PLoS ONE (Jan 2019)

Comparison of the molecular properties of retinitis pigmentosa P23H and N15S amino acid replacements in rhodopsin.

  • James Mitchell,
  • Fernanda Balem,
  • Kalyan Tirupula,
  • David Man,
  • Harpreet Kaur Dhiman,
  • Naveena Yanamala,
  • Julian Ollesch,
  • Joan Planas-Iglesias,
  • Barbara J Jennings,
  • Klaus Gerwert,
  • Alessandro Iannaccone,
  • Judith Klein-Seetharaman

DOI
https://doi.org/10.1371/journal.pone.0214639
Journal volume & issue
Vol. 14, no. 5
p. e0214639

Abstract

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Mutations in the RHO gene encoding for the visual pigment protein, rhodopsin, are among the most common cause of autosomal dominant retinitis pigmentosa (ADRP). Previous studies of ADRP mutations in different domains of rhodopsin have indicated that changes that lead to more instability in rhodopsin structure are responsible for more severe disease in patients. Here, we further test this hypothesis by comparing side-by-side and therefore quantitatively two RHO mutations, N15S and P23H, both located in the N-terminal intradiscal domain. The in vitro biochemical properties of these two rhodopsin proteins, expressed in stably transfected tetracycline-inducible HEK293S cells, their UV-visible absorption, their Fourier transform infrared, circular dichroism and Metarhodopsin II fluorescence spectroscopy properties were characterized. As compared to the severely impaired P23H molecular function, N15S is only slightly defective in structure and stability. We propose that the molecular basis for these structural differences lies in the greater distance of the N15 residue as compared to P23 with respect to the predicted rhodopsin folding core. As described previously for WT rhodopsin, addition of the cytoplasmic allosteric modulator chlorin e6 stabilizes especially the P23H protein, suggesting that chlorin e6 may be generally beneficial in the rescue of those ADRP rhodopsin proteins whose stability is affected by amino acid replacement.