The Role of Farnesyltransferase β-subunit in Neuronal Polarity in Caenorhabditis Elegans

Carr, David, A.

07 February 2013

Little is known about the molecular components and interactions of the planar cell polarity pathway that regulate neuronal polarity. This study uses a prkl-1 induced backwards locomotion defect as an array to perform a prkl-1 suppressor screen in C. elegans looking for new components of the planar cell polarity pathway involved in the neuronal polarization of VC4 and VC5. The screen discovered twelve new alleles of vang-1, one new allele of fntb-1 and five new mutations in unknown polarity genes. fntb-1 encodes for the worm ortholog of Farnesyltransferase β-subunit and is important for neuronal polarization. Acting cell and non-cell autonomously, fntb-1 regulates the function and localization of prkl-1 through the recognition of a CAAX motif. Therefore, fntb-1 modifies prkl-1 to regulate the neuronal polarity of VC4 and VC5.

fntb-1

prkl-1

farnesyltransferase

prickle

Planar Cell Polarity

neuronal polarity

C. elegans

Identification of Transforming Growth Factor-beta as an Extracellular Signal Required for Axon Specification in Embryonic Brain Development

Yi, Jason Joon-mo

January 2009

<p>The specification of a single axon and multiple dendrites is the first observable event during neuronal morphogenesis and such structural specialization underlies neural connectivity and nervous system function. Numerous intracellular signaling components that are required for axon specification have been described but how such signaling paradigms are initiated by extracellular factor(s) within the embryonic milieu is poorly understood. Here, I describe how transforming growth factor-&beta; (TGF-&beta;), an embryonic morphogen that directs structural plasticity and growth in various cell types, initiates signaling pathways both in vivo and in vitro to fate naïve neurites into axons. Using conditional knockout strategies, I found that cortical neurons lacking the type II TGF-&beta; receptor (T&beta;R2) fail to initiate axons during development, and interestingly, fail to engage radial migration. In cultured neurons, exogenous TGF-&beta; is sufficient to direct the rapid growth and differentiation of an axon and genetic enhancement of receptor activity promotes the formation of multiple axons. The cellular polarization of receptor activity occurs through the interaction of the type-I TGF-&beta; receptor with Par6, a component of the axon-specifying Par3/Par6 polarity complex. Receptor distribution is restricted to axons, and downstream signaling events required for axon specification are triggered when Par6 is phosphorylated by T&beta;R2. Together, these results indicate that TGF-&beta; is the extrinsic cue for neuronal polarity in vivo and directs neuronal polarity by controlling Par6 activity and cellular migration during axon generation.</p> / Dissertation

Biology, Neuroscience

Biology, Cell

Biology, Anatomy

Axon

Development

Embryo

Neuron

Neuronal polarity

TGF

beta

The Role of Farnesyltransferase β-subunit in Neuronal Polarity in Caenorhabditis Elegans

Carr, David, A.

07 February 2013

Little is known about the molecular components and interactions of the planar cell polarity pathway that regulate neuronal polarity. This study uses a prkl-1 induced backwards locomotion defect as an array to perform a prkl-1 suppressor screen in C. elegans looking for new components of the planar cell polarity pathway involved in the neuronal polarization of VC4 and VC5. The screen discovered twelve new alleles of vang-1, one new allele of fntb-1 and five new mutations in unknown polarity genes. fntb-1 encodes for the worm ortholog of Farnesyltransferase β-subunit and is important for neuronal polarization. Acting cell and non-cell autonomously, fntb-1 regulates the function and localization of prkl-1 through the recognition of a CAAX motif. Therefore, fntb-1 modifies prkl-1 to regulate the neuronal polarity of VC4 and VC5.

