Proliferation in the Alzheimer hippocampus is due to microglia, not astroglia, and occurs at sites of amyloid deposition.

Microglia and astrocytes contribute to Alzheimer's disease (AD) etiology and may mediate early neuroinflammatory responses. Despite their possible role in disease progression and despite the fact that they can respond to amyloid deposition in model systems, little is known about whether astro- or microglia can undergo proliferation in AD and whether this is related to the clinical symptoms or to local neuropathological changes. Previously, proliferation was found to be increased in glia-rich regions of the presenile hippocampus. Since their phenotype was unknown, we here used two novel triple-immunohistochemical protocols to study proliferation in astro- or microglia in relation to amyloid pathology. We selected different age-matched cohorts to study whether proliferative changes relate to clinical severity or to neuropathological changes. Proliferating cells were found across the hippocampus but never in mature neurons or astrocytes. Almost all proliferating cells were co-labeled with Iba1+, indicating that particularly microglia contribute to proliferation in AD. Proliferating Iba1+ cells was specifically seen within the borders of amyloid plaques, indicative of an active involvement in, or response to, plaque accumulation. Thus, consistent with animal studies, proliferation in the AD hippocampus is due to microglia, occurs in close proximity of plaque pathology, and may contribute to the neuroinflammation common in AD.

Prolonged running, not fluoxetine treatment, increases neurogenesis, but does not alter neuropathology, in the 3xTg mouse model of Alzheimer's disease.

Reductions in adult neurogenesis have been documented in the original 3xTg mouse model of Alzheimer's disease (AD), notably occurring at the same age when spatial memory deficits and amyloid plaque pathology appeared. As this suggested reduced neurogenesis was associated with behavioral deficits, we tested whether activity and pharmacological stimulation could prevent memory deficits and modify neurogenesis and/or neuropathology in the 3xTg model backcrossed to the C57Bl/6 strain. We chronically administered the antidepressant fluoxetine to one group of mice, allowed access to a running wheel in another, and combined both treatments in a third cohort. All treatments lasted for 11 months. The female 3xTg mice failed to exhibit any deficits in spatial learning and memory as measured in the Morris water maze, indicating that when backcrossed to the C57Bl/6 strain, the 3xTg mice lost the behavioral phenotype that was present in the original 3xTg mouse maintained on a hybrid background. Despite this, the backcrossed 3xTg mice expressed prominent intraneuronal amyloid beta (Aß) levels in the cortex and amygdala, with lower levels in the CA1 area of the hippocampus. In the combined cohort, fluoxetine treatment interfered with exercise and reduced the total distance run. The extent of Aß neuropathology, the tau accumulations, or BDNF levels, were not altered by prolonged exercise. Thus, neuropathology was present but not paralleled by spatial memory deficits in the backcrossed 3xTg mouse model of AD. Prolonged exercise for 11 months did improve the long-term survival of newborn neurons generated during middle-age, whereas fluoxetine had no effect. We further review and discuss the relevant literature in this respect.

Running throughout middle-age improves memory function, hippocampal neurogenesis, and BDNF levels in female C57BL/6J mice.

Age-related memory loss is considered to commence at middle-age and coincides with reduced adult hippocampal neurogenesis and neurotrophin levels. Consistent physical activity at midlife may preserve brain-derived neurotrophic factor (BDNF) levels, new cell genesis, and learning. In the present study, 9-month-old female C57Bl/6J mice were housed with or without a running wheel and injected with bromodeoxyuridine (BrdU) to label newborn cells. Morris water maze learning, open field activity and rotarod behavior were tested 1 and 6 months after exercise onset. Here we show that long-term running improved retention of spatial memory and modestly enhanced rotarod performance at 15 months of age. Both hippocampal neurogenesis and mature BDNF peptide levels were elevated after long-term running. Thus, regular exercise from the onset and during middle-age may maintain brain function.

Distinct structural plasticity in the hippocampus and amygdala of the middle-aged common marmoset (Callithrix jacchus).

