Your search keyword '"Urwyler O"' showing total 10 results

1. The Fine Art of Writing a Message: RNA Metabolism in the Shaping and Remodeling of the Nervous System.

Author

Landínez-Macías M and Urwyler O

Abstract

Neuronal morphogenesis, integration into circuits, and remodeling of synaptic connections occur in temporally and spatially defined steps. Accordingly, the expression of proteins and specific protein isoforms that contribute to these processes must be controlled quantitatively in time and space. A wide variety of post-transcriptional regulatory mechanisms, which act on pre-mRNA and mRNA molecules contribute to this control. They are thereby critically involved in physiological and pathophysiological nervous system development, function, and maintenance. Here, we review recent findings on how mRNA metabolism contributes to neuronal development, from neural stem cell maintenance to synapse specification, with a particular focus on axon growth, guidance, branching, and synapse formation. We emphasize the role of RNA-binding proteins, and highlight their emerging roles in the poorly understood molecular processes of RNA editing, alternative polyadenylation, and temporal control of splicing, while also discussing alternative splicing, RNA localization, and local translation. We illustrate with the example of the evolutionary conserved Musashi protein family how individual RNA-binding proteins are, on the one hand, acting in different processes of RNA metabolism, and, on the other hand, impacting multiple steps in neuronal development and circuit formation. Finally, we provide links to diseases that have been associated with the malfunction of RNA-binding proteins and disrupted post-transcriptional regulation., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Landínez-Macías and Urwyler.)

Published

2021

2. The RNA-binding protein Musashi controls axon compartment-specific synaptic connectivity through ptp69D mRNA poly(A)-tailing.

Author

Landínez-Macías M, Qi W, Bratus-Neuenschwander A, Müller M, and Urwyler O

Subjects

3' Untranslated Regions, Animals, Drosophila growth & development, Drosophila metabolism, Drosophila Proteins antagonists & inhibitors, Drosophila Proteins genetics, Larva metabolism, Morphogenesis, Neurons metabolism, Protein Binding, RNA Interference, RNA, Messenger genetics, RNA, Messenger metabolism, RNA, Small Interfering metabolism, RNA-Binding Proteins antagonists & inhibitors, RNA-Binding Proteins genetics, Receptor-Like Protein Tyrosine Phosphatases antagonists & inhibitors, Receptor-Like Protein Tyrosine Phosphatases genetics, Receptors, Odorant metabolism, Axons physiology, Drosophila Proteins metabolism, Poly A metabolism, RNA-Binding Proteins metabolism, Receptor-Like Protein Tyrosine Phosphatases metabolism, Synapses physiology

Abstract

Synaptic targeting with subcellular specificity is essential for neural circuit assembly. Developing neurons use mechanisms to curb promiscuous synaptic connections and to direct synapse formation to defined subcellular compartments. How this selectivity is achieved molecularly remains enigmatic. Here, we discover a link between mRNA poly(A)-tailing and axon collateral branch-specific synaptic connectivity within the CNS. We reveal that the RNA-binding protein Musashi binds to the mRNA encoding the receptor protein tyrosine phosphatase Ptp69D, thereby increasing poly(A) tail length and Ptp69D protein levels. This regulation specifically promotes synaptic connectivity in one axon collateral characterized by a high degree of arborization and strong synaptogenic potential. In a different compartment of the same axon, Musashi prevents ectopic synaptogenesis, revealing antagonistic, compartment-specific functions. Moreover, Musashi-dependent Ptp69D regulation controls synaptic connectivity in the olfactory circuit. Thus, Musashi differentially shapes synaptic connectivity at the level of individual subcellular compartments and within different developmental and neuron type-specific contexts., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2021

3. Branch-restricted localization of phosphatase Prl-1 specifies axonal synaptogenesis domains.

Author

Urwyler O, Izadifar A, Vandenbogaerde S, Sachse S, Misbaer A, and Schmucker D

Subjects

Animals, Axons enzymology, Central Nervous System enzymology, Drosophila Proteins chemistry, Drosophila Proteins genetics, Drosophila Proteins metabolism, Drosophila melanogaster genetics, Locomotion genetics, Locomotion physiology, Mechanoreceptors enzymology, Phosphatidylinositols metabolism, Protein Domains, Protein Tyrosine Phosphatases chemistry, Protein Tyrosine Phosphatases genetics, Proto-Oncogene Proteins c-akt metabolism, Receptor Protein-Tyrosine Kinases metabolism, Synapses enzymology, Axons physiology, Central Nervous System growth & development, Drosophila Proteins physiology, Drosophila melanogaster growth & development, Protein Tyrosine Phosphatases physiology, Synapses physiology

