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Journal of Neurobiology

Volume 56, Issue 2
Research Articles

Systematic regulation of spine sizes and densities in pyramidal neurons

Sıla Konur

Corresponding Author

E-mail address:sk841@columbia.edu

Department of Biological Sciences, Columbia University, New York, New York 10027

Department of Biological Sciences, Columbia University, New York, New York 10027
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Daniel Rabinowitz

Department of Statistics, Columbia University, New York, New York 10027

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Vivian L. Fenstermaker

Department of Biological Sciences, Columbia University, New York, New York 10027

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Rafael Yuste

Department of Biological Sciences, Columbia University, New York, New York 10027

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First published: 13 May 2003
https://doi.org/10.1002/neu.10229
Cited by: 55

Abstract

Dendritic spines receive most excitatory inputs in the CNS. Recent evidence has demonstrated that the spine head volume is linearly correlated with the readily releasable pool of neurotransmitter and the PSD size. These correlations can be used to functionally interpret spine morphology. Using Golgi impregnations and light microscopy, we reconstructed 23,000 spines from pyramidal neurons in layers 2/3, 4, 5 and 6 of mouse primary visual cortex and CA1 hippocampal region and measured their spine head diameters and densities. Spine head diameters and densities are variable within and across cells, although they are similar between apical and basal dendrites. When compared to other regions, layer 5 neurons have larger spine heads and CA1 neurons higher spine densities. Interestingly, we detect a correlation between spine head diameter and interspine distance within and across cells, whereby larger spines are spaced further away from each other than smaller spines. Finally, in CA1 neurons, spine head diameters are larger, and spine density lower, in distal apical dendrites (>200 μm from soma) compared to proximal regions. These results reveal that spine morphologies and densities, and therefore synaptic properties, are jointly modulated with respect to cortical region, laminar position, and, in some cases, even the position of the spine along the dendritic tree. Individual neurons also appear to regulate their apical and basal spine densities and morphologies in concert. Our data provide evidence for a homeostatic control of excitatory synaptic strength. © 2003 Wiley Periodicals, Inc. J Neurobiol 56: 95–112, 2003

