Neuronal endosomal/lysosomal membrane destabilization activates caspases and induces abnormal accumulation of the lipid secondary messenger ceramide.

Impairment of endosomal/lysosomal functions are reported as some of the earliest changes in several age-related neurological disorders such as Alzheimer's disease. Dysregulation of the lysosomal system is also accompanied by the accumulation of age-associated pigments and several recent reports have indicated that this age-related lipofuscin accumulation can sensitize cells to oxidative stress and apoptotic cell death. In this study, we have established and evaluated an in vitro age-related pathology paradigm that models lipofuscin accumulation. Our model consists of the treatment of cultured primary mouse neurons with lysosomotropic detergents. We have observed that one of the earliest biochemical changes associated with lysosomotropic detergent-induced membrane instability is a loss of the endosomal/lysosomal proton gradient integrity, followed by an activation of sphingomyelin hydrolysis and ceramide accumulation within enlarged endosomal/lysosomal vesicles. In addition, we demonstrate that ceramide accumulation correlates with the activation of proximal procaspases-8 and -9 as well as distal caspase-3, prior to the appearance of cell death. Taken together, we propose that disturbances of the endosomal/lysosomal system, in addition to the activation of the sphingomyelinase hydrolysis cycle, play essential roles in the course of post-mitotic neuronal aging. The abnormal accumulation of undigested lipids and proteins within dysfunctional endosomal/lysosomal vesicle populations during the process of pathological aging may serve as triggers of the cell death programs that are associated with downstream neurodegeneration.

The central role of the trans-Golgi network as a gateway of the early secretory pathway: physiologic vs nonphysiologic protein transit.

The current review focuses upon recent advances concerning the interrelationship between the ER and the trans-Golgi network (ER-TGN), the ER and the nucleus (ER-nucleus), and the ER-ubiquitin-proteasomal pathways at the level of basic cell biology. The overall emphasis of this paper centers upon the high likelihood that measurements of ER-associated protein or gene expression levels are not representative of a strict ER alone phenotype. Rather, that ER phenotype reflects a synthesis of phenotypes derived from intracellular compartments and phosphorylated messengers in rapport with the ER. The ER-TGN, ER-nuclear, and ER-ubiquitin-proteasomal transit paths share the ability to feed into the decision of whether TGN vesicles can interact with specific phosphorylated residues in order to drive physiologic, constitutive, anterograde traffic, retrograde traffic, and degradation. TGN vesicles can: (a) traffic to endosomes versus plasma membrane phosphodomains depending upon the presence or the absence of select Golgi-localized gamma-ear containing ADP ribosylation factor-binding proteins and/or protein kinase D; (b) be maintained within the TGN in the presence of a phosphosorting acidic cluster motif adaptor; (c) transit back to the ER via specialized TGN/ER glycosyltransferases (which modulate phosphorylated proteins); (d) transit to the nucleus via phosphatidylinositol-4-kinase-associated phosphodomains; and/or (e) retrotranslocate to the ubiquitin-proteasome pathway, which is equipped with E3 ligase potential, in order to further regulate endosomal versus plasma membrane traffic. The TGN is also a critical gateway for protein transit in the sense that, as a function of sorting within this compartment, proteins are sent to the axon, cell body, or dendrites. As the decision to sort to the axon versus the somatodendritic compartment is intimately tied to TGN function, future understanding of TGN biology at the levels of neurogenesis and protein sorting is predicted to also effectively increase our understanding of synaptic sorting/regulation.

Subcellular localization of presenilin 2 endoproteolytic C-terminal fragments.

