Hartmut Lüss

A proteasome inhibitor confers cardioprotection

OBJECTIVE In several cell types, proteasome inhibitors like carbobenzoxyl-leucinyl-leucinyl-leucinal (MG132) induce the 72 kDa heat shock protein (Hsp72) and exert cell protective effects. However, data in cardiomyocytes are currently lacking. METHODS AND RESULTS We investigated the effects of MG132 in cultured neonatal rat cardiomyocytes. MG132 time- and concentration-dependently induced Hsp72 and Hsp32 at mRNA and protein levels. Although Hsp60 mRNA was induced, Hsp60 protein levels were not altered. MG132 activated p38 MAP kinase already after 0.5 h. Hsp mRNA induction started after 2 h of MG132 treatment. Subsequently, Hsp72 and Hsp32 protein levels were increased after 4 h. SB202190, an inhibitor of p38 MAP kinase, concentration-dependently attenuated MG132-induced Hsp72-and Hsp32-elevations (by 59% and 41%, respectively, at 1 microM SB202190). In contrast, herbimycin A, a known inductor of Hsp72 in cardiomyocytes, enhanced the MG132-induced Hsp72 and Hsp32 expression even further: additionally applied 2 microM herbimycin A induced Hsp72 and Hsp32 about 2-fold higher than 1 microM MG132 alone. MG132 (1 microM) decreased the hyperthermia- or hydrogen peroxide-induced release of lactate dehydrogenase by 45% and by 35%, respectively (P<0.05, n=5). MG132 (1 microM) prolonged the spontaneous beating time of cardiomyocytes at 46 degrees C from 5+/-2 min (control hyperthermia) to 28+/-5 min (P<0.05, n=4). Thus, inhibition of the proteasome function by MG132 protects cardiomyocytes against hyperthermic or oxidative injury. This protective effect and Hsp induction were abolished by 1 microM SB202190. CONCLUSION Proteasome inhibition results in p38 MAP kinase-dependent induction of Hsp72 and Hsp32 and might be a novel cardioprotective modality.

Regional expression of phospholamban in the human heart.

BACKGROUND Several independent lines of evidence indicate that phospholamban (PLB) expression correlates positively with depression of force of contraction and duration of contraction in isolated cardiac preparations of several animal species. Here, we studied whether PLB levels correlate with attenuation of contractility and enhancement of contractile time parameters in different parts of the human heart. METHODS Force of contraction was measured in isolated electrically driven atrial and ventricular preparations from human hearts. Ca(2+)-uptake by human atrial and ventricular homogenates was assayed at different ionized Ca(2+)-concentrations. Protein expression of PLB and the sarcoplasmic Ca(2+)-ATPase (SERCA) was measured in homogenates by quantitative immunoblotting using specific antibodies. PLB mRNA expression was quantified in human cardiac preparations by Northern blot analysis. RESULTS The duration of contraction in isolated preparations of human right ventricle (RV) was double that found in right atrial preparations (RA) (620 +/- 25 ms versus 308 +/- 15 ms). In RA, PLB expression was reduced by 44% at the protein level and by 34% at the mRNA level compared to RV. In contrast, the SERCA protein content was increased by 104% in RA compared to RV. Ca(2+)-uptake at low ionized Ca(2+)-concentration, where the inhibiting effect of PLB is maximal, amounted to 1.39 +/- 0.28 nmol Ca2+/mg protein in RA and to 0.62 +/- 0.09 nmol Ca2+/mg protein in RV (n = 6 both). CONCLUSIONS It is suggested that duration of contraction is shorter in human atrium versus ventricle due to the combined effect of decreased PLB levels (which inhibits SERCA function) and increased SERCA levels. The lower relative ratio of PLB to SERCA leads to less inhibition of SERCA and increased Ca(2+)-uptake which enhances relaxation and contraction in human atrium.

Enhanced protein phosphorylation in hypertensive hypertrophy.