Abstract

Central nervous system (CNS) circuit development requires subcellular control of synapse formation and patterning of synapse abundance. We identified the Drosophila membrane-anchored phosphatase of regenerating liver (Prl-1) as an axon-intrinsic factor that promotes synapse formation in a spatially restricted fashion. The loss of Prl-1 in mechanosensory neurons reduced the number of CNS presynapses localized on a single axon collateral and organized as a terminal arbor. Flies lacking all Prl-1 protein had locomotor defects. The overexpression of Prl-1 induced ectopic synapses. In mechanosensory neurons, Prl-1 modulates the insulin receptor (InR) signaling pathway within a single contralateral axon compartment, thereby affecting the number of synapses. The axon branch-specific localization and function of Prl-1 depend on untranslated regions of the prl-1 messenger RNA (mRNA). Therefore, compartmentalized restriction of Prl-1 serves as a specificity factor for the subcellular control of axonal synaptogenesis., (Copyright © 2019 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2019

4. Slit and Receptor Tyrosine Phosphatase 69D Confer Spatial Specificity to Axon Branching via Dscam1.

Author

Dascenco D, Erfurth ML, Izadifar A, Song M, Sachse S, Bortnick R, Urwyler O, Petrovic M, Ayaz D, He H, Kise Y, Thomas F, Kidd T, and Schmucker D

Subjects

Animals, Cell Adhesion Molecules, Drosophila melanogaster cytology, Growth Cones metabolism, Axons metabolism, Drosophila Proteins metabolism, Drosophila melanogaster metabolism, Nerve Tissue Proteins metabolism, Neural Cell Adhesion Molecules metabolism, Receptor-Like Protein Tyrosine Phosphatases metabolism

Abstract

Axonal branching contributes substantially to neuronal circuit complexity. Studies in Drosophila have shown that loss of Dscam1 receptor diversity can fully block axon branching in mechanosensory neurons. Here we report that cell-autonomous loss of the receptor tyrosine phosphatase 69D (RPTP69D) and loss of midline-localized Slit inhibit formation of specific axon collaterals through modulation of Dscam1 activity. Genetic and biochemical data support a model in which direct binding of Slit to Dscam1 enhances the interaction of Dscam1 with RPTP69D, stimulating Dscam1 dephosphorylation. Single-growth-cone imaging reveals that Slit/RPTP69D are not required for general branch initiation but instead promote the extension of specific axon collaterals. Hence, although regulation of intrinsic Dscam1-Dscam1 isoform interactions is essential for formation of all mechanosensory-axon branches, the local ligand-induced alterations of Dscam1 phosphorylation in distinct growth-cone compartments enable the spatial specificity of axon collateral formation., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2015

5. Investigating CNS synaptogenesis at single-synapse resolution by combining reverse genetics with correlative light and electron microscopy.

Author

Urwyler O, Izadifar A, Dascenco D, Petrovic M, He H, Ayaz D, Kremer A, Lippens S, Baatsen P, Guérin CJ, and Schmucker D

Subjects

Animals, Drosophila, Immunohistochemistry, RNA Interference, Central Nervous System growth & development, Imaging, Three-Dimensional methods, Mechanoreceptors cytology, Microscopy, Electron, Scanning methods, Reverse Genetics methods, Synapses physiology, Synapses ultrastructure

Abstract

Determining direct synaptic connections of specific neurons in the central nervous system (CNS) is a major technical challenge in neuroscience. As a corollary, molecular pathways controlling developmental synaptogenesis in vivo remain difficult to address. Here, we present genetic tools for efficient and versatile labeling of organelles, cytoskeletal components and proteins at single-neuron and single-synapse resolution in Drosophila mechanosensory (ms) neurons. We extended the imaging analysis to the ultrastructural level by developing a protocol for correlative light and 3D electron microscopy (3D CLEM). We show that in ms neurons, synaptic puncta revealed by genetically encoded markers serve as a reliable indicator of individual active zones. Block-face scanning electron microscopy analysis of ms axons revealed T-bar-shaped dense bodies and other characteristic ultrastructural features of CNS synapses. For a mechanistic analysis, we directly combined the single-neuron labeling approach with cell-specific gene disruption techniques. In proof-of-principle experiments we found evidence for a highly similar requirement for the scaffolding molecule Liprin-α and its interactors Lar and DSyd-1 (RhoGAP100F) in synaptic vesicle recruitment. This suggests that these important synapse regulators might serve a shared role at presynaptic sites within the CNS. In principle, our CLEM approach is broadly applicable to the developmental and ultrastructural analysis of any cell type that can be targeted with genetically encoded markers., (© 2015. Published by The Company of Biologists Ltd.)

