Almudena Fuster-Matanzo

GSK3: a possible link between beta amyloid peptide and tau protein.

Tau is a neuronal microtubule-associated phosphoprotein that is highly phosphorylated by glycogen synthase kinase 3 (GSK3). Tau phosphorylation by GSK3 regulates tau binding to microtubules, tau degradation and tau aggregation. Tau phosphorylation is important in Alzheimer disease pathology and in other tauopathies. In Alzheimer disease, it has been proposed that the peptide beta amyloid promotes GSK3 activation, resulting in tau phosphorylation. In this work, we review the links between beta amyloid peptide, tau protein and GSK3 that occur in familial Alzheimer disease. We also discuss the possible links between GSK3 and sporadic Alzheimer disease. Finally, we include a brief review of the pathology of animal models overexpressing GSK3.

GSK3β overexpression induces neuronal death and a depletion of the neurogenic niches in the dentate gyrus

Overexpression of GSK3β in transgenic mice induces learning deficits and some features associated with Alzheimers disease (AD), including dentate gyrus (DG) atrophy. Here, we assessed whether these mice also recapitulate DG atrophy as well as impaired neurogenesis reported in AD. Ultrastructural analysis revealed that there were fewer and more disorganized neurogenic niches in these animals, coupled with an increase in the proportion of immature neurons. Indeed, the maturation of granule cells is delayed as witnessed by the alterations to the length and patterning of their dendritic trees and to the mossy fiber terminals. Together with an increase in neuronal death, these phenomena lead to a marked decrease in the number and disorganization of granule cells of the DG. Our results suggest that GSK3β overexpression perturbs proliferation and maturation, resulting in the loss of immature neurons. In turn, the activation of microglia is stimulated in conjunction with a decrease in the birth of new functional neurons, leading to the deterioration of this structure. These data support the idea that by inducing degeneration of the DG, GSK3β could be involved in the pathogenesis of AD.

Tau Protein and Adult Hippocampal Neurogenesis

Tau protein is a microtubule-associated protein found in the axonal compartment that stabilizes neuronal microtubules under normal physiological conditions. Tau metabolism has attracted much attention because of its role in neurodegenerative disorders called tauopathies, mainly Alzheimer disease. Here, we review recent findings suggesting that axonal outgrowth in subgranular zone during adult hippocampal neurogenesis requires a dynamic microtubule network and tau protein facilitates to maintain that dynamic cytoskeleton. Those functions are carried out in part by tau isoform with only three microtubule-binding domains (without exon 10) and by presence of hyperphosphorylated tau forms. Thus, tau is a good marker and a valuable tool to study new axons in adult neurogenesis.

Function of tau protein in adult newborn neurons

Levels of tau phosphorylation are high during the developmental period of intense neurite outgrowth, but decrease later. We here investigated whether tau protein plays a role in adult neurogenesis. First we demonstrate that new neurons generated in the subgranular zone express tau in a hyperphosphorylated form. Phospho‐tau expression colocalized with doublecortin but not with glial fibrillary acidic protein, Ki67 or calbindin. The same was observed in the subventricular zone. Tau knockout mice did not show a significant decrease in the number of doublecortin‐positive cells, although a deficit in migration was observed. These findings suggest that basal tau phosphorylation present in adult animals is in part due to neurogenesis, and from Tau knockout mice it seems that tau is involved in normal migration of new neurons.

Dual effects of increased glycogen synthase kinase-3β activity on adult neurogenesis

Adult neurogenesis, the generation of new neurons during the adulthood, is a process controlled by several kinases and phosphatases among which GSK3β exerts important functions. This protein is particularly abundant in the central nervous system, and its activity deregulation is believed to play a key role in chronic disorders such as Alzheimers disease. Previously, we reported that in vivo overexpression of GSK3β (Tet/GSK3β mice) causes alterations in adult neurogenesis, leading to a depletion of the neurogenic niches. Here, we have further characterized those alterations, finding a delay in the switching-off of doublecortin marker as well as changes in the survival and death rates of immature precursors and a decrease in the total number of mature neurons. Besides, we have highlighted the importance of the inflammatory environment, identifying eotaxin as a possible modulator of the detrimental effects on adult neurogenesis. Taking advantage of the conditional system, we have also explored whether these negative consequences of increasing GSK3 activity are susceptible to revert after doxycycline treatment. We show that transgene shutdown in symptomatic mice reverts microgliosis, abnormal eotaxin levels as well as the aforementioned alterations concerning immature neurons. Unexpectedly, the decrease in the number of mature neurons and neuronal precursor cells of the subgranular zone of Tet/GSK3β mice could not be reverted. Thus, alterations in adult neurogenesis and likely in neurodegenerative disorders can be restored in part, although neurogenic niche depletion represents a non-reversible damage persisting during lifetime with a remarkable impact in adult mature neurons.

