Elk-1 antibody immunoblotting was performed to assess ERK activity (upper panel). Lysates were also analyzed in parallel by immunoblotting with an anti-ERK (lower panel) antibody to control for protein content. Sham, sham operation.
Reduced cardiac Grb2 protein levels in haploinsufficient mice. To investigate the role of Grb2 in the cardiac hypertrophic growth program, Grb2+/– mice were analyzed. Grb2+/– mice in the 129/SvJ strain appear normal at birth and are fertile, and have normal cardiac structure and function at 12 weeks of age (20). Echocardiographic analysis of 12-week-old Grb2+/+ and Grb2+/– 129/SvJ mice revealed that Grb2 haploinsufficient mice have normal cardiac structure and intact ventricular systolic function, with a baseline LV fractional shortening of 51% ± 7%. There was no evidence of cardiac hypertrophy or of reduced cardiac wall thickness in Grb2+/– mice in the absence of pressure overload.
To determine whether disruption of one allele of the Grb2 gene resulted in reduced cardiac protein content, a series of immunoblot experiments were performed with cardiac cytosolic lysates. Anti-Grb2 immunoblotting of ventricular protein lysates demonstrated an approximately 40% reduction in Grb2 protein levels in Grb2+/– mice compared with Grb2+/+ mice (Figure 1b). This decrease in Grb2 protein levels is consistent with previously published observations in T cells (20). In addition to reduced cardiac Grb2 protein, pressure overload–induced Grb2/FAK complex formation was markedly decreased in cardiac tissue obtained from Grb2+/– mice after TAC (Figure 1a).
Analysis of MAPK cascade activation in Grb2+/– mice after TAC. In wild-type mice, multiple signaling cascades are activated in response to pressure overload induced by TAC. Grb2+/– mice were analyzed 7 days after TAC to determine whether there were defects in cardiac signal transduction. Grb2+/– mice tolerated TAC and had a survival rate of 92% after 7 days (12 of 13 animals). Ventricular cytosolic lysates obtained from animals 7 days after TAC were analyzed by immunoblotting using antibodies against both phospho-JNK and phospho–p38 MAPK. In both cases, parallel samples were analyzed by anti-JNK and anti-p38 MAPK immunoblotting to control for protein loading. Activation of p38 MAPK and JNK was markedly decreased after TAC in Grb2+/– mice compared with Grb2+/+ 129/SvJ mice (Figure 1, c and d). ERK activity in ventricular tissue samples was analyzed by in vitro kinase assay with recombinant Elk-1 protein used as a substrate. ERK activity increased in both Grb2+/+ and Grb2+/– mice after TAC. In some experiments, the fold increase in ERK activity was mildly reduced in Grb2+/– ventricular tissue (Figure 1e).
Hypertrophic response of Grb2+/– mice to TAC. In wild-type mice, prominent LV hypertrophy develops 7 days after TAC. Typically, there is a 25–30% increase in the ratio of LV weight to body weight (LVW/BW) in response to pressure overload. In Grb2+/+ 129/SvJ mice, LVW/BW increased by 31% 7 days after TAC, from 3.5 ± 0.5 mg/g to 4.6 ± 0.7 mg/g. In contrast, Grb2+/– mice were almost completely resistant to cardiac hypertrophy, and LVW/BW increased by only 5.7%, from 3.5 ± 0.3 to 3.7 ± 0.3 mg/g (Figure 2, a and b). Indeed, the difference in LVW/BW between Grb2+/– and Grb2+/+ mice after TAC was statistically significant by Student t test (P < 0.01). Echocardiographic analysis also demonstrated that Grb2+/– mice were resistant to TAC-induced cardiac hypertrophy. Echocardiographically determined LV mass to body weight ratio (LVM/BW) in Grb2+/+ mice increased by 39% 7 days after TAC, but increased by only 5.4% in Grb2+/– mice (Table 1). In addition, ventricular contractility was enhanced in Grb2+/– mice 7 days after TAC with a fractional shortening of 57%, compared with a fractional shortening of 48% in Grb2+/+ mice (Table 1). The failure of Grb2+/– mice to exhibit cardiac hypertrophy in response to TAC was not a result of less stringent aortic constriction. Proximal systolic aortic pressures increased from 142 ± 20 mmHg to 196 ± 6 mmHg in Grb2+/– mice, and increased from 132 ± 5 mmHg to 181 ± 12 mmHg in Grb2+/+ mice.
