Felix Junyent

Role of cell cycle re-entry in neurons: a common apoptotic mechanism of neuronal cell death.

Currently, there is no effective treatment for neurodegenerative disorders such as Alzheimer’s disease and Parkinson’s disease. Thus, a major focus of neuroscience research is to examine the mechanisms involved in neuronal loss in order to identify potential drug targets. Recent results indicate that DNA damage and re-entry into the cell cycle may constitute a common pathway in apoptosis in neurological diseases. The role of the cell cycle in such disorders is supported by data on the brain of patients who showed an increase in cell-cycle protein expression. Indeed, studies performed in neuronal cell preparations indicate that oxidative stress could be the main mechanism responsible for cell cycle re-entry. DNA damage and repair after oxidative stress may activate the enzyme ataxia telangiectasia mutated, which is a cell-cycle regulator. Once the cell cycle is activated, the increase in the expression of transcription factor E2F-1 could induce neuronal apoptosis. Furthermore, the potential routes involved in E2F-1 induced apoptosis could be p53-dependent or p53-independent. Under this E2F-1 hypothesis of cell death, multiple mitochondria-dependent pathways may be activated, including caspase and caspase-independent signaling cascades. Finally, given that cyclin-dependent kinase inhibitory drugs have neuroprotective and anti-apoptotic effects in experimental models, their potential application for the treatment of neurological disorders should be taken into account.

Sirtuin activators: Designing molecules to extend life span

Resveratrol (RESV) exerts important pharmacological effects on human health: in addition to its beneficial effects on type 2 diabetes and cardiovascular diseases, it also modulates neuronal energy homeostasis and shows antiaging properties. Although it clearly has free radical scavenger properties, the mechanisms involved in these beneficial effects are not fully understood. In this regard, one area of major interest concerns the effects of RESV on the activity of sirtuin 1 (SIRT1), an NAD(+)-dependent histone deacetylase that has been implicated in aging. Indeed, the role of SIRT1 is currently the subject of intense research due to the antiaging properties of RESV, which increases life span in various organisms ranging from yeast to rodents. In addition, when RESV is administered in experimental animal models of neurological disorders, it has similar beneficial effects to caloric restriction. SIRT1 activation could thus constitute a potential strategic target in neurodegenerative diseases and in disorders involving disturbances in glucose homeostasis, as well as in dyslipidaemias or cardiovascular diseases. Therefore, small SIRT1 activators such as SRT501, SRT2104, and SRT2379, which are currently undergoing clinical trials, could be potential drugs for the treatment of type 2 diabetes, obesity, and metabolic syndrome, among other disorders. This review summarises current knowledge about the biological functions of SIRT1 in aging and aging-associated diseases and discusses its potential as a pharmacological target.

Zac1 is expressed in progenitor/stem cells of the neuroectoderm and mesoderm during embryogenesis: Differential phenotype of the Zac1-expressing cells during development

Zac1, a new zinc‐finger protein that regulates both apoptosis and cell cycle arrest, is abundantly expressed in many neuroepithelia during early brain development. In the present work, we study the expression of Zac1 during early embryogenesis and we determine the cellular phenotype of the Zac1‐expressing cells throughout development. Our results show that Zac1 is expressed in the progenitor/stem cells of several tissues (nervous system, skeleton, and skeletal muscle), because they colocalize with several progenitor/stem markers (Nestin, glial fibrillary acidic protein, FORSE‐1, proliferating cell nuclear antigen, and bromodeoxyuridine). In postnatal development, Zac1 is expressed in all phases of the life cycle of the chondrocytes (from proliferation to apoptosis), in some limbic γ‐aminobutyric acid‐ergic neuronal subpopulations, and during developmental myofibers. Therefore, the intense expression of Zac1 in the progenitor/stem cells of different cellular lineages during the proliferative cycle, before differentiation into postmitotic cells, suggests that Zac1 plays an important role in the control of cell fate during neurogenesis, chondrogenesis, and myogenesis. Developmental Dynamics 233:667–679, 2005.

Novel huprine derivatives with inhibitory activity toward β-amyloid aggregation and formation as disease-modifying anti-Alzheimer drug candidates.