Adult neurogenesis in the primate brain is generally accepted to occur primarily in two specific areas; the subgranular zone (SGZ) of the hippocampal dentate gyrus (DG) and the subventricular zone (SVZ) of the lateral ventricles. Hippocampal neurogenesis is well known to be downregulated by stress and aging in rodents, however there is less evidence documenting the sensitivity of neuroblasts generated in the SVZ. In primates, migrating cells generated in the SVZ travel via a unique temporal stream (TS) to the amygdala and entorhinal cortex. Using adult common marmoset monkeys (Callithrix jacchus), we examined whether i) adult-generated cells in the marmoset amygdala differentiate into doublecortin-positive (DCX+) neuroblasts, and ii) whether lasting changes occur in DCX-expressing cells in the DG or amygdala when animals are exposed to 2 weeks of psychosocial stress. A surprisingly large population of DCX+ immature neurons was found in the amygdala of these 4-year-old monkeys with an average density of 163,000 DCX+ cells per mm(3). Co-labeling of these highly clustered cells with PSA-NCAM supports that a subpopulation of these cells are migratory and participate in chain-migration from the SVZ to the amygdala in middle-aged marmosets. Exposure to 2 weeks of isolation and social defeat stress failed to alter the numbers of BrdU+, or DCX+ cells in the hippocampus or amygdala when evaluated 2 weeks after psychosocial stress, indicating that the current stress paradigm has no long-term consequences on neurogenesis in this primate.

Presenilin mouse and zebrafish models for dementia: focus on neurogenesis.

Autosomal dominant mutations in the presenilin gene PSEN cause familial Alzheimer's disease (AD), a neurological disorder pathologically characterized by intraneuronal accumulation and extracellular deposition of amyloid-ß in plaques and intraneuronal, hyperphosphorylated tau aggregation in neurofibrillary tangles. Presenilins (PS/PSENs) are part of the proteolytic γ-secretase complex, which cleaves substrate proteins within the membrane. Cleavage of the amyloid precursor protein (APP) by γ-secretase releases amyloid-ß peptides. Besides its role in the processing of APP and other transmembrane proteins, presenilin plays an important role in neural progenitor cell maintenance and neurogenesis. In this review, we discuss the role of presenilin in relation to neurogenesis and neurodegeneration and review the currently available presenilin animal models. In addition to established mouse models, zebrafish are emerging as an attractive vertebrate model organism to study the role of presenilin during the development of the nervous system and in neurodegenerative disorders involving presenilin. Zebrafish is a suitable model organism for large-scale drug screening, making this a valuable model to identify novel therapeutic targets for AD.

Induction of Alzheimer's-like changes in brain of mice expressing mutant APP fed excess methionine.

Elevated plasma homocysteine, a risk factor for Alzheimer's disease, could result from increased production from methionine or by inefficient clearance by folate- and B-vitamin-dependent pathways. Understanding the relative contributions of these processes to pathogenesis is important for therapeutic strategies designed to lower homocysteine. To assess these alternatives, we elevated plasma homocysteine by feeding mutant amyloid precursor protein (APP)-expressing mice diets with either high methionine (HM) or deficient in B-vitamins and folate (B Def). Mutant APP mice fed HM demonstrated increased brain beta amyloid. Interestingly, this increase was not observed in mutant APP mice fed B Def diet, nor was it observed in C57Bl6 or YAC-APP mice fed HM. Furthermore, HM, but not B Def, produced a prolonged increase in brain homocysteine only in mutant APP mice but not wild-type mice. These changes were time-dependent over 10 weeks. Further, by 10 weeks HM increased brain cholesterol and phosphorylated tau in mutant APP mice. Transcriptional profiling experiments revealed robust differences in RNA expression between C57Bl6 and mutant APP mice. The HM diet in C57Bl6 mice transiently induced a transcriptional profile similar to mutant APP cortex, peaking at 2 weeks , following a time course comparable to brain homocysteine changes. Together, these data suggest a link between APP and methionine metabolism.

Comparison of neurogenic effects of fluoxetine, duloxetine and running in mice.

