Kemppainen, Joni Jaakko Tapani ORCID: 0000-0002-9140-6932 (2021) Photoreceptor microsaccades in Drosophila: Three-dimensional charaterisation. PhD thesis, University of Sheffield.
Abstract
My thesis is about the fruit fly (Drosophila melanogaster) photoreceptor microsaccades. These are light-induced rapid micrometer-sized photoreceptor displacements caused by their photomechanically contracting microvilli. I used two imaging methods to investigate this phenomenon: synchrotron X-rays and the deep pseudopupil. I was motivated by our group’s previous work, which showed that the microsaccades improve the Drosophila vision beyond the optical limits of a static eye. I desired to characterise the microsaccades in 3- dimensions. First, our high-speed synchrotron X-ray experiments led to an unexpected discovery that the X-rays themselves activate phototransduction similar to visible light. The X-ray induced microsaccades were left-right mirror-symmetric and stronger where the two eyes’ visual fields meet. In addition, the motion analysis along the receptor’s side-profile suggested spatial specialisations. Second, I developed the first goniometric (angle-measuring) high- speed deep pseudopupil (GHS-DPP) system for mapping photoreceptor microsaccades across the left and right eyes. My results suggest that the microsaccades are tuned to the optic flow and are developmentally set by the R1-R8 rhabdomere orientations, which also follow the optic flow. Third, the localised GHS-DPP experiments using rhodopsin- specific rescues showed that all R1-R8 rhabdomeres contributed towards the microsaccades, irrespective how I immobilised the flies. Furthermore, light stimulation with sinusoidal and frequency sweeps showed that the microsaccades could follow temporal contrast changes up to 30 Hz (3 dB cut-off at 13 Hz), indicating that the microsaccades happen during light contrast changes in the natural environment. Overall, my results suggest that the photoreceptor microsaccades improve vision, accommodating the fly’s behavioural needs. The insect eyes have evolved over hundreds of millions of years. My research helps to better understand some less obvious design choices, broadening our knowledge about how visual sensory systems work dynamically. The potential applications of this work range from man-made image sensors to stereo vision algorithms, autonomous drones, consumer electronics and improved medical implants, such as bionic eyes.
Metadata
Supervisors: | Juusola, Mikko and Marshall, James |
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Keywords: | photoreceptor, microsaccades, contraction, photomechanical, deep pseudopupil, DPP, X-ray imaging, Drosophila, eye movements, saccades, insect, active vision, motion analysis, phototransduction, microscanning |
Awarding institution: | University of Sheffield |
Academic Units: | The University of Sheffield > Faculty of Science (Sheffield) > Biomedical Science (Sheffield) |
Identification Number/EthosID: | uk.bl.ethos.858753 |
Depositing User: | Mr. Joni Jaakko Tapani Kemppainen |
Date Deposited: | 12 Jul 2022 15:16 |
Last Modified: | 01 Sep 2022 09:53 |
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