Apolipoprotein (apo) E4 increases the risk and accelerates the onset of Alzheimer's disease (AD). However, the underlying mechanisms remain to be determined. We previously found that apoE undergoes proteolytic cleavage in AD brains and in cultured neuronal cells, resulting in the accumulation of carboxyl-terminaltruncated fragments of apoE that are neurotoxic. Here we show that this fragmentation is caused by proteolysis of apoE by a chymotrypsin-like serine protease that cleaves apoE4 more efficiently than apoE3. Transgenic mice expressing the carboxylterminal-cleaved product, apoE4(⌬272-299), at high levels in the brain died at 2-4 months of age. The cortex and hippocampus of these mice displayed AD-like neurodegenerative alterations, including abnormally phosphorylated tau (p-tau) and Gallyas silverpositive neurons that contained cytosolic straight filaments with diameters of 15-20 nm, resembling preneurofibrillary tangles. Transgenic mice expressing lower levels of the truncated apoE4 survived longer but showed impaired learning and memory at 6 -7 months of age. Thus, carboxyl-terminal-truncated fragments of apoE4, which occur in AD brains, are sufficient to elicit AD-like neurodegeneration and behavioral deficits in vivo. Inhibiting their formation might inhibit apoE4-associated neuronal deficits.H uman apolipoprotein (apo) E, a 34-kDa protein composed of 299 amino acids, occurs as three major isoforms, apoE2, apoE3, and apoE4 (1-4). ApoE4 is a major risk or susceptibility factor for Alzheimer's disease (AD) (5-7). The apoE4 allele, which is found in 40-65% of cases of sporadic and familial AD, increases the occurrence and lowers the age of onset of the disease (7,8).Biochemical, cell biological, and transgenic animal studies have suggested several potential mechanisms to explain apoE4's contribution to the pathogenesis of AD. These include the modulation of the deposition and clearance of amyloid  peptides and the formation of plaques (9-15), impairment of the antioxidative defense system (16), dysregulation of neuronal signaling pathways (17), disruption of cytoskeletal structure and function (18,19), and altered phosphorylation of tau and the formation of neurofibrillary tangles (NFTs) (20-23). However, the mechanisms of these apoE4-mediated detrimental effects are still largely unknown, and it is not known which are the primary effects and which are subsequent or downstream effects.The neuropathological hallmarks of AD include extracellular amyloid plaques and intracellular NFTs in the brain (24-27). The plaques consist primarily of amyloid  peptides (24-26). The NFTs are composed largely of the highly phosphorylated microtubule-associated protein tau (p-tau) (25) and, to a lesser extent, of phosphorylated neurofilaments (28, 29). Both amyloid plaques and NFTs contain apoE (5, 30, 31); however, the role of apoE in the pathogenesis of these two lesions is uncertain. Histopathological and behavioral analyses of transgenic mice expressing different human apoE isoforms in the brain have revealed clear evi...
Apolipoprotein E (apoE) is found in amyloid plaques and neurofibrillary tangles (NFTs) in Alzheimer's disease (AD) brains, but its role in their pathogenesis is unclear. Previously, we found C-terminal-truncated fragments of apoE in AD brains and showed that such fragments can cause neurodegeneration and can induce NFT-like inclusions in cultured neuronal cells and in transgenic mice. Here, we analyzed apoE fragmentation in brain tissue homogenates from transgenic mice expressing apoE3 or apoE4 in neurons [neuron-specific enolase (NSE)-apoE] or astrocytes [glial fibrillary acidic protein (GFAP)-apoE] by Western blotting. The C-terminal-truncated fragments of apoE accumulated, in an age-dependent manner, in the brains of NSE-apoE4 and, to a significantly lesser extent, NSE-apoE3 mice; however, no fragments were detected in GFAP-apoE3 or GFAP-apoE4 mice. In NSE-apoE mice, the pattern of apoE fragmentation resembled that seen in AD brains, and the fragmentation was specific for certain brain regions, occurring in the neocortex and hippocampus, which are vulnerable to AD-related neurodegeneration, but not in the less vulnerable cerebellum. Excitotoxic challenge with kainic acid significantly increased apoE fragmentation in NSE-apoE4 but not NSE-apoE3 mice. Phosphorylated tau (p-tau) also accumulated in an age-dependent manner in NSE-apoE4 mice and, to a much lesser extent, in NSE-apoE3 mice but not in GFAP-apoE3 or GFAP-apoE4 mice. Intraneuronal p-tau inclusions in the hippocampus were prominent in 21-month-old NSE-apoE4 mice but barely detectable in NSE-apoE3 mice. Thus, the accumulation of potentially pathogenic C-terminal-truncated fragments of apoE depends on both the isoform and the cellular source of apoE. Neuron-specific proteolytic cleavage of apoE4 is associated with increased phosphorylation of tau and may play a key role in the development of AD-related neuronal deficits.