A new family of dual binding site acetylcholinesterase (AChE) inhibitors has been designed, synthesized, and tested for their ability to inhibit AChE, butyrylcholinesterase (BChE), AChE‐induced and self‐induced β‐amyloid (Aβ) aggregation and β‐secretase (BACE‐1), and to cross the blood–brain barrier. The new heterodimers consist of a unit of racemic or enantiopure huprine Y or X and a donepezil‐related 5,6‐dimethoxy‐2‐[(4‐piperidinyl)methyl]indane moiety as the active site and peripheral site to mid‐gorge‐interacting moieties, respectively, connected through a short oligomethylene linker. Molecular dynamics simulations and kinetics studies support the dual site binding to AChE. The new heterodimers are potent inhibitors of human AChE and moderately potent inhibitors of human BChE, AChE‐induced and self‐induced Aβ aggregation, and BACE‐1, and are predicted to be able to enter the central nervous system (CNS), thus constituting promising multitarget anti‐Alzheimer drug candidates with the potential to modify the natural course of this disease.

Neuroprotective and anti-ageing role of leptin

Leptin (Lep), an adipose-derived hormone, exerts very important functions in the body mainly on energy storage and availability. The physiological effects of Lep controlling the body weight and suppressing appetite are mediated by the long form of Lep receptor in the hypothalamus. Lep receptor activates several downstream molecules involved in key pathways related to cell survival such as STAT3, PI3K, MAPK, AMPK, CDK5 and GSK3β. Collectively, these pathways act in a coordinated manner and form a network that is fully involved in Lep physiological response. Although the major interest in Lep is related to its role in the regulation of energy balance, and since resistance to Lep affects is the primary risk factor for obesity, the interest on their effects on brain cognition and neuroprotection is increasing. Thus, Lep and Lep mimetic compounds now await and deserve systematic exploration as the orchestrator of protective responses in the nervous system. Moreover, Lep might promote the activation of a cognitive process that may retard or even partially reverse selected aspects of Alzheimers disease or ageing memory loss.

Prevention of epilepsy by taurine treatments in mice experimental model.

An experimental model based on kainic acid (KA) injections replicates many phenomenological features of human temporal lobe epilepsy, the most common type of epilepsy in adults. Taurine, 2‐aminoethanesulfonic acid, present in high concentrations in many invertebrate and vertebrate systems, is believed to serve several important biological functions. In addition, it is believed to have a neuroprotective role against several diseases. In the present study, an experimental mouse model based on taurine pretreatment prior to KA administration has been improved to study whether taurine has a neuroprotective effect against KA‐induced behavior and cell damage. Under different treatments tested, taurines most neuroprotective effects were observed with intraperitoneal taurine injection (150 mg/kg dosage) 12 hr before KA administration. Thus, a reduction in or total absence of seizures, together with a reduction in or even disappearance of cellular and molecular KA‐derived effects, was detected in mice pretreated with taurine compared with those treated only with KA. Moreover, the use of tritiated taurine revealed taurine entry into the brain, suggesting possible changes in intracellular:extracellular taurine ratios and the triggering of pathways related to neuroprotective effects.

Calpains as a Target for Therapy of Neurodegenerative Diseases: Putative Role of Lithium

Lithium is a simple cation that has been used clinically since 1950 for the treatment of bipolar disorder. However in the last decade numerous studies either using animal models or human trials suggest that this cation may delay progression of neurodegenerative diseases. One of the main challenges facing researchers in the neurosciences is to identify key molecules in neuronal apoptosis. This would facilitate the identification of targets in order to design drugs for the treatment of Alzheimers disease, Parkinsons disease and other neurological disorders. Although enormous effort has been made in the past few years and it has been demonstrated that the mitochondria comprise a key component of the neuronal apoptotic route, it seems that in addition to the mitochondria other intracellular components are implicated in this process. It has been proposed that DNA damage and re-entry into the cell cycle or the activation of different proteases, such as calpain, could constitute a common pathway in the apoptotic process and thus death processes in neurological diseases. The hypothesis about the implication of calpain in neuronal cell death is supported by existing data on neurodegenerative disorders in the brains of patients who show an increase in proteolytic activity of calpain compared with control brains. Indeed, studies performed in neuronal cell preparations suggest that activation of this protease is accompanied by other features such as structural modifications of the cytoskeleton, cleavage of several receptors, activation of kinases, such as cdk5 or GSK3ss, etc. Here, we summarize the potential routes involved in neurodegenerative disorders related to calpain activation, mainly those connected with changes in calcium homeostasis machinery, activation of kinase pathways, transcription factors, and the cell cycle.