Reduced hypertrophic response to pressure overload in Grb2+/– mice. (a) Gross morphology of hearts from Grb2+/+ (left) and Grb2+/– (right) mice 7 days after TAC. (b) Morphometric analysis of cardiac hypertrophy in Grb2+/+ and Grb2+/– mice. Seven days after TAC or sham operation, cardiac chambers were dissected and weighed to determine LVW/BW (*P < 0.01 vs. sham-operated control).
In vivo echocardiographic assessment of Grb-2+/– mice
Histological analysis of LV tissue of Grb2+/– and Grb2+/+ mice was performed 7 days after TAC. Grb2+/+ animals exhibited typical myocyte enlargement, myofibrillar disarray, and fibrosis after TAC, whereas Grb2+/– animals had little or no fibrosis and relatively preserved myofibrillar architecture (Figure 3).
Histological analysis of Grb2+/+ and Grb2+/– LV tissue 7 days after TAC or sham operation. Ventricular tissue sections from (a) Grb2+/+ mouse, stained with H&E after sham operation; (b) Grb2+/+ mouse, stained with H&E after TAC; (c) Grb2+/– mouse, stained with H&E after sham operation; (d) Grb2+/– mouse, stained with H&E after TAC; (e) Grb2+/+ mouse, stained with Masson trichrome after sham operation; (f) Grb2+/+ mouse, stained with trichrome after TAC. Note the increased extracellular matrix content (blue color), cardiomyocyte enlargement, and disarray. (g) Ventricular tissue section from Grb2+/– mouse, stained with trichrome after sham operation. (h) Ventricular tissue section from Grb2+/– mouse, stained with trichrome after TAC. The original magnification was ×400 in all sections.
Gene expression in Grb2+/– mice after TAC. Pressure overload leads to a variety of alterations in cardiac gene expression. In particular, β-MHC and ANF gene expression is typically increased in cardiac tissue in response to pressure overload. We used real-time quantitative RT-PCR to assess the expression of hypertrophic marker genes in mice after TAC. In wild-type 129/SvJ but not Grb2+/– mice, β-MHC and ANF gene expression was markedly induced 7 days after TAC. Indeed, β-MHC gene expression increased by 23-fold and ANF gene expression increased by 18-fold in wild-type mice (Figure 4, a and b).
Inhibition of β-MHC and ANF gene expression in Grb2+/– cardiac tissue after pressure overload. Ventricular tissue was obtained 7 days after TAC or sham operation from Grb2+/+ and Grb2+/– mice, and RNA was purified from the tissue samples. Gene expression was analyzed by use of quantitative real-time RT-PCR with specific primers and probes. GAPDH was used as an internal control in all cases. (a) β-MHC gene expression in Grb2+/+ and Grb2+/– ventricular tissue. (b) ANF gene expression in Grb2+/+ and Grb2+/– ventricular tissue. AU, arbitrary units.
Transgenic mice with cardiac-specific expression of dominant negative p38α or p38β MAPK. Grb2+/– mice are resistant to the development of cardiac hypertrophy and fibrosis after TAC and have markedly attenuated p38 MAPK and JNK signaling. Previous work demonstrated that p38α MAPK is activated in cultured cardiomyocytes in response to hypertrophic agonist stimulation (28, 29). In one study, p38 MAPK, but not JNK, was found to be required for phenylephrine-induced cardiomyocyte hypertrophy (28). In addition, pressure overload in rodents is known to activate cardiac p38α MAPK activity (30). In contrast to work with isolated cultured cardiomyocytes, previous whole-animal work does not support the hypothesis that p38 MAPK activity promotes cardiomyocyte growth. Liao et al. recently generated transgenic mice with cardiac-specific expression of activated forms of MKK3bE or MKK6bE, kinases that act immediately upstream of p38α and p38β MAPK (31). MKK3bE and MKK6bE transgenic mice developed cardiac fibrosis, systolic and diastolic dysfunction, and marked fetal gene induction, but no cardiac hypertrophy (31).