Hippocampal neurogenesis can be regulated by extrinsic factors, such as exercise and antidepressants. While there is evidence that the selective serotonin reuptake inhibitor (SSRI) fluoxetine enhances neurogenesis, the new dual serotonergic-noradrenergic reuptake inhibitor (SNRI) duloxetine has not been evaluated in this context. In addition, it is unclear whether effects of antidepressants and running on cell genesis and behavior are of similar magnitude in mice. Here, we assessed neurogenesis and open-field behavior in 2-month-old female C57Bl/6 mice after 28days of treatment with either fluoxetine (18mg/kg), duloxetine (2, 6 or 18mg/kg) or exercise. New cell survival, as measured by 5-bromo-2'-deoxyuridine (BrdU)-labeled cells, was enhanced by 200% in the running group only. Both running and fluoxetine, but not duloxetine, increased the percentage of new cells that became neurons. In the open-field test, animals treated with either drug spent less time in the center than controls and runners. In addition, fluoxetine treatment resulted in reduced locomotor activity. Together, these data show that the neurogenic response to exercise is much stronger than to antidepressants and imply a low likelihood that anxiolytic effects of these drugs are mediated by adult neurogenesis in C57Bl/6 mice.

Oxidative Stress and its Implications for Future Treatments and Management of Alzheimer Disease.

Oxidative imbalance is one of the earliest manifestations of Alzheimer disease (AD) actually preceding the classic pathology of amyloid ß deposits and neurofibrillary tangles. Clinical trials examining antioxidant modulation by a number of global interventions show efficacy, while simple supplementation has limited benefit suggesting complexity of multiple contributing factors. In this review, we highlight new insights regarding novel approaches to understanding and treating AD based on holistic views of oxidative balance including diet.

Subcellular and metabolic examination of amyloid-beta peptides in Alzheimer disease pathogenesis: evidence for Abeta(25-35).

Amyloid-beta peptide (Abeta) is a central player in the pathogenesis and diagnosis of Alzheimer disease. It aggregates to form the core of Alzheimer disease-associated plaques found in coordination with tau deposits in diseased individuals. Despite this clinical relevance, no single hypothesis satisfies and explicates the role of Abeta in toxicity and progression of the disease. To explore this area, investigators have focused on mechanisms of cellular dysfunction, aggregation, and maladaptive responses. Extensive research has been conducted using various methodologies to investigate Abeta peptides and oligomers, and these multiple facets have provided a wealth of data from specific models. Notably, the utility of each experiment must be considered in regards to the brain environment. The use of Abeta(25-35) in studies of cellular dysfunction has provided data indicating that the peptide is indeed responsible for multiple disturbances to cellular integrity. We will review how Abeta peptide induces oxidative stress and calcium homeostasis, and how multiple enzymes are deleteriously impacted by Abeta(25-35). Understanding and discussing the origin and properties of Abeta peptides is essential to evaluating their effects on various intracellular metabolic processes. Attention will also be specifically directed to metabolic compartmentation in affected brain cells, including mitochondrial, cytosolic, nuclear, and lysosomal enzymes.

Treatment advances in Alzheimer's disease based on the oxidative stress model.

Effective therapy for Alzheimer's disease (AD), up to this point, has been hampered by our inability to diagnose the disease in its early stages, before the occurrence of significant neurodegeneration and clinical symptoms. Because AD historically has been defined by neuropathologic criteria, treatment strategies have been aimed at diminishing the pathologic end result of the disease process, namely neurodegenerative changes associated with extracellular amyloid-beta-containing plaques, as well as intracellular neurofibrillary tangles of the hyper-phosphorylated microtubule protein, tau. While these avenues continue to be pursued, results thus far have been disappointing. It is now understood that oxidative stress plays a key role in the shared pathophysiology of neurodegenerative diseases and aging. For experimental treatment of AD, the focus of research and development efforts is increasingly shifting to target mechanisms of oxidative stress. Most recently, dimebon, whose mechanism of action relates to improved mitochondrial function, has emerged as a promising candidate for experimental treatment of AD.

Alzheimer's disease: cerebrovascular dysfunction, oxidative stress, and advanced clinical therapies.