Oxidative stress-induced DNA damage and cell cycle regulation in B65 dopaminergic cell line

Reactive oxygen species and oxidative stress are associated with neuronal cell death in many neurodegenerative conditions. However, the exact molecular mechanisms triggered by oxidative stress in neurodegeneration are still unclear. This study used the B65 rat neuroblastoma cell line as a model to study the molecular events that occur after H2O2 treatment. Treatment of B65 cells with H2O2 rapidly up-regulated the DNA damage pathway involved in double-strand breakage. Subsequently, proteins involved in p53 regulation, such as sirtuin 1 and STAT1, were modified. In addition, H2O2 treatment altered the pattern of cell cycle protein expression. Specifically, a decrease was found in the expression of cyclin D1, cdk4 and surprisingly the levels of cyclin A and the retinoblastoma protein phosphorylated at ser780 were increased. Furthermore, this study shows that pre-treatment of B65 cells with 50 µM trolox confers almost total protection against apoptotic cell death and restores the cell cycle. Likewise, the increase in retinoblastoma phosphorylation was attenuated by KU-55993, a selective ATM inhibitor, and also by trolox. These observations indicate that DNA damage and oxidative stress are responsible for cell cycle regulation. In summary, this study describes the molecular mechanisms involved in cell cycle alterations induced by oxidative stress in B65 cells. These findings highlight the relevance of ATM in the regulation of cell cycle after oxidative stress.

Antiapoptotic drugs: a therapautic strategy for the prevention of neurodegenerative diseases.

The purpose of this review is to discuss potential pathways involved in the pathogenesis of neurodegenerative diseases, highlighting current pharmacological drug targets in neuronal apoptosis prevention. The incidence of these disorders is expected to rise in the coming years and so finding effective treatments represents a significant challenge for medicine. Alzheimers disease and Parkinsons disease were both described almost a century ago and are the most important neurodegenerative disorders in the developed world. However, the molecular mechanisms that lead to the development of the neuronal pathology in both diseases are unclear. For this reason, despite substantial research in the area, an effective treatment for these diseases does not yet exist. In the present study we discuss in depth the pathways involved in apoptosis and neuronal death in neurodegenerative diseases. We also examine drugs that may have a neuroprotective effect. Inhibition of apoptosis mediated by oxidative stress generation and mitochondrial alteration or by the blockade of NMDA receptors could constitute a suitable therapeutic strategy for Alzheimers disease. A multiple therapy with antioxidants, cell cycle inhibitors, GSK3β inhibitors, and STATINS could, in the future, represent a suitable strategy for delaying the progression of neurodegenerative diseases. This research contributes to the development of new methods in the field of apoptosis inhibitors that could provide the future tools for the treatment of Alzheimers and Parkinsons disease, as well as other neurodegenerative diseases.

Neuroprotective role of intermittent fasting in senescence-accelerated mice P8 (SAMP8)

Dietary interventions have been proposed as a way to increase lifespan and improve health. The senescence-accelerated prone 8 (SAMP8) mice have a shorter lifespan and show alterations in the central nervous system. Moreover, this mouse strain shows decreased sirtuin 1 protein expression and elevated expression of the acetylated targets NFkappaB and FoxO1, which are implicated in transcriptional control of key genes in cell proliferation and cell survival, in reference to control strain, SAMR1. After eight weeks of intermittent fasting, sirtuin 1 protein expression was recovered in SAMP8. This recovery was accompanied by a reduction in the two acetylated targets. Furthermore, SAMP8 showed a lower protein expression of BDNF and HSP70 while intermittent fasting re-established normal values. The activation of JNK and FoxO1 was also reduced in SAMP8 mice subjected to an IF regimen, compared with control SAMP8. Our findings provide new insights into the participation of sirtuin 1 in ageing and point to a potential novel application of this enzyme to prevent frailty due to ageing processes in the brain.