Donald Chapman

Alterations in sarcoplasmic reticulum function and gene expression in ischemic-reperfused rat heart.

In view of the critical role of sarcoplasmic reticular (SR) Ca(2+) release and the Ca(2+) pump in cardiac contraction-relaxation, this study was undertaken to assess the status of SR function, protein content, and gene expression in isolated rat hearts subjected to global ischemia for 30 min followed by 60 min of reperfusion (I/R). Attenuated recovery of contractile function in the I/R hearts was associated with reduced SR Ca(2+) uptake, Ca(2+) release, and ryanodine-binding activities. mRNA levels and protein contents for SR Ca(2+) pump ATPase and Ca(2+) release channels were markedly depressed in the I/R hearts. Perfusion of hearts with superoxide dismutase plus catalase, well-known scavengers of oxyradicals, prevented the I/R-induced alterations in cardiac function and partially prevented SR Ca(2+) transport activities and mRNA abundance. In hearts perfused with xanthine plus xanthine oxidase or H(2)O(2), changes similar to those in the I/R hearts were observed. These results indicate that oxyradicals may participate in depressing the SR Ca(2+) handling and gene expression in the I/R heart. It is suggested that treatment of hearts with antioxidants may improve the recovery of cardiac function by preserving the SR function and partially protecting the SR gene expression.In view of the critical role of sarcoplasmic reticular (SR) Ca2+ release and the Ca2+ pump in cardiac contraction-relaxation, this study was undertaken to assess the status of SR function, protein content, and gene expression in isolated rat hearts subjected to global ischemia for 30 min followed by 60 min of reperfusion (I/R). Attenuated recovery of contractile function in the I/R hearts was associated with reduced SR Ca2+ uptake, Ca2+ release, and ryanodine-binding activities. mRNA levels and protein contents for SR Ca2+ pump ATPase and Ca2+ release channels were markedly depressed in the I/R hearts. Perfusion of hearts with superoxide dismutase plus catalase, well-known scavengers of oxyradicals, prevented the I/R-induced alterations in cardiac function and partially prevented SR Ca2+transport activities and mRNA abundance. In hearts perfused with xanthine plus xanthine oxidase or H2O2, changes similar to those in the I/R hearts were observed. These results indicate that oxyradicals may participate in depressing the SR Ca2+ handling and gene expression in the I/R heart. It is suggested that treatment of hearts with antioxidants may improve the recovery of cardiac function by preserving the SR function and partially protecting the SR gene expression.

Partial prevention of changes in SR gene expression in congestive heart failure due to myocardial infarction by enalapril or losartan

Although activation of the renin-angiotensin system (RAS) is known to produce ventricular remodeling and congestive heart failure (CHF), its role in inducing changes in the sarcoplasmic reticulum (SR) protein and gene expression in CHF is not fully understood. In this study, CHF was induced in rats by ligation of the left coronary artery for 3 weeks and then the animals were treated orally with or without an angiotensin converting enzyme inhibitor, enalapril (10 mg/kg/day) or an angiotensin II receptor antagonist, losartan (20 mg/kg/day) for 4 weeks. Sham-operated animals were used as control. The animals were hemodynamically assessed and protein content as well as gene expression of SR Ca2+-release channel (ryanodine receptor, RYR), Ca2+-pump ATPase (SERCA2), phospholamban (PLB) and calsequestrin (CQS) were determined in the left ventricle (LV). The infarcted animals showed cardiac hypertrophy, lung congestion, depression in LV +dP/dt and −dP/dt, as well as increase in LV end diastolic pressure. Both protein content and mRNA levels for RYR, SERCA2 and PLB were decreased without any changes in CQS in the failing heart. These alterations in LV function as well as SR protein and gene expression in CHF were partially prevented by treatment with enalapril or losartan. The results suggest that partial improvement in LV function by enalapril and losartan treatments may be due to partial prevention of changes in SR protein and gene expression in CHF and that these effects may be due to blockade of the RAS.

