Huzefa Photowala scite author profile

Activity-dependent rapid structural and functional modifications of central excitatory synapses contribute to synapse maturation, experience-dependent plasticity, and learning and memory and are associated with neurodevelopmental and psychiatric disorders. However, the signal transduction mechanisms that link glutamate receptor activation to intracellular effectors that accomplish structural and functional plasticity are not well understood. Here we report that NMDA receptor activation in pyramidal neurons causes CaMKII-dependent phosphorylation of the guanine-nucleotide exchange factor (GEF) kalirin-7 at residue threonine 95, regulating its GEF activity, leading to activation of small GTPase Rac1 and rapid enlargement of existing spines. Kalirin-7 also interacts with AMPA receptors and controls their synaptic expression. By demonstrating that kalirin expression and spine localization are required for activity-dependent spine enlargement and enhancement of AMPAR-mediated synaptic transmission, our study identifies a signaling pathway that controls structural and functional spine plasticity.

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Epac2 induces synapse remodeling and depression and its disease-associated forms alter spines

Woolfrey

et al. 2009

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Dynamic remodeling of spiny synapses is crucial for cortical circuit development, refinement, and plasticity, while abnormal morphogenesis is associated with neuropsychiatric disorders. Here we show in cultured rat cortical neurons that activation of Epac2, a PKA-independent cAMP target and Rap guanine-nucleotide exchange factor (GEF), induces spine shrinkage, increases spine motility, removes synaptic GluR2/3-containing AMPA receptors, and depresses excitatory transmission, while its inhibition promotes spine enlargement and stabilization. Epac2 is required for dopamine D1-like receptor-dependent spine shrinkage and GluR2 removal from spines. Epac2 interaction with neuroligin promotes its membrane recruitment and enhances its GEF activity. Rare missense mutations in the EPAC2 gene, previously found in individuals with autism, affect basal and neuroligin-stimulated GEF activity, dendritic Rap signaling, synaptic protein distribution, and spine morphology. Thus, we identify a novel mechanism that promotes dynamic remodeling and depression of spiny synapses, whose mutations may contribute to some aspects of disease.

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Kalirin regulates cortical spine morphogenesis and disease-related behavioral phenotypes

Cahill

Xie

Day

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

152

197

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Dendritic spine morphogenesis contributes to brain function, cognition, and behavior, and is altered in psychiatric disorders. Kalirin is a brain-specific guanine-nucleotide exchange factor (GEF) for Rac-like GTPases and is a key regulator of spine morphogenesis. Here, we show that KALRN -knockout mice have specific reductions in cortical, but not hippocampal, Rac1 signaling and spine density, and exhibit reduced cortical glutamatergic transmission. These mice exhibit robust deficits in working memory, sociability, and prepulse inhibition, paralleled by locomotor hyperactivity reversible by clozapine in a kalirin-dependent manner. Several of these deficits are delayed and age-dependent. Our study thus links spine morphogenic signaling with age-dependent, delayed, disease-related phenotypes, including cognitive dysfunction.

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Coordination of Synaptic Adhesion with Dendritic Spine Remodeling by AF-6 and Kalirin-7

Xie¹,

Photowala²,

Cahill³

et al. 2008

Journal of Neuroscience

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Remodeling of central excitatory synapses is crucial for synapse maturation and plasticity, and contributes to neurodevelopmental and psychiatric disorders. Remodeling of dendritic spines and the associated synapses has been postulated to require the coordination of adhesion with spine morphology and stability; however, the molecular mechanisms that functionally link adhesion molecules with regulators of dendritic spine morphology are mostly unknown. Here, we report that spine size and N-cadherin content are tightly coordinated. In rat mature cortical pyramidal neurons, N-cadherin-dependent adhesion modulates the morphology of existing spines by recruiting the Rac1 guanine-nucleotide exchange factor kalirin-7 to synapses through the scaffolding protein AF-6/afadin. In pyramidal neurons, N-cadherin, AF-6, and kalirin-7 colocalize at synapses and participate in the same multiprotein complexes. N-cadherin clustering promotes the reciprocal interaction and recruitment of N-cadherin, AF-6, and kalirin-7, increasing the content of Rac1 and in spines and PAK (p21-activated kinase) phosphorylation. N-cadherin-dependent spine enlargement requires AF-6 and kalirin-7 function. Conversely, disruption of N-cadherin leads to thin, long spines, with reduced Rac1 contact, caused by uncoupling of N-cadherin, AF-6, and kalirin-7 from each other. By dynamically linking N-cadherin with a regulator of spine plasticity, this pathway allows synaptic adhesion molecules to rapidly coordinate spine remodeling associated with synapse maturation and plasticity. This study hence identifies a novel mechanism whereby cadherins, a major class of synaptic adhesion molecules, signal to the actin cytoskeleton to control the morphology of dendritic spines, and outlines a mechanism that underlies the coordination of synaptic adhesion with spine morphology.

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G protein βγ-subunits activated by serotonin mediate presynaptic inhibition by regulating vesicle fusion properties

Photowala

Blackmer

Schwartz

et al. 2006

Proc. Natl. Acad. Sci. U.S.A.

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