Bridget Breen scite author profile

Amyotrophic lateral sclerosis (ALS) is an incurable neurodegenerative disorder affecting motoneurons. Mutations in angiogenin, encoding a member of the pancreatic RNase A superfamily, segregate with ALS. We previously demonstrated that angiogenin administration shows promise as a neuroprotective therapeutic in studies using transgenic ALS mice and primary motoneuron cultures. Its mechanism of action and target cells in the spinal cord, however, are largely unknown. Using mixed motoneuron cultures, motoneuron-like NSC34 cells, and primary astroglia cultures as model systems, we here demonstrate that angiogenin is a neuronally secreted factor that is endocytosed by astroglia and mediates neuroprotection in paracrine. We show that wild-type angiogenin acts unidirectionally to induce RNA cleavage in astroglia, while the ALS-associated K40I mutant is also secreted and endocytosed, but fails to induce RNA cleavage. Angiogenin uptake into astroglia requires heparan sulfate proteoglycans, and engages clathrin-mediated endocytosis. We show that this uptake mechanism exists for mouse and human angiogenin, and delivers a functional RNase output. Moreover, we identify syndecan 4 as the angiogenin receptor mediating the selective uptake of angiogenin into astroglia. Our data provide new insights into the paracrine activities of angiogenin in the nervous system, and further highlight the critical role of non-neuronal cells in the pathogenesis of ALS.

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Angiogenin protects motoneurons against hypoxic injury

Sebastià

Kieran

Breen

et al. 2009

Cell Death Differ

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Cells can adapt to hypoxia through the activation of hypoxia-inducible factor-1 (HIF-1), which in turn regulates the expression of hypoxia-responsive genes. Defects in hypoxic signaling have been suggested to underlie the degeneration of motoneurons in amyotrophic lateral sclerosis (ALS). We have recently identified mutations in the hypoxia-responsive gene, angiogenin (ANG), in ALS patients, and have shown that ANG is constitutively expressed in motoneurons. Here, we show that HIF-1a is sufficient and required to activate ANG in cultured motoneurons exposed to hypoxia, although ANG expression does not change in a transgenic ALS mouse model or in sporadic ALS patients. Administration of recombinant ANG or expression of wild-type ANG protected motoneurons against hypoxic injury, whereas gene silencing of ang1 significantly increased hypoxia-induced cell death. The previously reported ALS-associated ANG mutations (Q12L, K17I, R31K, C39W, K40I, I46V) all showed a reduced neuroprotective activity against hypoxic injury. Our data show that ANG plays an important role in endogenous protective pathways of motoneurons exposed to hypoxia, and suggest that loss of function rather than loss of expression of ANG is associated with ALS.

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Assembly of Protein-Based Hollow Spheres Encapsulating a Therapeutic Factor

Kraskiewicz

Breen²,

Sargeant³

et al. 2013

ACS Chem. Neurosci.

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Neurotrophins, as important regulators of neural development, function, and survival, have a therapeutic potential to repair damaged neurons. However, a controlled delivery of therapeutic molecules to injured tissue remains one of the greatest challenges facing the translation of novel drug therapeutics field. This study presents the development of an innovative protein−protein delivery technology of nerve growth factor (NGF) by an electrostatically assembled protein-based (collagen) reservoir system that can be directly injected into the injury site and provide long-term release of the therapeutic. A protein-based biomimetic hollow reservoir system was fabricated using a template method. The capability of neurotrophins to localize in these reservoir systems was confirmed by confocal images of fluorescently labeled collagen and NGF. In addition, high loading efficiency of the reservoir system was proven using ELISA. By comparing release profile from microspheres with varying cross-linking, highly cross-linked collagen spheres were chosen as they have the slowest release rate. Finally, biological activity of released NGF was assessed using rat pheochromocytoma (PC12) cell line and primary rat dorsal root ganglion (DRG) cell bioassay where cell treatment with NGF-loaded reservoirs induced significant neuronal outgrowth, similar to that seen in NGF treated controls. Data presented here highlights the potential of a high capacity reservoir-growth factor technology as a promising therapeutic treatment for neuroregenerative applications and other neurodegenerative diseases.

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Therapeutic Effect of Neurotrophin-3 Treatment in an Injectable Collagen Scaffold Following Rat Spinal Cord Hemisection Injury

Breen¹,

Kraskiewicz²,

Ronan³

et al. 2016

ACS Biomater. Sci. Eng.

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Background. Spinal cord injury (SCI) presents to the clinic as complete, incomplete or compressive. SCI patients also display varying quantities of spinal cord tissue damage or loss. One theory proposed to repair the injured spinal cord and regain motor control is to regenerate axons through the lesion site. Current methods proposed to increase neuroregeneration following SCI include; preserving spared neuronal tissue, increasing axonal regeneration, reducing inflammation, reducing glial scar formation and methods aimed at bridging the lesion gap to facilitate the transmittance of physical cues and provide a platform for neuronal sprouting and functional recovery. Objective. This study was designed to quantify the impact of a local injectable in situ forming hydrogel reservoir therapy following rat hemisection SCI. Method. Our group investigated the effect of hydrogel only treatment following SCI in addition to hydrogels loaded with a neuronal growth factor, Neurotrophin-3 (NT-3), immediately following SCI. Functional recovery, assessed by Basso Beattie Bresnahan (BBB), and local healing mechanism, including neuronal regeneration, neuronal survival, glial scar formation, inflammation, astrocytosis, and collagen deposition were investigated one and six weeks post-surgery. Results. Delivery of an injectable hydrogel increased functional recovery, reduced inhibitory glial scarring and reducing inflammation at the injury site. Similarly hydrogel + NT-3 delivered directly into the injury site reduced glial scarring and collagen deposition resulting in increased neuronal survival across the lesion site. Conclusion. This study represents a novel and effective therapy combining growth factor and a biomaterial based therapy following SCI.

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The BCL-2 family protein Bid is critical for pro-inflammatory signaling in astrocytes

König

Coughlan

Kinsella

et al. 2014

Neurobiology of Disease

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Bridget Breen

Motoneurons Secrete Angiogenin to Induce RNA Cleavage in Astroglia

Angiogenin protects motoneurons against hypoxic injury

Assembly of Protein-Based Hollow Spheres Encapsulating a Therapeutic Factor

Therapeutic Effect of Neurotrophin-3 Treatment in an Injectable Collagen Scaffold Following Rat Spinal Cord Hemisection Injury

The BCL-2 family protein Bid is critical for pro-inflammatory signaling in astrocytes

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