Laurdan is a fluorescent probe that detects changes in membrane phase properties through its sensitivity to the polarity of its environment in the bilayer. Variations in membrane water content cause shifts in the laurdan emission spectrum, which are quantified by calculating the generalized polarization (GP). We tested whether laurdan fluorescence could be used to distinguish differences in phospholipid order from changes in membrane fluidity by examining the temperature dependence of laurdan GP and fluorescence anisotropy in dipalmitoylphosphatidylcholine (DPPC) vesicles. The phase transition from the solid ordered phase to the liquid disordered phase was observed as a decrease in laurdan GP values from 0.7 to -0.14 and a reduction in anisotropy from 0.25 to 0.12. Inclusion of various amounts of cholesterol in the membranes to generate a liquid ordered phase caused an increase in the apparent melting temperature detected by laurdan GP. In contrast, cholesterol decreased the apparent melting temperature estimated from anisotropy measurements. Based on these results, it appeared that laurdan anisotropy detected changes in membrane fluidity while laurdan GP sensed changes in phospholipid order. Thus, the same fluorescent probe can be used to distinguish effects of perturbations on membrane order and fluidity by comparing the results of fluorescence emission and anisotropy measurements.
Exposure of human erythrocytes to the calcium ionophore ionomycin rendered them susceptible to the action of secretory phospholipase A 2 (sPLA 2 ). Analysis of erythrocyte phospholipid metabolism by thin-layer chromatography revealed significant hydrolysis of both phosphatidylcholine and phosphatidylethanolamine during incubation with ionomycin and sPLA 2 . Several possible mechanisms for the effect of ionomycin were considered. Involvement of intracellular phospholipases A 2 was excluded since inhibitors of these enzymes had no effect. Assessment of membrane oxidation by cis-parinaric acid fluorescence and comparison to the oxidants diamide and phenylhydrazine revealed that oxidation does not participate in the effect of ionomycin. Incubation with ionomycin caused classical physical changes to the erythrocyte membrane such as morphological alterations (spherocytosis), translocation of aminophospholipids to the outer leaflet of the membrane, and release of microvesicles. Experiments with phenylhydrazine, KCl, quinine, merocyanine 540, the calpain inhibitor E-64d, and the scramblase inhibitor R5421 revealed that neither phospholipid translocation nor vesicle release was required to induce susceptibility. Results from fluorescence spectroscopy and two-photon excitation scanning microscopy using the membrane probe laurdan argued that susceptibility to sPLA 2 is a consequence of increased order of membrane lipids.Under normal conditions, healthy cell membranes resist catalysis by secretory phospholipase A 2 (sPLA 2 ) 1 (1-4). However, they may become susceptible under circumstances that cause alteration of membrane physical properties (1-4). Previous studies using artificial membranes demonstrated that alterations that increase susceptibility generally increase the anionic charge of the outer leaflet, increase bilayer curvature, and/or decrease interactions among neighboring phospholipids (5-9). In some cases, enhanced susceptibility of artificial membranes depends on an increase in the order of the phospholipids (8, 10 -14). These changes increase susceptibility by augmenting the binding of sPLA 2 and/or by improving access of membrane phospholipids to the active site of the enzyme (5-12, 15, 16).It is not known whether the properties that induce susceptibility to sPLA 2 in artificial membranes also contribute to the vulnerability of biological membranes to attack by the enzyme. In order to address this issue, we manipulated various properties of erythrocyte membranes by preparing different types of ghosts as explained in the accompanying particle (17). We found that the factors that determined the degree of susceptibility were increased exposure of phosphatidylserine, an anionic phospholipid, and increased membrane order. These interpretations agreed with those from studies of susceptibility using artificial membranes (5-16). The next question, then, is whether these same factors are important in the hydrolysis of intact cells by sPLA 2 under conditions at which they have become susceptible such as in the presence...
