Characterization of the Dopaminergic Potential of the Human NTera2/D1 (NT2) Cell Line <em>In Vitro</em>

Misiuta, Iwona E

08 July 2005

Our laboratory is working with the human NTera2/D1 (NT2) cell line which have properties similar to progenitor cells in the CNS. These neural-like precursors cells can differentiate into all three major lineages - neurons, astrocytes, andoligodendrocytes. The pure neuronal population, called the hNT cells, possess characteristics of dopamine (DA) cells. In this dissertation, we performed various experiments to examine the neuronal and dopaminergic development of this cellline. We first cultured our hNT neurons with cells from the developingnigrostriatal (NS) pathway, the ventral mesencephalon and striatum, to determine their influence on survival, neuritic outgrowth, and DA phenotype. The survival ofhNT neurons was substantially greater when they were cultured with embryonicday (E) 18 cells, compared to monocultures or cocultures with either E14 orpostnatal day (P) 1 cells. The neuritic outgrowth of hNT neurons as assessed by the number of primary neurites per cell was increased when cultured with theareas of the brain from E14 and P1. The DA phenotype, as determined by the expression of the rate-limiting enzyme of DA synthesis was not increased in hNTneurons when they were cultured with primary rat cells from the NS pathway.Next we analyzed if the retinoic acid (RA)-treated hNT neurons and the NT2 precursor cells expressed three transcription factors required for development ofthe DA phenotype. We report that NT2 cells endogenously expressed Engrailed-1, Ptx3, and Nurr1 while RA treatment increased Nurr1 but down-regulated Engrailed-1 and Ptx3. Finally, lithium has been shown to stimulate neurogenesisin adult hippocampal precursors as well as influence the Wnt pathway known to be important for the induction of the DA phenotype.

hNT

NT2

dopamine

development

Parkinson’s disease

Engrailed

Ptx3

Nurr1

lithium

survival

proliferation

differentiation

neurite outgrowth

American Studies

Arts and Humanities

Dérégulation de la signalisation non génomique du récepteur aux androgènes dans un modèle SBMA in vitro / Deregulation of the AR non genomic signaling pathways in an in vitro SBMA model

Schindler Lamarque, Mathilde

12 November 2010

L'atrophie musculaire bulbo-spinale (SBMA) est une dégénérescence lente et progressive des motoneurones causée par l'élongation du triplet nucléotidique (CAG) dans le gène codant pour le récepteur aux androgènes (RA) localisé sur le chromosome X. Dans la SBMA, ce récepteur à extension polyglutaminique (polyQ) pathogène s'accumule de manière ligand dépendante dans le cytoplasme sous forme d'agrégats mais également dans le noyau y créant des corps d'inclusions nucléaires considérés comme la marque identitaire histologique, dont le caractère cytotoxique est aujourd'hui remis en question. Nous avons développé un modèle SBMA in vitro basé sur l'expression inductible d'un RA51Q dans la lignée hybride NSC34, qui est comparé au modèle normal NSC34 exprimant un RA contenant 20Q. Nous avons démontré que l'expression du RA51Q entraîne une diminution de la viabilité ainsi qu'une altération de la croissance neuritique sans formation d'agrégats insolubles dans le noyau ou le cytoplasme des cellules. Le RA en tant que membre de la superfamille des récepteurs nucléaires est un facteur de transcription mais peut également induire des voies de signalisation non génomiques via sa localisation membranaire. Après avoir montré une localisation du RA20Q et du RA51Q dans les « lipid rafts », nous avons corrélé la diminution de la viabilité et de la pousse neuritique induite par le RA51Q à une altération de la signalisation cellulaire non génomique. Les résultats obtenus mettent en évidence une dérégulation des voies de signalisation PI3K/Akt et JNK/c-jun induite par l'expression du RA muté dans notre modèle SBMA. / Spinal Bulbar Muscular Atrophy (SBMA) is a progressive inherited motoneuron disease caused by the expansion of a trinucleotide (CAG) repeat in the gene coding for the androgen receptor (AR) located on the X chromosome. This rare disease causes muscle weaknesses, hypotonia, hyporeflexia, fasciculations of facial muscles in male patients. The androgen-dependent formation of cytoplasmic aggregates and nuclear inclusions are pathological hallmarks of this polyglutamine disease but their potential neurotoxicity is still under debate. We developed a SBMA model based on a doxycycline-inducible AR51Q expression system in the NSC34 hybrid cell line. We have shown that the expression of the mutated AR leads to a reduced viability and to an alteration of neurite outgrowth compared to cells expressing the normal AR20Q. The AR belongs to the nuclear receptor superfamily of transcription factors. However, recent data have put in evidence a membrane localization of AR initiating non-genomic signaling pathways. Because we have not observed insoluble aggregates, reduced viability and neurite outgrowth could not be correlated to AR aggregation. We hypothesized that motoneuron death is not only due to aggregate formation but also to the alteration of AR signaling pathways. We focused on a correlation between the AR localization in lipid rafts and the observed phenotypes. Our results highlight the deregulation of PI3K/Akt and JNK/c-jun signaling pathways induced by the expression of AR51Q in our SBMA model.

