Although the role of APP and PSEN genes in genetic Alzheimer's disease (AD) cases is well established, fairly little is known about the molecular mechanisms affecting A generation in sporadic AD. Deficiency in A clearance is certainly a possibility, but increased expression of proteins like APP or BACE1/-secretase may also be associated with the disease. We therefore investigated changes in microRNA (miRNA) expression profiles of sporadic AD patients and found that several miRNAs potentially involved in the regulation of APP and BACE1 expression appeared to be decreased in diseased brain. We show here that miR-29a, -29b-1, and -9 can regulate BACE1 expression in vitro. The miR-29a/b-1 cluster was significantly (and AD-dementia-specific) decreased in AD patients displaying abnormally high BACE1 protein. Similar correlations between expression of this cluster and BACE1 were found during brain development and in primary neuronal cultures. Finally, we provide evidence for a potential causal relationship between miR-29a/b-1 expression and A generation in a cell culture model. We propose that loss of specific miRNAs can contribute to increased BACE1 and A levels in sporadic AD.neurodegeneration ͉ amyloid ͉ noncoding RNA M utations in the APP and PSEN genes cause A accumulation and familial Alzheimer's disease (AD) (1-4). However, little is known about the mechanisms that contribute to A accumulation in the vast majority of sporadic AD cases. BACE1/-secretase cleavage of APP is the rate-limiting step for A peptide production. Increased BACE1 expression is observed in patients with sporadic AD (5-8), and several mechanisms for this up-regulation have been proposed (9, 10). A link between BACE1 levels, A load, and AD pathology has been reported (11), suggesting that increased BACE1 expression is indeed an important risk factor for sporadic AD.miRNAs are small noncoding RNAs that control gene expression at the posttranscriptional level by binding to the 3Ј untranslated region (3ЈUTR) of target mRNAs leading to their translational inhibition or sometimes degradation. Several miRNAs are specifically expressed or enriched in the brain (12-15), and some have been associated with neuronal differentiation, synaptic plasticity, and memory formation (16,17). The hypothesis that miRNA pathways could contribute to neurodegeneration is appealing (18) and has been tested to a certain degree in Drosophila (19) and mouse models (18,20,21) in which all miRNAs are lacking. Recently, Kim et al. (21) identified a subgroup of miRNAs, normally enriched in the midbrain, which expression is altered in sporadic Parkinson's disease (PD). One of the affected miRNAs, miR-133b, controls the differentiation and function of dopaminergic neurons (which are lost in PD). Here, we sought to investigate whether changes in miRNA expression exist in sporadic AD, and whether these changes could contribute to A pathology. ResultsmiRNA Profile Analysis of Sporadic AD Brain. In a pilot study, we assessed the expression profiles of 328 human miRNAs f...
LRRK2 is a kinase mutated in Parkinson's disease, but how the protein affects synaptic function remains enigmatic. We identified LRRK2 as a critical regulator of EndophilinA. Using genetic and biochemical studies involving Lrrk loss-of-function mutants and Parkinson-related LRRK2(G2019S) gain-of-kinase function, we show that LRRK2 affects synaptic endocytosis by phosphorylating EndoA at S75, a residue in the BAR domain. We show that LRRK2-mediated EndoA phosphorylation has profound effects on EndoA-dependent membrane tubulation and membrane association in vitro and in vivo and on synaptic vesicle endocytosis at Drosophila neuromuscular junctions in vivo. Our work uncovers a regulatory mechanism that indicates that reduced LRRK2 kinase activity facilitates EndoA membrane association, while increased kinase activity inhibits membrane association. Consequently, both too much and too little LRRK2-dependent EndoA phosphorylation impedes synaptic endocytosis, and we propose a model in which LRRK2 kinase activity is part of an EndoA phosphorylation cycle that facilitates efficient vesicle formation at synapses.
