Abstract

Our long-term goal is to find out how axons and dendrites in the vertebrate brain determine when and where to form synapses. We focus on laminar specificity, a fundamental determinant of connectivity throughout the brain, whereby neuronal processes confine their arbors and synapses to specific laminae within a target area. Our object of study is the retinal ganglion cell (RGC), because it is relatively accessible, has a well-defined function, and displays exquisite laminar specificity: axons of distinct RGC subsets synapse in specific retinorecipient sublaminae of the superior colliculus, and their dendrites arborize in specific sublaminae of the inner plexiform layer (IPL), where they receive inputs from lamina-specified subsets of retinal interneurons. In work supported by this grant, we have obtained evidence that four related immunoglobulin superfamily (IgSF) adhesion molecules -Sidekick- 1, Sidekick-2, Dscam and DscamL- are critical determinants of an IgSF code that underlies some aspects of sublaminar specificity in the IPL. We will now use genetic methods to map the circuits that express these IgSF genes in mice, assess consequences of deleting them singly and in pairs, and determine whether they act cell-autonomously and/or homophilically. We will also test the possibility that close relatives of Sidekicks and Dscams, the Contactins, are additional components of the IgSF code. Then, we will use electrophysiological methods to relate circuit assembly to circuit function. We will map the receptive fields of IgSF-expressing RGC subsets, identify the interneurons that innervate then, and assess the effects of IgSF gene deletion on their properties. As an exacting test of our hypothesis, we will attempt to rewire a retinal circuit by replacing one IgSF gene with another, assessing the structural and functional effects of this swap. Finally, we will extend our analysis to the laminar targeting of RGC axons in the superior colliculus. We recently generated a map of projections that RGC subsets form in collicular retinorecipient sublaminae, and will now classify the target cells on which axons of these subsets form synapses. With this foundation, we will test our hypothesis, based on results from chick optic tectum, that members of the cadherin superfamily (particularly Type II cadherins) are involved in the targeting of RGCs to sublaminae in the superior colliculus. Together these studies will contribute to elucidation of mechanisms that promote lamina-specific synapse formation and, by extension, synaptic specificity generally.

Public Health Relevance

During development, neurons connect with each other in very specific ways, forming the complex circuits that underlie our mental activities. Conversely, impaired development of these circuits is believed to underlie many behavioral disorders including autism and schizophrenia. Our long-term goal is to find some of the cells and molecules that determine when and where these connections, called synapses, form. To this end, we are focusing on the accessible visual system, in which we can assess the structural and functional consequences of controlled alterions in patterns of synaptic specificity.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Method to Extend Research in Time (MERIT) Award (R37)
Project #
4R37NS029169-26
Application #
9002101
Study Section
Neurodifferentiation, Plasticity, and Regeneration Study Section (NDPR)
Program Officer
Talley, Edmund M
Project Start
1991-01-01
Project End
2016-12-31
Budget Start
2016-01-01
Budget End
2016-12-31
Support Year
26
Fiscal Year
2016
Total Cost
$535,943
Indirect Cost
$214,120

  Institution

Name
Harvard University
Department
Microbiology/Immun/Virology
Type
Schools of Arts and Sciences
DUNS #
082359691
City
Cambridge
State
MA
Country
United States
Zip Code
02138

  Publications

Nakanishi, Keiko; Niida, Hiroyuki; Tabata, Hidenori et al. (2018) Isozyme-Specific Role of SAD-A in Neuronal Migration During Development of Cerebral Cortex. Cereb Cortex :
Liu, Jinyue; Reggiani, Jasmine D S; Laboulaye, Mallory A et al. (2018) Tbr1 instructs laminar patterning of retinal ganglion cell dendrites. Nat Neurosci 21:659-670
Yamagata, Masahito; Sanes, Joshua R (2018) Reporter-nanobody fusions (RANbodies) as versatile, small, sensitive immunohistochemical reagents. Proc Natl Acad Sci U S A 115:2126-2131
Hong, Guosong; Fu, Tian-Ming; Qiao, Mu et al. (2018) A method for single-neuron chronic recording from the retina in awake mice. Science 360:1447-1451
Hong, Y Kate; Burr, Eliza F; Sanes, Joshua R et al. (2018) Heterogeneity of retinogeniculate axon arbors. Eur J Neurosci :
Sarin, Sumeet; Zuniga-Sanchez, Elizabeth; Kurmangaliyev, Yerbol Z et al. (2018) Role for Wnt Signaling in Retinal Neuropil Development: Analysis via RNA-Seq and In Vivo Somatic CRISPR Mutagenesis. Neuron 98:109-126.e8
Martersteck, Emily M; Hirokawa, Karla E; Evarts, Mariah et al. (2017) Diverse Central Projection Patterns of Retinal Ganglion Cells. Cell Rep 18:2058-2072
Liu, Jinyue; Sanes, Joshua R (2017) Cellular and Molecular Analysis of Dendritic Morphogenesis in a Retinal Cell Type That Senses Color Contrast and Ventral Motion. J Neurosci 37:12247-12262
Krieger, Brenna; Qiao, Mu; Rousso, David L et al. (2017) Four alpha ganglion cell types in mouse retina: Function, structure, and molecular signatures. PLoS One 12:e0180091
Norsworthy, Michael W; Bei, Fengfeng; Kawaguchi, Riki et al. (2017) Sox11 Expression Promotes Regeneration of Some Retinal Ganglion Cell Types but Kills Others. Neuron 94:1112-1120.e4

Showing the most recent 10 out of 24 publications