Sbma

Récepteur aux androgènes

Lipid rafts

Signalisation non génomique

Croissance neuritique

Nsc34

Sbma

Androgen receptor

Lipid rafts

Non genomic pathways

Neurite outgrowth

Nsc34

The Genetic and Functional Analysis of the Obsessive-Compulsive Disorder Spectrum

Ozomaro, Uzoezi

22 June 2011

Obsessive-compulsive disorder (OCD) and the spectrum of associated conditions, affect 2-4% of the population worldwide. Although heritability studies in OCD have shown a 3 - 12 times increased risk for first degree relatives, the identification of the underlying risk-conferring genetic variation using classic genetic association studies has proven to be difficult. The possibility of a larger contribution of rare genetic variants to the risk of psychiatric disorder has been suggested by several successful studies. We expect that a spectrum of risk allele frequencies exists, which includes not only common variation but also a substantial amount of rare genetic variants that contribute to OCD. This thesis is aimed at identifying and functionally characterizing rare genetic variation in the OCD spectrum. Identified statistically significant variants were scrutinized for changes related to synaptic function using high content screening and subsequent functional analyses. Identifying the genetic profile of rare variants found in the OCD spectrum cohort combined with the functional impact that these variants have has provided insight into the etiology of the OCD spectrum. With these approaches a foundation can be laid for the development of a predictive model of the OCD spectrum.

Obsessive-Compulsive Disorder (OCD)

neurite outgrowth

rare genetic variants

psychiatric genetics

next-generation sequencing (NGS)

