Although the exact etiology of Alzheimer's disease (AD) is a topic of debate, the consensus is that the accumulation of -amyloid (A) peptides in the senile plaques is one of the hallmarks of the progression of the disease. The A peptide is formed by the amyloidogenic cleavage of the amyloid precursor protein (APP) by -and ␥-secretases. The endocytic system has been implicated in the cleavages leading to the formation of A. However, the identity of the intracellular compartment where the amyloidogenic secretases cleave and the mechanism by which the intracellularly generated A is released into the extracellular milieu are not clear. Here, we show that -cleavage occurs in early endosomes followed by routing of A to multivesicular bodies (MVBs) in HeLa and N2a cells. Subsequently, a minute fraction of A peptides can be secreted from the cells in association with exosomes, intraluminal vesicles of MVBs that are released into the extracellular space as a result of fusion of MVBs with the plasma membrane. Exosomal proteins were found to accumulate in the plaques of AD patient brains, suggesting a role in the pathogenesis of AD. multivesicular bodies ͉ rafts ͉ amyloid precursor protein ͉ -secretase ͉ endocytosis A lzheimer's disease (AD) is a late-onset neurological disorder with progressive loss of memory and cognitive abilities as a result of excessive neurodegeneration (1). AD is characterized by extracellular aggregates of -amyloid (A) peptides known as amyloid plaques (2). The A peptide is derived from the sequential processing of the amyloid precursor protein (APP) by -and ␥-secretases. -secretase [(-APP cleaving enzyme (BACE)] is a type-1 transmembrane aspartyl protease and is mainly localized to endosomes, lysosomes and the transGolgi network (3). ␥-Secretase is a multicomponent complex that is composed of presenilin-1͞presenilin-2, nicastrin, Aph-1, and PEN-2 (4) and is localized to the early secretory (5, 6) and the endocytic compartments (7,8). Nonamyloidogenic processing of APP involves ␣-secretase that cleaves APP inside the A region, giving rise to the ␣-cleaved ectodomain, thus precluding the formation of A (9). Hence, the availability of APP to either ␣-or -secretase determines whether A peptide will be generated. Lateral organization of membranes (10) and subcellular localization (11, 12) of the substrate and the secretases have been documented to regulate A generation. Recent work suggests that -secretase associates with lipid rafts, liquid-ordered domains in the membrane (13,14), and that integrity of raft domains is required for -cleavage of APP to occur (ref. 10; see, however, ref. 15). ␣-Cleavage, in contrast, occurs outside raft domains (10). The ␥-secretase complex is also raft-associated (16); hence, amyloidogenic processing of APP could occur in clustered raft domains to generate A (10). Inhibition of endocytosis reduces -cleavage but not ␣-cleavage, suggesting that -cleavage mainly occurs in endosomes (10,11,(17)(18)(19). Accumulation of A peptides in extracellular...
We have developed a model system in Caenorhabditis elegans to perform genetic and molecular analysis of peptidergic neurotransmission using green fluorescent protein (GFP)-tagged IDA-1. IDA-1 represents the nematode ortholog of the transmembrane proteins ICA512 and phogrin that are localized to dense core secretory vesicles (DCVs) of mammalian neuroendocrine tissues. IDA-1::GFP was expressed in a small subset of neurons and present in both axonal and dendritic extensions, where it was localized to small mobile vesicular elements that at the ultrastructural level corresponded to 50 nm electron-dense objects in the neuronal processes. The post-translational processing of IDA-1::GFP in transgenic worms was dependent on the neuropeptide proprotein convertase EGL-3, indicating that the protein was efficiently targeted to the peptidergic secretory pathway. Time-lapse epifluorescence microscopy of IDA-1::GFP revealed that DCVs moved in a saltatory and bidirectional manner. DCV velocity profiles exhibited multiple distinct peaks, suggesting the participation of multiple molecular motors with distinct properties. Differences between velocity profiles for axonal and dendritic processes furthermore suggested a polarized distribution of the molecular transport machinery. Study of a number of candidate mutants identified the kinesin UNC-104 (KIF1A) as the microtubule motor that is specifically responsible for anterograde axonal transport of DCVs at velocities of 1.6 mm/sÀ2.7 mm/s.
The closely related mammalian proteins IA-2 and phogrin are protein tyrosine phosphatase-like receptor proteins spanning the membrane of dense core vesicles of neuroendocrine tissues. They are of interest as molecular components of the secretory machinery and as major targets of autoimmunity in type I diabetes mellitus. The Caenorhabditis elegans genome has a single copy of an IA-2/phogrin homolog ida-1 III (islet cell diabetic autoantigen), which encodes the ida-1 (B0244.2) gene product as a series of 12 exons over a 10-kb region of chromosome III. The full-length sequence of the ida-1 cDNA encoded a 767-amino acid type 1 transmembrane protein of 87 kDa. The PTP catalytic site consensus sequence of IDA-1, like IA-2 and phogrin, diverged and would not be active. Expression of green fluorescent protein (GFP) under the ida-1 gene promoter showed activity in a subset of around 30 neurons with sensory functions and the uv1 cells of the vulva in hermaphrodites. Males showed additional expression in male-specific neurons. In situ experiments in rat brain showing the distribution of IA-2 and phogrin suggested a complimentary and overlapping pattern compared with the proprotein convertases PC1 and PC2. In C. elegans, IDA-1-expressing cells comprised a subset of those expressing the PC2 homolog KPC-2 (C51E3. 7), consistent with IDA-1 being a component of neuropeptide-containing dense core vesicles. The results support the hypothesis that C. elegans IDA-1 is the functional homolog of IA-2 and phogrin in mammals. Analysis of the function of IDA-1 should contribute to our understanding of the function of these proteins in signal transduction, vesicle locomotion, and exocytosis.
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