Alzheimer's disease (AD) is characterized by senile plaques and neurodegeneration although the neurotoxic mechanisms have not been completely elucidated. It is clear that both oxidative stress and inflammation play an important role in the illness. The compound curcumin, with a broad spectrum of anti-oxidant, anti-inflammatory, and anti-fibrilogenic activities may represent a promising approach for preventing or treating AD. Curcumin is a small fluorescent compound that binds to amyloid deposits. In the present work we used in vivo multiphoton microscopy (MPM) to demonstrate that curcumin crosses the blood-brain barrier and labels senile plaques and cerebrovascular amyloid angiopathy (CAA) in APPswe/ PS1dE9 mice. Moreover, systemic treatment of mice with curcumin for 7 days clears and reduces existing plaques, as monitored with longitudinal imaging, suggesting a potent disaggregation effect. Curcumin also led to a limited, but significant reversal of structural changes in dystrophic dendrites, including abnormal curvature and dystrophy size. Together, these data suggest that curcumin reverses existing amyloid pathology and associated neurotoxicity in a mouse model of AD. This approach could lead to more effective clinical therapies for the prevention of oxidative stress, inflammation and neurotoxicity associated with AD.
We determined the crystal structure of 1TM-αVβ3, which represents the complete unconstrained ectodomain plus short C-terminal transmembrane stretches of the αV and β3 subunits. 1TM-αVβ3 is more compact and less active in solution when compared with ΔTM-αVβ3, which lacks the short C-terminal stretches. The structure reveals a bent conformation and defines the α–β interface between IE2 (EGF-like 2) and the thigh domains. Modifying this interface by site-directed mutagenesis leads to robust integrin activation. Fluorescent lifetime imaging microscopy of inactive full-length αVβ3 on live cells yields a donor–membrane acceptor distance, which is consistent with the bent conformation and does not change in the activated integrin. These data are the first direct demonstration of conformational coupling of the integrin leg and head domains, identify the IE2–thigh interface as a critical steric barrier in integrin activation, and suggest that inside-out activation in intact cells may involve conformational changes other than the postulated switch to a genu-linear state.
The Tg2576 transgenic mouse model of human cerebral amyloid angiopathy is characterized by age-dependent cerebrovascular deposition of amyloid-beta (Abeta) starting from 9 months of age and progressively worsening to involve most pial arterioles by 18 months; soluble Abeta levels are elevated long before vascular deposition takes place in this model. It has been suggested that elevated soluble Abeta levels alone are sufficient to impair cerebral blood flow (CBF) regulation thereby contributing to the early progression of Alzheimer's disease. Using laser speckle flowmetry through an intact skull, we studied the impact of elevated soluble Abeta levels and vascular Abeta deposition on a wide range of CBF responses to evaluate vasodilation and vasoconstriction in young or aged Tg2576 mice. Nineteen-month-old Tg2576 with severe vascular Abeta deposits showed an attenuated hyperaemic response during hypercapnia and whisker stimulation compared to wild-type littermates. The anticipated increase in CBF due to isoflurane anaesthesia was also suppressed, as were the typical hypoperfusion responses during cortical spreading depression and alpha-chloralose anaesthesia. The responses of 8-month-old Tg2576 with elevated soluble Abeta levels, but without vascular Abeta deposition, did not differ from age-matched controls. In conclusion, our data suggest that vascular Abeta deposition is associated with impaired vasodilator as well as vasoconstrictor responses to a wide range of stimuli. These responses do not differ from controls when studied non-invasively prior to vascular Abeta deposition, thus challenging the view that elevated soluble Abeta levels are sufficient to cause cerebrovascular dysfunction.
Cysteinyl leukotrienes (cys-LTs) induce inflammation through 2 G protein–coupled receptors (GPCRs), CysLT1 and CysLT2, which are coexpressed by most myeloid cells. Cys-LTs induce proliferation of mast cells (MCs), transactivate c-Kit, and phosphorylate extracellular signal-regulated kinase (ERK). Although MCs express CysLT2, their responses to cys-LTs are blocked by antagonists of CysLT1. We demonstrate that CysLT2 interacts with CysLT1, and that knockdown of CysLT2 increases CysLT1 surface expression and CysLT1-dependent proliferation of cord blood–derived human MCs (hMCs). Cys-LT–mediated responses were absent in MCs from mice lacking CysLT1 receptors, but enhanced by the absence of CysLT2 receptors. CysLT1 and CysLT2 receptors colocalized to the plasma membranes and nuclei of a human MC line, LAD2. Antibody-based fluorescent lifetime imaging microscopy confirmed complexes containing both receptors based on fluorescence energy transfer. Negative regulation of CysLT1-induced mitogenic signaling responses of MCs by CysLT2 demonstrates physiologically relevant functions for GPCR heterodimers on primary cells central to inflammation.