Mutations in the genes that encode the presenilin 1 and 2 (PS1 and PS2) proteins cause the majority of familial Alzheimer's disease (FAD). Differential cleavage of the presenilins results in a generation of at least two C-terminal fragments (CTFs). An increase in the smaller of these two CTFs is one of the few changes in presenilin processing associated with FAD mutations in both PS1 and PS2. Interestingly, the phosphorylation of PS2 modulates the production of the smaller, caspase-derived PS2 CTF, which indicates that the generation of this fragment is a regulated, physiologic event. To date, there is no data concerning the subcellular distribution of the caspase-derived PS2 CTF. Because this fragment is normally present at levels that are difficult to detect, we have used cell lines in which the production of wild-type or N141I mutant PS2 is controlled by a tetracycline-regulated promoter in order to assess the subcellular localization of the caspase CTF in relation to the larger, constitutive PS2 CTF and to PS2 holoprotein. We have found that when levels of PS2 are low, the constitutive CTF colocalizes with markers consistent with localization in the early Golgi-ER-Golgi intermediate compartment (ERGIC) while the caspase CTF colocalizes with markers for the endoplasmic reticulum (ER). Following induction of wild-type or mutant PS2, when the levels of PS2 are high, the primary localization of the constitutive CTF appears to shift from the early Golgi-ERGIC in addition to the ER. Interestingly, while the induction of wild-type PS2 resulted in the localization of the caspase CTF primarily in the ER, the induction of mutant PS2 resulted in the localization of the caspase CTF to both the ER and the early Golgi-ERGIC. In summary, these data suggest that the two presenilin 2 CTFs have different patterns of subcellular localization and that the N141I PS2 mutation alters the localization pattern of the PS2 caspase fragment.

Lysosomal membrane damage in soluble Abeta-mediated cell death in Alzheimer's disease.

Our previous studies suggest that a failure to degrade aggregated Abeta1-42 in late endosomes or secondary lysosomes is a mechanism that contributes to intracellular accumulation in Alzheimer's disease. In this study, we demonstrate that cultured primary neurons are able to internalize soluble Abeta1-42 from the culture medium and accumulate inside the endosomal/lysosomal system. The intracellular Abeta1-42 is resistant to protease degradation and stable for at least 48 h within the cultured neurons. Incubation of cultured neurons with a cytotoxic concentration of soluble Abeta1-42 invokes the rapid free radical generation within lysosomes and disruption of lysosomal membrane proton gradient which precedes cell death. The loss of lysosomal membrane impermeability is only specific to the Abeta1-42 isoform since incubation of cells with high concentrations of Abeta1-40 has no effect on lysosomal hydrolase release. To further support the role of lysosomal membrane damage in Abeta-mediated cell death, we demonstrate that photodisruption of acridine orange (AO)-loaded lysosomes with intense blue light induces a relatively rapid synchronous lysosomal membrane damage and neuronal death similar to that observed as a result of Abeta exposure. AO leaks quickly from late endosomes and lysosomes and partially shifts the fluorescence from an orange fluorescence to a diffuse, green cytoplasmic fluorescence. Such AO relocalization is due to an initial disruption of the lysosomal proton gradient, followed by the release of lysosomal hydrolases into the cytoplasmic compartment. Treatment of cells with either the antioxidant n-propyl gallate or lysosomotropic amine (methylamine) partially blocks the release of lysosomal contents suggesting that this AO relocalization is due to lysosomal membrane oxidation. Based on these findings, we propose that the cell death mediated by the soluble Abeta may be fundamentally different from the cell loss observed following extracellular Abeta deposition.

Toxicity of pyroglutaminated amyloid beta-peptides 3(pE)-40 and -42 is similar to that of A beta1-40 and -42.