Anaplastic Lymphoma Kinase mutations and downstream signalling

Schönherr, Christina

January 2012

The oncogene Anaplastic Lymphoma Kinase (ALK) is a Receptor Tyrosine Kinase (RTK) and was initially discovered as the fusion protein NPM (nucleophosmin)-ALK in a subset of Anaplastic Large Cell Lymphomas (ALCL). Since then more fusion proteins have been identified in a variety of cancers. Further, overexpression of ALK due to gene amplification has been observed in many malignancies, amongst others neuroblastoma, a pediatric cancer. Lately, activating point mutations in the kinase domain of ALK have been described in neuroblastoma patients and neuroblastoma cell lines. In contrast, the physiological function of ALK is still unclear, but ALK is suggested to play a role in the normal development and function of the nervous system. By employing cell culture based approaches, including a tetracycline-inducible PC12 cell system and the in vivo D. melanogaster model system, we aimed to analyze the downstream signalling of ALK and its role in neuroblastoma. First, we wished to analyze whether ALK is able to activate the small GTPase Rap1 contributing to differentiation/proliferation processes. Activated ALK recruits a complex of the GEF C3G and CrkL and activates C3G by tyrosine phosphorylation. This activated complex is able to activate Rap1 resulting either in neurite outgrowth in PC12 cells or proliferation of neuroblastoma cells suggesting a potential role in the oncogenesis of neuroblastoma driven by gain-of-function mutant ALK. Next, we could show that seven investigated ALK mutations with a high probability of being oncogenic (G1128A, I1171N, F1174L, F1174S, R1192P, F1245C and R1275Q), are true gain-of-function mutations, respond differently to ALK inhibitors and have different transforming ability. Especially the F1174S mutation correlates with aggressive disease development. However, the assumed active germ line mutation I1250T is in fact a kinase dead mutation and suggested to act as a dominant-negative receptor. Finally, ALK mutations are most frequently observed in MYCN amplified tumours correlating with a poor clinical outcome. Active ALK regulates mainly the initiation of MYCN transcription in human neuroblastoma cell lines. Further, ALK gain-of-function mutants and MYCN synergize in transforming NIH3T3 cells. Overall, somatic mutations appear to be more aggressive than germ line mutations, implying a different impact on neuroblastoma. Further, successful application of ALK inhibitors suggests a promising future for the development of patient-specific treatments for neuroblastoma patients.

Anaplastic Lymphoma Kinase

oncogene

RTK

neuroblastoma

crizotinib

NVP-TAE684

gain-of-function

MYCN

transcription factor

small GTPase

Rap1

C3G

PC12 cells

neurite outgrowth

Genetics of pain : studies of migraine and pain insensitivity

Norberg, Anna

January 2006

Pain is a major public health issue throughout the world. Increased understanding of the different forms of pain and identification of susceptibility genes could contribute to improved treatments. The main aims of this thesis were to identify the underlying genetic causes of pain by studying two large families affected with migraine and pain insensitivity, respectively. Migraine is one of the most common neurovascular disorders, affecting over 12% of the western population. The genetic contribution to migraine is about 50% according to family and twin studies. To identify novel susceptibility loci for migraine, we performed a genome-wide screen in a large family with migraine from northern Sweden. Linkage analysis revealed significant evidence of linkage (LOD=5.41) on chromosome 6p12.2-p21.1. A predisposing haplotype spanning 10 Mb was inherited with migraine in all affected members of the pedigree. Further fine-mapping of multiple SNP markers restricted the disease critical region to 8.5 Mb. Nine candidate genes were sequenced, revealing no disease-associated polymorphisms in SLC29A1, CLIC5, PLA2G7, IL17, SLC25A27 and TNFRSF21, but rare novel polymorphisms segregating with the disease haplotype in EFHC1, RHAG and MEP1A. EFHC1 has recently been shown to be involved in epilepsy, which is interesting considering the link between migraine and epilepsy. However, association analysis of EFHC1 revealed no difference between patients and controls, suggesting that this gene is not a risk factor for migraine. The combination of the two polymorphisms in RHAG and MEP1A could, however, not be found in any control individuals, indicating that they might be involved in genetic predisposition to migraine in this family. Disorders with reduced pain sensitivity are very rare, since pain perception is essential for survival. A number of disorders have still been identified with pain insensitivity and peripheral nerve degeneration as major clinical signs, including the hereditary sensory and autonomic neuropathies (HSAN). In order to identify novel susceptibility genes for HSAN V, we performed a genome-wide screen in a large consanguineous pedigree from a small village in northern Sweden. A homozygous region identical-by-descent was identified on chromosome 1p11.2-p13.2 in the three most severely affected patients. Subsequent analysis of candidate genes revealed a missense mutation in a conserved region of the nerve growth factor beta (NGFB) gene, causing a drastic amino acid change (R211W) in the NGF protein. NGF is important for the development and maintenance of the sympathetic and sensory nervous system and is therefore likely to be involved in disease. Functional analysis revealed that mutant NGF failed to induce neurite outgrowth and cell differentiation in PC12 cells. Furthermore, almost no mutant NGF was secreted by COS-7 cells, indicating that the processing and/or secretion of the protein might be disrupted. In conclusion, these findings present a novel migraine locus on chromosome 6 and identification of two rare polymorphisms that might be risk factors for migraine. Furthermore, a mutation in NGFB was found to cause complete loss of deep pain perception, which represents a very interesting model system to study pain mechanisms.

