Transient calcium and dopamine increase PKA activity and DARPP-32 phosphorylation

Reinforcement learning theorizes that strengthening of synaptic connections in medium spiny neurons of the striatum occurs when glutamatergic input (from cortex) and dopaminergic input (from substantia nigra) are received simultaneously. Subsequent to learning, medium spiny neurons with strengthened...

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Veröffentlicht in:	PLoS computational biology 2006-09, Vol.2 (9), p.e119-e119
Hauptverfasser:	Lindskog, Maria, Kim, MyungSook, Wikström, Martin A, Blackwell, Kim T, Kotaleski, Jeanette Hellgren
Format:	Artikel
Sprache:	eng
Schlagworte:	adenosine 3'-5'-monophosphate-regulated phosphoprotein adenylyl-cyclase Analysis Animal Behavior bidirectional synaptic plasticity Bioinformatics - Computational Biology Calcium Calcium - metabolism camp-regulated phosphoprotein Cell Biology Computational Biology Computer Simulation Cyclic AMP-Dependent Protein Kinases - metabolism Cyclin-dependent kinases dependent protein-kinase Differential equations Dopamine Dopamine - metabolism Dopamine and cAMP-Regulated Phosphoprotein 32 - metabolism Experiments Kinases long-term potentiation Mammals Medicin och hälsovetenskap medium spiny neurons Models, Biological Neurology Neurons Neuroscience nucleus-accumbens neurons Ordinary differential equations Phosphorylation Phosphothreonine - metabolism Plasticity Protein Binding Protein kinases Proteins receptor stimulation increases Second Messenger Systems striatal projection neurons Systems Biology
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description	Reinforcement learning theorizes that strengthening of synaptic connections in medium spiny neurons of the striatum occurs when glutamatergic input (from cortex) and dopaminergic input (from substantia nigra) are received simultaneously. Subsequent to learning, medium spiny neurons with strengthened synapses are more likely to fire in response to cortical input alone. This synaptic plasticity is produced by phosphorylation of AMPA receptors, caused by phosphorylation of various signalling molecules. A key signalling molecule is the phosphoprotein DARPP-32, highly expressed in striatal medium spiny neurons. DARPP-32 is regulated by several neurotransmitters through a complex network of intracellular signalling pathways involving cAMP (increased through dopamine stimulation) and calcium (increased through glutamate stimulation). Since DARPP-32 controls several kinases and phosphatases involved in striatal synaptic plasticity, understanding the interactions between cAMP and calcium, in particular the effect of transient stimuli on DARPP-32 phosphorylation, has major implications for understanding reinforcement learning. We developed a computer model of the biochemical reaction pathways involved in the phosphorylation of DARPP-32 on Thr34 and Thr75. Ordinary differential equations describing the biochemical reactions were implemented in a single compartment model using the software XPPAUT. Reaction rate constants were obtained from the biochemical literature. The first set of simulations using sustained elevations of dopamine and calcium produced phosphorylation levels of DARPP-32 similar to that measured experimentally, thereby validating the model. The second set of simulations, using the validated model, showed that transient dopamine elevations increased the phosphorylation of Thr34 as expected, but transient calcium elevations also increased the phosphorylation of Thr34, contrary to what is believed. When transient calcium and dopamine stimuli were paired, PKA activation and Thr34 phosphorylation increased compared with dopamine alone. This result, which is robust to variation in model parameters, supports reinforcement learning theories in which activity-dependent long-term synaptic plasticity requires paired glutamate and dopamine inputs.