Number of times cited: 55

  • Paul G. Anastasiades, Andre Marques‐Smith and Simon J. B. Butt, Studies of cortical connectivity using optical circuit mapping methods, The Journal of Physiology, 596, 2, (145-162), (2017).
    Wiley Online Library
  • Patrick J. Mulholland, Tara L. Teppen, Kelsey M. Miller, Hannah G. Sexton, Subhash C. Pandey and H. Scott Swartzwelder, Donepezil Reverses Dendritic Spine Morphology Adaptations and Fmr1 Epigenetic Modifications in Hippocampus of Adult Rats After Adolescent Alcohol Exposure, Alcoholism: Clinical and Experimental Research, 42, 4, (706-717), (2018).
    Wiley Online Library
  • Kristen A. McLaurin, Hailong Li, Rosemarie M. Booze, Amanda J. Fairchild and Charles F. Mactutus, Unraveling Individual Differences In The HIV-1 Transgenic Rat: Therapeutic Efficacy Of Methylphenidate, Scientific Reports, 8, 1, (2018).
    Crossref
  • Anne‐Lieke F. van Deijk, Nutabi Camargo, Jaap Timmerman, Tim Heistek, Jos F. Brouwers, Floriana Mogavero, Huibert D. Mansvelder, August B. Smit and Mark H.G. Verheijen, Astrocyte lipid metabolism is critical for synapse development and function in vivo, Glia, 65, 4, (670-682), (2017).
    Wiley Online Library
  • Vassilis Kehayas and Anthony Holtmaat, Structural Plasticity and Cortical Connectivity, The Rewiring Brain, 10.1016/B978-0-12-803784-3.00001-9, (3-26), (2017).
    Crossref
  • Annabella Pignataro, Roberto Pagano, Giorgia Guarneri, Silvia Middei and Martine Ammassari-Teule, Extracellular matrix controls neuronal features that mediate the persistence of fear, Brain Structure and Function, 222, 9, (3889), (2017).
    Crossref
  • Chengyu Zou, Sophie Crux, Stephane Marinesco, Elena Montagna, Carmelo Sgobio, Yuan Shi, Song Shi, Kaichuan Zhu, Mario M Dorostkar, Ulrike C Müller and Jochen Herms, Amyloid precursor protein maintains constitutive and adaptive plasticity of dendritic spines in adult brain by regulating D‐serine homeostasis, The EMBO Journal, 35, 20, (2213-2222), (2016).
    Wiley Online Library
  • Joachim D. Uys, Natalie S. McGuier, Justin T. Gass, William C. Griffin, Lauren E. Ball and Patrick J. Mulholland, Chronic intermittent ethanol exposure and withdrawal leads to adaptations in nucleus accumbens core postsynaptic density proteome and dendritic spines, Addiction Biology, 21, 3, (560-574), (2015).
    Wiley Online Library
  • Kunjumon I. Vadakkan, Rapid chain generation of interpostsynaptic functional LINKs can trigger seizure generation: Evidence for potential interconnections from pathology to behavior, Epilepsy & Behavior, 10.1016/j.yebeh.2016.03.014, 59, (28-41), (2016).
    Crossref
  • Kunjumon I. Vadakkan, A framework for the first-person internal sensation of visual perception in mammals and a comparable circuitry for olfactory perception in Drosophila, SpringerPlus, 10.1186/s40064-015-1568-4, 4, 1, (2015).
    Crossref
  • Bérengère Petit, Alain Boissy, Adroaldo Zanella, Elodie Chaillou, Stéphane Andanson, Sébastien Bes, Frédéric Lévy and Marjorie Coulon, Stress during pregnancy alters dendritic spine density and gene expression in the brain of new-born lambs, Behavioural Brain Research, 291, (155), (2015).
    Crossref
  • Veronica L. Peterson, Brian A. McCool and Derek A. Hamilton, Effects of ethanol exposure and withdrawal on dendritic morphology and spine density in the nucleus accumbens core and shell, Brain Research, 1594, (125), (2015).
    Crossref
  • C. R. Wasser, I. Masiulis, M. S. Durakoglugil, C. Lane-Donovan, X. Xian, U. Beffert, A. Agarwala, R. E. Hammer and J. Herz, Differential splicing and glycosylation of Apoer2 alters synaptic plasticity and fear learning, Science Signaling, 7, 353, (ra113), (2014).
    Crossref
  • Rony H. Salloum, Guoyou Chen, Liliya Velet, Nauman F. Manzoor, Rachel Elkin, Grahame J. Kidd, John Coughlin, Christopher Yurosko, Stephanie Bou-Anak, Shirin Azadi, Stephanie Gohlsch, Harold Schneider and James A. Kaltenbach, Mapping and morphometric analysis of synapses and spines on fusiform cells in the dorsal cochlear nucleus, Frontiers in Systems Neuroscience, 8, (2014).
    Crossref
  • David A. Orner, Chia-Chien Chen, Daniella E. Orner and Joshua C. Brumberg, Alterations of dendritic protrusions over the first postnatal year of a mouse: an analysis in layer VI of the barrel cortex, Brain Structure and Function, 219, 5, (1709), (2014).
    Crossref