Migraine

pain insensitivity

susceptibility genes

genome-wide scan

linkage

polymorphism

association

HSAN V

nerve growth factor

neurite outgrowth

Medical genetics

Medicinsk genetik

Vascular outgrowth of normal and atherosclerotic aortic grafts in modified fibrin gels : a clinically translatable model

Collins, Scott Forrest

13 June 2011

The success of regenerative cardiac therapy requires reestablishing a capable blood supply via vasculature. The objective of this study was to develop an optimal scaffold formulation for de novo collateral vessel growth of aortic grafts using modified fibrin clots. This ex vivo vascular outgrowth model can be used to interrogate the complex cell or tissue interactions on the angiogenic front as vessels are formed. Based on formulation constraints, the methods used here may provide a clinically applicable option for guided collateral formation. Once understood, the methods and procedures can be tested and modified as necessary for in vivo, in situ regenerative therapy. Aortic segments from wild-type (C57BL/6J) and apolipoprotein-E deficient (ApoE) atherosclerosis-prone mice were cultured in a 3D environment created by various formulations of PEGylated fibrin. Aortic outgrowth was assessed and the optimal formulation was chosen to test the formation of de novo vascular circuits -- the first step necessary for collateral artery formation. The cultures were examined by conventional and confocal microscopy as well as by optical coherence tomography. Experiments testing the relationship between fibrin PEGylation and aortic vascular outgrowth showed that PEGylating fibrinogen prior to clot formation increased outgrowth over non-PEG control (n=6, p<.05) at lower fibrin concentrations. Lowering fibrin concentration to 10, 5, or 2.5mg/ml resulted in significantly higher outgrowth that was 1.92, 2.04, or 2.20 times that of 20mg/ml PEGylated fibrin gels. When multiple aortic segments are cultured in proximity, microvascular outgrowths visually anastamose suggesting that aorta-aorta conduits can be formed in fibrin based hydrogels. Anastomosing circuits appeared between wild-type aortic segments as well as between wild-type and atherosclerotic prone ApoE knockout segments. Fibrin gels, with or without PEGylation, form scaffolds suitable for regenerative vascular outgrowth ex vivo in normal and atherogenic environments. PEGylating fibrin prior to thrombin-initiated polymerization will allow the incorporation of growth factors or other bioactive components, making this a customizable therapy for guided collateral formation. Additionally, the incorporation of PEG itself does not limit and may actually increase the outgrowth from aortic segments in lower density gels. Finally, PEGylated fibrin gels offer an environment that will promote vascular extensions that visually anastamose, making this a viable model for ex vivo collateral formation. / text

Scaffold formulation

Collateral vessel growth

Aortic grafts

Fibrin clots

Vascular outgrowth

Angiogenic front

Guided collateral formation

Regenerative therapy

PEGylation

Fibrin gels

"Eine neue Rolle für Myelin-assoziierte Inhibitoren für die Mobilität von Mikroglia" / "A novel role for myelin-associated inhibitors in modulating microglial motility"

Orfaniotou, Foteini

08 January 2009

No description available.

570 Biowissenschaften

Biologie

microglia

myelin inhibitors

Nogo receptor 1

process outgrowth

Mikroglia

Myelin Inhibitoren

Nogo Rezeptor 1

Fortsatzwachstum

42

WA

Imidazoline receptor antisera-selected protein: a unique modulator of neuronal differentiation.

