Single opsin driven white noise ERGs in mice

Nina Stallwitz; Anneka Joachimsthaler; Jan Kremers

doi:10.3389/fnins.2023.1211329

Single opsin driven white noise ERGs in mice

Front Neurosci. 2023 Jul 31:17:1211329. doi: 10.3389/fnins.2023.1211329. eCollection 2023.

Authors

Nina Stallwitz^{1

2}, Anneka Joachimsthaler^{1

2}, Jan Kremers¹

Affiliations

¹ Department of Ophthalmology, University Hospital Erlangen, Erlangen, Germany.
² Animal Physiology, Department of Biology, Friedrich-Alexander-University Erlangen-Nürnberg, Erlangen, Germany.

Abstract

Purpose: Electroretinograms elicited by photopigment isolating white noise stimuli (wnERGs) in mice were measured. The dependency of rod- and cone-opsin-driven wnERGs on mean luminance was studied.

Methods: Temporal white noise stimuli (containing all frequencies up to 20 Hz, equal amplitudes, random phases) that modulated either rhodopsin, S-opsin or L*-opsin, using the double silent substitution technique, were used to record wnERGs in mice expressing a human L*-opsin instead of the native murine M-opsin. Responses were recorded at 4 mean luminances (MLs).Impulse response functions (IRFs) were obtained by cross-correlating the wnERG recordings with the corresponding modulation of the photopigment excitation elicited by the stimulus. So-called modulation transfer functions (MTFs) were obtained by performing a Fourier transform on the IRFs.Potentials of two repeated wnERG recordings at corresponding time points were plotted against each other. The correlation coefficient (r²_repr) of the linear regression through these data was used to quantify reproducibility. Another correlation coefficient (r²_ML) was used to quantify the correlations of the wnERGs obtained at different MLs with those at the highest (for cone isolating stimuli) or lowest (for rod isolating stimuli) ML.

Results: IRFs showed an initial negative (a-wave like) trough N1 and a subsequent positive (b-wave like) peak P1. No oscillatory potential-like components were observed. At 0.4 and 1.0 log cd/m² ML robust L*- and S-opsin-driven IRFs were obtained that displayed similar latencies and dependencies on ML. L*-opsin-driven IRFs were 2.5-3 times larger than S-opsin-driven IRFs. Rhodopsin-driven IRFs were observed at -0.8 and - 0.2 log cd/m² and decreased in amplitude with increasing ML. They displayed an additional pronounced late negativity (N2), which may be a correlate of retinal ganglion cell activity.R²_repr and r²_ML values increased for cones with increasing ML whereas they decreased for rods. For rhodopsin-driven MTFs at low MLs and L*-opsin-driven MTFs at high MLs amplitudes decreased with increasing frequency, with much faster decreasing amplitudes for rhodopsin. A delay was calculated from MTF phases showing larger delays for rhodopsin- vs. low delays for L*-opsin-driven responses.

Conclusion: Opsin-isolating wnERGs in mice show characteristics of different retinal cell types and their connected pathways.

Keywords: electroretinography (ERG); mouse retina; photopigment; silent substitution; temporal white noise (TWN).