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The development and evolution of inhibitory neurons in primate cerebrum

Author

Listed:
  • Matthew T. Schmitz

    (University of California, San Francisco
    University of California, San Francisco)

  • Kadellyn Sandoval

    (University of California, San Francisco
    University of California, San Francisco)

  • Christopher P. Chen

    (University of California, San Francisco
    University of California, San Francisco)

  • Mohammed A. Mostajo-Radji

    (University of California, San Francisco
    University of California, San Francisco)

  • William W. Seeley

    (University of California, San Francisco)

  • Tomasz J. Nowakowski

    (University of California, San Francisco
    University of California, San Francisco
    University of California, San Francisco
    University of California, San Francisco)

  • Chun Jimmie Ye

    (Chan Zuckerberg Biohub
    University of California, San Francisco
    University of California, San Francisco
    Parker Institute for Cancer Immunotherapy)

  • Mercedes F. Paredes

    (University of California, San Francisco
    University of California, San Francisco)

  • Alex A. Pollen

    (University of California, San Francisco
    University of California, San Francisco
    University of California, San Francisco
    Chan Zuckerberg Biohub)

Abstract

Neuroanatomists have long speculated that expanded primate brains contain an increased morphological diversity of inhibitory neurons (INs)1, and recent studies have identified primate-specific neuronal populations at the molecular level2. However, we know little about the developmental mechanisms that specify evolutionarily novel cell types in the brain. Here, we reconstruct gene expression trajectories specifying INs generated throughout the neurogenic period in macaques and mice by analysing the transcriptomes of 250,181 cells. We find that the initial classes of INs generated prenatally are largely conserved among mammals. Nonetheless, we identify two contrasting developmental mechanisms for specifying evolutionarily novel cell types during prenatal development. First, we show that recently identified primate-specific TAC3 striatal INs are specified by a unique transcriptional programme in progenitors followed by induction of a distinct suite of neuropeptides and neurotransmitter receptors in new-born neurons. Second, we find that multiple classes of transcriptionally conserved olfactory bulb (OB)-bound precursors are redirected to expanded primate white matter and striatum. These classes include a novel peristriatal class of striatum laureatum neurons that resemble dopaminergic periglomerular cells of the OB. We propose an evolutionary model in which conserved initial classes of neurons supplying the smaller primate OB are reused in the enlarged striatum and cortex. Together, our results provide a unified developmental taxonomy of initial classes of mammalian INs and reveal multiple developmental mechanisms for neural cell type evolution.

Suggested Citation

  • Matthew T. Schmitz & Kadellyn Sandoval & Christopher P. Chen & Mohammed A. Mostajo-Radji & William W. Seeley & Tomasz J. Nowakowski & Chun Jimmie Ye & Mercedes F. Paredes & Alex A. Pollen, 2022. "The development and evolution of inhibitory neurons in primate cerebrum," Nature, Nature, vol. 603(7903), pages 871-877, March.
  • Handle: RePEc:nat:nature:v:603:y:2022:i:7903:d:10.1038_s41586-022-04510-w
    DOI: 10.1038/s41586-022-04510-w
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    Cited by:

    1. Yueqi Wang & Simone Chiola & Guang Yang & Chad Russell & Celeste J. Armstrong & Yuanyuan Wu & Jay Spampanato & Paisley Tarboton & H. M. Arif Ullah & Nicolas U. Edgar & Amelia N. Chang & David A. Harmi, 2022. "Modeling human telencephalic development and autism-associated SHANK3 deficiency using organoids generated from single neural rosettes," Nature Communications, Nature, vol. 13(1), pages 1-25, December.
    2. Jia-Ru Wei & Zhao-Zhe Hao & Chuan Xu & Mengyao Huang & Lei Tang & Nana Xu & Ruifeng Liu & Yuhui Shen & Sarah A. Teichmann & Zhichao Miao & Sheng Liu, 2022. "Identification of visual cortex cell types and species differences using single-cell RNA sequencing," Nature Communications, Nature, vol. 13(1), pages 1-21, December.

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