Gliosis of astrocytes cultivated on coral skeleton is regulated by the matrix surface topography.

Astrogilosis is the response of astrocytes to brain trauma which manifest opposite roles on brain injury repair. On the one hand, astrocytes undergoing astrogliosis inhibit tissue regeneration by forming scar tissue, but, on the other hand, they enhance damage repair through secretion of neuro-protecting and neurotrophic factors. Therefore, identifying means that regulate astrogliosis can provide a control over progression and repair of brain damage. We have previously shown that the calcium carbonate skeleton of corals upregulates two manifestations of astrogliosis in astrocytes in culture-expression of the Glial Fibrillay Acidic Protein (GFAP), and shape conversion from non-spiky to reactive spiky cell morphology. Here, we investigated if the surface topography of the coralline skeleton plays a role in GFAP expression and the morphogenesis of reactive astrocytes. To address that, we utilized the non-porous exoskeleton of the coral Trachyphyllia geoffroyi, having three topographies of distinct heights on its surface: rough surface (made of <30 µm height bumps), protrusions (50-250 µm) and ridges (>250 µm). We observed that astrocytes reacted similarly to all three structures in terms of adhesion, acquisition of a spiky morphology and organization in networks. By contrast, the extent by which these cells expressed GFAP was structure-dependent. The expression was 2-fold higher on protrusions and ridges than on the rough surface and acquired. Accordingly, the distribution pattern of the GFAP overexpressing astrocytes followed that of the protrusions and ridges. Hence, fabricating coralline scaffolds with designed flatness/protrusions/ridges ratios can serve to control astrogliosis-derived regeneration in TBI wounds, and as a result improve the capacity to repair brain damage.

p300 activation by Presenilin 1 but not by its M146L mutant.

The transcriptional co-activator p300 plays an important role in regulating gene expression in a number of different cell types. We have shown that wild type (WT) Presenilin 1 (PS1) stimulates the transcriptional activity ability of CREB Binding Protein (CBP), a close homolog of p300, whereas the Alzheimer's disease (AD) associated mutant of PS1 does not have this effect. A recent report has suggested that mutant PS1 can also disrupt the TCF/beta-catenin/CBP interaction but has no effect on the TCF/beta-catenin/p300 interaction. This suggests that the malregulation of CBP, but not of p300, caused by mutation in PS1 may be involved in the disease process. Here we show that wild type PS1 stimulates the transcriptional activity ability of p300 whereas an Alzheimer's disease-associated mutant of PS1 did not produce this effect. To our knowledge, this is the first report that shows regulation of p300 activity by WT PS1 and not by mutant PS1, indicating that like CBP, p300 can be differentially regulated by WT PS1 compared to its AD-associated mutant.

CREB-binding protein activation by presenilin 1 but not by its M146L mutant.

The transcriptional coactivator CREB-binding protein plays a key role in regulating gene expression in a number of different cell types. Recently, a report has suggested a link between CREB-binding protein and presenilins, which are mutated in many cases of early onset Alzheimer's disease. Thus, presenilin 1 and 2 double knockout mice showed reductions in CREB-binding protein levels and in cAMP response element-dependent gene expression in the cerebral cortex, which is likely to contribute to the subsequent neuronal degeneration. This suggests that the inactivation of CREB-binding protein caused by mutation in presenilin 1 may be involved in the disease process. We have shown that wild-type presenilin 1 stimulates the transcriptional activity ability of CREB-binding protein whereas presenilin 1 M146L mutant did not produce such an effect. The activation of CREB-binding protein by wild-type presenilin 1 involves the PI 3-kinase, p38 mitogen-activated protein kinase (MAPK) and p42/p44 MAPK pathways and targets primarily the C terminus of CREB-binding protein. To our knowledge, this is the first report that shows regulation of CREB-binding protein activity by wild-type presenilin 1 and not by its M146L mutant, and suggests a mechanism in which mutation of presenilin 1 may lead to neurodegeneration.

Dynamin 1 is required for memory formation.

Dynamin 1-3 isoforms are known to be involved in endocytotic processes occurring during synaptic transmission. No data has directly linked dynamins yet with normal animal behavior. Here we show that dynamin pharmacologic inhibition markedly impairs hippocampal-dependent associative memory. Memory loss was associated with changes in synaptic function occurring during repetitive stimulation that is thought to be linked with memory induction. Synaptic fatigue was accentuated by dynamin inhibition. Moreover, dynamin inhibition markedly reduced long-term potentiation, post-tetanic potentiation, and neurotransmitter released during repetitive stimulation. Most importantly, the effect of dynamin inhibition onto memory and synaptic plasticity was due to a specific involvement of the dynamin 1 isoform, as demonstrated through a genetic approach with siRNA against this isoform to temporally block it. Taken together, these findings identify dynamin 1 as a key protein for modulation of memory and release evoked by repetitive activity.

Soluble amyloid beta levels are elevated in the white matter of Alzheimer's patients, independent of cortical plaque severity.

