Fluoxetine Prevents Aβ1-42-Induced Toxicity via a Paracrine Signaling Mediated by Transforming-Growth-Factor-β1

Caraci, Filippo; Tascedda, Fabio; Merlo, Sara; Benatti, Cristina; Spampinato, Simona Federica; Munafò, Antonio; Leggio, Gian Marco; Nicoletti, Ferdinando; Brunello, Nicoletta; Drago, Filippo; Sortino, Maria Angela; Copani, Agata

doi:10.3389/fphar.2016.00389

Cited by 44 publications

(35 citation statements)

References 66 publications

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“…Indeed, there are some reports of tau-induced cell cycle entry in neurons (Andorfer et al, 2005;Bonda et al, 2009;Jaworski et al, 2009;Seward et al, 2013a;Hradek et al, 2014), albeit entry mediated by NFT has been contested (Jaworski et al, 2009), and at least in some cases it involves Aβ (Seward et al, 2013a;Hradek et al, 2014). When compared to tau-related models, cell cycle deregulation has been vigorously researched in models of Aβ pathology (Copani et al, 1999(Copani et al, , 2006Giovanni et al, 1999Giovanni et al, , 2000Park et al, 2000;Wu et al, 2000;Kruman et al, 2004;Sortino et al, 2004;Yang et al, 2006;Caraci et al, 2008;Majd et al, 2008;Varvel et al, 2008Varvel et al, , 2009Bhaskar et al, 2009;Lopes et al, 2009Lopes et al, , 2010Li et al, 2011;Modi et al, 2012Modi et al, , 2015Seward et al, 2013b;Hradek et al, 2014;Merlo et al, 2015;Caraci et al, 2016;Leggio et al, 2016; Table 1). Virtually all reports report cell cycle related cell death, which is of relevance for senescence.…”

Section: Neuronal Cell Cycle Entry In Admentioning

confidence: 99%

Senescence as an Amyloid Cascade: The Amyloid Senescence Hypothesis

Walton

Begelman

Nguyen

et al. 2020

Front. Cell. Neurosci.

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Section: Neuronal Cell Cycle Entry In Admentioning

confidence: 99%

Senescence as an Amyloid Cascade: The Amyloid Senescence Hypothesis

Walton

Begelman

Nguyen

et al. 2020

Front. Cell. Neurosci.

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“…Interestingly different preclinical and clinical studies have shown that ketamine is endowed with anti-inflammatory activity (De Kock et al, 2013) and reverses inflammation-induced depression in the lipopolysaccharide model by decreasing brain levels of inflammatory cytokines (Yang et al, 2013) or by blocking the effects of quinolinic acid, a downstream product of the kynurenine pathway, on NMDA receptors (Walker et al, 2013b). Furthermore, recent in vitro studies have shown that fluoxetine and venlafaxine increase the release of TGF-b1, an antiinflammatory cytokine that is reduced in nonresponder MDD patients (Vollmar et al, 2008;Caraci et al, 2016).…”

Section: E Immune System Dysregulation and Neuroinflammationmentioning

confidence: 99%

International Union of Basic and Clinical Pharmacology CIV: The Neurobiology of Treatment-resistant Depression: From Antidepressant Classifications to Novel Pharmacological Targets

et al. 2018

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Major depressive disorder is one of the most prevalent and life-threatening forms of mental illnesses and a major cause of morbidity worldwide. Currently available antidepressants are effective for most patients, although around 30% are considered treatment resistant (TRD), a condition that is associated with a significant impairment of cognitive function and poor quality of life. In this respect, the identification of the molecular mechanisms contributing to TRD represents an essential step for the design of novel and more efficacious drugs able to modify the clinical course of this disorder and increase remission rates in clinical practice. New insights into the neurobiology of TRD have shed light on the role of a number of different mechanisms, including the glutamatergic system, immune/inflammatory systems, neurotrophin function, and epigenetics. Advances in drug discovery processes in TRD have also influenced the classification of antidepressant drugs and novel classifications are available, such as the neuroscience-based nomenclature that can incorporate such advances in drug development for TRD. This review aims to provide an up-to-date description of key mechanisms in TRD and describe current therapeutic strategies for TRD before examining novel approaches that may ultimately address important neurobiological mechanisms not targeted by currently available antidepressants. All in all, we suggest that drug targeting different neurobiological systems should be able to restore normal function but must also promote resilience to reduce the long-term vulnerability to recurrent depressive episodes.

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“…Fluoxetine effectively acts on a wide spectrum of mood disorders and protects against the adverse effects of different types of stressors by decreasing some effects of stress on the immune system and by protecting against oxidative damage. Different molecular mechanisms have been proposed to explain its neuroprotective effects, including BDNF (Brain-derived Neurotrophic Factor) release, antagonism on NMDA (N-methyl-D-aspartate) receptors, the inhibition of NF-kB (Nuclear Factor Kappa B Subunit 1) activity, and inhibition of the release of pro-inflammatory factors (TNF-α, Tumor Necrosis Factor-Alpha, IL-1β, Interleukin 1 Beta) from microglial cells [12]. However, the underlying mechanisms of its therapeutic efficacy remain unclear, particularly those related to its antioxidant activity.…”

Section: Introductionmentioning

confidence: 99%

Major Depressive Disorder and Oxidative Stress: In Silico Investigation of Fluoxetine Activity against ROS

et al. 2019

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Major depressive disorder is a psychiatric disease having approximately a 20% lifetime prevalence in adults in the United States (U.S.), as reported by Hasin et al. in JAMA Psichiatry 2018 75, 336–346. Symptoms include low mood, anhedonia, decreased energy, alteration in appetite and weight, irritability, sleep disturbances, and cognitive deficits. Comorbidity is frequent, and patients show decreased social functioning and a high mortality rate. Environmental and genetic factors favor the development of depression, but the mechanisms by which stress negatively impacts on the brain are still not fully understood. Several recent works, mainly published during the last five years, aim at investigating the correlation between treatment with fluoxetine, a non-tricyclic antidepressant drug, and the amelioration of oxidative stress. In this work, the antioxidant activity of fluoxetine was investigated using a computational protocol based on the density functional theory approach. Particularly, the scavenging of five radicals (HO•, HOO•, CH3OO•, CH2=CHOO•, and CH3O•) was considered, focusing on hydrogen atom transfer (HAT) and radical adduct formation (RAF) mechanisms. Thermodynamic as well as kinetic aspects are discussed, and, for completeness, two metabolites of fluoxetine and serotonin, whose extracellular concentration is enhanced by fluoxetine, are included in our analysis. Indeed, fluoxetine may act as a radical scavenger, and exhibits selectivity for HO• and CH3O•, but is inefficient toward peroxyl radicals. In contrast, the radical scavenging efficiency of serotonin, which has been demonstrated in vitro, is significant, and this supports the idea of an indirect antioxidant efficiency of fluoxetine.

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Fluoxetine Prevents Aβ1-42-Induced Toxicity via a Paracrine Signaling Mediated by Transforming-Growth-Factor-β1

Cited by 44 publications

References 66 publications

Senescence as an Amyloid Cascade: The Amyloid Senescence Hypothesis

Senescence as an Amyloid Cascade: The Amyloid Senescence Hypothesis

International Union of Basic and Clinical Pharmacology CIV: The Neurobiology of Treatment-resistant Depression: From Antidepressant Classifications to Novel Pharmacological Targets

Major Depressive Disorder and Oxidative Stress: In Silico Investigation of Fluoxetine Activity against ROS

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