Although apolipoprotein (apo) E is synthesized in the brain primarily by astrocytes, neurons in the central nervous system express apoE, albeit at lower levels than astrocytes, in response to various physiological and pathological conditions, including excitotoxic stress. To investigate how apoE expression is regulated in neurons, we transfected Neuro-2a cells with a 17-kilobase human apoE genomic DNA construct encoding apoE3 or apoE4 along with upstream and downstream regulatory elements. The baseline expression of apoE was low. However, conditioned medium from an astrocytic cell line (C6) or from apoE-null mouse primary astrocytes increased the expression of both isoforms by 3-4-fold at the mRNA level and by 4 -10-fold at the protein level. These findings suggest that astrocytes secrete a factor or factors that regulate apoE expression in neuronal cells. The increased expression of apoE was almost completely abolished by incubating neurons with U0126, an inhibitor of extracellular signal-regulated kinase (Erk), suggesting that the Erk pathway controls astroglial regulation of apoE expression in neuronal cells. Human neuronal precursor NT2/D1 cells expressed apoE constitutively; however, after treatment of these cells with retinoic acid to induce differentiation, apoE expression diminished. Cultured mouse primary cortical and hippocampal neurons also expressed low levels of apoE. Astrocyte-conditioned medium rapidly up-regulated apoE expression in fully differentiated NT2 neurons and in cultured mouse primary cortical and hippocampal neurons. Thus, neuronal expression of apoE is regulated by a diffusible factor or factors released from astrocytes, and this regulation depends on the activity of the Erk kinase pathway in neurons.The ⑀4 allele of the gene encoding apolipoprotein (apo) 1 E has been genetically linked to late-onset familial and sporadic Alzheimer's disease (AD) and has a gene-dose effect on the risk and age of onset of the disease (1-5). Individuals with two copies of the ⑀4 allele have a 50 -90% chance of developing AD by the age of 85, and those with one copy have about a 45% chance (1,6). Only about 20% of the general population develops AD by the age of 85 (1).ApoE is found in amyloid plaques and neurofibrillary tangles, two neuropathological hallmarks of AD (7-13), but its role in their pathogenesis is unclear. ApoE4 has several adverse effects that might explain the association between AD and the ⑀4 allele. It modulates the deposition and clearance of amyloid  peptides and plaque formation (14 -21), impairs the antioxidative defense system (22), dysregulates neuronal signaling pathways (23), disrupts cytoskeletal structure and function (24,25), and alters the phosphorylation of tau and the formation of neurofibrillary tangles (26 -30). However, the mechanisms of these effects are still largely unknown, and it is not known which are the primary effects and which are subsequent or downstream effects.Initially, apoE was thought to be synthesized in the brain only by astrocytes, oligodendrocyte...