Dehle, Francis Christian

January 2008

The imidazoline I1 receptor (I1-R) is a novel receptor found primarily in the brain and nervous tissue where it modulates neurotransmission. It is named for its high affinity for compounds with an imidazoline structure such as the anti-hypertensive drugs, clonidine and moxonidine. The imidazoline receptor antisera-selected protein (IRAS) is the putative clone of the I1-R. IRAS has a unique structure, which does not resemble any other receptor protein. IRAS is present throughout the body with highest levels in the brain. There is a growing body of research examining the physiological roles of IRAS as an I1-R, in cell survival, migration and protein trafficking. However, there is little research into its neuronal functions. IRAS interacts with other membrane receptors: the mouse homologue of IRAS reorganises the actin cytoskeleton through interaction with the α5β1 fibronectin receptor. IRAS also binds insulin receptor substrate 4 and enhances insulin-induced extracellular signal-regulated kinase1/2 (ERK1/2) activation. Actin reorganisation and ERK1/2 activation are important for the development of neurites during neuronal differentiation. Therefore, the work described in this thesis aimed to investigate the effects of IRAS on neuronal differentiation. Studies reported in this thesis also aimed to investigate whether IRAS affected ERK1/2 signalling of other receptors involved in neuronal differentiation such as the NGF receptor, TrkA, and lysophospholipid receptors. The above aims were carried out in neuronal model PC12 cells transfected with either IRAS or a vector plasmid. Fluorescence microscopy and Western blotting techniques were used to examine the effect of IRAS on cell morphology and ERK1/2 signalling. The work described in this thesis found that IRAS reorganises the actin cytoskeleton and enhances growth cone development in PC12 cells. This study also shows that IRAS differentially enhances or inhibits NGF-induced PC12 cell differentiation depending on the presence or absence of serum in the media. In full-serum conditions, IRAS enhanced neurite outgrowth and this was accompanied by an increase in ERK1/2 activation. In serum-starved cells, IRAS inhibited neurite outgrowth with similar levels of ERK1/2 activation observed in vector- and IRAS-transfected cells. Finally, studies presented in this thesis found that IRAS enhances lysophosphatidic acid-induced ERK1/2 activation and that IRAS interacting with lysophospholipid receptor agonists present in serum is a potential mechanism by which it enhances NGF-induced ERK1/2 activation in full-serum conditions. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1345359 / Thesis (Ph.D.) - University of Adelaide, School of Medical Sciences, 2008

AXONAL OUTGROWTH AND PATHFINDING OF HUMAN PLURIPOTENT STEM CELL-DERIVED RETINAL GANGLION CELLS

Clarisse Marie Fligor (8917073)

16 June 2020

Retinal ganglion cells (RGCs) serve as a vital connection between the eye and the brain with damage to their axons resulting in loss of vision and/or blindness. Retinal organoids are three-dimensional structures derived from human pluripotent stem cells (hPSCs) which recapitulate the spatial and temporal differentiation of the retina, providing a valuable model of RGC development in vitro. The working hypothesis of these studies is that hPSC-derived RGCs are capable of extensive outgrowth and display target specificity and pathfinding abilities. Initial efforts focused on characterizing RGC differentiation throughout early stages of organoid development, with a clearly defined RGC layer developing in a temporally-appropriate manner expressing a compliment of RGC-associated markers. Beyond studies of RGC development, retinal organoids may also prove useful to investigate and model the extensive axonal outgrowth necessary to reach post-synaptic targets. As such, additional efforts aimed to elucidate factors promoting axonal outgrowth. Results demonstrated significant enhancement of axonal outgrowth through modulation of both substrate composition and growth factor signaling. Furthermore, RGCs possessed guidance receptors that are essential in influencing outgrowth and pathfinding. Subsequently, to determine target specificity, aggregates of hPSC-derived RGCs were co-cultured with explants of mouse lateral geniculate nucleus (LGN), the primary post-synaptic target of RGCs. Axonal outgrowth was enhanced in the presence of LGN, and RGCs displayed recognition of appropriate targets, with the longest neurites projecting towards LGN explants compared to control explants or RGCs grown alone. Generated from the fusion of regionally-patterned organoids, assembloids model projections between distinct regions of the nervous system. Therefore, final efforts of these studies focused upon the generation of retinocortical assembloids in order to model the long-distance outgrowth characteristic of RGCs. RGCs displayed extensive axonal outgrowth into cortical organoids, with the ability to respond to environmental cues. Collectively, these results establish retinal organoids as a valuable tool for studies of RGC development, and demonstrate the utility of organoid-derived RGCs as an effective platform to study factors influencing outgrowth as well as modeling long-distance projections and pathfinding abilities.

