URV's Author/s: | Cilleros Mañé, Víctor / DURAN ROMASEWSKYS, MARIA SOLEDAD / Garcia Sancho, Maria de les Neus / Just Borràs, Laia / Lanuza Escolano, María Angel / POLISHCHUK, ALEKSANDRA / Tomás Ferré, José Maria / Tomas Marginet, Marta |
Author, as appears in the article.: | Garcia, Neus; Lanuza, Maria A.; Tomas, Marta; Cilleros-Mane, Victor; Just-Borras, Laia; Duran, Maria; Polishchuk, Aleksandra; Tomas, Josep; |
Author's mail: | aleksandra.polishchuk@urv.cat laia.just@urv.cat marta.tomas@urv.cat aleksandra.polishchuk@urv.cat victor.cilleros@urv.cat josepmaria.tomas@urv.cat laia.just@urv.cat mariaangel.lanuza@urv.cat |
Author identifier: | 0000-0001-6445-1538 0000-0003-0473-3730 0000-0002-4151-1697 0000-0001-6445-1538 0000-0001-5690-9932 0000-0002-0406-0006 0000-0003-0473-3730 0000-0003-4795-4103 |
Journal publication year: | 2021 |
Publication Type: | Journal Publications |
e-ISSN: | 2073-4409 |
APA: | Garcia, Neus; Lanuza, Maria A.; Tomas, Marta; Cilleros-Mane, Victor; Just-Borras, Laia; Duran, Maria; Polishchuk, Aleksandra; Tomas, Josep; (2021). PKA and PKC Balance in Synapse Elimination during Neuromuscular Junction Development. Cells, 10(6), 1384-. DOI: 10.3390/cells10061384 |
Papper original source: | Cells. 10 (6): 1384- |
Abstract: | During the development of the nervous system, synaptogenesis occurs in excess though only the appropriate connections consolidate. At the neuromuscular junction, competition between several motor nerve terminals results in the maturation of a single axon and the elimination of the others. The activity-dependent release of transmitter, cotransmitters, and neurotrophic factors allows the direct mutual influence between motor axon terminals through receptors such as presynaptic muscarinic ACh autoreceptors and the tropomyosin-related kinase B neurotrophin receptor. In previous studies, we investigated the synergistic and antagonistic relations between these receptors and their downstream coupling to PKA and PKC pathways and observed a metabotropic receptor-driven balance between PKA (stabilizes multinnervation) and PKC (promotes developmental axonal loss). However, how much does each kinase contribute in the developmental synapse elimination process? A detailed statistical analysis of the differences between the PKA and PKC effects in the synapse elimination could help to explore this point. The present short communication provides this analysis and results show that a similar level of PKA inhibition and PKC potentiation would be required during development to promote synapse loss. |
Article's DOI: | 10.3390/cells10061384 |
Link to the original source: | https://www.mdpi.com/2073-4409/10/6/1384 |
Papper version: | info:eu-repo/semantics/publishedVersion |
licence for use: | https://creativecommons.org/licenses/by/3.0/es/ |
Department: | Ciències Mèdiques Bàsiques |
Licence document URL: | https://repositori.urv.cat/ca/proteccio-de-dades/ |
Thematic Areas: | Medicine (miscellaneous) Cell biology Biochemistry, genetics and molecular biology (miscellaneous) Biochemistry, genetics and molecular biology (all) |
Keywords: | Tropomyosin Transgenic mouse Synaptogenesis Synaptic transmission Synapse Sodium Signal transduction Receptors Protein kinases Protein kinase c Protein expression Protein Presynaptic terminals Postnatal synapse elimination Pkc Pka Phorbol 13 acetate 12 myristate Nonhuman Nicotinic receptor Nicotinic acetylcholine receptor clusters Neurotrophin receptor Neurotrophic factor Neurotransmitter Neuromuscular junction Neurogenesis Nervous system development Nervous system Nerve ending Musculoskeletal development Muscarinic receptor Muscarinic m4 receptor Muscarinic m3 receptor Muscarinic m2 receptor Muscarinic m1 receptor Mouse Motor end-plate Motor end plate Mice, transgenic Mice Metabotropic receptor Metabolism Maturation Growth, development and aging Genetics Gene expression Decision making Cyclic amp-dependent protein kinases Cyclic amp dependent protein kinase Confocal microscopy Competition Chelerythrine Calphostin c Axonal competition Axon Article Animals Animal tissue Animal model Animal experiment Animal Alpha bungarotoxin Adenosine receptor Adenosine a2a receptor Adenosine a1 receptor Adenosine 3',5' phosphorothioate Adenosine Acetylcholine release 8 bromo cyclic amp 12 deoxyphorbol derivative |
