Stuart Dickens scite author profile

Cell surface β-Amyloid precursor protein (APP) is known to have a functional role in iron homeostasis through stabilising the iron export protein ferroportin (FPN). Mechanistic evidence of this role has previously only been provided through transcriptional or translational depletion of total APP levels. However, numerous post-translational modifications of APP are reported to regulate the location and trafficking of this protein to the cell surface. Stable overexpressing cell lines were generated that overexpressed APP with disrupted N-glycosylation (APP N467K and APP N496K ) or ectodomain phosphorylation (APP S206A ); sites selected for their proximity to the FPN binding site on the E2 domain of APP. We hypothesise that impaired N-glycosylation or phosphorylation of APP disrupts the functional location on the cell surface or binding to FPN to consequentially alter intracellular iron levels through impaired cell surface FPN stability. Outcomes confirm that these post-translational modifications are essential for the correct location of APP on the cell surface and highlight a novel mechanism by which the cell can modulate iron homeostasis. Further interrogation of other post-translational processes to APP is warranted in order to fully understand how each modification plays a role on regulating intracellular iron levels in health and disease.

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Regulation of CNS Plasticity Through the Extracellular Matrix

Warren¹,

Dickens²,

Gigout³

et al. 2018

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Contrary to established dogma, the central nervous system (CNS) has a capacity for regeneration and is moderately plastic. Traditionally, such changes have been recognized through development, but more recently, this has been documented in adults through learning and memory or during the advent of trauma and disease. One of the causes of such plasticity has been related to changes in the extracellular matrix (ECM). This complex scaffold of sugars and proteins in the extracellular space alters functionality of the surrounding tissue through moderation of synaptic connections, neurotransmission, ion diffusion, and modification to the cytoskeleton. This chapter discusses the role of the ECM in CNS plasticity in development and the adult. Further, it determines how the ECM affects normal neuronal functioning in critical processes such as memory. Finally, the chapter assesses how the ECM contributes to adverse CNS changes in injury and disease, concentrating on how this matrix may be targeted for therapeutic intervention.

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An in vitro neuronal model replicating the in vivo maturation and heterogeneity of perineuronal nets

Dickens

Goodenough

Kwok

2022

Preprint

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The perineuronal net (PNN) is a condensed form of extracellular matrix (ECM) that enwraps specific populations of neurons and regulates plasticity. To create a PNN, only three classes of components are needed: membrane bound hyaluronan by its synthetic enzyme hyaluronan synthases (HASs), a link protein and a CSPG. However, there is redundancy within the classes as multiple HAS isoforms, link proteins and CSPGs have been found in the PNN in vivo. The effect of this heterogeneity has on PNN function is unresolved. Currently, the most common way to address this question is through the creation and study of PNN component in knockout animals. Here, we reported the development of a primary neuronal culture model which reproduces the in vivo maturation and heterogeneity of PNNs. This model accurately replicated mature cortical PNNs, both in terms of the heterogeneity in PNN composition and its maturation. PNNs transitioned from an immature punctate morphology to the reticular morphology as observed in the mature CNS. We also observed a small population of PNNs that were mature at an earlier time point and a distinct composition, highlighting further heterogeneity. This model will provide a valuable tool for the study of PNN biology, their roles in diseases and the development of PNN focused plasticity treatment.

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Stuart Dickens

Post Translational Modulation of β-Amyloid Precursor Protein Trafficking to the Cell Surface Alters Neuronal Iron Homeostasis

Regulation of CNS Plasticity Through the Extracellular Matrix

An in vitro neuronal model replicating the in vivo maturation and heterogeneity of perineuronal nets

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