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High-speed imaging of light-induced photoreceptor microsaccades in compound eyes.

Joni KemppainenNeveen MansourJouni TakaloMikko Juusola
Published in: Communications biology (2022)
Inside compound eyes, photoreceptors contract to light changes, sharpening retinal images of the moving world in time. Current methods to measure these so-called photoreceptor microsaccades in living insects are spatially limited and technically challenging. Here, we present goniometric high-speed deep pseudopupil (GHS-DPP) microscopy to assess how the rhabdomeric insect photoreceptors and their microsaccades are organised across the compound eyes. This method enables non-invasive rhabdomere orientation mapping, whilst their microsaccades can be locally light-activated, revealing the eyes' underlying active sampling motifs. By comparing the microsaccades in wild-type Drosophila's open rhabdom eyes to spam-mutant eyes, reverted to an ancestral fused rhabdom state, and honeybee's fused rhabdom eyes, we show how different eye types sample light information. These results show different ways compound eyes initiate the conversion of spatial light patterns in the environment into temporal neural signals and highlight how this active sampling can evolve with insects' visual needs.
Keyphrases
  • optical coherence tomography
  • high speed
  • diabetic retinopathy
  • high resolution
  • atomic force microscopy
  • wild type
  • optic nerve
  • cataract surgery
  • minimally invasive
  • machine learning