doi_str_mv	10.1371/journal.pcbi.0020119
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Subsequent to learning, medium spiny neurons with strengthened synapses are more likely to fire in response to cortical input alone. This synaptic plasticity is produced by phosphorylation of AMPA receptors, caused by phosphorylation of various signalling molecules. A key signalling molecule is the phosphoprotein DARPP-32, highly expressed in striatal medium spiny neurons. DARPP-32 is regulated by several neurotransmitters through a complex network of intracellular signalling pathways involving cAMP (increased through dopamine stimulation) and calcium (increased through glutamate stimulation). Since DARPP-32 controls several kinases and phosphatases involved in striatal synaptic plasticity, understanding the interactions between cAMP and calcium, in particular the effect of transient stimuli on DARPP-32 phosphorylation, has major implications for understanding reinforcement learning. We developed a computer model of the biochemical reaction pathways involved in the phosphorylation of DARPP-32 on Thr34 and Thr75. Ordinary differential equations describing the biochemical reactions were implemented in a single compartment model using the software XPPAUT. Reaction rate constants were obtained from the biochemical literature. The first set of simulations using sustained elevations of dopamine and calcium produced phosphorylation levels of DARPP-32 similar to that measured experimentally, thereby validating the model. The second set of simulations, using the validated model, showed that transient dopamine elevations increased the phosphorylation of Thr34 as expected, but transient calcium elevations also increased the phosphorylation of Thr34, contrary to what is believed. When transient calcium and dopamine stimuli were paired, PKA activation and Thr34 phosphorylation increased compared with dopamine alone. 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Subsequent to learning, medium spiny neurons with strengthened synapses are more likely to fire in response to cortical input alone. This synaptic plasticity is produced by phosphorylation of AMPA receptors, caused by phosphorylation of various signalling molecules. A key signalling molecule is the phosphoprotein DARPP-32, highly expressed in striatal medium spiny neurons. DARPP-32 is regulated by several neurotransmitters through a complex network of intracellular signalling pathways involving cAMP (increased through dopamine stimulation) and calcium (increased through glutamate stimulation). Since DARPP-32 controls several kinases and phosphatases involved in striatal synaptic plasticity, understanding the interactions between cAMP and calcium, in particular the effect of transient stimuli on DARPP-32 phosphorylation, has major implications for understanding reinforcement learning. We developed a computer model of the biochemical reaction pathways involved in the phosphorylation of DARPP-32 on Thr34 and Thr75. Ordinary differential equations describing the biochemical reactions were implemented in a single compartment model using the software XPPAUT. Reaction rate constants were obtained from the biochemical literature. The first set of simulations using sustained elevations of dopamine and calcium produced phosphorylation levels of DARPP-32 similar to that measured experimentally, thereby validating the model. The second set of simulations, using the validated model, showed that transient dopamine elevations increased the phosphorylation of Thr34 as expected, but transient calcium elevations also increased the phosphorylation of Thr34, contrary to what is believed. When transient calcium and dopamine stimuli were paired, PKA activation and Thr34 phosphorylation increased compared with dopamine alone. This result, which is robust to variation in model parameters, supports reinforcement learning theories in which activity-dependent long-term synaptic plasticity requires paired glutamate and dopamine inputs.