OBJECTIVE Chronic pressure overload in spontaneously hypertensive rats (SHR) is accompanied by heart hypertrophy and signs of heart failure. Since there is growing evidence for a possible pathophysiological role of altered protein phosphorylation in heart hypertrophy and failure, we studied here cardiac regulatory phosphoproteins and the kinases and phosphatases which regulate their phosphorylation state. METHODS The experiments were performed in ventricles of SHR (12-13 weeks old) and age-matched normotensive Wistar-Kyoto rats (WKY). RESULTS Basal as well as isoproterenol (Iso)-stimulated force of contraction (FOC) was markedly decreased in isolated electrically driven papillary muscles of SHR. Iso (3 micromol/l, 10 min) increased FOC by 0.91+/-0.20 mN in SHR and by 3.88+/-0.52 mN in WKY, respectively. Ca(2+)-uptake by sarcoplasmic reticulum (SR) at low ionized Ca(2+)-concentration was increased in homogenates from SHR. This was not due to altered expression of phospholamban (PLB), SR-Ca(2+)-ATPase and calsequestrin. However, PLB-phosphorylation at threonine-17 (PLB-PT-17) and the activity of Ca(2+)/calmodulin dependent protein kinase (Ca(2+)/Cam-PK) was increased in SHR. In addition, we found an enhanced protein kinase A (PKA)-dependent phosphorylation of the inhibitory subunit of troponin (TnI). In contrast, there was no difference in the activity or expression (protein- and mRNA-level) of protein phosphatases type 1 or type 2A between SHR and WKY. CONCLUSIONS It is suggested that increased Ca(2+)/Cam-PK-activity with resulting increase of PLB-PT-17 enhanced SR-Ca(2+)-uptake in SHR and might contribute to the pathophysiological changes in cardiac hypertrophy of SHR.

Postnatal changes in contractile time parameters, calcium regulatory proteins, and phosphatases

Compared with isolated electrically driven neonatal ventricular preparations, the total time of contraction, the time to peak tension, and the time of relaxation were decreased to ∼50% in adult ventricular preparations. The expression of sarco(endo)plasmic reticulum Ca2+-ATPase (SERCA) was increased to 133% at the protein level and to 154% at the mRNA level in adult vs. neonatal ventricular preparations, whereas phospholamban was unchanged at both the protein and mRNA levels. Moreover, Ca2+ uptake was increased to 180% in adult vs. neonatal ventricular preparations. Phospholamban phosphorylation was enhanced in adult vs. neonatal ventricular preparations. In adult ventricular preparations, phosphatase activity was reduced to 53% of neonatal preparations, the protein levels of the immunologically detectable catalytic subunits of protein phosphatase types 1 and 2A were reduced to 28 and 61% of neonatal preparations, respectively, and the mRNA levels of type 1α, 1β, 1γ, 2Aα, and 2Aβ phosphatase isoforms were decreased to 69, 68, 54, 67, and 63%, respectively. We conclude that in the adult rat heart, the shortened time parameters of contraction can be explained by an elevated expression of SERCA. In addition, an increased phosphorylation state of phospholamban due to reduced phosphatase activity may be involved.Compared with isolated electrically driven neonatal ventricular preparations, the total time of contraction, the time to peak tension, and the time of relaxation were decreased to approximately 50% in adult ventricular preparations. The expression of sarco(endo)plasmic reticulum Ca2+-ATPase (SERCA) was increased to 133% at the protein level and to 154% at the mRNA level in adult vs. neonatal ventricular preparations, whereas phospholamban was unchanged at both the protein and mRNA levels. Moreover, Ca2+ uptake was increased to 180% in adult vs. neonatal ventricular preparations. Phospholamban phosphorylation was enhanced in adult vs. neonatal ventricular preparations. In adult ventricular preparations, phosphatase activity was reduced to 53% of neonatal preparations, the protein levels of the immunologically detectable catalytic subunits of protein phosphatase types 1 and 2A were reduced to 28 and 61% of neonatal preparations, respectively, and the mRNA levels of type 1alpha, 1beta, 1gamma, 2Aalpha, and 2Abeta phosphatase isoforms were decreased to 69, 68, 54, 67, and 63%, respectively. We conclude that in the adult rat heart, the shortened time parameters of contraction can be explained by an elevated expression of SERCA. In addition, an increased phosphorylation state of phospholamban due to reduced phosphatase activity may be involved.

