Abstract
In the vertebrate retina, an interplay between retinal ganglion cells (RGCs), amacrine (AC), and bipolar (BP) cells establishes a synaptic layer called the inner plexiform layer (IPL). This circuit conveys signals from photoreceptors to visual centers in the brain. However, the molecular mechanisms involved in its development remain poorly understood. Striatin-interacting protein 1 (Strip1) is a core component of the striatin-interacting phosphatases and kinases (STRIPAK) complex, and it has shown emerging roles in embryonic morphogenesis. Here, we uncover the importance of Strip1 in inner retina development. Using zebrafish, we show that loss of Strip1 causes defects in IPL formation. In strip1 mutants, RGCs undergo dramatic cell death shortly after birth. AC and BP cells subsequently invade the degenerating RGC layer, leading to a disorganized IPL. Mechanistically, zebrafish Strip1 interacts with its STRIPAK partner, Striatin 3 (Strn3), and both show overlapping functions in RGC survival. Furthermore, loss of Strip1 or Strn3 leads to activation of the proapoptotic marker, Jun, within RGCs, and Jun knockdown rescues RGC survival in strip1 mutants. In addition to its function in RGC maintenance, Strip1 is required for RGC dendritic patterning, which likely contributes to proper IPL formation. Taken together, we propose that a series of Strip1-mediated regulatory events coordinates inner retinal circuit formation by maintaining RGCs during development, which ensures proper positioning and neurite patterning of inner retinal neurons.
Highlights
The retina has a highly organized neural circuit that consists of six major classes of neurons, which are assembled into three cellular layers with two synaptic or plexiform layers in between
We found that Striatin21 interacting protein 1 (Strip1) is necessary for retinal ganglion cells (RGCs) dendritic patterning, which likely promotes interaction between RGCs and amacrine cells (ACs) for inner plexiform layer (IPL) formation
Strip1/Strip has emerged as an essential protein in embryonic development (Bazzi et al, 2017, La Marca et al, 2019, Neal et al, 2020, Sakuma et al, 2014, Sakuma et al, 2015)
Summary
The retina has a highly organized neural circuit that consists of six major classes of neurons, which are assembled into three cellular layers with two synaptic or plexiform layers in between. This beautiful layered architecture is termed “retinal lamination”. Neurogenesis, cell migration and neurite patterning are spatially and temporally coordinated to form retinal lamination. Any defect in these events can disrupt retinal wiring and compromise visual function (Amini et al, 2018). Molecular mechanisms that govern retinal neural circuit formation are not fully understood
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