</description><subject>adenosine 3'-5'-monophosphate-regulated phosphoprotein</subject><subject>adenylyl-cyclase</subject><subject>Analysis</subject><subject>Animal Behavior</subject><subject>bidirectional synaptic plasticity</subject><subject>Bioinformatics - Computational Biology</subject><subject>Calcium</subject><subject>Calcium - metabolism</subject><subject>camp-regulated phosphoprotein</subject><subject>Cell Biology</subject><subject>Computational Biology</subject><subject>Computer Simulation</subject><subject>Cyclic AMP-Dependent Protein Kinases - metabolism</subject><subject>Cyclin-dependent kinases</subject><subject>dependent protein-kinase</subject><subject>Differential equations</subject><subject>Dopamine</subject><subject>Dopamine - metabolism</subject><subject>Dopamine and cAMP-Regulated Phosphoprotein 32 - metabolism</subject><subject>Experiments</subject><subject>Kinases</subject><subject>long-term potentiation</subject><subject>Mammals</subject><subject>Medicin och hälsovetenskap</subject><subject>medium spiny neurons</subject><subject>Models, Biological</subject><subject>Neurology</subject><subject>Neurons</subject><subject>Neuroscience</subject><subject>nucleus-accumbens neurons</subject><subject>Ordinary differential equations</subject><subject>Phosphorylation</subject><subject>Phosphothreonine - metabolism</subject><subject>Plasticity</subject><subject>Protein Binding</subject><subject>Protein kinases</subject><subject>Proteins</subject><subject>receptor stimulation increases</subject><subject>Second Messenger Systems</subject><subject>striatal projection neurons</subject><subject>Systems Biology</subject><issn>1553-7358</issn><issn>1553-734X</issn><issn>1553-7358</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2006</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><sourceid>ABUWG</sourceid><sourceid>AFKRA</sourceid><sourceid>AZQEC</sourceid><sourceid>BENPR</sourceid><sourceid>CCPQU</sourceid><sourceid>DWQXO</sourceid><sourceid>GNUQQ</sourceid><sourceid>D8T</sourceid><sourceid>DOA</sourceid><recordid>eNqVk29r1DAcx4sobk7fgWhBEATvbJKmSZ4Ix-afw6HnnD4NaZrc5dY2NWmn9-5N73pulQ0ZpTT88vl--_uTRNFTkEwBIuDN2nauFuW0kbmZJglMAGD3okOAMZoQhOn9a-uD6JH36yQJS5Y9jA5AxjIMCDmMvp47UXuj6jaWopSmq2JRF3FhG1GZWsWmlk4Jr-LFp1ksZGsuTbvZIiezs8VigmDcrKwPr9uUojW2fhw90KL06snwPYq-v393fvxxcvrlw_x4djqRDLI2pJWqlGGN0wIKhnFCMM01yYmSlGqoNaEES5kRoahSVDCo07CjcolD5hiio-j5zrcpredDNzwHCMA0RRnFgZjviMKKNW-cqYTbcCsM3wasW3LhWiNLxWmesYRmMMUFS0mOGdMyF5qkmCZaAxG8Jjsv_0s1XT5yG0IXYaU4JohBGnh2K984W1yJ9kK4H0rQkjtqAcOhJX3Fr29Vnpgfs23NF-2KgywBacDfDi3s8koVMpwCJ8rx_0Y7tVnxpb3kAPet6mfwcjBw9menfMsr46UqS1Er23meUcAYQ-l_QcBQhhDoa3_xD3jzZAdqKcLwTK1tSE_2lnwGMKSUYdR7TW-gwlOoykhbK21CfCR4NRIEplW_26XovOfzb2d3YD-P2XTHSme9d0r_bTFIeH-Z90Xy_jLz4TIH2bPr47kS7Q_KH98QRoc</recordid><startdate>20060901</startdate><enddate>20060901</enddate><creator>Lindskog, Maria</creator><creator>Kim, MyungSook</creator><creator>Wikström, Martin A</creator><creator>Blackwell, Kim T</creator><creator>Kotaleski, Jeanette Hellgren</creator><general>Public Library of Science</general><general>Public Library of Science (PLoS)</general><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>ISN</scope><scope>ISR</scope><scope>3V.</scope><scope>7QO</scope><scope>7QP</scope><scope>7TK</scope><scope>7TM</scope><scope>7X7</scope><scope>7XB</scope><scope>88E</scope><scope>8AL</scope><scope>8FD</scope><scope>8FE</scope><scope>8FG</scope><scope>8FH</scope><scope>8FI</scope><scope>8FJ</scope><scope>8FK</scope><scope>ABUWG</scope><scope>AFKRA</scope><scope>ARAPS</scope><scope>AZQEC</scope><scope>BBNVY</scope><scope>BENPR</scope><scope>BGLVJ</scope><scope>BHPHI</scope><scope>CCPQU</scope><scope>DWQXO</scope><scope>FR3</scope><scope>FYUFA</scope><scope>GHDGH</scope><scope>GNUQQ</scope><scope>HCIFZ</scope><scope>JQ2</scope><scope>K7-</scope><scope>K9.