Expression of calcium regulatory proteins in short-term hibernation and stunning in the in situ porcine heart

BACKGROUND Myocardial hibernation and stunning are characterised by a reversible contractile dysfunction during and after ischaemia, respectively. Calcium homeostasis might be disturbed in hibernation and stunning due to altered expression of cardiac proteins involved in calcium handling. METHODS In enflurane-anaesthetised swine the coronary blood flow through the left anterior descending coronary artery was decreased to reduce regional contractile function (microsonometry) by approximately 50%. In transmural biopsies obtained during ischaemia and reperfusion creatine phosphate as well as the expression of sarcoplasmic reticulum calcium ATPase (SERCA), phospholamban (PLB), calsequestrin (CSQ), and troponin inhibitor (TnI) were determined. RESULTS During ischaemia creatine phosphate, after an initial reduction, recovered back to control values, and necrosis was absent (hibernation). After 90 min of ischaemia the myocardium was reperfused for 120 min but regional contractile function continued to be depressed (stunning). PLB, SERCA, CSQ, and TnI proteins were unchanged during ischaemia as well as reperfusion. Likewise, levels of PLB and SERCA mRNAs were unchanged. CONCLUSION It is concluded that other mechanisms than altered expression of these regulating proteins underlie the contractile dysfunction observed during acute ischaemia, short-term hibernation and stunning.

Activation and inactivation of cAMP-response element-mediated gene transcription in cardiac myocytes

OBJECTIVE Chronic beta-adrenergic stimulation of the cAMP-dependent signalling pathway is implicated in functionally relevant expressional changes in congestive heart failure. We studied activation and inactivation of the cardiac gene transcription mediated by the cAMP-response element (CRE) and the CRE-binding protein (CREB) as an important mechanism of a cAMP-dependent gene regulation. METHODS We investigated the transcriptional activation by forskolin, an activator of the adenylyl cyclase, in chick embryonic cardiomyocytes transfected with a CRE-controlled luciferase construct in comparison to the phosphorylation and expression of CREB determined on immunoblots. RESULTS Forskolin (10 micromol/l; 8 h) increased CRE-mediated transcription and phosphorylation of CREB 13- and 1.5-fold, respectively. The phosphorylation was further elevated in combination with cantharidin, an inhibitor of type 1+2A protein phosphatases. The transcriptional response to forskolin was desensitized by pretreatment with forskolin (1 micromol/l; 24 h) while CREB phosphorylation was increased. In forskolin-pretreated cells, total CREB protein levels were decreased. Cantharidin did not restore the attenuated transcriptional response. CONCLUSIONS In cardiomyocytes, there is an activation of the CRE-mediated gene transcription by forskolin that is attenuated after prolonged stimulation, and this attenuation is not dependent from a dephosphorylation of CREB. We suggest that attenuation of the CRE-mediated transcription through chronic stimulation of the cAMP-pathway, e.g. by elevated catecholamines, contributes to the altered expressional regulation in congestive heart failure.

Contractility and inhibition of protein phosphatases by cantharidin

1. Cantharidin is a natural defensive toxicant produced by blister beetles. 2. Cantharidin shares structural similarity with highly toxic commercial herbicides (e.g., endothall, endothall anhydride and endothall thioanhydride). 3. Cantharidin inhibits the activity of purified catalytic subunits of serine/threonine protein phosphatases (PP) type 1 and type 2A. 4. Cantharidin increases force of contraction in isolated myocardial and vascular preparations. 5. Cantharidin enhances the phosphorylation state of myocardial and vascular regulatory proteins. 6. Cantharidin is a valuable tool for studying the function of PP in regulatory phosphorylation-dephosphorylation events.