Cell Biology

Developmental Biology

Organoid

stem cells

axonal outgrowth

pathfinding

human pluripotent stem cells

Understanding the Role of Nrg1 Signaling Upon Brain Damage: Novel Models of Cortical Regeneration

González Manteiga, Ana

27 November 2023

[ES] El daño cerebral es la mayor causa de discapacidad en la etapa adulta, particularmente afectando a la población anciana. Independientemente de la causa, los diferentes tipos de daño cerebral comparten eventos fisiopatológicos similares. Hasta ahora, la mayoría de los estudios se enfocaron en estudiar las respuestas inmediatas tras la lesión, mientras que los mecanismos que subyacen bajo los procesos de plasticidad y regeneración cortical aún son desconocidos. Neuregulina 1 (Nrg1) es una proteína esencial en el desarrollo de los circuitos corticales que se ha asociado a diferentes trastornos psiquiátricos, como la esquizofrenia. En las últimas décadas, varios trabajos proponen a Nrg1 como un factor neuroprotector emergente en el ámbito de lesión. No obstante, la mayoría de las investigaciones se centran en estudiar la respuesta temprana de la forma soluble de Nrg1 tras el daño, mediada por la activación de los receptores ErbB, la cual no recapitula totalmente la compleja señalización de Nrg1. De este modo, nuestro laboratorio ha demostrado previamente que la señalización intracelular de Nrg1 se activa en situaciones de hipoxia, promoviendo la supervivencia neuronal tras ictus. El principal objetivo de esta tesis es estudiar el papel de la señalización de Nrg1 en la regeneración y plasticidad cortical tras daño cerebral. Para ello, hemos desarrollado nuevos modelos para 1) ofrecer una metodología que permita estudiar la regeneración axonal in vitro e in vivo y 2) específicamente estudiar el papel de la señalización intracelular de Nrg1 en el ámbito de daño cortical. Primero, desarrollamos un nuevo modelo in vitro de lesión axonal en cultivos de neuronas corticales, utilizando técnicas de electroporación para marcar un número limitado de neuronas, combinado con una posterior lesión física basada en una transección mecánica de los axones. En este modelo, también se realizaron estudios de ganancia y pérdida de función para comprender el papel de Nrg1 en el crecimiento axonal. Nuestros resultados mostraron que Nrg1, y específicamente la activación de su vía intracelular, potencia el crecimiento axonal tras daño. Posteriormente, diseñamos una metodología novedosa en ratones para estudiar la regeneración cortical, combinando técnicas de trazado de conexiones cortico-corticales con una lesión focal y mecánica en la corteza primaria motora. Se realizó una extensa caracterización funcional empleando diversas pruebas comportamentales específicas para detectar déficits motores en lesiones unilaterales como la ofrecida en este modelo. Gracias al procesamiento del tejido cerebral en series flotantes, se combinaron diferentes tinciones para realizar reconstrucciones 3D del cerebro y, así, ofrecer un estudio completo incluyendo medidas volumétricas y un análisis de diferentes poblaciones celulares y estructuras subcelulares. Como ejemplo, se investigó la correlación entre la eliminación de redes perineuronales y la activación de células microgliales en la zona adyacente a la lesión. Esta metodología de lesión cortical in vivo se utilizó en innovadores modelos genéticos de ratón en esta tesis para entender el papel de Nrg1 tras daño cortical. Así, se eliminó la expresión del gen de Nrg1 en ratonas jóvenes y maduras previamente a la lesión, observando que la ausencia de Nrg1 promueve la respuesta neuroinflamatoria y una preservación axonal limitada, conllevando una menor recuperación motora espontánea tras la lesión. Finalmente, para ofrecer una visión mecanicista del papel de la señalización intracelular de Nrg1, su dominio intracelular se expresó específicamente en neuronas corticales, observando que la activación de esta vía de señalización reduce la respuesta inflamatoria tras lesión cortical. En conclusión, estos resultados