Entity: | Universitat Rovira i Virgili |
Record's date: | 2024-07-27 |
Journal volume: | 10 |
Description: | During the development of the nervous system, synaptogenesis occurs in excess though only the appropriate connections consolidate. At the neuromuscular junction, competition between several motor nerve terminals results in the maturation of a single axon and the elimination of the others. The activity-dependent release of transmitter, cotransmitters, and neurotrophic factors allows the direct mutual influence between motor axon terminals through receptors such as presynaptic muscarinic ACh autoreceptors and the tropomyosin-related kinase B neurotrophin receptor. In previous studies, we investigated the synergistic and antagonistic relations between these receptors and their downstream coupling to PKA and PKC pathways and observed a metabotropic receptor-driven balance between PKA (stabilizes multinnervation) and PKC (promotes developmental axonal loss). However, how much does each kinase contribute in the developmental synapse elimination process? A detailed statistical analysis of the differences between the PKA and PKC effects in the synapse elimination could help to explore this point. The present short communication provides this analysis and results show that a similar level of PKA inhibition and PKC potentiation would be required during development to promote synapse loss. |
Type: | Journal Publications |
Contributor: | Universitat Rovira i Virgili |
Títol: | PKA and PKC Balance in Synapse Elimination during Neuromuscular Junction Development |
Subject: | Biochemistry, Genetics and Molecular Biology (Miscellaneous),Cell Biology,Medicine (Miscellaneous) Tropomyosin Transgenic mouse Synaptogenesis Synaptic transmission Synapse Sodium Signal transduction Receptors Protein kinases Protein kinase c Protein expression Protein Presynaptic terminals Postnatal synapse elimination Pkc Pka Phorbol 13 acetate 12 myristate Nonhuman Nicotinic receptor Nicotinic acetylcholine receptor clusters Neurotrophin receptor Neurotrophic factor Neurotransmitter Neuromuscular junction Neurogenesis Nervous system development Nervous system Nerve ending Musculoskeletal development Muscarinic receptor Muscarinic m4 receptor Muscarinic m3 receptor Muscarinic m2 receptor Muscarinic m1 receptor Mouse Motor end-plate Motor end plate Mice, transgenic Mice Metabotropic receptor Metabolism Maturation Growth, development and aging Genetics Gene expression Decision making Cyclic amp-dependent protein kinases Cyclic amp dependent protein kinase Confocal microscopy Competition Chelerythrine Calphostin c Axonal competition Axon Article Animals Animal tissue Animal model Animal experiment Animal Alpha bungarotoxin Adenosine receptor Adenosine a2a receptor Adenosine a1 receptor Adenosine 3',5' phosphorothioate Adenosine Acetylcholine release 8 bromo cyclic amp 12 deoxyphorbol derivative Medicine (miscellaneous) Cell biology Biochemistry, genetics and molecular biology (miscellaneous) Biochemistry, genetics and molecular biology (all) |
Date: | 2021 |
Creator: | Garcia, Neus Lanuza, Maria A. Tomas, Marta Cilleros-Mane, Victor Just-Borras, Laia Duran, Maria Polishchuk, Aleksandra Tomas, Josep |
Rights: | info:eu-repo/semantics/openAccess |
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