Many lines of independent research have provided convergent evidence regarding oxidative stress, cerebrovascular disease, dementia, and Alzheimer's disease (AD). Clinical studies spurred by these findings engage basic and clinical communities with tangible results regarding molecular targets and patient outcomes. Focusing on recent progress in characterizing age-related diseases specifically highlights oxidative stress and mechanisms for therapeutic action in AD. Oxidative stress has been investigated independently for its relationship with aging and cardiovascular and neurodegenerative diseases and provides evidence of shared pathophysiology across these conditions. The mechanisms by which oxidative stress impacts the cerebrovasculature and blood-brain barrier are of critical importance for evaluating antioxidant therapies. Clinical research has identified homocysteine as a relevant risk factor for AD and dementia; basic research into molecular mechanisms associated with homocysteine metabolism has revealed important findings. Oxidative stress has direct implications in the pathogenesis of age-related neurodegenerative diseases and careful scrutiny of oxidative stress in the CNS has therapeutic implications for future clinical trials. These mechanisms of dysfunction, acting independently or in concert, through oxidative stress may provide the research community with concise working concepts and promising new directions to yield new methods for evaluation and treatment of dementia and AD.

The application of microarray technology to neuropathology: cutting edge tool with clinical diagnostics potential or too much information?

Microarray technology is a tremendously powerful method for simultaneously monitoring the expression of thousands of species of nucleic acids, usually cellular mRNA, producing a high-resolution representation of the genes encoded or expressed in a cell. As such, microarray technology has great potential for impacting research and clinical approaches to treatment. However, this complex technology has been challenging to apply as a result of difficulties discerning biologic variation from technologic issues, therefore slowing the application of the technology to human diagnostics. Nevertheless, significant advances in microarray technology, improvements that avoid potential pitfalls, and a wider spectrum of application are making this technology easier to apply. Indeed, microarray technology has provided valuable insights into mechanisms involving gene regulation and expression in Alzheimer disease, and it remains a powerful tool to identify biomarkers for disease diagnosis. Ultimately, the most robust markers will enable the application of more specific treatments particular to disease stages or subcategories. Currently, no widely applicable molecular test is available to identify those at risk for developing Alzheimer disease or those who have early markers of pathology but show discernible cognitive impairment. The progression of this technology will lead to earlier detection of the disease through enhanced understanding of disease onset and progression.

Estrogen bows to a new master: the role of gonadotropins in Alzheimer pathogenesis.

Epidemiological data showing a predisposition of women to develop Alzheimer disease (AD) led many researchers to investigate the role of sex steroids, namely estrogen, in disease pathogenesis. Although there is circumstantial support for the role of estrogen, the unexpected results of the Women's Health Initiative (WHI) Memory Study, which reported an increase in the risk for probable dementia and impaired cognitive performance in postmenopausal women treated with a combination of estrogen and progestin, have raised serious questions regarding the protective effects of estrogen. Although explanations for these surprising results vary greatly, the WHI Memory Study cannot be correctly interpreted without a complete investigation of the effects of the other hormones of the hypothalamic-pituitary-gonadal (HPG) axis on the aging brain. Certain hormones of the HPG axis, namely, the gonadotropins (luteinizing hormone and follicle-stimulating hormone), are not only involved in regulating reproductive function via a complex feedback loop but are also known to cross the blood-brain barrier. We propose that the increase in gonadotropin concentrations, and not the decrease in steroid hormone (e.g., estrogen) production following menopause/andropause, is a potentially primary causative factor for the development of AD. In this review, we examine how the gonadotropins may play a central and determining role in modulating the susceptibility to, and progression of, AD. On this basis, we suggest that the results of the WHI Memory Study are not only predictable but also avoidable by therapeutically targeting the gonadotropins instead of the sex steroids.

The cell cycle in Alzheimer disease: a unique target for neuropharmacology.