Expression of Gi-2α and Gsα in myofibroblasts localized to the infarct scar in heart failure due to myocardial infarction

Objective: Patients surviving large transmural myocardial infarction (MI) are at risk for congestive heart failure with attendant alteration of ventricular geometry and scar remodeling. Altered Gi-2α and Gsα protein expression may be involved in cardiac remodeling associated with heart failure, however their expression in scar tissue remains unclear. Methods: MI was produced in Sprague–Dawley rats by ligation of the left coronary artery. Gi-2α and Gsα protein concentration, localization and mRNA abundance were noted in surviving left ventricle remote to the infarct, in border and in scar tissues from 8 week post-MI hearts with moderate heart failure. Results: We observed a 4.5- and 5.0-fold increase in immunoreactive Gi-2α protein concentration occurs in the border and scar regions vs. control values, respectively, in 8-week post-MI rat hearts. Similarly, immunoreactive Gsα protein concentration was increased 3.4- and 8.2-fold, respectively, in these tissues vs. controls. Double-fluorescence labeling and phenotyping studies revealed that both Gi-2α and Gsα proteins were localized to myofibroblasts in the infarct scar and to viable myocytes bordering the scar. Northern analysis revealed that the Gi-2α/GAPDH ratio was increased in both viable and scar regions (1.24- and 1.85-fold respectively) from experimental hearts when compared to sham-operated control values when compared to noninfarcted left ventricle, the value of this ratio in scar tissue was elevated ∼1.5 fold. The Gsα/GAPDH ratio was significantly increased (1.28-fold) only in the scar region vs. control. Conclusion: Our results indicate a marked increase in the expression of Gi-2α and Gsα from myofibroblasts of the infarct scar as well as remnant myocytes bordering the scar in 8-week post-MI rat hearts. We suggest that these changes may be associated with ongoing remodeling in the infarct scar in chronic post-MI phase of this experimental model.

Differential changes in cardiac myofibrillar and sarcoplasmic reticular gene expression in alloxan-induced diabetes.

In order to examine the relationship between heart dysfunction and subcellular abnormalities as well as molecular mechanisms during the development of diabetes, we studied changes in cardiac performance, myofibrillar as well as sarcoplasmic reticular (SR) activities, and cardiac gene expression at different time intervals upon inducing diabetes in rats by an injection of alloxan (65 mg/kg; i.v.). Cardiac dysfunction was associated with a depression in myofibrillar Ca2+-stimulated ATPase and changes in myosin isozyme composition at 2-12 weeks of inducing diabetes. A reduction in SR Ca2+-uptake and Ca2+-pump (SERCA2) activities was evident at 10 days to 12 weeks of inducing diabetes. Alterations in cardiac function during 2-12 weeks of diabetes show a linear relationship with changes in myofibrils and SR membranes. Furthermore, alterations in cardiac function as well as myofibrillar and SR activities in 4 week diabetic animals were normalized upon treatment with insulin for 4 weeks. The steady-state mRNA abundance for α-myosin heavy chain in the heart was decreased at 2 and 3 weeks but was unchanged at 5 and 6 weeks, whereas mRNA levels for β-myosin heavy chain remained elevated during 2-6 weeks after inducing diabetes. SERCA2 mRNA abundance in diabetic heart was significantly increased at 3 and 5 weeks but was unaltered at 2 and 6 weeks. These results support the view that heart dysfunction in diabetes may be a consequence of myofibrillar and SR abnormalities; however, defects in myofibrillar proteins, unlike those in the SR membranes, appear to be due to changes in their gene expression.

Mechanisms of lysophosphatidic acid-induced DNA synthesis in vascular smooth muscle cells.

In order to investigate the signal transduction mechanisms of lysophosphatidic acid (LPA)-induced vascular smooth muscle (VSM) DNA synthesis, rat aortic A10 cells were used as an experimental model and [3H]-thymidine incorporation was used as an index of DNA synthesis. LPA caused dose- and time-dependent increase in DNA synthesis in A10 VSM cells. LPA (10 &mgr;M) also stimulated the activity of casein kinase II (CKII) in a time-dependent manner. The inhibitors of CKII, daidzein and 5,6-dichlorobenzimidazole riboside, diminished the LPA-induced increase in CKII activity and DNA synthesis. The LPA-stimulated activities of extracellularly regulated kinases (ERK) and p38 kinases as well as the stimulatory effects of LPA on DNA synthesis were blocked by ERK inhibitor, PD98059, and p38 kinase inhibitor, SB203580. The LPA-induced increase in intracellular free Ca2+ and the LPA-induced DNA synthesis were not affected by Ca2+ channel blockers, verapamil and diltiazem, as well as a Ca2+-dependent protein phosphatase (calcineurin) inhibitor, cyclosporine A. These data suggest that the LPA-induced DNA synthesis in VSM cells may be mediated by a signal transduction mechanism involving CKII, ERK, and p38 K.