The mechanism of action of cantharidin in smooth muscle

1 The aim of this study was to investigate the mechanism(s) of the vasoconstrictor effect of cantharidin in bovine preparations. 2 Catalytic subunits of protein phosphatase type 1 (PP 1) and type 2A (PP 2A) were immunologically identified in coronary arteries, isolated smooth muscle cells and ventricular myocardium. 3 The mRNAs coding for catalytic subunits of PP 1α, PP 1β and PP 2Aα were identified by hybridization with specific cDNA‐probes in total RNA from coronary arteries, isolated smooth muscle cells and ventricles. 4 The activities of catalytic subunits of PP 1 and PP 2A separated by column chromatography from coronary arteries, isolated smooth muscle cells and ventricles were inhibited by cantharidin in a concentration‐dependent manner. 5 Cantharidin increased the phosphorylation state of smooth muscle proteins including the regulatory light chains of myosin in 32P‐labelled intact smooth muscle cells in a concentration‐dependent manner. 6 Cantharidin did not affect cytosolic calcium concentrations in aortic smooth muscle cells. 7 It is suggested that cantharidin contracts smooth muscle preparations by increasing the phosphorylation state of regulatory proteins due to inhibition of phosphatase activities. Thus, cantharidin might be a useful tool to study the function of phosphatases in smooth muscle.

Functional studies in atrium overexpressing A1-adenosine receptors

Adenosine and the A1‐adenosine receptor agonist R‐PIA, exerted a negative inotropic effect in isolated, electrically driven left atria of wild‐type mice. In left atria of mice overexpressing the A1‐adenosine receptor, adenosine and R‐PIA exerted a positive inotropic effect. The positive inotropic effect of adenosine and R‐PIA in transgenic atria could be blocked by the A1‐adenosine receptor antagonist DPCPX. In the presence of isoprenaline, adenosine exerted a negative inotropic effect in wild‐type atria but a positive inotropic effect in atria from A1‐adenosine receptor overexpressing mice. The rate of beating in right atria was lower in mice overexpressing A1‐adenosine receptors compared with wild‐type. Adenosine exerted comparable negative chronotropic effects in right atria from both A1‐adenosine receptor overexpressing and wild‐type mice. A1‐adenosine receptor overexpression in the mouse heart can reverse the inotropic but not the chronotropic effects of adenosine, implying different receptor‐effector coupling mechanisms.

Ischemic preconditioning by unstable angina reduces the release of CK-MB following CABG and stimulates left ventricular HSP-72 protein expression.

Abstract  Background and Aim: Whether the CK‐MB reducing effect of ischemic preconditioning (IP) by unstable angina within 24 to 48 hours before CABG is achieved by early or by delayed preconditioning of left ventricular myocardium in humans is unknown. We investigated whether IP is associated with phosphorylation of p38 MAPK (characteristic for early preconditioning) or with increased protein expression of HSP‐72 (characteristic for delayed preconditioning) at the time of CABG in patients. Methods: Nineteen patients were grouped according to the occurrence of ischemic episodes within 48 hours before CABG. The patients without angina were assigned to the control group (CON, n = 10) whereas patients who had experienced angina within 48 hours before CABG were assigned to the preconditioned group (IP, n = 9). The effect of IP on the CABG induced maximal release of creatine kinase (CK) and CK‐MB was examined. Left ventricular biopsy specimens taken immediately before cross clamping from ischemic (ISCH) and from reference (REF) areas were processed to analyze p38 MAPK phosphorylation and HSP‐72‐protein expression. Results: While IP significantly reduced CK‐MB (18.7 ± 1.3 vs. 13.8 ± 1.5 U/L, mean ± SEM, p < 0.05), it only tended to reduce CK (292.7 ± 32.8 vs. 274.1±31.1 U/L, p = NS, mean ± SEM). CK‐MB release for any given cross‐clamp time was significantly reduced by IP (regression lines: CON, y= 0.4x+ 2, r= 0.8; IP, y= 0.1x+ 10, r= 0.2; p < 0.01, ANCOVA). There was no effect of IP on left ventricular p38 MAPK phosphorylation. IP increased left ventricular HSP‐72‐protein expression in ischemic areas when compared to reference areas (1.78 ± 0.35 vs. 2.58 ± 0.65, REF vs. ISCH, PhosphorImager units ×106, mean ± SEM, p < 0.05, ANCOVA). Conclusions: Thus, in the human left ventricular myocardium there is a second window of protection lasting for at least 48 hours, while at that time the early phase of preconditioning has already gone.