The Absence of FAIM Leads to a Delay in Dark Adaptation and Hampers Arrestin-1 Translocation upon Light Reception in the Retina

Anna Sirés, Mateo Pazo-González, Joaquín López-Soriano, Ana Méndez, Enrique J. de la Rosa, Pedro de la Villa, Joan X. Comella, Catalina Hernández-Sánchez, Montse Solé*

*Corresponding author for this work

Research output: Contribution to journalArticleResearchpeer-review

Abstract

The short and long isoforms of FAIM (FAIM-S and FAIM-L) hold important functions in the central nervous system, and their expression levels are specifically enriched in the retina. We previously described that Faim knockout (KO) mice present structural and molecular alterations in the retina compatible with a neurodegenerative phenotype. Here, we aimed to study Faim KO retinal functions and molecular mechanisms leading to its alterations. Electroretinographic recordings showed that aged Faim KO mice present functional loss of rod photoreceptor and ganglion cells. Additionally, we found a significant delay in dark adaptation from early adult ages. This functional deficit is exacerbated by luminic stress, which also caused histopathological alterations. Interestingly, Faim KO mice present abnormal Arrestin-1 redistribution upon light reception, and we show that Arrestin-1 is ubiquitinated, a process that is abrogated by either FAIM-S or FAIM-L in vitro. Our results suggest that FAIM assists Arrestin-1 light-dependent translocation by a process that likely involves ubiquitination. In the absence of FAIM, this impairment could be the cause of dark adaptation delay and increased light sensitivity. Multiple retinal diseases are linked to deficits in photoresponse termination, and hence, investigating the role of FAIM could shed light onto the underlying mechanisms of their pathophysiology.

Original languageEnglish
Article number487
Number of pages28
JournalCells
Volume12
Issue number3
DOIs
Publication statusPublished - 2 Feb 2023

Keywords

  • Arrestin-1
  • dark adaptation
  • FAIM
  • knockout mouse model
  • light damage
  • retina
  • rod photoreceptors
  • ubiquitin

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