señalan que Nrg1, y específicamente la activación de su vía intracelular, podría ser una diana molecular prometedora en el contexto de neuroprotección, regeneración y recuperación cortical tras daño cerebral. / [CA] El dany cerebral és la major causa de discapacitat en l'etapa adulta, particularment en la població anciana. Independentment de la causa, els diferents tipus de dany cerebral comparteixen esdeveniments fisiopatològics similars. Fins ara, la majoria dels estudis es van enfocar a estudiar les respostes immediates després de la lesió, mentre que els mecanismes que subjauen sota els processos de plasticitat i regeneració cortical encara són desconeguts. Neuregulina 1 (Nrg1) és una proteïna essencial en el desenvolupament dels circuits corticals que s'ha associat a diferents trastorns psiquiàtrics, com l'esquizofrènia. En les últimes dècades, diversos treballs proposen a Nrg1 com un factor neuroprotector emergent en l'àmbit de lesió. No obstant això, la majoria de les investigacions se centren en estudiar la resposta primerenca de la forma soluble de Nrg1 després del mal, mediada per l'activació dels receptors ErbB, la qual no recapitula totalment la complexa senyalització de Nrg1. D'aquesta manera, el nostre laboratori ha demostrat prèviament que la senyalització intracel·lular de Nrg1 s'activa en situacions d'hipòxia, promovent la supervivència neuronal després de l'ictus. El principal objectiu d'aquesta tesi és estudiar el paper de la senyalització de Nrg1 en la regeneració i plasticitat cortical després de dany cerebral. Per a això, hem desenvolupat nous models per a 1) oferir una metodologia que permeta estudiar la regeneració axonal in vitro i in vivo i 2) específicament estudiar el paper de la senyalització intracel·lular de *Nrg1 en l'àmbit de mal cortical. Primer, desenvolupem un nou model in vitro de lesió axonal en cultius de neurones corticals, utilitzant tècniques de electroporació per a marcar un nombre limitat de neurones, combinat amb una posterior lesió física basada en una secció mecànica dels axons. En aquest model, també es van realitzar estudis de guany i pèrdua de funció per a comprendre el paper de Nrg1 en el creixement axonal. Aquests resultats van mostrar que Nrg1, i específicament l'activació de la seua via intracel·lular, potència el creixement axonal després de mal. Posteriorment, dissenyem una metodologia nova en ratolins per a estudiar la regeneració cortical, combinant tècniques de traçat de connexions cortico-corticals amb una lesió focal i mecànica en l'escorça primària motora. Es va realitzar una extensa caracterització funcional emprant diverses proves comportamentals específiques per a detectar dèficits motors en lesions unilaterals com l'oferida en aquest model. Gràcies al processament del teixit cerebral en sèries flotants, es van combinar diferents tincions per a realitzar reconstruccions 3D del cervell i, així, oferir un estudi complet incloent mesures volumètriques i una anàlisi de diferents poblacions cel·lulars i estructures subcel·lulars. Com a exemple, es va investigar la correlació entre l'eliminació de xarxes perineuronals i l'activació de cèl·lules microglials en la zona adjacent a la lesió. Aquesta metodologia de lesió cortical in vivo es va utilitzar en innovadors models genètics de ratolí per a entendre el paper de Nrg1 després de mal cortical. Es va eliminar l'expressió del gen de Nrg1 en ratolins joves i madurs prèviament a la lesió, observant que l'absència de Nrg1 promou la resposta neuroinflamatoria i una preservació axonal limitada, el que comporta una menor recuperació motora espontània després de la lesió. Finalment, per a oferir una visió mecanicista del paper de la senyalització intracel·lular de Nrg1, el seu domini intracel·lular es va expressar específicament en neurones corticals, observant que l'activació d'aquesta via de senyalització redueix la resposta inflamatòria després de lesió cortical. En conclusió, aquests resultats assenyalen que la senyalització de Nrg1, i específicament l'activació