  • Sascha W Weyer, Marta Zagrebelsky, Ulrike Herrmann, Meike Hick, Lennard Ganss, Julia Gobbert, Morna Gruber, Christine Altmann, Martin Korte, Thomas Deller and Ulrike C Müller, Comparative analysis of single and combined APP/APLP knockouts reveals reduced spine density in APP-KO mice that is prevented by APPsα expression, Acta Neuropathologica Communications, 2, 1, (2014).
    Crossref
  • Yunyong Ma, Anu Ramachandran, Naomi Ford, Isabel Parada and David A. Prince, Remodeling of dendrites and spines in the C1q knockout model of genetic epilepsy, Epilepsia, 54, 7, (1232-1239), (2013).
    Wiley Online Library
  • Mustafa S. Kassem, Jim Lagopoulos, Tim Stait-Gardner, William S. Price, Tariq W. Chohan, Jonathon C. Arnold, Sean N. Hatton and Maxwell R. Bennett, Stress-Induced Grey Matter Loss Determined by MRI Is Primarily Due to Loss of Dendrites and Their Synapses, Molecular Neurobiology, 47, 2, (645), (2013).
    Crossref
  • Paul C. Bressloff, Propagation of CaMKII translocation waves in heterogeneous spiny dendrites, Journal of Mathematical Biology, 66, 7, (1499), (2013).
    Crossref
  • Rafael Yuste, Electrical Compartmentalization in Dendritic Spines, Annual Review of Neuroscience, 36, 1, (429), (2013).
    Crossref
  • Marjorie Coulon, Cara L. Wellman, Inderjit S. Marjara, Andrew M. Janczak and Adroaldo J. Zanella, Early adverse experience alters dendritic spine density and gene expression in prefrontal cortex and hippocampus in lambs, Psychoneuroendocrinology, 38, 7, (1112), (2013).
    Crossref
  • Ruth Benavides-Piccione, Isabel Fernaud-Espinosa, Victor Robles, Rafael Yuste and Javier DeFelipe, Age-Based Comparison of Human Dendritic Spine Structure Using Complete Three-Dimensional Reconstructions, Cerebral Cortex, 23, 8, (1798), (2013).
    Crossref
  • Aniruddha Yadav, Yuan Z. Gao, Alfredo Rodriguez, Dara L. Dickstein, Susan L. Wearne, Jennifer I. Luebke, Patrick R. Hof and Christina M. Weaver, Morphologic evidence for spatially clustered spines in apical dendrites of monkey neocortical pyramidal cells, Journal of Comparative Neurology, 520, 13, (2888-2902), (2012).
    Wiley Online Library
  • Neil R. Hardingham, Tim Gould and Kevin Fox, Anatomical and sensory experiential determinants of synaptic plasticity in layer 2/3 pyramidal neurons of mouse barrel cortex, Journal of Comparative Neurology, 519, 11, (2090-2124), (2011).
    Wiley Online Library
  • Chris I. De Zeeuw and Tycho M. Hoogland, Anomalous diffusion imposed by dendritic spines (Commentary on Santamaria et al.), European Journal of Neuroscience, 34, 4, (559-560), (2011).
    Wiley Online Library
  • Fidel Santamaria, Stefan Wils, Erik De Schutter and George J. Augustine, The diffusional properties of dendrites depend on the density of dendritic spines, European Journal of Neuroscience, 34, 4, (561-568), (2011).
    Wiley Online Library
  • K.-P. Huang, F.L. Huang and P.K. Shetty, Stimulation-mediated translocation of calmodulin and neurogranin from soma to dendrites of mouse hippocampal CA1 pyramidal neurons, Neuroscience, 178, (1), (2011).
    Crossref
  • M.S. Landers, G.W. Knott, H.P. Lipp, I. Poletaeva and E. Welker, Synapse formation in adult barrel cortex following naturalistic environmental enrichment, Neuroscience, 199, (143), (2011).
    Crossref
  • Adrian Briner, Mathias De Roo, Alexandre Dayer, Dominique Muller, Jozsef Z. Kiss and Laszlo Vutskits, Bilateral whisker trimming during early postnatal life impairs dendritic spine development in the mouse somatosensory barrel cortex, Journal of Comparative Neurology, 518, 10, (1711-1723), (2009).
    Wiley Online Library
  • D. Minciacchi, C. Del Tongo, D. Carretta, D. Nosi and A. Granato, Alterations of the cortico-cortical network in sensori-motor areas of dystrophin deficient mice, Neuroscience, 166, 4, (1129), (2010).
    Crossref
  • Paul C. Bressloff, Cable theory of protein receptor trafficking in a dendritic tree, Physical Review E, 79, 4, (2009).
    Crossref
  • Anthony Holtmaat and Karel Svoboda, Experience-dependent structural synaptic plasticity in the mammalian brain, Nature Reviews Neuroscience, 10, 9, (647), (2009).
    Crossref
  • Anthony Holtmaat, Tobias Bonhoeffer, David K Chow, Jyoti Chuckowree, Vincenzo De Paola, Sonja B Hofer, Mark Hübener, Tara Keck, Graham Knott, Wei-Chung A Lee, Ricardo Mostany, Tom D Mrsic-Flogel, Elly Nedivi, Carlos Portera-Cailliau, Karel Svoboda, Joshua T Trachtenberg and Linda Wilbrecht, Long-term, high-resolution imaging in the mouse neocortex through a chronic cranial window, Nature Protocols, 4, 8, (1128), (2009).
    Crossref
  • Oliver von Bohlen und Halbach, Structure and function of dendritic spines within the hippocampus, Annals of Anatomy - Anatomischer Anzeiger, 191, 6, (518), (2009).
