The Ferdinando Rossi Memorial Lecture: Zones and Stripes—Pattern Formation in the Cerebellum
- 301 Downloads
The cerebellum has a complex architecture—highly reproducible and conserved through evolution. Cerebellar architecture is organized around the Purkinje cell. Purkinje cells in the mouse cerebellum come in many different subtypes, identifiable by expression markers, sensitivity to mutation, etc. These are organized first into five “transverse zones,” each of which is further subdivided into dozens of reproducible “stripes.” This arrangement serves as the scaffolding to organize afferent topography and restrict the distribution of excitatory and inhibitory interneurons. This brief review will survey some of the mechanisms that lead to the formation of this elaborate pattern during cerebellar development. Pattern formation in the cerebellar cortex is a multistage process that begins early in development with the generation of the various Purkinje cell subtypes, and matures through the dispersal of Purkinje cell clusters into stripes. Two developmental processes will be discussed in particular: the mechanisms that lead to Purkinje cell subtype specification (i.e., how different kinds of Purkinje cells are made) and the role played by Purkinje cell migration in pattern formation (i.e., how these Purkinje cell subtypes end up in a reproducible array of stripes).
KeywordsStripes Transverse zones Purkinje cells Development Zebrins
I am grateful to Giacomo Consalez (Milan), Hassan Marzban (Winnipeg), and Roy Sillitoe (Houston) for reviewing an early draft of this MS; my many friends and colleagues for over 30 years of collaboration on zones and stripes; and the Big Rock Brewery (Calgary), without whose constant sustinance the present essay might never have been completed.
Compliance with Ethical Standards
Conflict of Interest
The author declares that he has no conflicts of interest.
- 10.Armstrong CL, Hawkes R. Pattern formation in the cerebellum. Colloquium Digital Library of Life Sciences. Morgan & Claypool: 2014; pp. 138.Google Scholar
- 31.Reeber SL, Otis TS, Silitoe RV. Bergmann glia are patterned into topographic molecular zones in the developing and adult mouse cerebellum. Cerebellum. 2014; https://doi.org/10.1007/s12311-014-0571-6.
- 33.D’Arcangelo G. Reelin in the years: controlling neuronal migration and maturation in the mammalian brain. Adv Neurosci. 2014;2014(ID 597395):9. https://doi.org/10.4199/C00096ED1V01Y201310DBR011
- 38.Casoni F, Croci L, Cremona O, Hawkes R, Consalez GG. Early Purkinje cell development and the origins of cerebellar patterning. In: H. Marzban (Ed.) Development of the cerebellum—from molecular aspects to diseases. Cham Springer. 2017; pp. 67–86. https://doi.org/10.1007/978-3-319-59749-2_4.
- 42.Welker W. Spatial organization of somatosensory projections to granule cell cerebellar cortex: functional and connectional implications of fractured somatotopy. In: King JS, editor. New Concepts in Cerebellar Neurobiology. New York: A. R. Liss; 1987. p. 239–80.Google Scholar