An N-terminal truncated isoform of the amyloid beta-peptide (A beta) that begins with a pyroglutamate (pE) residue at position 3 [A beta3(pE)-42] is the predominant isoform found in senile plaques. Based upon previous in vitro studies regarding A beta N-terminal truncated isoforms, it has been hypothesized that A beta3(pE)-x isoforms may aggregate more rapidly and become more toxic than corresponding Abeta1-x peptides. However, the toxicity and aggregation properties of A beta3(pE)-42 and A beta3(pE)-40 have not previously been examined. After initial solubilization and 1-week preaggregation of each peptide at 37 degrees C and pH 7.4, the toxicity of 5-50 microM A beta3(pE)-42 was similar to that of A beta1-42. Moreover, the toxicity of A beta3(pE)-40 paralleled that induced by A beta1-40 in both 1 day in vitro (DIV) cortical and 7 DIV hippocampal cells. Circular dichroism spectra did not reveal major differences in secondary structure between aged A beta1-42, A beta3(pE)-42, A beta3(pE)-40, and A beta1-40 or freshly solubilized forms of these peptides. Overall, the data indicate that the loss of the two N-terminal amino acids and the cyclization of glutamate at position 3 do not alter the extracellular toxicity of A beta.

N-terminal heterogeneity of parenchymal and cerebrovascular Abeta deposits.

The goals of this study were twofold: to determine whether species differences in Abeta N-terminal heterogeneity explain the absence of neuritic plaques in the aged dog and aged bear in contrast to the human; and to compare Abeta N-terminal isoforms in parenchymal vs cerebrovascular Abeta (CVA) deposits in each of the species, and in individuals with Alzheimer disease (AD) vs nondemented individuals. N-terminal heterogeneity can affect the aggregation, toxicity, and stability of Abeta. The human, polar bear, and dog brain share an identical Abeta amino acid sequence. Tissues were immunostained using affinity-purified polyclonal antibodies specific for the L-aspartate residue of Abeta at position one (AbetaN1[D]), D-aspartate at N1 (AbetaN1[rD]), and pyroglutamate at N3 (AbetaN3[pE]) and p3, a peptide beginning with leucine at N17 (AbetaN17[L]). The results demonstrate that each Abeta N-terminal isoform can be present in diffuse plaques and CVA deposits in AD brain, nondemented human, and the examined aged animal models. Though each Abeta N-terminal isoform was present in diffuse plaques, the average amyloid burden of each isoform was highest in AD vs polar bear and dog (beagle) brain. Moreover, the ratio of AbetaN3(pE) (an isoform that is resistant to degradation by most aminopeptidases) vs AbetaN17(L)-x (the potentially nonamyloidogenic p3 fragment) was greatest in the human brain when compared with aged dog or polar bear. Neuritic plaques in AD brain typically immunostained with antibodies against AbetaN1(D) and AbetaN3(pE), but not AbetaN17(L) or AbetaN1(rD). Neuritic deposits in nondemented individuals with atherosclerotic and vascular hypertensive changes could be identified with AbetaN1(D), AbetaN3(pE), and AbetaN1(rD). The presence of AbetaN1(rD) in neuritic plaques in nondemented individuals with atherosclerosis or hypertension, but not in AD, suggests a different evolution of the plaques in the two conditions. AbetaN1(rD) was usually absent in human CVA, except in AD cases with atherosclerotic and vascular hypertensive changes. Together, the results demonstrate that diffuse plaques, neuritic plaques, and CVA deposits are each associated with distinct profiles of Abeta N-terminal isoforms.

Comparison of neuropathologic criteria for the diagnosis of Alzheimer's disease.

The National Institute on Aging and Reagan Institute (NIA-RI) criteria, and other neuropathologic criteria for Alzheimer's disease (AD), were compared with the clinical diagnosis of dementia in a well defined population of Catholic sisters. The 47-participant subset examined in this study were college educated and lacked complicating conditions such as brain infarcts or diffuse Lewy body disease. Sixteen participants had a clinical diagnosis of dementia. The NIA-RI criteria imply a perfect correlation between neuritic plaque (NP) density and neurofibrillary tangle distribution. However, NP density often did not coincide with tangle distribution. As a result, it was not possible to categorize many of the participants using the NIA-RI guidelines. The 'high likelihood' category of the NIA-RI criteria for AD research settings (neocortical Braak stage and frequent neocortical NP) had relatively high specificity (90% of nondemented participants did not meet this criteria). However, only half of the demented participants were in this category. Neuropathologic criteria requiring the presence of neocortical tangles (rather than neocortical Braak stage) had relatively high sensitivity, accounting for 87-94% of participants with dementia, but also included 32-35% of nondemented participants. Criteria based on neocortical NP or senile plaques had 100% sensitivity, but a majority of nondemented participants also met these criteria. The results support consideration of both tangles and NP for the neuropathologic diagnosis of AD, but indicate that refinement of the NIA-RI criteria is necessary. A possible refinement is suggested for further consideration.