fntb-1

prkl-1

farnesyltransferase

prickle

Planar Cell Polarity

neuronal polarity

C. elegans

The role of the Golgi apparatus in neuronal polarity

Ash, Tyler Dale

08 April 2016

ABSTRACT The Golgi apparatus has always been an interesting organelle of study because of its unique morphology as well as the critical roles it plays in cell biology. It is situated next to the endoplasmic reticulum and secreted proteins must pass through the Golgi vesicular pathway for modifications and targeting. In addition, the Golgi apparatus plays an essential role in establishing cellular polarity. Cell polarity refers to difference in orientation of cell structures spatially, and is involved in establishing functionality. The Golgi apparatus establishes cell polarity in various ways including orienting itself spatially, biasing vesicular trafficking within the cell, and most importantly through its role as a microtubule organizing center. The cytoskeleton provides the structural framework for cells. Microtubules nucleated from the Golgi-dependent microtubule organizing center result in an asymmetric cytoskeleton. An asymmetric cytoskeleton is essential to establishing cell polarity. Neurons require cell polarity to establish the essential structures such as the axon and dendrites. The Golgi apparatus establishes neuronal polarity through its extensive network of associated proteins. In this review, we will discuss the growing evidence supporting the role of the Golgi apparatus in establishing neuronal polarity.

Neurosciences

CLASP2

GCC185

Neurodevelopment

Golgi apparatus

Microtubule organizing center

Neuronal polarity

The Role of Farnesyltransferase β-subunit in Neuronal Polarity in Caenorhabditis Elegans

Carr, David, A.

January 2013

Little is known about the molecular components and interactions of the planar cell polarity pathway that regulate neuronal polarity. This study uses a prkl-1 induced backwards locomotion defect as an array to perform a prkl-1 suppressor screen in C. elegans looking for new components of the planar cell polarity pathway involved in the neuronal polarization of VC4 and VC5. The screen discovered twelve new alleles of vang-1, one new allele of fntb-1 and five new mutations in unknown polarity genes. fntb-1 encodes for the worm ortholog of Farnesyltransferase β-subunit and is important for neuronal polarization. Acting cell and non-cell autonomously, fntb-1 regulates the function and localization of prkl-1 through the recognition of a CAAX motif. Therefore, fntb-1 modifies prkl-1 to regulate the neuronal polarity of VC4 and VC5.

fntb-1

prkl-1

farnesyltransferase

prickle

Planar Cell Polarity

neuronal polarity

C. elegans

Etude structurale et fonctionnelle de la « Collapsin Response Mediator Protein » CRMP5 / Structural and Functional Study of « Collapsin Response Mediator Protein » CRMP5

Brot, Sébastien

07 December 2010

Le travail de cette thèse s’est articulé autour de l’étude de CRMP5 au cours du développement du système nerveux central. Nous avons mis en évidence une interaction directe entre CRMP5 et la tubuline, conduisant à une inhibition de la pousse neuritique dans différentes lignées cellulaires, ainsi qu’à une inhibition d’élongation uniquement au niveau des dendrites et non de l’axone, dans des cultures primaires de neurones de l’hippocampe. De plus, nous avons montré que CRMP5 pouvait annuler l’action de CRMP2, connue pour promouvoir la pousse neuritique, de façon dominante mais dépendante de la présence sur CRMP5 du site de fixation à la tubuline. Contrairement à CRMP2, l’expression de CRMP5 étant transitoire pendant la différentiation neuronale, elle permettrait de restreindre de façon spatio-temporelle l’effet de CRMP2 sur la pousse neuritique, régulant ainsi la polarité neuronale. D’autre part, nous avons également rapporté la présence de CRMP5 au niveau mitochondrial où elle pourrait jouer un rôle dans le processus d’autophagie des mitochondries. Enfin, nous nous sommes intéressés à l’étude de la CRMP5 exprimée en conditions pathologiques, et nous avons observé une nouvelle localisation nucléaire de la protéine dans certaines cellules cancéreuses. Etant localisée dans plusieurs compartiments subcellulaires et impliquée dans différents mécanismes moléculaires, l’ensemble de ce travail décrit donc la protéine CRMP5 comme une protéine « multi-fonctionnelle ». / The purpose of this work is to focus on the study of CRMP5 during development of the central nervous system. We have demonstrated a direct interaction between CRMP5 and tubulin, leading to inhibition of neurite outgrowth in different cell lines, and inhibition of growth only at dendritic but not axonal level, in hippocampal neurons. Furthermore, we showed that CRMP5 could counteract the previously described CRMP2 effect on neurite outgrowth. The CRMP5 acted as a dominant signal to counteract CRMP2 outgrowth promotion and this function is also dependent on the tubulin-binding capacity of CRMP5.Unlike CRMP2, the CRMP5 expression being transient during neuronal differentiation, it would imply in the spatiotemporal regulation of the CRMP2 effect on neurite outgrowth, thereby regulating neuronal polarity. In another part, we also reported the presence of CRMP5 at mitochondrial level in vivo where it could play a role in mitochondrial autophagic process.Finally, we were interested in the study of CRMP5 expressed in pathological conditions, and we discovered a new nuclear localization of the protein in some cancer cells. Being localizedin several subcellular compartments and involved in different molecular mechanisms, this work describes CRMP5 as a "multi-functional" protein.