</scope><scope>LK8</scope><scope>M0N</scope><scope>M0S</scope><scope>M1P</scope><scope>M7P</scope><scope>P5Z</scope><scope>P62</scope><scope>P64</scope><scope>PIMPY</scope><scope>PQEST</scope><scope>PQQKQ</scope><scope>PQUKI</scope><scope>Q9U</scope><scope>RC3</scope><scope>7X8</scope><scope>5PM</scope><scope>ADTPV</scope><scope>AOWAS</scope><scope>D8V</scope><scope>D8T</scope><scope>ZZAVC</scope><scope>DOA</scope></search><sort><creationdate>20060901</creationdate><title>Transient calcium and dopamine increase PKA activity and DARPP-32 phosphorylation</title><author>Lindskog, Maria ; Kim, MyungSook ; Wikström, Martin A ; Blackwell, Kim T ; Kotaleski, Jeanette Hellgren</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c929t-734e495f54d2a9550758bf7b7ec88f2ff7875cc67ae8ee8a92f4c88ebc5517523</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2006</creationdate><topic>adenosine 3'-5'-monophosphate-regulated phosphoprotein</topic><topic>adenylyl-cyclase</topic><topic>Analysis</topic><topic>Animal Behavior</topic><topic>bidirectional synaptic plasticity</topic><topic>Bioinformatics - Computational Biology</topic><topic>Calcium</topic><topic>Calcium - metabolism</topic><topic>camp-regulated phosphoprotein</topic><topic>Cell Biology</topic><topic>Computational Biology</topic><topic>Computer Simulation</topic><topic>Cyclic AMP-Dependent Protein Kinases - metabolism</topic><topic>Cyclin-dependent kinases</topic><topic>dependent protein-kinase</topic><topic>Differential equations</topic><topic>Dopamine</topic><topic>Dopamine - metabolism</topic><topic>Dopamine and cAMP-Regulated Phosphoprotein 32 - metabolism</topic><topic>Experiments</topic><topic>Kinases</topic><topic>long-term potentiation</topic><topic>Mammals</topic><topic>Medicin och hälsovetenskap</topic><topic>medium spiny neurons</topic><topic>Models, Biological</topic><topic>Neurology</topic><topic>Neurons</topic><topic>Neuroscience</topic><topic>nucleus-accumbens neurons</topic><topic>Ordinary differential equations</topic><topic>Phosphorylation</topic><topic>Phosphothreonine - metabolism</topic><topic>Plasticity</topic><topic>Protein Binding</topic><topic>Protein kinases</topic><topic>Proteins</topic><topic>receptor stimulation increases</topic><topic>Second Messenger Systems</topic><topic>striatal projection neurons</topic><topic>Systems Biology</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Lindskog, Maria</creatorcontrib><creatorcontrib>Kim, MyungSook</creatorcontrib><creatorcontrib>Wikström, Martin A</creatorcontrib><creatorcontrib>Blackwell, Kim T</creatorcontrib><creatorcontrib>Kotaleski, Jeanette Hellgren</creatorcontrib><collection>Medline</collection><collection>MEDLINE</collection><collection>MEDLINE (Ovid)</collection><collection>MEDLINE</collection><collection>MEDLINE</collection><collection>PubMed</collection><collection>CrossRef</collection><collection>Gale In Context: Canada</collection><collection>Gale In Context: Science</collection><collection>ProQuest Central (Corporate)</collection><collection>Biotechnology Research Abstracts</collection><collection>Calcium & Calcified Tissue Abstracts</collection><collection>Neurosciences Abstracts</collection><collection>Nucleic Acids Abstracts</collection><collection>Health & Medical Collection</collection><collection>ProQuest Central (purchase pre-March 2016)</collection><collection>Medical Database (Alumni Edition)</collection><collection>Computing Database (Alumni Edition)</collection><collection>Technology Research Database</collection><collection>ProQuest SciTech Collection</collection><collection>ProQuest Technology Collection</collection><collection>ProQuest Natural Science Collection</collection><collection>Hospital Premium Collection</collection><collection>Hospital Premium Collection (Alumni Edition)</collection><collection>ProQuest Central (Alumni) (purchase pre-March 2016)</collection><collection>ProQuest Central (Alumni Edition)</collection><collection>ProQuest Central UK/Ireland</collection><collection>Advanced Technologies & Aerospace Collection</collection><collection>ProQuest Central Essentials</collection><collection>Biological Science Collection</collection><collection>ProQuest Central</collection><collection>Technology Collection</collection><collection>Natural Science Collection</collection><collection>ProQuest One Community College</collection><collection>ProQuest Central Korea</collection><collection>Engineering Research Database</collection><collection>Health Research Premium Collection</collection><collection>Health Research