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Herpes simplex virus type 1 (HSV-1) and herpes simplex virus type 2 (HSV-2) belong to the family Herpesviridae, the subfamily Alphaherpesvirinae, and the genus Simplexvirus. They are ubiquitous, neurotropic, and the most common pathogenic cause of sporadic acute encephalitis in humans. Herpes simplex encephalitis (HSE) is associated with a high mortality rate and significant neurological, neuropsychological, and neurobehavioral sequelae, which afflict patients for life. HSV-1 has been suggested as an environmental risk factor for Alzheimer's disease. However, the mechanisms involved in HSV-1 infection that may trigger the neurodegenerative process are still unknown. In general, HSV-1 induced cytoskeletal alterations reported to date involve the overall disruption of one or more elements of the cytoskeleton in cell lines. Axonal injury has recently attracted attention as a key predictor for the outcome of a number of brain disorders. Here we show that infection of mice neuronal cultures with HSV-1 result in marked neurite damage and neuronal death. Furthermore, in this in vitro model of infection, neurons manifested considerable alterations in microtubule dynamics and tau hyperphosphorylation. These results suggest a possible link between HSV-1 infection and neuronal cytoskeletal disruption.
A set of different protein kinases have been involved in tau phosphorylations, including glycogen synthase kinase 3beta (GSK3 beta), MARK kinase, MAP kinase, the cyclin-dependent kinase 5 (Cdk5) system and others. The latter system include the catalytic component Cdk5 and the regulatory proteins p35, p25 and p39. Cdk5 and its neuron-specific activator p35 are essential molecules for neuronal migration and for the laminar configuration of the cerebral cortex. Recent evidence that the Cdk5/p35 complex concentrates at the leading edge of axonal growth cones, together with the involvement of this system in the phosphorylation of neuronal microtubule-asociated proteins (MAPs), provide further support to the role of this protein kinase in regulating axonal extension in developing brain neurons. Although the aminoacid sequence of p35 has little similarity with those of normal cyclins, studies have shown that its activation domain may adopt a conformation of the cyclin-folded structure. The computed structure for Cdk5 is compatible with experimental data obtained from studies on the Cdk5/p35 complex, and has allowed predictions on the protein interacting domains. This enzyme exhibits a wide cell distribution, even though a regulated Cdk5 activity has been shown only in neuronal cells. Cdk5 has been characterized as a proline-directed Ser/Thr protein kinase, that contributes to phosphorylation of human tau on Ser202, Thr205, Ser235 and Ser404. Cdk5 is active in postmitiotic neurons, and it has been implicated in cytoskeleton assembly and its organization during axonal growth. In addition to tau and other MAPs, Cdk5 phosphorylates the high molecular weight neurofilament proteins at their C-terminal domain. Moreover, nestin, a protein that regulates cytoskeleton organization of neuronal and muscular cells during development of early embryos, and several other regulatory proteins appear to be substrates of Cdk5 and are phosphorylated by this kinase. Studies also suggest, that in addition to Cdk5 involvement in neuronal differentiation, its activity is induced during myogenesis, however, the mechanisms of how this activity is regulated during muscular differentiation has not yet been elucidated. Recent studies have shown that the beta-amyloid peptide (A beta) induces a deregulation of Cdk5 in cultured brain cells, and raises the question on the possible roles of this tau-phosphorylating protein kinase in the sequence of molecular events leading to neuronal death triggered by A beta. In this context, there are evidence that Cdk5 is involved in tau hyperphosphorylation promoted by A beta in its fibrillary form. Cdk5 inhibitors protect hippocampal neurons against both tau anomalous phosphorylations and neuronal death. The links between the studies on the Cdk5/p35 system in normal neurogenesis and its claimed participation in neurodegeneration, provide the framework to understand the regulatory relevance of this kinase system, and changes in its regulation that may be implicated in disturbances such as those occurring in Alzheime...
Previous studies of Aβ-induced neuronal damage of hippocampal cells in culture have provided strong evidence that deregulation of the Cdk5/p35 kinase system is involved in the neurodegeneration pathway. Cdk5 inhibitors and antisense probes neuroprotected hippocampal cells against the neurotoxic action of Aβ. To further investigate the mechanisms underlying the participation of Cdk5 in neuronal degeneration, the transgenic mouse containing the Swedish mutations, Tg2576, was used as an animal model. Immunocytochemical studies using anti-Aβ (1−17) antibody evidenced the presence of labeled small-clustered core plaques in the hippocampus and cortex of 18-month-old transgenic mice brains. The loss of granular cells without a compressed appearance was detected in the vicinity of the cores in the dentate gyrus of the hippocampus. Immunostaining of Tg2576 brain sections with antibodies AT8, PHF1 and GFAP labeled punctuate dystrophic neurites in and around the amyloid core. Reactive astrogliosis around the plaques in the hippocampus was also observed. Studies at the molecular level showed differences in the expression of the truncated Cdk5 activator p25 in the transgenic animal, as compared with wild type controls. However no differences in Cdk5 levels were detected, thus corroborating previous cellular findings. Interestingly, hyperphosphorylated tau epitopes were substantially increased as assessed with the AT8 and PHF1 antibodies, in agreement with the observation of a p25 increase in the transgenic animal. These observations strongly suggest that the increased exposure of Alzheimer's type tau phosphoepitopes in the transgenic mice correlated with deregulation of Cdk5 leading to an increase in p25 levels. These studies also provide further evidence on the links between extraneuronal amyloid deposition and tau pathology.
Alzheimer’s disease (AD) is the most common cause of age-related dementia leading to severe irreversible cognitive decline and massive neurodegeneration. While therapeutic approaches for managing symptoms are available, AD currently has no cure. AD associates with a progressive decline of the two major catabolic pathways of eukaryotic cells—the autophagy-lysosomal pathway (ALP) and the ubiquitin-proteasome system (UPS)—that contributes to the accumulation of harmful molecules implicated in synaptic plasticity and long-term memory impairment. One protein recently highlighted as the earliest initiator of these disturbances is the amyloid precursor protein (APP) intracellular C-terminal membrane fragment β (CTFβ), a key toxic agent with deleterious effects on neuronal function that has become an important pathogenic factor for AD and a potential biomarker for AD patients. This review focuses on the involvement of regulatory molecules and specific post-translational modifications (PTMs) that operate in the UPS and ALP to control a single proteostasis network to achieve protein balance. We discuss how these aspects can contribute to the development of novel strategies to strengthen the balance of key pathogenic proteins associated with AD.
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