Alzheimer's disease (AD) is the most common neurodegenerative disease and the leading cause of dementia. In addition to grey matter pathology, white matter changes are now recognized as an important pathological feature in the emergence of the disease. Despite growing recognition of the importance of white matter abnormalities in the pathogenesis of AD, the causes of white matter degeneration are still unknown. While multiple studies propose Wallerian-like degeneration as the source of white matter change, others suggest that primary white matter pathology may be due, at least in part, to other mechanisms, including local effects of toxic Aß peptides. In the current study, we investigated levels of soluble amyloid-beta (Aß) in white matter of AD patients (n=12) compared with controls (n=10). Fresh frozen white matter samples were obtained from anterior (Brodmann area 9) and posterior (Brodmann area 1, 2 and 3) areas of post-mortem AD and control brains. ELISA was used to examine levels of soluble Aß -42 and Aß -40. Total cortical neuritic plaque severity rating was derived from individual ratings in the following areas of cortex: mid-frontal, superior temporal, pre-central, inferior parietal, hippocampus (CA1), subiculum, entorhinal cortex, transentorhinal cortex, inferior temporal, amygdala and basal forebrain. Compared with controls, AD samples had higher white matter levels of both soluble Aß -42 and Aß -40. While no regional white matter differences were found in Aß -40, Aß -42 levels were higher in anterior regions than in posterior regions across both groups. After statistically controlling for total cortical neuritic plaque severity, differences in both soluble Aß -42 and Aß -40 between the groups remained, suggesting that white matter Aß peptides accumulate independent of overall grey matter fibrillar amyloid pathology and are not simply a reflection of overall amyloid burden. These results shed light on one potential mechanism through which white matter degeneration may occur in AD. Given that white matter degeneration may be an early marker of disease, preceding grey matter atrophy, understanding the mechanisms and risk factors that may lead to white matter loss could help to identify those at high risk and to intervene earlier in the pathogenic process.

Synthesis of quinoline derivatives: discovery of a potent and selective phosphodiesterase 5 inhibitor for the treatment of Alzheimer's disease.

Phosphodiesterase type 5 (PDE5) mediates the degradation of cGMP in a variety of tissues including brain. Recent studies have demonstrated the importance of the nitric oxide/cGMP/cAMP-responsive element-binding protein (CREB) pathway to the process of learning and memory. Thus, PDE5 inhibitors (PDE5Is) are thought to be promising new therapeutic agents for the treatment of Alzheimer's disease (AD), a neurodegenerative disorder characterized by memory loss. To explore this possibility, a series of quinoline derivatives were synthesized and evaluated. We found that compound 7a selectively inhibits PDE5 with an IC(50) of 0.27 nM and readily crosses the blood brain barrier. In an in vivo mouse model of AD, compound 7a rescues synaptic and memory defects. Quinoline-based, CNS-permeant PDE5Is have potential for AD therapeutic development.

Preparation of oligomeric beta-amyloid 1-42 and induction of synaptic plasticity impairment on hippocampal slices.

Impairment of synaptic connections is likely to underlie the subtle amnesic changes occurring at the early stages of Alzheimer s Disease (AD). beta-amyloid (A beta), a peptide produced in high amounts in AD, is known to reduce Long-Term Potentiation (LTP), a cellular correlate of learning and memory. Indeed, LTP impairment caused by A beta is a useful experimental paradigm for studying synaptic dysfunctions in AD models and for screening drugs capable of mitigating or reverting such synaptic impairments. Studies have shown that A beta produces the LTP disruption preferentially via its oligomeric form. Here we provide a detailed protocol for impairing LTP by perfusion of oligomerized synthetic A beta1-42 peptide onto acute hippocampal slices. In this video, we outline a step-by-step procedure for the preparation of oligomeric A beta(1-42;). Then, we follow an individual experiment in which LTP is reduced in hippocampal slices exposed to oligomerized A beta(1-42;) compared to slices in a control experiment where no A beta(1-42;) exposure had occurred.

Dysregulation of histone acetylation in the APP/PS1 mouse model of Alzheimer's disease.

Epigenetic mechanisms such as post-translational histone modifications are increasingly recognized for their contribution to gene activation and silencing in the brain. Histone acetylation in particular has been shown to be important both in hippocampal long-term potentiation (LTP) and memory formation in mice. The involvement of the epigenetic modulation of memory formation has also been proposed in neuropathological models, although up to now no clear-cut connection has been demonstrated between histone modifications and the etiology of Alzheimer's disease (AD). Thus, we have undertaken preclinical studies in the APP/PS1 mouse model of AD to determine whether there are differences in histone acetylation levels during associative memory formation. After fear conditioning training, levels of hippocampal acetylated histone 4 (H4) in APP/PS1 mice were about 50% lower than in wild-type littermates. Interestingly, acute treatment with a histone deacetylase inhibitor, Trichostatin A (TSA), prior to training rescued both acetylated H4 levels and contextual freezing performance to wild-type values. Moreover, TSA rescued CA3-CA1 LTP in slices from APP/PS1 mice. Based on this evidence, we propose the hypothesis that epigenetic mechanisms are involved in the altered synaptic function and memory associated with AD. In this respect, histone deacetylase inhibitors represent a new therapeutic target to effectively counteract disease progression.