Literature DB >> 28388510

Mechanisms of input and output synaptic specificity: finding partners, building synapses, and fine-tuning communication.

Randi L Rawson1, E Anne Martin1, Megan E Williams2.   

Abstract

For most neurons to function properly, they need to develop synaptic specificity. This requires finding specific partner neurons, building the correct types of synapses, and fine-tuning these synapses in response to neural activity. Synaptic specificity is common at both a neuron's input and output synapses, whereby unique synapses are built depending on the partnering neuron. Neuroscientists have long appreciated the remarkable specificity of neural circuits but identifying molecular mechanisms mediating synaptic specificity has only recently accelerated. Here, we focus on recent progress in understanding input and output synaptic specificity in the mammalian brain. We review newly identified circuit examples for both and the latest research identifying molecular mediators including Kirrel3, FGFs, and DGLα. Lastly, we expect the pace of research on input and output specificity to continue to accelerate with the advent of new technologies in genomics, microscopy, and proteomics.
Copyright © 2017 Elsevier Ltd. All rights reserved.

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Year:  2017        PMID: 28388510      PMCID: PMC5554725          DOI: 10.1016/j.conb.2017.03.006

Source DB:  PubMed          Journal:  Curr Opin Neurobiol        ISSN: 0959-4388            Impact factor:   6.627


  40 in total

1.  Distinct FGFs promote differentiation of excitatory and inhibitory synapses.

Authors:  Akiko Terauchi; Erin M Johnson-Venkatesh; Anna B Toth; Danish Javed; Michael A Sutton; Hisashi Umemori
Journal:  Nature       Date:  2010-05-26       Impact factor: 49.962

Review 2.  Synapse-type-specific plasticity in local circuits.

Authors:  Rylan S Larsen; P Jesper Sjöström
Journal:  Curr Opin Neurobiol       Date:  2015-08-25       Impact factor: 6.627

3.  Inhibitory Synapses Are Repeatedly Assembled and Removed at Persistent Sites In Vivo.

Authors:  Katherine L Villa; Kalen P Berry; Jaichandar Subramanian; Jae Won Cha; Won Chan Oh; Hyung-Bae Kwon; Yoshiyuki Kubota; Peter T C So; Elly Nedivi
Journal:  Neuron       Date:  2016-02-04       Impact factor: 17.173

4.  Specific trans-synaptic interaction with inhibitory interneuronal neurexin underlies differential ability of neuroligins to induce functional inhibitory synapses.

Authors:  Kensuke Futai; Christopher D Doty; Brian Baek; Jubin Ryu; Morgan Sheng
Journal:  J Neurosci       Date:  2013-02-20       Impact factor: 6.167

5.  NGL family PSD-95-interacting adhesion molecules regulate excitatory synapse formation.

Authors:  Seho Kim; Alain Burette; Hye Sun Chung; Seok-Kyu Kwon; Jooyeon Woo; Hyun Woo Lee; Karam Kim; Hyun Kim; Richard J Weinberg; Eunjoon Kim
Journal:  Nat Neurosci       Date:  2006-09-17       Impact factor: 24.884

6.  Elfn1 regulates target-specific release probability at CA1-interneuron synapses.

Authors:  Emily L Sylwestrak; Anirvan Ghosh
Journal:  Science       Date:  2012-10-04       Impact factor: 47.728

7.  Segregated Glycine-Glutamate Co-transmission from vGluT3 Amacrine Cells to Contrast-Suppressed and Contrast-Enhanced Retinal Circuits.

Authors:  Seunghoon Lee; Yi Zhang; Minggang Chen; Z Jimmy Zhou
Journal:  Neuron       Date:  2016-03-17       Impact factor: 17.173

8.  Semaphorin 3E-Plexin-D1 signaling controls pathway-specific synapse formation in the striatum.

Authors:  Jun B Ding; Won-Jong Oh; Bernardo L Sabatini; Chenghua Gu
Journal:  Nat Neurosci       Date:  2011-12-18       Impact factor: 24.884

9.  LRRTM2 functions as a neurexin ligand in promoting excitatory synapse formation.

Authors:  Jaewon Ko; Marc V Fuccillo; Robert C Malenka; Thomas C Südhof
Journal:  Neuron       Date:  2009-12-24       Impact factor: 17.173

10.  Sidekick 2 directs formation of a retinal circuit that detects differential motion.

Authors:  Arjun Krishnaswamy; Masahito Yamagata; Xin Duan; Y Kate Hong; Joshua R Sanes
Journal:  Nature       Date:  2015-08-19       Impact factor: 49.962
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  5 in total

1.  Circuit-Specific Plasticity of Callosal Inputs Underlies Cortical Takeover.

Authors:  Emily Petrus; Sarah Dembling; Ted Usdin; John T R Isaac; Alan P Koretsky
Journal:  J Neurosci       Date:  2020-09-10       Impact factor: 6.167

2.  A muscle-epidermis-glia signaling axis sustains synaptic specificity during allometric growth in Caenorhabditis elegans.

Authors:  Jiale Fan; Tingting Ji; Kai Wang; Jichang Huang; Mengqing Wang; Laura Manning; Xiaohua Dong; Yanjun Shi; Xumin Zhang; Zhiyong Shao; Daniel A Colón-Ramos
Journal:  Elife       Date:  2020-04-07       Impact factor: 8.140

Review 3.  Mechanisms Underlying Target Selectivity for Cell Types and Subcellular Domains in Developing Neocortical Circuits.

Authors:  Alan Y Gutman-Wei; Solange P Brown
Journal:  Front Neural Circuits       Date:  2021-09-24       Impact factor: 3.492

4.  LRRTM3 regulates activity-dependent synchronization of synapse properties in topographically connected hippocampal neural circuits.

Authors:  Jinhu Kim; Dongseok Park; Na-Young Seo; Taek-Han Yoon; Gyu Hyun Kim; Sang-Hoon Lee; Jinsoo Seo; Ji Won Um; Kea Joo Lee; Jaewon Ko
Journal:  Proc Natl Acad Sci U S A       Date:  2022-01-18       Impact factor: 12.779

5.  2,3,7,8-Tetrachlorodibenzo-p-dioxin modifies alternative splicing in mouse liver.

Authors:  Ana B Villaseñor-Altamirano; John D Watson; Stephenie D Prokopec; Cindy Q Yao; Paul C Boutros; Raimo Pohjanvirta; Jesús Valdés-Flores; Guillermo Elizondo
Journal:  PLoS One       Date:  2019-08-06       Impact factor: 3.240
  5 in total

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