Parkinson's disease mutations in PINK1 result in decreased Complex I activity and deficient synaptic function
Mutations of the mitochondrial PTEN (phosphatase and tensin homologue)-induced kinase1 (PINK1) are important causes of recessive Parkinson disease (PD). Studies on loss of function and overexpression implicate PINK1 in apoptosis, abnormal mitochondrial morphology, impaired dopamine release and motor deficits. However, the fundamental mechanism underlying these various phenotypes remains to be clarified. Using fruit fly and mouse models we show that PINK1 deficiency or clinical mutations impact on the function of Complex I of the mitochondrial respiratory chain, resulting in mitochondrial depolarization and increased sensitivity to apoptotic stress in mammalian cells and tissues. In Drosophila neurons, PINK1 deficiency affects synaptic function, as the reserve pool of synaptic vesicles is not mobilized during rapid stimulation. The fundamental importance of PINK1 for energy maintenance under increased demand is further corroborated as this deficit can be rescued by adding ATP to the synapse. The clinical relevance of our observations is demonstrated by the fact that human wild type PINK1, but not PINK1 containing clinical mutations, can rescue Complex 1 deficiency. Our work suggests that Complex I deficiency underlies, at least partially, the pathogenesis of this hereditary form of PD. As Complex I dysfunction is also implicated in sporadic PD, a convergence of genetic and environmental causes of PD on a similar mitochondrial molecular mechanism appears to emerge.
The genetic hierarchy that controls myelination of peripheral nerves by Schwann cells includes the POU domain Oct-6/Scip/Tst-1 and the zinc-finger Krox-20/Egr2 transcription factors. These pivotal transcription factors act to control the onset of myelination during development and tissue regeneration in adults following damage. In this report we demonstrate the involvement of a third transcription factor, the POU domain factor Brn-2. We show that Schwann cells express Brn-2 in a developmental profile similar to that of Oct-6 and that Brn-2 gene activation does not depend on Oct-6. Overexpression of Brn-2 in Oct-6-deficient Schwann cells, under control of the Oct-6 Schwann cell enhancer (SCE), results in partial rescue of the developmental delay phenotype, whereas compound disruption of both Brn-2 and Oct-6 results in a much more severe phenotype. Together these data strongly indicate that Brn-2 function largely overlaps with that of Oct-6 in driving the transition from promyelinating to myelinating Schwann cells. The high conduction velocity of nerve fibers is a hallmark of the nervous system of higher vertebrates and depends on structural and molecular specializations that are elaborated during development. These specializations occur through intimate and continued interactions between the neuron and its associated glial cells and result in the elaboration by glial cells of myelin, the important membranous structure that ensheaths and insulates axons (Arroyo and Scherer 2000; Fields and StevensGraham 2002;Mirsky et al. 2002). Two glial cell types produce myelin: the oligodendrocyte in the central nervous system (CNS) and the Schwann cell in the peripheral nervous system (PNS). Although very similarly organized, the molecular composition of CNS and PNS myelin differs significantly, and oligodendrocytes and Schwann cells have adopted different, but overlapping, sets of transcriptional regulators to coordinate myelogenesis (Hudson 2001; Topilko and Meijer 2001). These differences reflect their distinct embryonic origins. Whereas oligodendrocytes originate from the neuroepithelial precursors that line the lumen of the spinal cord and ventricles of the brain, Schwann cells derive mainly from the neural crest, a transient embryonic stem (ES) cell population that generates a wide variety of cell types including sensory and autonomic neurons and melanocytes (Le Douarin and Kalcheim 1999;Richardson 2001). Schwann cell precursors populate the early outgrowing nerve bundles, where they proliferate and segregate individual and groups of fibers until the number of Schwann cells and fibers is eventually matched. During the first few days of postnatal development, many Schwann cells establish a 1:1 relationship with axons, cease to proliferate, and initiate myelin formation such that by the end of the first postnatal week of development, all myelin-competent axons are actively being myelinated. Schwann cells that remain associated with groups of lower-caliber fibers will segregate these fibers in cytoplasmic cuffs without mye...
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