VEGF preconditioning leads to stem cell remodeling and attenuates age-related decay of adult hippocampal neurogenesis

Licht, Tamar; Rothe, Gadiel; Kreisel, Tirzah; Wolf, Brachi; Benny, Ofra; Rooney, Alasdair G; ffrench‐Constant, Charles; Enikolopov, Grigori; Keshet, Eli

doi:10.1073/pnas.1609592113

Cited by 64 publications

(55 citation statements)

References 55 publications

(75 reference statements)

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“…Vascular endothelial growth factor (VEGF) may mediate exercise-induced vascular plasticity, adult neurogenesis, and communication between peripheral tissues and brain (Carmeliet 2003; Fabel et al 2003; Cotman et al 2007; Udo et al 2008). VEGF is involved in blood vessel formation (Prior et al 2003; Gavin et al 2004; Kraus et al 2004) and can attenuate the aged-related decline in neurogenesis (Licht et al 2016). The importance of VEGF for neurogenesis was first shown in songbirds.…”

Section: Cerebrovascular Plasticitymentioning

confidence: 99%

On the Run for Hippocampal Plasticity

Cooper

Moon

Praag

2017

Cold Spring Harb Perspect Med

125

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Accumulating research in rodents and humans indicates that exercise benefits brain function and may prevent or delay onset of neurodegenerative conditions. In particular, exercise modifies the structure and function of the hippocampus, a brain area important for learning and memory. This review addresses the central and peripheral mechanisms underlying the beneficial effects of exercise on the hippocampus. We focus on running-induced changes in adult hippocampal neurogenesis, neural circuitry, neurotrophins, synaptic plasticity, neurotransmitters, and vasculature. The role of peripheral factors in hippocampal plasticity is also highlighted. We discuss recent evidence that systemic factors released from peripheral organs such as muscle (myokines), liver (hepatokines), and adipose tissue (adipokines) during exercise contribute to hippocampal neurotrophin and neurogenesis levels, and memory function. A comprehensive understanding of the body–brain axis is needed to elucidate how exercise improves hippocampal plasticity and cognition.

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Section: Cerebrovascular Plasticitymentioning

confidence: 99%

On the Run for Hippocampal Plasticity

Cooper

Moon

Praag

2017

Cold Spring Harb Perspect Med

125

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“…Some NSCs are short-lived and divide rapidly to mainly produce granule neuronsexhibiting "division-coupled differentiation" behavior (Encinas et al, 2011) or "developmental-like model" behavior (Pilz et al, 2018). Meanwhile, some studies (Bonaguidi et al, 2011;Dranovsky et al, 2011;Jang et al, 2013;Licht et al, 2016) have advanced a stem cell maintenance model where NSCs are longer lived, slowly cycle in and out of quiescence, can generate neurons, astrocyte and self-renew. We reasoned that cellular heterogeneity within the radial glial-like NSC pool masks the ability to precisely uncover which mechanisms contribute to NSC dysfunction over time (Bonaguidi et al, , 2016.…”

Section: Asynchronous Nsc Decline During Agingmentioning

confidence: 99%

“…Consistently, forced accelerated neurogenesis (Ehm et al, 2010;Jones et al, 2015;Renault et al, 2009) and pathological conditions (Mu and Gage, 2011;Sierra et al, 2015) can result in premature NSC depletion. In another scenario, studies (Bonaguidi et al, 2011;Dranovsky et al, 2011;Licht et al, 2016) have shown that self-renewing NSCs are maintained and neurogenesis instead could decline during aging due to an increase in NSC quiescence (Hattiangady and Shetty, 2008;Ziebell et al, 2018). While NSCs as a population clearly undergo early age-related changes, when and how specific NSC subpopulation begin to exhibit dysfunction remain unclear.…”

Section: Introductionmentioning

confidence: 99%

Early Stem Cell Aging in the Mature Brain

Ibrayeva

Bay

et al. 2019

Preprint

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Stem cell dysfunction drives many age-related disorders. Identifying mechanisms that initiate stem cell dysfunction represent early targets to enhance tissue resiliency throughout life. Here, we pinpoint multiple factors that compromise neural stem cell (NSC) behavior in the adult hippocampus. We find that NSCs exhibit asynchronous depletion by identifying short-term (ST-NSC) and intermediate-term NSCs (IT-NSCs). ST-NSC divide rapidly to generate neurons and deplete in the young brain. Meanwhile, multipotent IT-NSCs are maintained for months, but are pushed out of homeostasis by lengthening quiescence. Single cell transcriptome analysis of deep NSC quiescence revealed several hallmarks of cellular aging in the mature brain, including changes in tyrosine-protein kinases Abl1 and Abl2. Treatment with the Abl-inhibitor Imatinib was sufficient to overcome deep quiescence and restore NSC proliferation in the middle-aged brain. Further examination of mature NSC with old epidermal, hematopoietic and muscle stem cell transcriptomes identified consensus changes in stem cell aging. Our study elucidates multiple origins of adult neurogenesis decline and reveals that hippocampal NSCs are particularly vulnerable to a shared stem cell aging signature.