Carboxy terminal of beta-amyloid deposits in aged human, canine, and polar bear brains.

Immunocytochemistry, using antibodies specific for different carboxy termini of beta-amyloid. A beta 40 and A beta 42(43), was used to compare beta-amyloid deposits in aged animal models to nondemented and demented Alzheimer's disease human cases. Aged beagle dogs exhibit diffuse plaques in the absence of neurofibrillary pathology and the aged polar bear brains contain diffuse plaques and PHF-1-positive neurofibrillary tangles. The brains of nondemented human subjects displayed abundant diffuse plaques, whereas the AD cases had both diffuse and mature (cored) neuritic plaques. Diffuse plaques were positively immunostained with an antibody against A beta 42(43) in all examined species, whereas A beta 40 immunopositive mature plaques were observed only in the human brain. Anti-A beta 40 strongly immunolabeled cerebrovascular beta-amyloid deposits in each of the species examined, although some deposits in the polar bear brain were preferentially labeled with anti-A beta 42(43). beta-amyloid deposition was evident in the outer molecular layer of the dentate gyrus in the aged dog, polar bear, and human. Within this layer, A beta 42 was present as diffuse deposits, although these deposits were morphologically distinct in each of the examined animal models. In dogs, A beta 42 was cloud-like in nature; the polar bear demonstrated a more aggregated type of deposition, and the nondemented human displayed well-defined deposits. Alzheimer's disease cases were most frequently marked by neuritic plaques in this region. Taken together, the data indicate that beta-amyloid deposition in aged mammals is similar to the earliest stages observed in human brain. In each species, A beta 42(43) is the initially deposited isoform in diffuse plaques.

Perikaryal accumulation and proteolysis of neurofilament proteins in the post-mortem rat brain.

Investigations of neurofilament alterations in neurodegenerative disorders utilize postmortem human tissues obtained at autopsy. To determine if alterations in the levels or distribution of neurofilament proteins might occur during the interval between death and autopsy, the postmortem cooling curve of the human brain was modeled in Sprague-Dawley rats and neurofilament proteins were examined by immunocytochemistry and immunoblots. One hour after death, enhanced perikaryal immunostaining of NF-M and both phosphorylated and nonphosphorylated NF-H epitopes was observed throughout the hippocampal formation. A greater number of neurons exhibited increased somatic immunostaining 4-h postmortem. In addition, loss of neurofilament protein immunostaining was observed in the neuropil, particularly in the molecular layer of the dentate gyrus. This corresponded with, but lagged behind, the pattern of calpain activation determined using an antibody against calpain-cleaved alpha-spectrin. Immunoblots confirmed the postmortem loss of neurofilament proteins in both triton-soluble and insoluble fractions. These results demonstrate that the levels and localization of neurofilament proteins observed in tissues obtained at autopsy even with short postmortem intervals may not accurately reflect the premortem condition.

Sexual differences in sensitivity to methamphetamine toxicity.

Male and female mice were treated with methamphetamine (10.0 mg/kg/injection for four injections) and sacrificed two weeks later. It was observed that the methamphetamine treatment caused depletions in striatal dopamine which were significantly greater in males (74%) than in females (56%). These results indicate that estrogen may have a protective effect against methamphetamine-induced dopamine depletions and may relate to the fact that males are more likely to incur Parkinson's disease than females.