Although apolipoprotein (apo) E4 is present in amyloid plaques and neurofibrillary tangles, its pathogenic role in Alzheimer's disease (AD) is unclear. Neuronal expression of apoE4 or apoE4 fragments in transgenic mice increases tau phosphorylation. To identify the kinase responsible for the increase, we studied transgenic mice expressing human apoE3 or apoE4 in neurons under the control of the neuron-specific enolase promoter. Brain levels of phosphorylated tau (p-tau) and phosphorylated (active) extracellular signal-regulated kinase (pErk) increased with age in both groups but were considerably higher in the apoE4 mice. Other candidate kinases, including glycogen synthase kinase 3 and cyclin-dependent kinase-5 and its activators p25 and p35, were not significantly altered. The increases in p-Erk and p-tau were highest in the hippocampus, intermediate in the cortex, and lowest in the cerebellum. In the hippocampus, p-Erk and p-tau accumulated in the hilus and CA3 region of the dentate gyrus, where high levels of zinc are found along mossy fibers. In Neuro-2a cells stably expressing apoE3 or apoE4, treatment with ZnCl 2 generated 2-fold more p-Erk and 3-fold more p-tau in the apoE4-expressing cells. Phosphorylation of Erk and tau was reduced by preincubation with the Erk pathway inhibitor U0126. Thus, increased tau phosphorylation in apoE4 transgenic mice was associated with Erk activation and could be modified by zinc, suggesting that apoE4 and zinc act in concert to contribute to the pathogenesis of AD.Human apolipoprotein (apo) 1 E4 has been identified as a major risk factor for Alzheimer's disease (AD) (1, 2). It increases the occurrence and lowers the age of onset of AD and is associated with ϳ40 -65% of cases of sporadic and familial AD (1, 2). The neuropathological hallmarks of AD are neuritic amyloid plaques and neurofibrillary tangles (NFTs) in the brain (3-5). The plaques are extracellular deposits consisting primarily of amyloid-beta (A) peptides (3-5), the proteolytic products of the amyloid protein precursor. NFTs are primarily intracellular deposits composed largely of highly phosphorylated tau (p-tau), a microtubule-associated protein (4), as well as phosphorylated neurofilaments of high molecular weight (6, 7). Both plaques and NFTs contain apoE (8 -10), but the role of apoE in the pathogenesis of these lesions is unclear.Several hypotheses have been proposed to explain the association of apoE4 with AD (10 -14). They include modulation of the deposition and clearance of A peptides and the formation of plaques (15-21), impairment of the antioxidative defense system (22), dysregulation of neuronal signaling pathways (23), altered phosphorylation of tau and NFT formation (24 -29), depletion of cytosolic androgen receptor levels in the brain (30, 31), potentiation of A-induced lysosomal leakage and apoptosis in neuronal cells (32), and promotion of endosomal abnormalities linked to A overproduction (33-35). However, the mechanisms of these apoE4-mediated detrimental effects are largely unknown, ...
Artificial membranes may be resistant or susceptible to catalytic attack by secretory phospholipase A 2 (sPLA 2 ) depending on the physical properties of the membrane. Living cells are normally resistant but become susceptible during trauma, apoptosis, and/or a significant elevation of intracellular calcium. Intact erythrocytes and ghosts were studied to determine whether the principles learned from artificial systems apply to biological membranes. Membrane properties such as phospholipid and/or protein composition, morphology, and microscopic characteristics (e.g. fluidity) were manipulated by preparing ghosts under different experimental conditions such as in the presence or absence of divalent cations with or without ATP. The properties of each membrane preparation were assessed by biochemical and physical means (fluorescence spectroscopy and electron and two-photon microscopy using the membrane probes bis-pyrene and laurdan) and compared with sPLA 2 activity. The properties that appeared most relevant were the degree of phosphatidylserine exposure on the outer face of the membrane and changes to the membrane physical state detected by bis-pyrene and laurdan. Specifically, vulnerability to hydrolysis by sPLA 2 was associated with an increase in bilayer order apparently reflective of expansion of membrane regions of diminished fluidity. These results argue that the general principles identified from studies with artificial membranes apply to biological systems.
The plastid genome is transcribed by two distinct RNA polymerases, the PEP encoded by the plastid genome and the NEP encoded in the nucleus. Initial models of plastid transcription held that the NEP is responsible for the transcription of housekeeping genes needed early in development, and that the PEP transcribes genes required for photosynthesis. Recently, this model was challenged by the discovery that all plastid genes are transcribed by NEP in PEP-deficient tobacco plastids, suggesting that mRNA turnover may have a strong role in previously observed transcription patterns. In this study, we provide evidence that the NEP enzyme level decreases as plastids mature. In contrast, production of mRNAs by NEP increases as plastids mature, yet their accumulations remain constant. These results suggest that as plastids mature NEP may become more active, and that mRNA turnover varies between transcripts synthesized by NEP and PEP.
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