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The technique of self absorption has been applied for the first time to study the decay pattern of low-lying dipole states of 140Ce. In particular, ground-state transition widths 0 and branching ratios 0/ to the ground state have been investigated in the energy domain of the pygmy dipole resonance. Relative self-absorption measurements allow for a model-independent determination of 0. Without the need to perform a full spectroscopy of all decay channels, also the branching ratio to the ground state can be determined. The experiment on 140Ce was conducted at the bremsstrahlung facility of the superconducting Darmstadt electron linear accelerator S-DALINAC. In total, the self-absorption and, thus, 0 were determined for 104 excited states of 140Ce. The obtained results are presented and discussed with respect to simulations of γ cascades using the DICEBOX code.
The decay properties of the Pygmy Dipole Resonance (PDR) have been investigated in the semi-magic N=82 nucleus 140Ce using a novel combination of nuclear resonance fluorescence and γ–γ coincidence techniques. Branching ratios for transitions to low-lying excited states are determined in a direct and model-independent way both for individual excited states and for excitation energy intervals. Comparison of the experimental results to microscopic calculations in the quasi-particle phonon model exhibits an excellent agreement, supporting the observation that the Pygmy Dipole Resonance couples to the ground state as well as to low-lying excited states. A 10% mixing of the PDR and the [21+ x PDR] is extracted.
The decay behavior of low-lying dipole states in 140Ce was investigated exploiting the γ3-setup at the HIγS facility using quasi-monochromatic photon beams. Branching ratios of individual excited states as well as average branching ratios to low-lying states have been extracted using γ – γ coincidence measurements. The comparison of the average branching ratios to QPM calculations shows a remarkable agreement between experiment and theory in the energy range from 5.0 to 8.5 MeV.
The electric dipole strength distribution in 130Te has been investigated using the method of Nuclear Resonance Fluorescence. The experiments were performed at the Darmstadt High Intensity Photon Setup using bremsstrahlung as photon source and at the High Intensity -Ray Source, where quasi-monochromatic and polarized photon beams are provided. Average decay properties of 130Te below the neutron separation energy are determined. Comparing the experimental data to the predictions of the statistical model indicate, that nuclear structure effects play an important role even at sufficiently high excitation energies. Preliminary results will be presented.
A series of photon scattering experiments has been performed on the double-beta decay partners 76Ge and 76Se, in order to investigate their dipole response up to the neutron separation threshold. Gamma-ray beams from bremsstrahlung at the S-DALINAC and from Compton-backscattering at HIGS have been used to measure absolute cross sections and parities of dipole excited states, respectively. The HIGS data allows for indirect measurement of averaged branching ratios, which leads to significant corrections in the observed excitation cross sections. Results are compared to statistical calculations, to test photon strength functions and the Axel-Brink hypothesis.
The method of relative self absorption is based on the technique of nuclear resonance fluorescence measurements. It allows for a model-independent determination of ground-state transition widths, natural level widths, and, consequently, of branching ratios to the ground state for individual excitations. Relative self–absorption experiments have been performed on the nuclei 6Li and 140Ce. In order to investigate the total level width for the 0+1, T = 1 level at 3563 keV in 6Li, a high-precision self-absorption measurement has been performed. In the case of 140Ce, self absorption has been applied for the first time to study decay widths of dipole-excited states in the energy regime of the pygmy dipole resonance.
We analysed our experimental recent findings of the dipole response of the odd-mass stable nucleus 205Tl within the quasi-particle phonon model. Using the phonon basis constructed for the neighbouring 204Hg and wave function configurations for 205Tl consisting of a mixture of quasiparticle ⊗ N-phonon configurations (N=0,1,2), only one group of fragmented dipole excited states has been reproduced at 5.5 MeV in comparison to the experimental distribution which shows a second group at about 5 MeV. The computed dipole transition strengths are mainly of E1 character which could be associated to the pygmy dipole resonance.
