Ed on 14 mm frozen sections from 100 hpf Tg(cmlc2:DsRed2-nuc

Ed on 14 mm frozen sections from 100 hpf Tg(cmlc2:DsRed2-nuc

Ed on 14 mm frozen sections from 100 hpf Tg(cmlc2:DsRed2-nuc) zebrafish embedded in OCT (optimal cutting temperature, Tissue-Tek, Sakura) using the In situ cell death detection kit, POD (Roche) based on the manufacturer’s protocol. Images were analysed on IMARIS to model TUNEL+ cells which co-localise with Tg(cmlc2:DsRed2-nuc) cardiomyocytes.(p,0.05) was considered statistically significant. Statistical tests were conducted using a commercially available software package (SPSS Statistics 17.0).Results Morphologic and Molecular Profile of Zebrafish Heart FailureWe first characterised the concentration and time dependent cardiotoxic actions of AA in zebrafish. We found that there was a temporal and dose related (data not shown) effect of AA in inducing a heart failure phenotype marked by impaired altered cardiac morphology, pericardial oedema, and reduced contractility (Figure 1A and 1B). Arising from these preliminary studies we selected an AA exposure concentration of 2.5 mM for 3 hours duration from 72?5 hpf. Using this regimen, the HF phenotype developed in 37.5 of larvae exposed to AA by 168 hpf (p,0.001, n = 96), compared to controls in which no HF developed (Figure 1C). As shown in Figure 1D, AA exposure and HF development was associated with a mortality rate of 20.8 byStatistical AnalysisGroup data are presented as mean 6 standard error of the mean. Between-group comparisons were performed using an unpaired students t-test or ANOVA as appropriate. Kaplan-Meier survival curves were constructed to evaluate the mortality and heart failure incidence, and between group comparisons were performed using the Mantel-Cox log rank test. A p value of ,0.NGF Rescues Heart FailureFigure 4. NGF does not attenuate AA induced apoptosis. A. Bar graph represents absence of effect of NGF on caspase 3 mRNA expression in AA treated (72?5 hpf) zebrafish hearts at 96 hpf. B and C. Representative IMARIS images of cardiomyocyte TUNEL staining in control and AA treated zebrafish heart at 100 hpf. Scale bar = 50 mm. D. Bar graph showing quantitative analysis of TUNEL staining (n = 6 per group, * p,0.05 vs control). doi:10.1371/journal.pone.0053210.g168 hpf, compared with controls where none died (p,0.001, n = 96). In conjunction with the functional and morphologic assessment of this model of cardiotoxin mediated heart failure, we evaluated the cellular and molecular signature of this model of HF. Following exposure to AA (72?5 hpf), at 96 hpf there was a 62 increase (p,0.05, n = 6) in expression of caspase 3 mRNA in the heart (Figure 2A). This was accompanied by a progressive reduction in the total number of VRT-831509 cost cardiomyocytes (p,0.01, n = 5, Figure 2B) and there was a significant reduction in the frequencyof cardiomyocytes undergoing cell cycling as assessed by BrdU incorporation for 76?00 hpf (Figure 2C).NGF Rescues Zebrafish Heart FailureTo support our contention that reduced tissue NGF levels contribute to the pathogenesis of the response to cardiac injury and heart failure we evaluated the levels of NGF mRNA expression in AA treated zebrafish hearts. By order GSK1278863 RT-PCR we demonstrated a 42613 reduction in NGF mRNA in AA treated fish (n = 6 per group, p,0.05). Next, in order to determineNGF Rescues Heart FailureFigure 5. NGF stimulates CM proliferation following AA exposure. A. Bar graph showing the effect of NGF on cardiomyocyte proliferation. B . Representative IMARIS images of BrdU+ cardiomyocytes in the heart (76?00 hpf) from control (B), AA treated (C) and A.Ed on 14 mm frozen sections from 100 hpf Tg(cmlc2:DsRed2-nuc) zebrafish embedded in OCT (optimal cutting temperature, Tissue-Tek, Sakura) using the In situ cell death detection kit, POD (Roche) based on the manufacturer’s protocol. Images were analysed on IMARIS to model TUNEL+ cells which co-localise with Tg(cmlc2:DsRed2-nuc) cardiomyocytes.(p,0.05) was considered statistically significant. Statistical tests were conducted using a commercially available software package (SPSS Statistics 17.0).Results Morphologic and Molecular Profile of Zebrafish Heart FailureWe first characterised the concentration and time dependent cardiotoxic actions of AA in zebrafish. We found that there was a temporal and dose related (data not shown) effect of AA in inducing a heart failure phenotype marked by impaired altered cardiac morphology, pericardial oedema, and reduced contractility (Figure 1A and 1B). Arising from these preliminary studies we selected an AA exposure concentration of 2.5 mM for 3 hours duration from 72?5 hpf. Using this regimen, the HF phenotype developed in 37.5 of larvae exposed to AA by 168 hpf (p,0.001, n = 96), compared to controls in which no HF developed (Figure 1C). As shown in Figure 1D, AA exposure and HF development was associated with a mortality rate of 20.8 byStatistical AnalysisGroup data are presented as mean 6 standard error of the mean. Between-group comparisons were performed using an unpaired students t-test or ANOVA as appropriate. Kaplan-Meier survival curves were constructed to evaluate the mortality and heart failure incidence, and between group comparisons were performed using the Mantel-Cox log rank test. A p value of ,0.NGF Rescues Heart FailureFigure 4. NGF does not attenuate AA induced apoptosis. A. Bar graph represents absence of effect of NGF on caspase 3 mRNA expression in AA treated (72?5 hpf) zebrafish hearts at 96 hpf. B and C. Representative IMARIS images of cardiomyocyte TUNEL staining in control and AA treated zebrafish heart at 100 hpf. Scale bar = 50 mm. D. Bar graph showing quantitative analysis of TUNEL staining (n = 6 per group, * p,0.05 vs control). doi:10.1371/journal.pone.0053210.g168 hpf, compared with controls where none died (p,0.001, n = 96). In conjunction with the functional and morphologic assessment of this model of cardiotoxin mediated heart failure, we evaluated the cellular and molecular signature of this model of HF. Following exposure to AA (72?5 hpf), at 96 hpf there was a 62 increase (p,0.05, n = 6) in expression of caspase 3 mRNA in the heart (Figure 2A). This was accompanied by a progressive reduction in the total number of cardiomyocytes (p,0.01, n = 5, Figure 2B) and there was a significant reduction in the frequencyof cardiomyocytes undergoing cell cycling as assessed by BrdU incorporation for 76?00 hpf (Figure 2C).NGF Rescues Zebrafish Heart FailureTo support our contention that reduced tissue NGF levels contribute to the pathogenesis of the response to cardiac injury and heart failure we evaluated the levels of NGF mRNA expression in AA treated zebrafish hearts. By RT-PCR we demonstrated a 42613 reduction in NGF mRNA in AA treated fish (n = 6 per group, p,0.05). Next, in order to determineNGF Rescues Heart FailureFigure 5. NGF stimulates CM proliferation following AA exposure. A. Bar graph showing the effect of NGF on cardiomyocyte proliferation. B . Representative IMARIS images of BrdU+ cardiomyocytes in the heart (76?00 hpf) from control (B), AA treated (C) and A.

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