de la seua via intracel·lular, podria ser una diana molecular prometedora en el context de neuroprotecció, regeneració i recuperació cortical després de dany cerebral. / [EN] Brain damage is the leading cause of disability in adults, particularly in the elderly population. Regardless of the cause, different types of brain injury share similar physiopathological events. Most studies to date have focused on the immediate post-injury response, whereas less is known about cortical regeneration and plasticity after brain injury. Neuregulin 1 (Nrg1) is essential for the development of cortical circuits and has been implicated in several psychiatric disorders, such as schizophrenia. In the last decades, several works proposed Nrg1 signaling as an emergent modulator of neuroprotection upon damage. However, most research has focused on the early response of Nrg1 diffusible isoforms mediated by ErbB receptor activation after injury, which does not fully recapitulate the complexity of Nrg1 signaling. In this context, we have previously shown that Nrg1 intracellular signaling is activated under hypoxic conditions and promotes neuronal survival after cortical stroke. The overall goal of this dissertation is to investigate the role of Nrg1 signaling in cortical regeneration and plasticity after cortical damage. To achieve this goal, we developed novel, refined models to 1) provide new methodological approaches to study axonal regeneration in vitro and in vivo and 2) specifically target Nrg1 signaling and particularly investigate the role of Nrg1 intracellular pathway upon cortical injury. First, we developed a novel in vitro model of axonal injury in cortical neuron cultures. Specifically, we performed sparse labeling of the cultures by electroporation techniques and induced physical injury by mechanical transection of the axons. In this model, we also performed gain- and loss-of-function approaches to investigate the role of Nrg1 in axonal outgrowth. Our results showed that Nrg1, and specifically the activation of its intracellular signaling, potentiates axonal outgrowth upon injury. Second, we developed a novel methodology in mice that combines cortico-cortical projection tracing with focal mechanically controlled cortical damage (CCD) to study cortical regeneration. We performed extensive functional characterization of the model and provided meaningful behavioral tasks to detect motor impairment in unilateral focal injuries. Since tissue processing is performed in serial floating sections, we combined different immunolabeling and 3D brain reconstruction to evaluate stereological measurements and analysis of axonal projections and different cell populations. As a biological result, we showed a correlation between perineuronal nets (PNNs) disruption and microglial activation in the perilesional region. Later, we applied the CCD methodology in novel genetic mouse models to better understand the role of Nrg1 signaling in vivo after cortical injury. We induced acute Nrg1 deletion prior to injury in young and aged mice and observed that Nrg1 deletion promoted neuroinflammatory response and limited axonal preservation and spontaneous motor recovery after cortical injury. Finally, we specifically expressed Nrg1-ICD to provide a mechanistic perspective and observed that activation of this intracellular pathway decreased the neuroinflammatory response. Collectively, our results shed light on Nrg1 signaling, and specifically the activation of its intracellular pathway, as a promising molecular target in neuroprotection, cortical regeneration, and recovery after brain injury. / González Manteiga, A. (2023). Understanding the Role of Nrg1 Signaling Upon Brain Damage: Novel Models of Cortical Regeneration [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/200224

Crecimiento axonal

Daño cerebral

Neuregulina 1

Neuroinflamación

Regeneración cortical

Neuregulin 1

Brain damage

Axonal outgrowth

Neuroinflammation

Cortical regeneration

Cortical rewiring

Inducible conditional mouse model