Role of the Cellular Prion Protein in the Neuron Adaptation Strategy to Copper Deficiency

Urso, Emanuela; Manno, D.; Serra, A.; Buccolieri, Alessandro; Rizzello, Antonia; Danieli, Antonio; Acierno, Raffaele; Salvato, Benedetto; Maffia, Michele

doi:10.1007/s10571-012-9815-5

Cited by 14 publications

(15 citation statements)

References 89 publications

(103 reference statements)

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“…The upregulation of PrP expression and subsequent enhancement of Cu uptake was detected under reduced Cu availability, explained as the mechanism to sustain the copper delivery for Cu/Zn SOD (Urso et al, 2012). These results are in contrast with our data, since we have found out /1 are more sensitive to copper, manganese and nickel toxicity.…”

Section: Discussioncontrasting

confidence: 99%

Prion protein prevents heavy metals overloading of cells and thus protects them against their toxicity

Prčina¹,

Kontseková²,

Novák³

2015

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Summary. -Physiological function of a prion protein (PrP) is not known yet. Regarding the relation of PrP to heavy metals it is known that PrP is able to bind divalent ions of copper, zinc, manganese and nickel through its octarepeat region. It has been hypothesized but not yet confirmed that PrP could play a role in copper metabolism. In this study, cells expressing human full-length PrP (HuPrP1)

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Section: Discussioncontrasting

confidence: 99%

Prion protein prevents heavy metals overloading of cells and thus protects them against their toxicity

Prčina¹,

Kontseková²,

Novák³

2015

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“…The presence of blebs at the margins of the aggregates can suggest an apoptotic induction, as confirmed by the observed reduction of the proliferation rate ( Fig. 7): this result could also be explained by the well-known protection role of PrP protein against oxidative stress (13,15). Previous studies performed in spheroids derived from prostatitis tumor cells showed that mitochondrial generated ROS induce an increase of PrP protein expression and its cellular colocalization with mitochondrial enzymes such as superoxide dismutase (SOD1) and catalase (75).…”

Section: Discussionsupporting

confidence: 57%

“…Thanks to a rapid constitutive clathrin-/cavolein-dependent process (9)(10)(11), PrP is endocyted and then recycled or degraded (12,13). The protein can also regulate intracellular copper content through its ability to bind the metal ions and promote their endocytosis (14)(15)(16)(17). In fact, the histidine residues present at the PrP N-terminal domain can bind up to 6 copper ions with low affinity (18)(19)(20) triggering their cellular internalization at the synaptic cleft (9,12,21,22).…”

Section: Introductionmentioning

confidence: 99%

Physiological role of Prion Protein in Copper homeostasis and angiogenic mechanisms of endothelial cells

Riccardis

Rizzo

Urso

et al. 2019

The EuroBiotech Journal

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The Prion Protein (PrP) is mostly known for its role in prion diseases, where its misfolding and aggregation can cause fatal neurodegenerative conditions such as the bovine spongiform encephalopathy and human Creutzfeldt–Jakob disease. Physiologically, PrP is involved in several processes including adhesion, proliferation, differentiation and angiogenesis, but the molecular mechanisms behind its role remain unclear. PrP, due to its well-described structure, is known to be able to regulate copper homeostasis; however, copper dyshomeostasis can lead to developmental defects. We investigated PrP-dependent regulation of copper homeostasis in human endothelial cells (HUVEC) using an RNA-interference protocol. PrP knockdown did not influence cell viability in silenced HUVEC (PrPKD) compared to control cells, but significantly increased PrPKD HUVEC cells sensitivity to cytotoxic copper concentrations. A reduction of PrPKD cells reductase activity and copper ions transport capacity was observed. Furthermore, PrPKD-derived spheroids exhibited altered morphogenesis and their derived cells showed a decreased vitality 24 and 48 hours after seeding. PrPKD spheroid-derived cells also showed disrupted tubulogenesis in terms of decreased coverage area, tubule length and total nodes number on matrigel, preserving unaltered VEGF receptors expression levels. Our results highlight PrP physiological role in cellular copper homeostasis and in the angiogenesis of endothelial cells.

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“…High-affinity (range: μ M- n M ) copper-binding sequences, highly conserved in mammals, are localized N-terminally [185,186] and this strongly suggests the involvement of PrP C in the homeostasis of copper [187,188,189]. In particular, several pieces of evidence support the idea of proteins as copper transporters across the plasma membrane [189,190,191,192,193,194,195]. The endothelial expression of PrP C is a controversial but intriguing research topic, since blood vessels represent an ‘obligatory gate' for prions toward the central nervous system.…”

Section: Role Of Copper Transport Systems During Angiogenesismentioning

confidence: 99%

Behind the Link between Copper and Angiogenesis: Established Mechanisms and an Overview on the Role of Vascular Copper Transport Systems

Urso

Maffia²

2015

J Vasc Res

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118

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Angiogenesis critically sustains the progression of both physiological and pathological processes. Copper behaves as an obligatory co-factor throughout the angiogenic signalling cascades, so much so that a deficiency causes neovascularization to abate. Moreover, the progress of several angiogenic pathologies (e.g. diabetes, cardiac hypertrophy and ischaemia) can be tracked by measuring serum copper levels, which are being increasingly investigated as a useful prognostic marker. Accordingly, the therapeutic modulation of body copper has been proven effective in rescuing the pathological angiogenic dysfunctions underlying several disease states. Vascular copper transport systems profoundly influence the activation and execution of angiogenesis, acting as multi-functional regulators of apparently discrete pro-angiogenic pathways. This review concerns the complex relationship among copper-dependent angiogenic factors, copper transporters and common pathological conditions, with an unusual accent on the multi-faceted involvement of the proteins handling vascular copper. Functions regulated by the major copper transport proteins (CTR1 importer, ATP7A efflux pump and metallo-chaperones) include the modulation of endothelial migration and vascular superoxide, known to activate angiogenesis within a narrow concentration range. The potential contribution of prion protein, a controversial regulator of copper homeostasis, is discussed, even though its angiogenic involvement seems to be mainly associated with the modulation of endothelial motility and permeability.

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Role of the Cellular Prion Protein in the Neuron Adaptation Strategy to Copper Deficiency

Cited by 14 publications

References 89 publications

Prion protein prevents heavy metals overloading of cells and thus protects them against their toxicity

Prion protein prevents heavy metals overloading of cells and thus protects them against their toxicity

Physiological role of Prion Protein in Copper homeostasis and angiogenic mechanisms of endothelial cells

Behind the Link between Copper and Angiogenesis: Established Mechanisms and an Overview on the Role of Vascular Copper Transport Systems

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