Different Susceptibility to Neurodegeneration of Dorsal and Ventral Hippocampal Dentate Gyrus: A Study with Transgenic Mice Overexpressing GSK3β

Dorsal hippocampal regions are involved in memory and learning processes, while ventral areas are related to emotional and anxiety processes. Hippocampal dependent memory and behaviour alterations do not always come out in neurodegenerative diseases at the same time. In this study we have tested the hypothesis that dorsal and ventral dentate gyrus (DG) regions respond in a different manner to increased glycogen synthase kinase-3β (GSK3β) levels in GSK3β transgenic mice, a genetic model of neurodegeneration. Reactive astrocytosis indicate tissue stress in dorsal DG, while ventral area does not show that marker. These changes occurred with a significant reduction of total cell number and with a significantly higher level of cell death in dorsal area than in ventral one as measured by fractin-positive cells. Biochemistry analysis showed higher levels of phosphorylated GSK3β in those residues that inactivate the enzyme in hippocampal ventral areas compared with dorsal area suggesting that the observed susceptibility is in part due to different GSK3 regulation. Previous studies carried out with this animal model had demonstrated impairment in Morris Water Maze and Object recognition tests point out to dorsal hippocampal atrophy. Here, we show that two tests used to evaluate emotional status, the light–dark box and the novelty suppressed feeding test, suggest that GSK3β mice do not show any anxiety-related disorder. Thus, our results demonstrate that in vivo overexpression of GSK3β results in dorsal but not ventral hippocampal DG neurodegeneration and suggest that both areas do not behave in a similar manner in neurodegenerative processes.

Looking for novel functions of tau.

The lack or excess of the protein tau can be deleterious for neurons. The absence of tau can result in retarded neurogenesis and neuronal differentiation, although adult mice deficient in tau are viable, probably because of the compensation of the loss of tau by other MAPs (microtubule-associated proteins). On the contrary, the overexpression of tau can be toxic for the cell. One way to reduce intracellular tau levels can be achieved by its secretion through microvesicles to the extracellular space. Furthermore, tau can be found in the extracellular space because of the neuronal cell death occurring in neurodegenerative disorders such as Alzheimers disease. The presence of toxic extracellular tau could be the mechanism for the spreading of tau pathology in these neurodegenerative disorders.

Tau Kinase I Overexpression Induces Dentate Gyrus Degeneration

Familial Alzheimer gene mutations result in a signaling mechanism that converges, downstream, in the activation of GSK3 activity. We have generated a GSK3 transgenic mouse model to study the consequences of GSK3 activation. In this model, dentate gyrus is degenerated in a process in which phosphorylated tau can be involved.

Tau Spreading Mechanisms; Implications for Dysfunctional Tauopathies

Tauopathies comprise a group of progressive age-associated neurodegenerative diseases where tau protein deposits are found as the predominant pathological signature (primary tauopathies) or in combination with the presence of other toxic aggregates (secondary tauopathies). In recent years, emerging evidence suggests that abnormal tau accumulation is mediated through spreading of seeds of the protein from cell to cell, favouring the hypothesis of a prion-like transmission of tau to explain the propagation of the pathology. This would also support the concept that the pathology initiates in a very small part of the brain before becoming symptomatic and spreads across the brain over time. To date, many key questions still remain unclear, such as the nature of the tau species involved in the spreading, the precise seeding/template and uptaking mechanisms or the selectivity explaining why certain neurons are affected and some others are not. A better understanding of the tau spreading machinery will contribute to the development of new therapeutic approaches focused on halting the abnormal propagation, offering also new perspectives for early diagnosis and preventive therapies. In this review, we will cover the most recent advances in tau spreading mechanisms as well as the implications of these findings for dysfunctional tauopathies.

GSK-3ò, Adult Neurogenesis and Neurodegeneration

The most outstanding histopathological hallmarks of Alzheimer disease (AD) are the senile plaques (main component is the Beta Amyloid (Aβ) peptide) and the neurofibrillary tangles (composed of tau protein, mainly in its phosphorylated form) [1]. One of the earliest and more prominent clinical symptoms of the disease is episodic memory impairment. Several studies have attempted to correlate the presence of plaques and/or tangles with the cognitive decline, trying to correlate Aβ, tau protein and cognitive performance [2].