Valerie Mariën scite author profile

Age-related neurodegenerative diseases are highly debilitating and incurable pathologies that impinge a high socio-economic burden on our society (El-Hayek et al., 2019). They share a progressive degeneration of neurons, which results in loss of brain function and a heterogeneous array of incapacitating symptoms (Dugger & Dickson, 2017). Therapeutic strategies for brain restoration consist of compensating for neuronal loss by generating new neurons from the existing stem cell pools that can integrate into the existing circuitry. The capacity for neuroregeneration is naturally limited in the adult mammalian brain (Zhao et al., 2016). Neural stem cells

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Modeling Neuroregeneration and Neurorepair in an Aging Context: The Power of a Teleost Model

houcke

Mariën

Zandecki

et al. 2021

Front. Cell Dev. Biol.

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Aging increases the risk for neurodegenerative disease and brain trauma, both leading to irreversible and multifaceted deficits that impose a clear societal and economic burden onto the growing world population. Despite tremendous research efforts, there are still no treatments available that can fully restore brain function, which would imply neuroregeneration. In the adult mammalian brain, neuroregeneration is naturally limited, even more so in an aging context. In view of the significant influence of aging on (late-onset) neurological disease, it is a critical factor in future research. This review discusses the use of a non-standard gerontology model, the teleost brain, for studying the impact of aging on neurorepair. Teleost fish share a vertebrate physiology with mammals, including mammalian-like aging, but in contrast to mammals have a high capacity for regeneration. Moreover, access to large mutagenesis screens empowers these teleost species to fill the gap between established invertebrate and rodent models. As such, we here highlight opportunities to decode the factor age in relation to neurorepair, and we propose the use of teleost fish, and in particular killifish, to fuel new research in the neuro-gerontology field.

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Intracardial perfusion of the African turquoise killifish v1

Mariën¹,

houcke²,

Arckens³

2021

Preprint

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This perfusion protocol is essential for preserving tissue morphology in order to perform good quality immunohistochemical stainings. Here, we show you how we perform our perfusions on the African turquoise killifish. This protocol was already used in the following publications: Aging impairs the essential contributions of non-glial progenitors to neurorepair in the dorsal telencephalon of the Killifish Nothobranchius furzeri - PubMed (nih.gov) Single-cell sequencing of the adult killifish (N. furzeri) brain identifies an atypical progenitor, glial and neuronal heterogeneity | bioRxiv

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Morphological Analysis of Aging Hallmarks in the Central Nervous System of the Fast-Aging African Turquoise Killifish

Bergmans

Vanhunsel

houcke

et al. 2023

Cold Spring Harb Protoc

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As the number of elderly individuals is increasing in modern society, the need for a relevant gerontology model is higher than ever before. Aging can be defined by specific cellular hallmarks, described by López-Otín and colleagues, who provided a map which can be used to scavenge the aging tissue environment. As revealing the presence of individual hallmarks does not necessarily indicate aging, here we provide different (immuno)histochemical approaches that can be used to investigate several aging hallmarks—namely, genomic damage, mitochondrial dysfunction/oxidative stress, cellular senescence, stem cell exhaustion, and altered intercellular communication—in the killifish retina, optic tectum, and/or telencephalon at a morphological level. In combination with molecular and biochemical analysis of these aging hallmarks, this protocol offers the opportunity to fully characterize the aged killifish central nervous system.

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A short dasatinib and quercetin treatment is sufficient to reinstate potent adult neuroregenesis in the aged killifish

et al. 2023

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The young African turquoise killifish has a high regenerative capacity, but loses it with advancing age, adopting several aspects of the limited form of mammalian regeneration. We deployed a proteomic strategy to identify pathways that underpin the loss of regenerative power caused by aging. Cellular senescence stood out as a potential brake on successful neurorepair. We applied the senolytic cocktail Dasatinib and Quercetin (D + Q) to test clearance of chronic senescent cells from the aged killifish central nervous system (CNS) as well as rebooting the neurogenic output. Our results show that the entire aged killifish telencephalon holds a very high senescent cell burden, including the parenchyma and the neurogenic niches, which could be diminished by a short-term, late-onset D + Q treatment. Reactive proliferation of non-glial progenitors increased substantially and lead to restorative neurogenesis after traumatic brain injury. Our results provide a cellular mechanism for age-related regeneration resilience and a proof-of-concept of a potential therapy to revive the neurogenic potential in an already aged or diseased CNS.

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Valerie Mariën

Aging impairs the essential contributions of non‐glial progenitors to neurorepair in the dorsal telencephalon of the Killifish Nothobranchius furzeri

Modeling Neuroregeneration and Neurorepair in an Aging Context: The Power of a Teleost Model

Intracardial perfusion of the African turquoise killifish v1

Morphological Analysis of Aging Hallmarks in the Central Nervous System of the Fast-Aging African Turquoise Killifish

A short dasatinib and quercetin treatment is sufficient to reinstate potent adult neuroregenesis in the aged killifish

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