Premium Collection (Alumni)</collection><collection>ProQuest Central Student</collection><collection>SciTech Premium Collection</collection><collection>ProQuest Computer Science Collection</collection><collection>Computer Science Database</collection><collection>ProQuest Health & Medical Complete (Alumni)</collection><collection>ProQuest Biological Science Collection</collection><collection>Computing Database</collection><collection>Health & Medical Collection (Alumni Edition)</collection><collection>Medical Database</collection><collection>Biological Science Database</collection><collection>Advanced Technologies & Aerospace Database</collection><collection>ProQuest Advanced Technologies & Aerospace Collection</collection><collection>Biotechnology and BioEngineering Abstracts</collection><collection>Access via ProQuest (Open Access)</collection><collection>ProQuest One Academic Eastern Edition (DO NOT USE)</collection><collection>ProQuest One Academic</collection><collection>ProQuest One Academic UKI Edition</collection><collection>ProQuest Central Basic</collection><collection>Genetics Abstracts</collection><collection>MEDLINE - 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Subsequent to learning, medium spiny neurons with strengthened synapses are more likely to fire in response to cortical input alone. This synaptic plasticity is produced by phosphorylation of AMPA receptors, caused by phosphorylation of various signalling molecules. A key signalling molecule is the phosphoprotein DARPP-32, highly expressed in striatal medium spiny neurons. DARPP-32 is regulated by several neurotransmitters through a complex network of intracellular signalling pathways involving cAMP (increased through dopamine stimulation) and calcium (increased through glutamate stimulation). Since DARPP-32 controls several kinases and phosphatases involved in striatal synaptic plasticity, understanding the interactions between cAMP and calcium, in particular the effect of transient stimuli on DARPP-32 phosphorylation, has major implications for understanding reinforcement learning. We developed a computer model of the biochemical reaction pathways involved in the phosphorylation of DARPP-32 on Thr34 and Thr75. Ordinary differential equations describing the biochemical reactions were implemented in a single compartment model using the software XPPAUT. Reaction rate constants were obtained from the biochemical literature. The first set of simulations using sustained elevations of dopamine and calcium produced phosphorylation levels of DARPP-32 similar to that measured experimentally, thereby validating the model. The second set of simulations, using the validated model, showed that transient dopamine elevations increased the phosphorylation of Thr34 as expected, but transient calcium elevations also increased the phosphorylation of Thr34, contrary to what is believed. When transient calcium and dopamine stimuli were paired, PKA activation and Thr34 phosphorylation increased compared with dopamine alone. 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subjects	adenosine 3'-5'-monophosphate-regulated phosphoprotein adenylyl-cyclase Analysis Animal Behavior bidirectional synaptic plasticity Bioinformatics - Computational Biology Calcium Calcium - metabolism camp-regulated phosphoprotein Cell Biology Computational Biology Computer Simulation Cyclic AMP-Dependent Protein Kinases - metabolism Cyclin-dependent kinases dependent protein-kinase Differential equations Dopamine Dopamine - metabolism Dopamine and cAMP-Regulated Phosphoprotein 32 - metabolism Experiments Kinases long-term potentiation Mammals Medicin och hälsovetenskap medium spiny neurons Models, Biological Neurology Neurons Neuroscience nucleus-accumbens neurons Ordinary differential equations Phosphorylation Phosphothreonine - metabolism Plasticity Protein Binding Protein kinases Proteins receptor stimulation increases Second Messenger Systems striatal projection neurons Systems Biology
title	Transient calcium and dopamine increase PKA activity and DARPP-32 phosphorylation
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