The role of the Ca2+-dependent protease calpain in the diabetes-associated platelet hyperreactivity
(2012)
Platelets from diabetic patients are characterised by hyperreactivity resulting in exaggerated adhesion, aggregation and thrombus formation which contribute to the development of cardiovascular complications known to be one of the main causes of diabetes-related mortality. One of the mechanisms suggested to be involved in the diabetes-related platelet hyperactivation is the increased [Ca2+]i which leads to the overactivation of Ca2+-dependent proteases, the calpains. Among the calpain isoforms expressed in platelets the two ubquitiously expressed μ- and m-calpain are thought to play an important role in physiological and pathophysiological processes. Particularly μ-calpain is known to be involved in many steps of physiological platelet activation such as aggregation, adhesion, secretion, and signalling. However, we could show that diabetes was associated with an enhanced activation of both μ- and m-calpain in platelets
In the first part of the study we focussed on the characterization of the molecular mechanism regulating calpain activity. Indeed, although Ca2+ is considered to be the main regulator of the proteolytic activity of the conventional calpains, other mechanisms such as the presence of phospholipids and phosphorylation have been reported to affect their activity. Since most studies reported the phosphorylation of m-calpain we were interested to see whether μ-calpain activity might be also affected by phosphorylation. We could show that the activity of μ-calpain was enhanced by the PKC activator PMA suggesting its possible regulation by phosphorylation. However, whether PKC directly targeted μ-calpain remains unclear. Given that substrate recognition is important for a protease to process its substrate and since no common consensus could be attributed to calpain substrates, our next interest was to understand the mechanism regulating the recognition of its substrates by calpain. Since phosphorylation has been reported to protect different proteins from calpain degradation we investigated whether the calpain substrate CD31 could be phosphorylated in platelets and whether this could affect its recognition by calpain. Although we could show that the tyrosine phosphorylation of CD31 was increased after activation of platelets by thrombin and that this effect was attenuated in platelets from diabetic patients, tyrosine phosphorylation of CD31 seemed to have no effect on its sensitivity to calpain-mediated proteolysis.
After the analysis of the mechanism regulating calpain activity as well as its interaction with its substrates, our next interest was the identification of new calpain substrates in platelets. Since a previous study from our group showed that PPARγ agonists could indirectly reverse the diabetes-associated calpain activation we performed DIGE analysis of platelet samples from diabetic patients before and after PPARγ agonist treatment. Using this approach we could identify four novel calpain substrates in platelets: Integrin-linked kinase (ILK), α parvin, CLP36 and septin-5. Next, we assessed the effect of calpain-mediated cleavage on the function of these newly identified proteins. We could show that μ-calpain was essential for the dissociation of ILK from the IPP complex and its activation while m-calpain-mediated cleavage led to its cleavage and inactivation. Functionally, we also showed that μ-calpain was involved in platelet adhesion while m-calpain was important for spreading.
The next protein we analysed was septin-5, a small GTPase known to regulate platelet degranulation by association with other septins and syntaxin-4. We found that the interaction between septin-5 and syntaxin-4 was inhibitory for platelet degranulation. We could demonstrate that the μ-calpain-mediated cleavage dissociated septin-5 from syntaxin 4 and led to increased secretion of platelet α-granules. Next, we investigated the in vivo role of calpain in the diabetes-associated platelet hyperreactivity. We induced diabetes in mice and could reproduce calpain activation in platelets such as that found in human. Indeed, calpain activation in murine platelets also led to the cleavage of several calpain substrates including ILK and septin-5. Moreover, platelets from diabetic mice demonstrated an increased aggregation and thrombus formation in vivo. Treatment of the animals with the calpain inhibitor A-705253 (30 mg/kg/day for 10 days) significantly restored platelet function and substrate cleavage. In conclusion, in this part of the study, we could show that the increased calpain-dependent α-granule secretion and platelet adhesion may account for the enhanced vascular proliferation and thrombus formation in diabetes and calpain inhibition represents a promising way to prevent atherothrombosis development.
In the last part of the study we analysed another enzyme known to play a crucial role in diabetes, the AMPK which is an energy-sensing kinase known to be impaired in diabetes. We could show that the two catalytic subunits AMPK α1 and α2 are expressed in platelets. The AMPKα2 seemed to be the subunit involved in platelet activation since AMPKα2-deficient mice demonstrated a defect in clot retraction and the stabilization of the thrombus while the animals showed a normal bleeding time. Mechanistically, we showed in platelets that the upstream kinase of AMPKα2 is LKB1 which was activated by thrombin stimulation via a PI-3K-dependent pathway. AMPKα2 then phosphorylated the Src-family kinase Fyn, which is responsible for the phosphorylation of its substrate β3 integrin on Tyr747. These data indicate that AMPKα2, by affecting Fyn phosphorylation and activity, plays a key role in platelet αIIbβ3 integrin signalling, leading to clot retraction and thrombus stability. Although the effect of diabetes in the AMPK-dependent pathway could not be investigated we assume that the dysregulation of this pathway may account for the thrombus destabilization and enhanced embolization encountered in diabetes.