Several hypotheses have been proposed attempting to explain the pathogenesis of Alzheimer disease including, among others, theories involving amyloid deposition, tau phosphorylation, oxidative stress, metal ion dysregulation and inflammation. While there is strong evidence suggesting that each one of these proposed mechanisms contributes to disease pathogenesis, none of these mechanisms are able to account for all the physiological changes that occur during the course of the disease. For this reason, we and others have begun the search for a causative factor that predates known features found in Alzheimer disease, and that might therefore be a fundamental initiator of the pathophysiological cascade. We propose that the dysregulation of the cell cycle that occurs in neurons susceptible to degeneration in the hippocampus during Alzheimer disease is a potential causative factor that, together with oxidative stress, would initiate all known pathological events. Neuronal changes supporting alterations in cell cycle control in the etiology of Alzheimer disease include the ectopic expression of markers of the cell cycle, organelle kinesis and cytoskeletal alterations including tau phosphorylation. Such mitotic alterations are not only one of the earliest neuronal abnormalities in the disease, but as discussed herein, are also intimately linked to all of the other pathological hallmarks of Alzheimer disease including tau protein, amyloid beta protein precursor and oxidative stress, and even risk factors such as mutations in the presenilin genes. Therefore, therapeutic interventions targeted toward ameliorating mitotic changes would be predicted to have a profound and positive impact on Alzheimer disease progression.

Therapeutic opportunities in Alzheimer disease: one for all or all for one?

In recent years, Alzheimer disease (AD) has received great attention as an incurable and fatal disease that threatens the lives of aging individuals. Debates regarding areas of research and treatment designs have made headlines as scientists in the field question ongoing work. Despite these academic quarrels, significant insights concerning the cellular and molecular basis of AD have illuminated the potential causes and consequences of AD pathogenesis in the human brain. Additionally, assigning relationships among scientific evidence is difficult due to the nature of the disease. It is crucial to note that all findings do not constitute causality as AD has many stages of progression, and therefore a particular finding may reflect disease epiphenomenon. Determining the primary causes of disease are even more problematic when considering that a succinct timeline in which a normal aging brain develops AD-like changes due to a single cause may not be appropriate, as increasing lines of evidence indicate that multiple factors likely contribute to the clinical manifestation of AD. Implications for therapeutic strategies are dramatically affected by viewing AD as a multi-factorial disease state, one specific treatment may not be able to prevent or reverse AD if this is indeed the case. In this regard, the current focus on individual therapeutic targets may prove to be ineffective in the successful treatment of AD; however, if taken in combination, these singular therapies may likely result in the global suppression of AD. In this review, the scientific basis for common AD therapeutics as well as the efficacy of these treatments will be discussed.

Sources and mechanisms of cytoplasmic oxidative damage in Alzheimer's disease.

While evidence supports a pathogenic and proximal role for oxidative stress in Alzheimer's disease, the causes and consequences of reactive oxygen species that promote oxidative damage have not been directly demonstrated. Co-incident with the reduced energy metabolism during the development of the disease, some of the key mitochondrial enzymes have shown deficient activity in AD neurons, which may lead to increased ROS production. However, we found that oxidative damage occurs primarily within the cytoplasm rather than in mitochondria. Given that SOD activity is increased in AD mitochondria and that metal ions such as iron and copper are enriched in susceptible neurons, we hypothesize that mitochondria, as a source, provide hydrogen peroxide, which, as an intermediate, once in the cytoplasm, will be converted into highly reactive hydroxyl radicals through Fenton reaction in the presence of metal ion and cause damage in cytoplasm.

The role of metabotropic glutamate receptors in Alzheimer's disease.

While glutamatergic transmission is severely altered by early degeneration of cortico-cortical connections and hippocampal projections in Alzheimer's disease (AD), the role of glutamate receptors in the pathogenesis of AD is not yet defined clearly. Nonetheless, as reviewed here, the topographical distribution of different types of receptors likely contributes to the regional selective nature of neuronal degeneration. In particular, metabotropic glutamate receptors (mGluR) may contribute the pathogenesis of many neurological conditions and also regulate neuronal vulnerability against cytotoxic stress. Thus, we here discuss the possible role of mGluR in the pathogenesis of AD based on the results from other neurodegenerative diseases that may give us clues to solve the mysterious selective neurodegeneration evident in AD.