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Training-induced circuit-specific excitatory synaptogenesis in mice is required for effort control

Author

Listed:
  • Francesco Paolo Ulloa Severino

    (Duke University Medical Center
    Duke University
    Cajal Institute (CSIC))

  • Oluwadamilola O. Lawal

    (Duke University Medical Center)

  • Kristina Sakers

    (Duke University Medical Center)

  • Shiyi Wang

    (Duke University Medical Center)

  • Namsoo Kim

    (Duke University)

  • Alexander David Friedman

    (Duke University)

  • Sarah Anne Johnson

    (Duke University Medical Center)

  • Chaichontat Sriworarat

    (Duke University Medical Center)

  • Ryan H. Hughes

    (Duke University)

  • Scott H. Soderling

    (Duke University Medical Center
    Duke University Medical Center
    Duke Institute for Brain Sciences (DIBS))

  • Il Hwan Kim

    (University of Tennessee Health and Science Center)

  • Henry H. Yin

    (Duke University
    Duke University Medical Center
    Duke Institute for Brain Sciences (DIBS))

  • Cagla Eroglu

    (Duke University Medical Center
    Duke University Medical Center
    Duke Institute for Brain Sciences (DIBS)
    Duke University)

Abstract

Synaptogenesis is essential for circuit development; however, it is unknown whether it is critical for the establishment and performance of goal-directed voluntary behaviors. Here, we show that operant conditioning via lever-press for food reward training in mice induces excitatory synapse formation onto a subset of anterior cingulate cortex neurons projecting to the dorsomedial striatum (ACC→DMS). Training-induced synaptogenesis is controlled by the Gabapentin/Thrombospondin receptor α2δ−1, which is an essential neuronal protein for proper intracortical excitatory synaptogenesis. Using germline and conditional knockout mice, we found that deletion of α2δ−1 in the adult ACC→DMS circuit diminishes training-induced excitatory synaptogenesis. Surprisingly, this manipulation does not impact learning but results in a significant increase in effort exertion without affecting sensitivity to reward value or changing contingencies. Bidirectional optogenetic manipulation of ACC→DMS neurons rescues or phenocopies the behaviors of the α2δ−1 cKO mice, highlighting the importance of synaptogenesis within this cortico-striatal circuit in regulating effort exertion.

Suggested Citation

  • Francesco Paolo Ulloa Severino & Oluwadamilola O. Lawal & Kristina Sakers & Shiyi Wang & Namsoo Kim & Alexander David Friedman & Sarah Anne Johnson & Chaichontat Sriworarat & Ryan H. Hughes & Scott H., 2023. "Training-induced circuit-specific excitatory synaptogenesis in mice is required for effort control," Nature Communications, Nature, vol. 14(1), pages 1-22, December.
    • Handle: RePEc:nat:natcom:v:14:y:2023:i:1:d:10.1038_s41467-023-41078-z
    DOI: 10.1038/s41467-023-41078-z
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    References listed on IDEAS

    as
    1. Christina M. Gremel & Rui M. Costa, 2013. "Orbitofrontal and striatal circuits dynamically encode the shift between goal-directed and habitual actions," Nature Communications, Nature, vol. 4(1), pages 1-12, October.
    2. Tonghui Xu & Xinzhu Yu & Andrew J. Perlik & Willie F. Tobin & Jonathan A. Zweig & Kelly Tennant & Theresa Jones & Yi Zuo, 2009. "Rapid formation and selective stabilization of synapses for enduring motor memories," Nature, Nature, vol. 462(7275), pages 915-919, December.
    3. Nicola J. Allen & Mariko L. Bennett & Lynette C. Foo & Gordon X. Wang & Chandrani Chakraborty & Stephen J. Smith & Ben A. Barres, 2012. "Astrocyte glypicans 4 and 6 promote formation of excitatory synapses via GluA1 AMPA receptors," Nature, Nature, vol. 486(7403), pages 410-414, June.
    4. Qiaojie Xiong & Petr Znamenskiy & Anthony M. Zador, 2015. "Selective corticostriatal plasticity during acquisition of an auditory discrimination task," Nature, Nature, vol. 521(7552), pages 348-351, May.
    5. Xin Jin & Rui M. Costa, 2010. "Start/stop signals emerge in nigrostriatal circuits during sequence learning," Nature, Nature, vol. 466(7305), pages 457-462, July.
    6. Xu Liu & Steve Ramirez & Petti T. Pang & Corey B. Puryear & Arvind Govindarajan & Karl Deisseroth & Susumu Tonegawa, 2012. "Optogenetic stimulation of a hippocampal engram activates fear memory recall," Nature, Nature, vol. 484(7394), pages 381-385, April.
    7. Guang Yang & Feng Pan & Wen-Biao Gan, 2009. "Stably maintained dendritic spines are associated with lifelong memories," Nature, Nature, vol. 462(7275), pages 920-924, December.
    8. Andrew M. Swanson & Lauren M. DePoy & Shannon L. Gourley, 2017. "Inhibiting Rho kinase promotes goal-directed decision making and blocks habitual responding for cocaine," Nature Communications, Nature, vol. 8(1), pages 1-12, December.
    9. Akiko Hayashi-Takagi & Sho Yagishita & Mayumi Nakamura & Fukutoshi Shirai & Yi I. Wu & Amanda L. Loshbaugh & Brian Kuhlman & Klaus M. Hahn & Haruo Kasai, 2015. "Labelling and optical erasure of synaptic memory traces in the motor cortex," Nature, Nature, vol. 525(7569), pages 333-338, September.
    10. Ee-Lynn Yap & Noah L. Pettit & Christopher P. Davis & M. Aurel Nagy & David A. Harmin & Emily Golden & Onur Dagliyan & Cindy Lin & Stephanie Rudolph & Nikhil Sharma & Eric C. Griffith & Christopher D., 2021. "Bidirectional perisomatic inhibitory plasticity of a Fos neuronal network," Nature, Nature, vol. 590(7844), pages 115-121, February.
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