Aβ42 is known to be a primary amyloidogenic and pathogenic agent in Alzheimer's disease. However, the role of Aβ43, found just as frequently in patient brains, remains unresolved. We generated knockin mice containing a pathogenic presenilin-1 R278I mutation that causes overproduction of Aβ43. Homozygous mice exhibited embryonic lethality, indicating that the mutation involves loss of function. Crossing amyloid precursor protein transgenic mice with heterozygous mutant mice resulted in elevation of Aβ43 levels, impairment of short-term memory, and acceleration of Aβ pathology, accompanying pronounced accumulation of Aβ43 in plaque cores similar to the biochemical composition observed in patient brains. Consistently, Aβ43 showed a higher propensity to aggregate and was more neurotoxic than Aȕ42. Other pathogenic presenilin mutations also caused overproduction of Aβ43 in a manner correlating with Aβ42 and with age of disease onset. These findings indicate that Aβ43, an overlooked species, is potently amyloidogenic, neurotoxic, and abundant in vivo. 3 Alzheimer's disease, the most common form of dementia, is characterized by two pathological features in the brain, extracellular senile plaques and intracellular neurofibrillary tangles. Senile plaques consist of amyloid-β peptide (Aβ) generated from amyloid precursor protein (APP) through sequential proteolytic processing by β-secretase and γ-secretase. Two major forms of Aβ exist, Aβ40 and Aβ42, with Aβ42 being more neurotoxic due to its higher hydrophobicity, which results in faster oligomerization and aggregation 1 . A number of mutations associated with early-onset familial Alzheimer's disease (FAD) have been identified in the APP, PSEN1 and PSEN2 genes, and these mutations lead to accelerated production of Aβ42 or an increase in the Aβ42/Aβ40 ratio. Together these findings indicate that Aβ42 plays an essential role in the initiation of pathogenesis. However, the possible involvement of longer Aβ species that also exist in Alzheimer's disease brains has not yet been fully investigated.Thus far, various longer Aβ species, such as Aβ43, Aβ45, Aβ48, Aβ49 and Aβ50, have been qualitatively described in Alzheimer's disease brains 2 . Similar Aβ species have also been found in transgenic mice that overexpress APP carrying FAD-linked mutations 3 . Further quantitative studies have revealed that Aβ43 is deposited more frequently than Aβ40 in both sporadic Alzheimer's disease (SAD) and FAD [4][5][6][7] .How these Aβ species with different C-terminal ends are generated from the precursor has mainly been investigated by cell biological and biochemical methods. A number of studies 8,9 demonstrated that γ/ε-cleavage by γ-secretase activity controls the fate of the C-terminal end. Aβ43, generated from Aβ49 via Aβ46, is subsequently converted to Aβ40 by γ-secretase whereas Aβ42 is independently generated from Aβ48 via Aβ45. It has also been reported that the FAD-associated I213T mutation in the PSEN1 gene increases the generation of longer Aβ species, such as Aβ43, Aβ45 a...
Expression of somatostatin in the brain declines during aging in various mammals including apes and humans. A prominent decrease in this neuropeptide also represents a pathological characteristic of Alzheimer disease. Using in vitro and in vivo paradigms, we show that somatostatin regulates the metabolism of amyloid beta peptide (Abeta), the primary pathogenic agent of Alzheimer disease, in the brain through modulating proteolytic degradation catalyzed by neprilysin. Among various effector candidates, only somatostatin upregulated neprilysin activity in primary cortical neurons. A genetic deficiency of somatostatin altered hippocampal neprilysin activity and localization, and increased the quantity of a hydrophobic 42-mer form of Abeta, Abeta(42), in a manner similar to presenilin gene mutations that cause familial Alzheimer disease. These results indicate that the aging-induced downregulation of somatostatin expression may be a trigger for Abeta accumulation leading to late-onset sporadic Alzheimer disease, and suggest that somatostatin receptors may be pharmacological-target candidates for prevention and treatment of Alzheimer disease.
A subtle but chronic alteration in metabolic balance between amyloid- peptide (A) anabolic and catabolic activities is thought to cause A accumulation, leading to a decade-long pathological cascade of Alzheimer disease. However, it is still unclear whether a reduction of the catabolic activity of A in the brain causes neuronal dysfunction in vivo. In the present study, to clarify a possible connection between a reduction in neprilysin activity and impairment of synaptic and cognitive functions, we cross-bred amyloid precursor protein (APP) transgenic mice (APP23) with neprilysin-deficient mice and biochemically and immunoelectron-microscopically analyzed A accumulation in the brain. We also examined hippocampal synaptic plasticity using an in vivo recording technique and cognitive function using a battery of learning and memory behavior tests, including Y-maze, novel-object recognition, Morris water maze, and contextual fear conditioning tests at the age of 13-16 weeks. We present direct experimental evidence that reduced activity of neprilysin, the major A-degrading enzyme, in the brain elevates oligomeric forms of A at the synapses and leads to impaired hippocampal synaptic plasticity and cognitive function before the appearance of amyloid plaque load. Thus, reduced neprilysin activity appears to be a causative event that is at least partly responsible for the memory-associated symptoms of Alzheimer disease. This supports the idea that a strategy to reduce A oligomers in the brain by up-regulating neprilysin activity would contribute to alleviation of these symptoms. Accumulation of amyloid- peptide (A)4 is a triggering event leading to a decade-long pathological cascade of Alzheimer disease (AD) (1, 2). A subtle but chronic alteration in metabolic balance between A anabolic and catabolic activities could result in A accumulation and change monomeric A to pathogenic forms (3,4). Neprilysin is an A-degrading enzyme first identified as a major in vivo peptidase capable of hydrolyzing synthetic multiple-radiolabeled A injected into rat hippocampus (5). A genetic deficiency in neprilysin results in an elevation of A levels in the mouse brain (6). Transgenic or viral expression of neprilysin in the brains of amyloid precursor protein (APP) transgenic mice consistently leads to marked attenuation of A pathology (7-9). The exposure of APP transgenic mice to an enriched environment is reported to result in pronounced deceleration in cerebral A levels and amyloid deposits with a concomitant elevation of brain neprilysin activity (10). Neprilysin is a presynaptic membrane-associated ectoenzyme with an extracellular active site, and it is involved in A degradation at presynaptic sites (9,11,12). A recent study showed that somatostatin causes selective reduction of A 42 by promoting the surface appearance of neprilysin on the presynaptic membrane (13). Down-regulation of neprilysin in the hippocampus and cerebral cortex with aging (14,15) and at an early stage of AD development (15-17) suggests a cl...
Mutations in EFHC1 gene have been previously reported in patients with epilepsies, including those with juvenile myoclonic epilepsy. Myoclonin1, also known as mRib72-1, is encoded by the mouse Efhc1 gene. Myoclonin1 is dominantly expressed in embryonic choroid plexus, post-natal ependymal cilia, tracheal cilia and sperm flagella. In this study, we generated viable Efhc1-deficient mice. Most of the mice were normal in outward appearance, and both sexes were found to be fertile. However, the ventricles of the brains were significantly enlarged in the null mutants, but not in the heterozygotes. Although the ciliary structure was found intact, the ciliary beating frequency was significantly reduced in null mutants. In adult stages, both the heterozygous and null mutants developed frequent spontaneous myoclonus. Furthermore, the threshold of seizures induced by pentylenetetrazol was significantly reduced in both heterozygous and null mutants. These observations seem to further suggest that decrease or loss of function of myoclonin1 may be the molecular basis for epilepsies caused by EFHC1 mutations.
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