Ischemia–reperfusion alters gene expression of Na+–K+ ATPase isoforms in rat heart

The present study investigated whether oxidative stress plays a role in ischemia-reperfusion-induced changes in cardiac gene expression of Na(+)-K(+) ATPase isoforms. The levels of mRNA for Na(+)-K(+) ATPase isoforms were assessed in the isolated rat heart subjected to global ischemia (30 min) followed by reperfusion (60 min) in the presence or absence of superoxide dismutase (5 x 10(4)U/L) plus catalase (7.5 x 10(4)U/L), an antioxidant mixture. The levels of mRNA for the alpha(2), alpha(3), and beta(1) isoforms of Na(+)-K(+) ATPase were significantly reduced in the ischemia-reperfusion hearts, unlike the alpha(1) isoform. Pretreatment with superoxide dismutase+catalase preserved the ischemia-reperfusion-induced changes in alpha(2), alpha(3), and beta(1) isoform mRNA levels of the Na(+)-K(+) ATPase, whereas the alpha(1) mRNA levels were unaffected. In order to test if oxidative stress produced effects similar to those seen with ischemia-reperfusion, hearts were perfused with an oxidant, H(2)O(2) (300 microM), or a free radical generator, xanthine (2mM) plus xanthine oxidase (0.03 U/ml) for 20 min. Perfusion of hearts with H(2)O(2) or xanthine/xanthine oxidase depressed the alpha(2), alpha(3), and beta(1) isoform mRNA levels of the Na(+)-K(+) ATPase, but had lesser effects on alpha(1) mRNA levels. These results indicate that Na(+)-K(+) ATPase isoform gene expression is altered differentially in the ischemia-reperfusion hearts and that antioxidant treatment appears to attenuate these changes. It is suggested that alterations in Na(+)-K(+) ATPase isoform gene expression by ischemia-reperfusion may be mediated by oxidative stress.

Differential gene expression in infarct scar and viable myocardium from rat heart following coronary ligation

Post‐myocardial infarction (MI) remodeling of cardiac myocytes and the myocardial interstitium results in alteration of gross ventricular geometry and ventricular dysfunction. To investigate the mechanisms of the remodeling process of the heart after large MI, the expression of various genes in viable left ventricle and infarct scar tissue were examined at 16 weeks post‐MI. Steady‐state expression of Na+‐K+ATPase α‐1 and −2, phospholamban (PLB), α‐myosin heavy chain (α‐MHC), ryanodine receptor (Rya) and Ca2+ ATPase (Serca2) mRNAs were decreased in the infarct scar vs noninfarcted sham‐operated controls (P < 0.05). On the other hand, Giα2 and β‐MHC mRNAs were upregulated (P < 0.05, respectively) in the infarct scar whereas Na+‐K+ ATPase‐β, Na+‐Ca2+ exchanger and Gs mRNAs were not altered vs control values. In viable left ventricle, the a‐1 subunit of Na+‐K+ATPase, α‐3, β‐isoforms, Rya, β‐MHC, Giα2, Gs and Na+‐Ca2+ exchanger were significantly elevated while expression of the a‐2 subunit of Na+‐K+ ATPase, PLB and Serca2 were significantly decreased compared to controls. Expression of CK2α mRNA was elevated in noninfarcted heart (145 ± 15%) and diminished in the infarct scar (66 ± 13%) vs controls. Expression of β‐MHC mRNA was elevated in both viable and infarct scar tissues of experimental hearts (140 ± 31% and 183 ± 30% vs. controls, respectively). These results suggest that cardiac genes in the infarcted tissue and viable left ventricle following MI are differentially regulated.