To test whether Grb2-facilitated p38 MAPK activation is an essential regulator of cardiac hypertrophy, we analyzed transgenic mice with cardiac-specific expression of dominant negative mutants of p38α and p38β MAPK. In these mutants, the threonine-X-tyrosine (TXY) activation loop is altered as previously described (21, 22, 26). The α-MHC promoter was linked to cDNA’s encoding DN-p38α or DN-p38β, and transgenic mice in the Swiss Black strain were generated. Multiple lines were generated for each construct, and the highest-expressing lines were analyzed in this work. DN-p38α mice with integration of ten copies of the transgene and DN-p38β mice with integration of 15 copies of the transgene were viable and fertile. Expression of the dominant negative forms of p38 was robust in transgenic mice as determined by immunoblotting of ventricular cytosolic lysates with isoform-specific anti–p38 MAPK primary antibodies (Figure 5a).
Biochemical characterization of DN-p38α and DN-p38β transgenic mice. (a) Analysis of DN-p38α and DN-p38β MAPK protein levels in cardiac tissue from transgenic mice. Ventricular protein lysates obtained from DN-p38α mice, DN-p38β mice, and nontransgenic Swiss Black mice were separated by SDS-PAGE and examined by immunoblotting. Upper panel, isoform-specific anti–p38α MAPK immunoblot. Middle panel, isoform-specific anti–p38β MAPK immunoblot. Lower panel, anti-ERK immunoblot to control for protein loading. (b) Reduced p38α MAPK activity in DN-p38α transgenic mice. Ventricular protein lysates were generated 7 days after TAC or sham operation in DN-p38α transgenic mice or nontransgenic Swiss Black mice (NTG). Upper panel, anti-phospho–p38 MAPK immunoprecipitates were analyzed by isoform-specific anti–p38α MAPK immunoblotting. Middle panel, ventricular lysates were analyzed by anti-ERK immunoblotting to control for protein content. Lower panel, quantification of p38α MAPK protein levels in ventricular lysates by densitometric analysis of immunoreactive bands. Data are from three experiments. (c) Reduced p38β MAPK activity in DN-p38β transgenic mice. Upper panel, anti-phospho–p38 MAPK immunoprecipitates were analyzed by isoform-specific anti–p38β MAPK immunoblotting. Middle panel, ventricular lysates were analyzed by anti-ERK immunoblotting to control for protein content. Lower panel, quantification of p38β MAPK protein levels by densitometric analysis of immunoreactive bands. Data are from three experiments.
The ability of the dominant negative mutant forms of p38 MAPK to specifically inhibit native p38α or p38β kinase activity was analyzed. Cardiac p38α and p38β MAPK activity was analyzed by in vitro kinase assay following immunoprecipitation of phospho–p38 MAPK protein from ventricular lysates. DN-p38α transgenic mice exhibited reduced p38α MAPK activity and DN-p38β transgenic mice exhibited reduced p38β MAPK activity in ventricular cytosolic lysates (Figure 5, b and c).
Response of DN-p38α or DN-p38β transgenic mice to TAC. In response to TAC, 15 of 19 DN-p38α mice (79%), and 11 of 17 DN-p38β mice (65%) survived, and these rates were similar to those observed in nontransgenic littermates. Seven days after TAC, hearts were isolated and LVW/BW was calculated as a measure of cardiac hypertrophy. As expected, LVW/BW increased by 34% in nontransgenic Swiss Black mice, from 3.5 ± 0.2 to 4.7 ± 0.1 mg/g (P < 0.01). DN-p38α transgenic mice also developed cardiac hypertrophy after TAC (Figure 6). LVW/BW increased by 32% in DN-p38α mice, from 3.4 ± 0.1 to 4.5 ± 0.6 mg/g (P < 0.05). DN-p38β mice developed cardiac hypertrophy 7 days after TAC and LVW/BW increased by 51%, from 3.3 ± 0.5 to 5.0 ± 0.8 mg/g (P < 0.0001) (Figure 6). Echocardiographic analysis confirmed that DN-p38α and DN-p38β mice developed cardiac hypertrophy in response to pressure overload. Echocardiographically derived LVM/BW increased by 48% in nontransgenic mice, by 39% in DN-p38α mice, and by 61% in DN-p38β mice 7 days after TAC (Table 2).