Published

2015

6. Cell-intrinsic requirement of Dscam1 isoform diversity for axon collateral formation.

Author

He H, Kise Y, Izadifar A, Urwyler O, Ayaz D, Parthasarthy A, Yan B, Erfurth ML, Dascenco D, and Schmucker D

Subjects

Alleles, Animals, Cell Adhesion Molecules genetics, Drosophila Proteins genetics, Drosophila melanogaster genetics, Gene Dosage, Mechanotransduction, Cellular genetics, Mechanotransduction, Cellular physiology, Protein Isoforms genetics, RNA Interference, Axons physiology, Cell Adhesion Molecules physiology, Drosophila Proteins physiology, Drosophila melanogaster growth & development, Protein Isoforms physiology

Abstract

The isoform diversity of the Drosophila Dscam1 receptor is important for neuronal self-recognition and self-avoidance. A canonical model suggests that homophilic binding of identical Dscam1 receptor isoforms on sister dendrites ensures self-avoidance even when only a single isoform is expressed. We detected a cell-intrinsic function of Dscam1 that requires the coexpression of multiple isoforms. Manipulation of the Dscam1 isoform pool in single neurons caused severe disruption of collateral formation of mechanosensory axons. Changes in isoform abundance led to dominant dosage-sensitive inhibition of branching. We propose that the ratio of matching to nonmatching isoforms within a cell influences the Dscam1-mediated signaling strength, which in turn controls axon growth and growth cone sprouting. Cell-intrinsic use of surface receptor diversity may be of general importance in regulating axonal branching during brain wiring., (Copyright © 2014, American Association for the Advancement of Science.)

Published

2014

7. Drosophila sosie functions with β(H)-Spectrin and actin organizers in cell migration, epithelial morphogenesis and cortical stability.

Author

Urwyler O, Cortinas-Elizondo F, and Suter B

Abstract

Morphogenesis in multicellular organisms requires the careful coordination of cytoskeletal elements, dynamic regulation of cell adhesion and extensive cell migration. sosie (sie) is a novel gene required in various morphogenesis processes in Drosophila oogenesis. Lack of sie interferes with normal egg chamber packaging, maintenance of epithelial integrity and control of follicle cell migration, indicating that sie is involved in controlling epithelial integrity and cell migration. For these functions sie is required both in the germ line and in the soma. Consistent with this, Sosie localizes to plasma membranes in the germ line and in the somatic follicle cells and is predicted to present an EGF-like domain on the extracellular side. Two positively charged residues, C-terminal to the predicted transmembrane domain (on the cytoplasmic side), are required for normal plasma membrane localization of Sosie. Because sie also contributes to normal cortical localization of β(H)-Spectrin, it appears that cortical β(H)-Spectrin mediates some of the functions of sosie. sie also interacts with the genes coding for the actin organizers Filamin and Profilin and, in the absence of sie function, F-actin is less well organized and nurse cells frequently fuse.

Published

2012

8. Drosophila Xpd regulates Cdk7 localization, mitotic kinase activity, spindle dynamics, and chromosome segregation.

Author

Li X, Urwyler O, and Suter B

Subjects

Alleles, Animals, CDC2 Protein Kinase metabolism, Cell Cycle Proteins genetics, Cell Nucleus pathology, Chromosomal Instability, Chromosomes metabolism, Cyclin B metabolism, DNA Helicases, Drosophila Proteins genetics, Drosophila melanogaster embryology, Drosophila melanogaster genetics, Embryo, Nonmammalian cytology, Embryo, Nonmammalian enzymology, Genes, Essential, Protein Transport, Subcellular Fractions enzymology, Cyclin-Dependent Kinase-Activating Kinase, Cell Cycle Proteins metabolism, Chromosome Segregation, Cyclin-Dependent Kinases metabolism, Drosophila Proteins metabolism, Drosophila melanogaster cytology, Drosophila melanogaster enzymology, Mitosis, Spindle Apparatus metabolism

Abstract

The trimeric CAK complex functions in cell cycle control by phosphorylating and activating Cdks while TFIIH-linked CAK functions in transcription. CAK also associates into a tetramer with Xpd, and our analysis of young Drosophila embryos that do not require transcription now suggests a cell cycle function for this interaction. xpd is essential for the coordination and rapid progression of the mitotic divisions during the late nuclear division cycles. Lack of Xpd also causes defects in the dynamics of the mitotic spindle and chromosomal instability as seen in the failure to segregate chromosomes properly during ana- and telophase. These defects appear to be also nucleotide excision repair (NER)-independent. In the absence of Xpd, misrouted spindle microtubules attach to chromosomes of neighboring mitotic figures, removing them from their normal location and causing multipolar spindles and aneuploidy. Lack of Xpd also causes changes in the dynamics of subcellular and temporal distribution of the CAK component Cdk7 and local mitotic kinase activity. xpd thus functions normally to re-localize Cdk7(CAK) to different subcellular compartments, apparently removing it from its cell cycle substrate, the mitotic Cdk. This work proves that the multitask protein Xpd also plays an essential role in cell cycle regulation that appears to be independent of transcription or NER. Xpd dynamically localizes Cdk7/CAK to and away from subcellular substrates, thereby controlling local mitotic kinase activity. Possibly through this activity, xpd controls spindle dynamics and chromosome segregation in our model system. This novel role of xpd should also lead to new insights into the understanding of the neurological and cancer aspects of the human XPD disease phenotypes., Competing Interests: The authors have declared that no competing interests exist.