While accumulation of amyloid- (A) deposited as senile plaques is a hallmark feature of Alzheimer's disease (AD), the neurotoxicity of these deposits remains controversial. Recent in vitro studies suggested a link between elevated A and mitochondrial dysfunction that might contribute to the pathogenesis of AD. However, the in vivo evidence for mitochondria dysfunction caused by A is still missing. Using intravital multiphoton imaging with a range of fluorescent markers, we systematically surveyed mitochondrial structural and functional changes in AD mouse models. We observed severe impairments to be limited to the vicinity of A plaques, which included reduction of both numbers and membrane potential of mitochondria and the emergence of dystrophic and fragmented mitochondria. Both neuronal soma and neurites with oxidative stress show severe alterations in mitochondrial membrane potential in amyloid precursor protein mice. These results provide in vivo evidence revealing A plaques as focal sources of toxicity that lead to severe structural and functional abnormalities in mitochondria. These alterations may contribute to neuronal network dysfunction and warrant further investigation as possible targets for therapeutic intervention in AD.
Flow cytometric techniques are precious tools for investigating the activation of the humoral response against HLA antigens of the graft in renal transplantation. DS-Abs production has a worse impact on organ function and survival than ARj episodes. These findings represent further proof of the threat posed by DS-Abs on long-term graft function and draw attention to the need for a specific immunosuppressive therapy aimed at counteracting the different kinds of immune activation toward graft.
Cerebral amyloid angiopathy (CAA), characterized by extracellular β‐amyloid peptide (Aβ) deposits in vessel walls, is present in the majority of cases of Alzheimer’s disease and is a major cause of hemorrhagic stroke. Although the molecular pathways activated by vascular Aβ are poorly understood, extracellular matrix metalloproteinases (MMP) and Aβ‐induced oxidative stress appear to play important roles. We adapted fluorogenic assays for MMP activity and reactive oxygen species generation for use in vivo. Using multiphoton microcopy in APPswe/PS1dE9 and Tg‐2576 transgenic mice, we observed strong associations between MMP activation, oxidative stress, and CAA deposition in leptomeningeal vessels. Antioxidant treatment with α‐phenyl‐N‐tert‐butyl‐nitrone reduced oxidative stress associated with CAA (∼50% reduction) without affecting MMP activation. Conversely, a selection of agents that inhibit MMP by different mechanisms of action, including minocycline, simvastatin, and GM6001, reduced not only CAA‐associated MMP activation (∼30–40% reduction) but also oxidative stress (∼40% reduction). The inhibitors of MMP did not have direct antioxidant effects. Treatment of animals with α‐phenyl‐N‐tert‐butyl‐nitrone or minocycline did not have a significant effect on CAA progression rates. These data suggest a close association between Aβ‐related MMP activation and oxidative stress in vivo and raise the possibility that treatment with MMP inhibitors may have beneficial effects by indirectly reducing the oxidative stress associated with CAA.
The γ-secretase complex is a major therapeutic target for the prevention and treatment of Alzheimer's disease. Previous studies have shown that treatment of young APP mice with specific inhibitors of γ-secretase prevented formation of new plaques. It has not yet been shown directly whether existing plaques would be affected by γ-secretase inhibitor treatment. Similarly, alterations in neuronal morphology in the immediate vicinity of plaques represent a plaque-specific neurotoxic effect. Reversal of these alterations is an important endpoint of successful therapy whether or not a treatment affects plaque size. In the present study we used longitudinal imaging in vivo with multiphoton microscopy to study the effects of the orally active γ-secretase inhibitor LY-411575 in 10-11 month old APP:PS1 mice with established amyloid pathology and neuritic abnormalities. Neurons expressed YFP allowing fluorescent detection of morphology whereas plaques were labelled with methoxy-XO4. The same identified neurites and plaques were followed in weekly imaging sessions in living mice treated daily (5 mg/kg) for 3 weeks with the compound. Although LY-411575 reduced Aβ levels in plasma and brain, it did not have an effect on the size of existing plaques. There was also no effect on the abnormal neuritic curvature near plaques, or the dystrophies in very close proximity to senile plaques. Our results suggest that therapeutics aimed at inhibition of Aβ generation are less effective for reversal of existing plaques than for prevention of new plaque formation and have no effect on the plaque-mediated neuritic abnormalities, at least under these conditions where Aβ production is suppressed but not completely blocked. Therefore, a combination therapy of Aβ suppression with agents that increase clearance of amyloid and/or prevent neurotoxicity might be needed for a more effective treatment in patients with pre-existing pathology.
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