CRMP

Polarité neuronale

Tubuline

MAP2

Mitochondrie

Autophagie

Glioblastomes

NLS

CRMP

Neuronal polarity

Tubuline

MAP2

Mitochondria

Autophagy

Glioblastoma

NLS

612.8

Myosin1b controls the formation of the axon and the establishment of neuronal polarity by regulating actin waves / Myosine 1b contrôle la formation de l'axone et l'établissement de la polarité neuronale en régulant les ondes d'actine

Iuliano, Olga

23 September 2016

Les neurones sont des cellules polarisées qui présentent un seul axone et de nombreuses dendrites courtes. Les réarrangements du cytosquelette, l'augmentation du transport dépendant des microtubules et le couplage mécanique du cytosquelette d'actine à la membrane plasmique sont nécessaires pour établir cette polarité neuronale. Les Myosines 1 qui couplent le cytosquelette d'actine à la membrane plasmique sont des bons candidats pour réguler l'axonogenèse. La Myosine1b étant fortement exprimée dans le cerveau en développement, nous avons donc étudié son rôle dans l'axonogenèse. L'inhibition de l'expression de Myo1b dans les neurones corticaux retarde la différenciation neuronale et empêche l'axonogenèse et l'établissement de la polarité neuronale. La surexpression de Myo1b accélère le développement neuronal et induit la formation d'axones surnuméraires. L'activité motrice et l'interaction de Myo1b avec des phosphoinositides via son domaine PH est nécessaire pour ce processus. Myo1b est associée et contrôle la formation d'ondes d'actine antérogrades qui 'cross-talk" avec les microtubules pour diriger le transport de la kinésine1 sur les microtubules et conduire à la formation de l'axone. L'inhibition de Myo1b empêche la propagation des ondes d'actine et le mouvement de KIF5560 une version constitutivement active du moteur Kinésine 1 associé aux microtubules. L' activité motrice et le domaine PH de Myo1b sont nécessaire à la propagation des ondes d'actine. Nos résultats indiquent que la Myosine 1b contrôle la rupture de la symétrie axonale et la formation de l'axone en contrôllant l'orientation de la polymérisation d'actine à la membrane dans les ondes d'actine antérograde. / Neurons are highly polarized cells, with a long axon and multiple short dendrites. Rearrangements of cytoskeleton, increased microtubule-based transport and coupling mechanically actin cytoskeleton to plasma membrane are required for the establishment of neuronal polarity. Class 1 Myosin, with the unique property to couple mechanically actin cytoskeleton to plasmamembrane are good candidate for regulatin axonogenesis. Myosin1b is highly expressed in developing brain where it was first identified. Thus, we investigated its role in axonogenesis. Depletion of endogenous Myo1b in cultured cortical neurons delays the neuronal differentiation and impairs the axonogenesis and the establishment of the neuronal polarity. The overexpression of Myosin1b rushes the neuronal development and promotes the formation of supernumerary axon-like structures. Myo1b requires its motor activity and its interaction with phosphoinositides via its PH motif to promote the axonogenesis. Myo1b associates and controls the formation of anterograde actin waves that cross-talk with microtubules to direct microtubules-bases transport of kinesin-1, and drive axon formation. Myo1b depletion impairs the propagation of actin waves and the translocation of KIF5560, a constitutively active version of the microtubules motor Kinesin-1. The motor activity and interaction with phosphoinositides of Myo1b are also required for the propagation of actin waves. Together our data indicate that myosin1b controls the neuronal symmetry breaking and the axogenesis by controlling the orientation of the actin polymerization to the membrane in the waves that drive the propagation of anterograde actin waves.

Polarité neuronale

Ondes d'actine

Neurone

Différenciation neuronale

Axone

Myosine 1b

Neuronal polarity

Axon formation

Myosin 1b

571.6