Changes in the expression of cardiac Na+-K+ ATPase subunits in the UM-X7.1 cardiomyopathic hamster

Previous studies have shown that cardiac Na+ -K+ ATPase activity in the UM-X7.1 hamster strain is decreased at an early stage of genetic cardiomyopathy and remains depressed; however, the mechanism for this decrease is unknown. The objective of the present study was to assess whether changes in the expression of cardiac Na+-K+ ATPase subunits in control and UM-X7.1 cardiomyopathic hamsters are associated with alterations in the enzyme activity. Accordingly, we examined sarcolemmal Na+-K+ ATPase activity as well as protein content and mRNA levels for the alpha1, alpha2, alpha3 and beta1-subunit of the Na+-K+ ATPase in 250-day-old UM-X7.1 and age-matched, control Syrian hamsters; this age corresponds to the severe stage of heart failure in the UM-X7.1 hamster. Na+-K+ ATPase activity in UM-X7.1 hearts was decreased compared to controls (9.0 +/- 0.8 versus 5.6 +/- 0.8 micromol Pi/mg protein/hr). Western blot analysis revealed that the protein content of Na+-K+ ATPase alpha1- and beta1-subunits were increased to 164 +/- 27% and 146 +/- 22% in UM-X7.1 hearts respectively, whereas that of the alpha2- and alpha3-subunits were decreased to 82 +/- 5% and 69 +/- 11% of control values. The results of Northern blot analysis for mRNA levels were consistent with the protein levels; mRNA levels for the alpha1- and beta1-subunits in UM-X7.1 hearts were elevated to 165 +/- 14% and 151 +/- 10%, but the alpha2-subunit was decreased to 60 +/- 8% of the control value. We were unable to detect mRNA for the alpha3-subunit in either UM-X7. 1 or control hearts. These data suggest that the marked depression of Na+-K+ ATPase activity in UM-X7.1 cardiomyopathic hearts may be due to changes in the expression of subunits for this enzyme.

Modulation of cardiac sarcoplasmic reticulum gene expression by lack of oxygen and glucose

Although ischemia reperfusion has been shown to depress gene expression of the sarcoplasmic reticulum (SR) proteins, such as the ryanodine receptor, Ca2+‐pump ATPase, phospholamban, and calsequestrin in the heart, the mechanisms of these changes are not understood. Given the occurrence of hypoxia and the lack of glucose during the ischemic phase, we investigated the effects of these factors on the cardiac SR gene expression. Isolated rat hearts perfused in the absence of oxygen and/or glucose for 30 min showed an increase in the expression of SR genes. However, perfusion of hearts for 60 min with normal oxygenated medium after 30 min of lack of both oxygen and glucose depressed the transcript levels for the SR proteins; these changes did not occur when hearts were deprived of either oxygen or glucose. The effect of intracellular Ca2+‐overload, which occurs during reperfusion, was studied by using hearts perfused for 5 min with Ca2+‐free medium and then reperfused for 30 min. Ca2+‐depletion/repletion induced a dramatic decrease in the transcript levels of the SR genes. These results suggest that the lack of both oxygen and glucose during ischemia are necessary for reperfusion‐induced depression in SR gene expression, possibly due to the occurrence of intracellular Ca2+‐overload.

A conserved MADS-box phosphorylation motif regulates differentiation and mitochondrial function in skeletal, cardiac, and smooth muscle cells.

Exposure to metabolic disease during fetal development alters cellular differentiation and perturbs metabolic homeostasis, but the underlying molecular regulators of this phenomenon in muscle cells are not completely understood. To address this, we undertook a computational approach to identify cooperating partners of the myocyte enhancer factor-2 (MEF2) family of transcription factors, known regulators of muscle differentiation and metabolic function. We demonstrate that MEF2 and the serum response factor (SRF) collaboratively regulate the expression of numerous muscle-specific genes, including microRNA-133a (miR-133a). Using tandem mass spectrometry techniques, we identify a conserved phosphorylation motif within the MEF2 and SRF Mcm1 Agamous Deficiens SRF (MADS)-box that regulates miR-133a expression and mitochondrial function in response to a lipotoxic signal. Furthermore, reconstitution of MEF2 function by expression of a neutralizing mutation in this identified phosphorylation motif restores miR-133a expression and mitochondrial membrane potential during lipotoxicity. Mechanistically, we demonstrate that miR-133a regulates mitochondrial function through translational inhibition of a mitophagy and cell death modulating protein, called Nix. Finally, we show that rodents exposed to gestational diabetes during fetal development display muscle diacylglycerol accumulation, concurrent with insulin resistance, reduced miR-133a, and elevated Nix expression, as young adult rats. Given the diverse roles of miR-133a and Nix in regulating mitochondrial function, and proliferation in certain cancers, dysregulation of this genetic pathway may have broad implications involving insulin resistance, cardiovascular disease, and cancer biology.