35 research outputs found

    Flavaglines Alleviate Doxorubicin Cardiotoxicity: Implication of Hsp27

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    Background: Despite its effectiveness in the treatment of various cancers, the use of doxorubicin is limited by a potentially fatal cardiomyopathy. Prevention of this cardiotoxicity remains a critical issue in clinical oncology. We hypothesized that flavaglines, a family of natural compounds that display potent neuroprotective effects, may also alleviate doxorubicininduced cardiotoxicity. Methodology/Principal Findings: Our in vitro data established that a pretreatment with flavaglines significantly increased viability of doxorubicin-injured H9c2 cardiomyocytes as demonstrated by annexin V, TUNEL and active caspase-3 assays. We demonstrated also that phosphorylation of the small heat shock protein Hsp27 is involved in the mechanism by which flavaglines display their cardioprotective effect. Furthermore, knocking-down Hsp27 in H9c2 cardiomyocytes completely reversed this cardioprotection. Administration of our lead compound (FL3) to mice attenuated cardiomyocyte apoptosis and cardiac fibrosis, as reflected by a 50 % decrease of mortality. Conclusions/Significance: These results suggest a prophylactic potential of flavaglines to prevent doxorubicin-induce

    Adrenaline-activated structure of ÎČ2-adrenoceptor stabilized by an engineered nanobody

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    G protein-coupled receptors (GPCRs) are integral membrane proteins that play an essential role in human physiology, yet the molecular processes through which they bind to their endogenous agonists and activate effector proteins remain poorly understood. Thus far, it has not been possible to capture an active-state GPCR bound to its native neurotransmitter. Crystal structures of agonist-bound GPCRs have relied on the use of either exceptionally high-affinity agonists(1,2) or receptor stabilization by mutagenesis(3-5). Many natural agonists such as adrenaline, which activates the ÎČ(2)-adrenoceptor (ÎČ(2)AR), bind with relatively low affinity, and they are often chemically unstable. Using directed evolution, we engineered a high-affinity camelid antibody fragment that stabilizes the active state of the ÎČ(2)AR, and used this to obtain crystal structures of the activated receptor bound to multiple ligands. Here, we present structures of active-state ÎČ(2)AR bound to three chemically distinct agonists: the ultra high-affinity agonist BI167107, the high-affinity catecholamine agonist hydroxybenzyl isoproterenol, and the low-affinity endogenous agonist adrenaline. The crystal structures reveal a highly conserved overall ligand recognition and activation mode despite diverse ligand chemical structures and affinities that range from 100 nM to ~80 pM. The adrenaline-bound receptor structure is overall similar to the others, but shows substantial rearrangements in extracellular loop three and the extracellular tip of transmembrane helix 6. These structures also reveal a water-mediated hydrogen bond between two conserved tyrosines, which appears to stabilize the active state of the ÎČ(2)AR and related GPCRs
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