Published

2010

9. Systematic functional analysis of Bicaudal-D serine phosphorylation and intragenic suppression of a female sterile allele of BicD.

Author

Koch R, Ledermann R, Urwyler O, Heller M, and Suter B

Subjects

Alleles, Animals, Binding Sites, Drosophila Proteins genetics, Drosophila Proteins metabolism, Embryonic Development, Female, Mutation, Missense, Oocytes, Oogenesis, Phosphorylation physiology, Phosphoserine, Serine metabolism, Drosophila Proteins physiology

Abstract

Protein phosphorylation is involved in posttranslational control of essentially all biological processes. Using mass spectrometry, recent analyses of whole phosphoproteomes led to the identification of numerous new phosphorylation sites. However, the function of most of these sites remained unknown. We chose the Drosophila Bicaudal-D protein to estimate the importance of individual phosphorylation events. Being involved in different cellular processes, BicD is required for oocyte determination, for RNA transport during oogenesis and embryogenesis, and for photoreceptor nuclei migration in the developing eye. The numerous roles of BicD and the available evidence for functional importance of BicD phosphorylation led us to identify eight phosphorylation sites of BicD, and we tested a total of 14 identified and suspected phosphoserine residues for their functional importance in vivo in flies. Surprisingly, all these serines turned out to be dispensable for providing sufficient basal BicD activity for normal growth and development. However, in a genetically sensitized background where the BicD(A40V) protein variant provides only partial activity, serine 103 substitutions are not neutral anymore, but show surprising differences. The S103D substitution completely inactivates the protein, whereas S103A behaves neutral, and the S103F substitution, isolated in a genetic screen, restores BicD(A40V) function. Our results suggest that many BicD phosphorylation events may either be fortuitous or play a modulating function as shown for Ser(103). Remarkably, amongst the Drosophila serines we found phosphorylated, Ser(103) is the only one that is fully conserved in mammalian BicD.

Published

2009

10. Tissue-dependent subcellular localization of Drosophila arginine methyl-transferase 4 (DART4), a coactivator whose overexpression affects neither viability nor differentiation.

Author

Urwyler O, Zhang L, Li X, Imboden H, and Suter B

Subjects

Animals, Cell Survival physiology, Drosophila Proteins biosynthesis, Drosophila Proteins genetics, Drosophila melanogaster cytology, Larva enzymology, Methyltransferases biosynthesis, Methyltransferases genetics, Organ Specificity physiology, Pupa enzymology, Subcellular Fractions metabolism, Cell Differentiation physiology, Drosophila Proteins metabolism, Drosophila melanogaster enzymology, Methyltransferases metabolism

Abstract

Drosophila arginine methyl-transferase 4 (DART4) belongs to the type I class of arginine methyltransferases. It catalyzes the methylation of arginine residues to monomethylarginines and asymmetrical dimethylarginines. The DART4 sequence is highly similar to mammalian PRMT4/CARM1, and DART4 substrate specificity has been conserved, too. Recently it was suggested that DART4/Carmer functions in ecdysone receptor mediated apoptosis of the polytene larval salivary glands and an apparent up-regulation of DART4/Carmer mRNA levels before tissue histolysis was reported. Here we show that in Drosophila larvae, DART4 is mainly expressed in the imaginal disks and in larval brains, and to a much lesser degree in the polytene larval tissue such as salivary glands. In glands, DART4 protein is present in the cytoplasm and the nucleus. The nuclear signal emanates from the extrachromosomal domain and gets progressively restricted to the region of the nuclear lamina upon pupariation. Surprisingly, DART4 levels do not increase in salivary glands during pupariation, and overexpression of DART4 does not cause precautious cell death in the glands. Furthermore, over- and misexpression of DART4 under the control of the alpha tubulin promoter do not lead to any major problem in the life of a fly. This suggests that DART4 activity is regulated at the posttranslational level and/or that it acts as a true cofactor in vivo. We present evidence that nuclear localization of DART4 may contribute to its function because DART4 accumulation changes from a distribution with a strong cytoplasmic component during the transcriptional quiescence of the young embryo to a predominantly nuclear one at the onset of zygotic transcription.

Published

2007