    Crossref
  • T. Fares and A. Stepanyants, Cooperative synapse formation in the neocortex, Proceedings of the National Academy of Sciences, 106, 38, (16463), (2009).
    Crossref
  • Albert Gidon and Idan Segev, Spike-Timing–Dependent Synaptic Plasticity and Synaptic Democracy in Dendrites, Journal of Neurophysiology, 101, 6, (3226), (2009).
    Crossref
  • Haowei Shen, Susan R. Sesack, Shigenobu Toda and Peter W. Kalivas, Automated quantification of dendritic spine density and spine head diameter in medium spiny neurons of the nucleus accumbens, Brain Structure and Function, 213, 1-2, (149), (2008).
    Crossref
  • B. A. Earnshaw and P. C. Bressloff, Modeling the role of lateral membrane diffusion in AMPA receptor trafficking along a spiny dendrite, Journal of Computational Neuroscience, 25, 2, (366), (2008).
    Crossref
  • Paul C. Bressloff, Berton A. Earnshaw and Michael J. Ward, Diffusion of Protein Receptors on a Cylindrical Dendritic Membrane with Partially Absorbing Traps, SIAM Journal on Applied Mathematics, 68, 5, (1223), (2008).
    Crossref
  • J.I. Arellano, A. Espinosa, A. Fairén, R. Yuste and J. DeFelipe, Non-synaptic dendritic spines in neocortex, Neuroscience, 145, 2, (464), (2007).
    Crossref
  • Masanori Matsuzaki, Factors critical for the plasticity of dendritic spines and memory storage, Neuroscience Research, 57, 1, (1), (2007).
    Crossref
  • G.N. Elston, Specialization of the Neocortical Pyramidal Cell during Primate Evolution, Evolution of Nervous Systems, 10.1016/B0-12-370878-8/00164-6, (191-242), (2007).
    Crossref
  • P. C. Bressloff and B. A. Earnshaw, Diffusion-trapping model of receptor trafficking in dendrites, Physical Review E, 75, 4, (2007).
    Crossref
  • R. Araya, K. B. Eisenthal and R. Yuste, Dendritic spines linearize the summation of excitatory potentials, Proceedings of the National Academy of Sciences, 103, 49, (18799), (2006).
    Crossref
  • M. Nuriya, J. Jiang, B. Nemet, K. B. Eisenthal and R. Yuste, Imaging membrane potential in dendritic spines, Proceedings of the National Academy of Sciences, 103, 3, (786), (2006).
    Crossref
  • Oliver von Bohlen und Halbach, Sonja Krause, Diego Medina, Carla Sciarretta, Liliana Minichiello and Klaus Unsicker, Regional- and Age-Dependent Reduction in trkB Receptor Expression in the Hippocampus Is Associated with Altered Spine Morphologies, Biological Psychiatry, 59, 9, (793), (2006).
    Crossref
  • I. Ballesteros-Yáñez, R. Benavides-Piccione, G.N. Elston, R. Yuste and J. DeFelipe, Density and morphology of dendritic spines in mouse neocortex, Neuroscience, 138, 2, (403), (2006).
    Crossref
  • R. Araya, J. Jiang, K. B. Eisenthal and R. Yuste, The spine neck filters membrane potentials, Proceedings of the National Academy of Sciences, 103, 47, (17961), (2006).
    Crossref
  • Ivan Mikolaenko, Lekha M. Rao, Rosalinda C. Roberts, Bryan Kolb and H.A. Jinnah, A Golgi study of neuronal architecture in a genetic mouse model for Lesch–Nyhan disease, Neurobiology of Disease, 10.1016/j.nbd.2005.04.005, 20, 2, (479-490), (2005).
    Crossref
  • Shira Knafo, Frederic Libersat and Edi Barkai, Olfactory learning‐induced morphological modifications in single dendritic spines of young rats, European Journal of Neuroscience, 21, 8, (2217-2226), (2005).
    Wiley Online Library
  • Rafael Yuste and Tobias Bonhoeffer, Genesis of dendritic spines: insights from ultrastructural and imaging studies, Nature Reviews Neuroscience, 5, 1, (24), (2004).
    Crossref
  • Wen‐Jun Gao and Ze‐Hui Zheng, Target‐specific differences in somatodendritic morphology of layer V pyramidal neurons in rat motor cortex, Journal of Comparative Neurology, 476, 2, (174-185), (2004).
    Wiley Online Library
  • Elenia Vega, Maria de Jésus Gómez-Villalobos and Gonzalo Flores, Alteration in dendritic morphology of pyramidal neurons from the prefrontal cortex of rats with renovascular hypertension, Brain Research, 1021, 1, (112), (2004).
    Crossref
  • S.J Lee, R.D Romeo, P Svenningsson, C.R Campomanes, P.B Allen, P Greengard and B.S McEwen, Estradiol affects spinophilin protein differently in gonadectomized males and females, Neuroscience, 127, 4, (983), (2004).
    Crossref
  • Lily Kang, Michael K. Tian, Craig D. C. Bailey and Evelyn K. Lambe, Dendritic spine density of prefrontal layer 6 pyramidal neurons in relation to apical dendrite sculpting by nicotinic acetylcholine receptors, Frontiers in Cellular Neuroscience, 10.3389/fncel.2015.00398, 9, (2015).
    Crossref