We quantified the amount of amyloid -peptide (A) immunoreactivity as well as amyloid deposits in a large cohort of transgenic mice overexpressing the V717F human amyloid precursor protein (APP V717F؉/؊ TG mice) with no, one, or two mouse apolipoprotein E (Apoe) alleles at various ages. Remarkably, no amyloid deposits were found in any brain region of APP V717F؉/؊ Apoe ؊/؊ TG mice as old as 22 mo of age, whereas age-matched APP V717F ؉/؊ Apoe ؉/؊ and Apoe ؉/؉ TG mice display abundant amyloid deposition. The amount of A immunoreactivity in the hippocampus was also markedly reduced in an Apoe gene dose-dependent manner (Apoe ؉/؉ > Apoe ؉/؊ Ͼ Ͼ Apoe ؊/؊ ), and no A immunoreactivity was detected in the cerebral cortex of APP V717F؉/؊ Apoe ؊/؊ TG mice at any of the time points examined. The absence of apolipoprotein E protein (apoE) dramatically reduced the amount of both A1-40 and A1-42 immunoreactive deposits as well as the resulting astrogliosis and microgliosis normally observed in APP V717F TG mice. ApoE immunoreactivity was detected in a subset of A immunoreactive deposits and in virtually all thioflavine-Sfluorescent amyloid deposits. Because the absence of apoE alters neither the transcription or translation of the APP V717F transgene nor its processing to A peptide(s), we postulate that apoE promotes both the deposition and fibrillization of A, ultimately affecting clearance of protease-resistant A/apoE aggregates. ApoE appears to play an essential role in amyloid deposition in brain, one of the neuropathological hallmarks of Alzheimer's disease.
Matrix metalloproteinase-3 (MMP-3) degrades components of the extracellular matrix and may participate in the pathogenesis of stroke. Here we examine the expression, activation, and cellular location of MMP-3 and the cleavage of agrin, an MMP-3 substrate, following transient middle cerebral artery occlusion in the rat. MMP-3 was activated by ischemia/reperfusion, which was revealed by the appearance of a cleaved form and increased degradation of a substrate. MMP-3 was observed in ischemic neurons, oligodendrocytes, microvasculature, and reactive microglia/macrophages. In cell cultures, MMP-3 expression was observed in neurons and, to a lesser extent, in mature oligodendrocytes, but not in oligodendrocyte progenitors, astrocytes, or microglia. Casein zymography revealed MMP-3 in cultured neurons. Agrin was expressed in cultured neurons and cultured astrocytes. In brain tissue, agrin was detected in neurons, and following ischemia it was also detected in reactive astrocytes. Addition of MMP-3 to protein extracts from control brain caused neuronal agrin degradation. Following ischemia/reperfusion, agrin disappeared from the tissue membrane fraction and a cleaved agrin fragment was found in tissue protein extracts. The present results show MMP-3 activation and neuronal transmembrane agrin cleavage after ischemia/reperfusion. In addition, the finding that MMP-3 cleaves brain agrin strongly suggests that ischemia-induced MMP-3 activation causes agrin cleavage.
Disconnection of the axon from the soma of spinal motoneurons (MNs) leads either to a retrograde degenerative process or to a regenerative reaction, depending on the severity and the proximity to the soma of the axonal lesion. The endoplasmic reticulum (ER) is a continuous membranous network that extends from the nucleus to the entire cytoplasm of the neuronal soma, axon and dendrites. We investigated whether axonal injury is sensed by the ER and triggers the activation of protective mechanisms, such as the unfolded protein response (UPR) and autophagy. We found early (at 3 days) accumulation of beclin1, LC3II and Lamp-1, hallmarks of autophagy, in both degenerating MNs after spinal root avulsion and in non-degenerating MNs after distal nerve section, although Lamp-1 disappeared by 5 days only in the former. In contrast, only degenerating MNs presented early activation of IRE1a, revealed by an increase of the spliced isoform of Xbp1 and accumulation of ATF4 in their nucleus, two branches of the UPR, and late BiP downregulation in association with cytoskeletal and organelle disorganization. We conclude that BiP decrease is a signature of the degenerating process, as its overexpression led to an increase in MN survival after root avulsion. Besides, Bcl2 is strongly implicated in the survival pathway activated by BiP overexpression.
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