Preserved hypertrophic response to pressure overload in DN-p38α and DN-p38β transgenic mice. Morphometric analysis of cardiac hypertrophy in DN-p38α mice, DN-p38β mice, and nontransgenic Swiss Black mice. Seven days after TAC or sham operation, cardiac chambers were dissected and weighed to determine LVW/BW.
In vivo echocardiographic assessment of DN-p38 mice
The ability of DN-p38α and DN-p38β mice to exhibit cardiac hypertrophy in response to TAC was not a result of more robust aortic constriction. Proximal systolic aortic pressures increased from 127 ± 16 to 157 ± 9 mmHg in nontransgenic mice, increased from 126 ± 9 to 162 ± 9 mmHg in DN-p38α mice, and increased from 129 ± 10 to 169 ± 3 mmHg in DN-p38β mice after TAC.
Recent work demonstrated that cardiac-specific expression of activated forms of MKK3bE or MKK6bE, kinases that act immediately upstream of p38 MAPK, resulted in a phenotype that was characterized by cardiac interstitial fibrosis, systolic contractile dysfunction, and induction of fetal marker genes (31). Surprisingly, these transgenic mice did not develop cardiac hypertrophy. To test whether DN-p38α and DN-p38β mice were resistant to the development of cardiac fibrosis 7 days after TAC, cardiac tissue was examined by trichrome staining. Both DN-p38α and DN-p38β animals exhibited typical myocyte enlargement with little or no fibrosis and relatively preserved myofibrillar architecture (Figure 7). These results contrasted with those of nontransgenic Swiss Black mice that exhibited marked fibrosis as well as myocyte enlargement after TAC. Therefore, DN-p38α and DN-p38β transgenic mice exhibited reduced cardiac fibrosis in response to pressure overload, despite the fact that they both developed cardiomyocyte hypertrophy.
Histological analysis of DN-p38α, DN-p38β, and nontransgenic LV tissue 7 days after TAC or sham operation. Ventricular tissue sections from (a) nontransgenic Swiss Black mouse, stained with H&E after sham operation; (b) nontransgenic Swiss Black mouse, stained with H&E after TAC; (c) DN-p38α transgenic mouse, stained with H&E after TAC; (d) DN-p38β transgenic mouse, stained with H&E after TAC; (e) nontransgenic Swiss Black mouse, stained with Masson trichrome after sham operation; (f) nontransgenic Swiss Black mouse, stained with trichrome after TAC. Note the increased extracellular matrix content (blue color), cardiomyocyte enlargement, and disarray. (g) Ventricular tissue section from DN-p38α transgenic mouse, stained with trichrome after TAC. (h) Ventricular tissue section from DN-p38β transgenic mouse, stained with trichrome after TAC. The original magnification was ×400 in all sections.
Gene expression analysis revealed that DN-p38α and DN-p38β mice were not resistant to TAC-induced alterations in cardiac gene expression. In response to TAC, cardiac ANF gene expression was robustly induced in nontransgenic Swiss Black, DN-p38α, and DN-p38β mice (Figure 8a). In addition, cardiac SERCA and MCAD gene expression was reduced in nontransgenic Swiss Black mice, DN-p38α mice, and DN-p38β mice after TAC (Figure 8, b and c).
Pressure overload–stimulated gene expression in DN-p38α and DN-p38β transgenic cardiac tissue and in nontransgenic Swiss Black cardiac tissue. Ventricular tissue was obtained 7 days after TAC or sham operation, and RNA was purified from the tissue samples. Gene expression was analyzed by use of quantitative real-time RT-PCR with specific primers and probes. GAPDH was used as an internal control in all cases. (a) ANF gene expression. (b) SERCA gene expression. (c) MCAD gene expression.