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“…Since norvaline elevates NOS3 levels [16], we suggest a significant involvement of VEGF activation in the phenotype observed following norvaline treatment. VEGF is essential for neuroprotection [22], and its activation is beneficial for individuals with early signs of AD-associated dementia [23].VEGF preconditioning has been shown to attenuate age-related decay of adult hippocampal neurogenesis in mice [24]. Additionally, the administration of VEGF in rats with focal cerebral ischemia reduces the infarct size and enhances neurogenesis [25].…”

mentioning

confidence: 99%

“…VEGF preconditioning has been shown to attenuate age-related decay of adult hippocampal neurogenesis in mice [24]. Additionally, the administration of VEGF in rats with focal cerebral ischemia reduces the infarct size and enhances neurogenesis [25].…”

mentioning

confidence: 99%

Arginase Inhibition Supports Survival and Differentiation of Neuronal Precursors in Adult Alzheimer’s Disease Mice

Polis

Gurevich

Bloch

et al. 2019

Preprint

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Adult neurogenesis is a complex physiological process, which plays a central role in maintaining cognitive functions, and consists of progenitor cell proliferation, newborn cell migration, and cell maturation. Adult neurogenesis is susceptible to alterations under various physiological and pathological conditions. A substantial decay of neurogenesis has been documented in Alzheimer's disease (AD) patients and animal AD models; however, several treatment strategies can halt any further decline and even induce neurogenesis.Our previous results indicated a potential effect of arginase inhibition, with norvaline, on various aspects of neurogenesis in triple-transgenic mice. To better evaluate this effect, we chronically administer an arginase inhibitor, norvaline, to triple-transgenic and wild-type mice, and apply an advanced immunohistochemistry approach with several biomarkers and bright-field microscopy.Remarkably, we evidence a significant reduction in the density of neuronal progenitors, which demonstrate a different phenotype in the hippocampi of triple-transgenic mice as compared to wild-type animals. However, norvaline shows no significant effect upon the progenitor cell number and constitution. We demonstrate that norvaline treatment leads to an escalation of the polysialylated neuronal cell adhesion molecule immunopositivity, which suggests an improvement in the newborn neuron survival rate. Additionally, we identify a significant increase in the hippocampal microtubule-associated protein 2 stain intensity. We also explore the molecular mechanisms underlying the effects of norvaline on adult mice neurogenesis and provide insights into their machinery.However, the existence of human adult neurogenesis has been a subject of intense scientific debate, until recently. Tobin et al. (2019) evidenced hippocampal neurogenesis persisting throughout life in the brains of centenarians and even of Alzheimer's disease (AD) patients [2]. Convincingly, they demonstrated that the density of NPCs, neuroblasts, and immature neurons significantly decreases in cases of mild cognitive impairment and in clinical AD as compared to healthy controls. In addition, various animal models of AD are characterized by diminished adult neurogenesis. In particular, triple-transgenic mice (3×Tg) show an age-dependent neurogenesis insufficiency that is detectable in the hippocampus starting at four months of age [3]. Of note, the decline of neurogenesis in this AD model precedes the manifestation of classical hallmarks of AD pathology, such as deposition of amyloid plaques and neurofibrillary tangles in the brain, as well as memory impairment. Remarkably, as a form of neuroplasticity, adult neurogenesis has been shown to modulate vulnerability to degenerative processes and influence the course of AD [4]. Moreover, various supporting adult neurogenesis treatment strategies have demonstrated their competence to counteract the pathological behavioral outcomes in murine AD models [5]. Nevertheless, the mechanisms that regulate NPC proliferation, ...

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VEGF preconditioning leads to stem cell remodeling and attenuates age-related decay of adult hippocampal neurogenesis

Cited by 64 publications

References 55 publications

On the Run for Hippocampal Plasticity

On the Run for Hippocampal Plasticity

Early Stem Cell Aging in the Mature Brain

Arginase Inhibition Supports Survival and Differentiation of Neuronal Precursors in Adult Alzheimer’s Disease Mice

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