Single Opsin Driven White Noise ERGs in Mice

Overview

Journal Front Neurosci

Date 2023 Aug 16

PMID 37583414

Authors

Nina Stallwitz

Anneka Joachimsthaler

Jan Kremers

Affiliations

Soon will be listed here.

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 (r) of the linear regression through these data was used to quantify reproducibility. Another correlation coefficient (r) 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/m 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/m 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.R and r 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.

Citing Articles

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References

Field G, Gauthier J, Sher A, Greschner M, Machado T, Jepson L . Functional connectivity in the retina at the resolution of photoreceptors. Nature. 2010; 467(7316):673-7. PMC: 2953734. DOI: 10.1038/nature09424. View

Ishibashi M, Keung J, Morgans C, Aicher S, Carroll J, Singer J . Analysis of rod/cone gap junctions from the reconstruction of mouse photoreceptor terminals. Elife. 2022; 11. PMC: 9170248. DOI: 10.7554/eLife.73039. View

Porciatti V . Electrophysiological assessment of retinal ganglion cell function. Exp Eye Res. 2015; 141:164-70. PMC: 4628896. DOI: 10.1016/j.exer.2015.05.008. View

Bouskila J, Javadi P, Palmour R, Bouchard J, Ptito M . Standardized full-field electroretinography in the Green Monkey (Chlorocebus sabaeus). PLoS One. 2014; 9(10):e111569. PMC: 4216091. DOI: 10.1371/journal.pone.0111569. View

Remtulla S, HALLETT P . A schematic eye for the mouse, and comparisons with the rat. Vision Res. 1985; 25(1):21-31. DOI: 10.1016/0042-6989(85)90076-8. View

Endeman D, Klaassen L, Kamermans M . Action spectra of zebrafish cone photoreceptors. PLoS One. 2013; 8(7):e68540. PMC: 3702584. DOI: 10.1371/journal.pone.0068540. View

Wang J, Saul A, Smith S . Activation of Sigma 1 Receptor Extends Survival of Cones and Improves Visual Acuity in a Murine Model of Retinitis Pigmentosa. Invest Ophthalmol Vis Sci. 2019; 60(13):4397-4407. PMC: 6808049. DOI: 10.1167/iovs.19-27709. View

Greenwald S, Kuchenbecker J, Roberson D, Neitz M, Neitz J . S-opsin knockout mice with the endogenous M-opsin gene replaced by an L-opsin variant. Vis Neurosci. 2014; 31(1):25-37. PMC: 4167788. DOI: 10.1017/S0952523813000515. View

Saul A, Still A . Multifocal Electroretinography in the Presence of Temporal and Spatial Correlations and Eye Movements. Vision (Basel). 2019; 1(1). PMC: 6849053. DOI: 10.3390/vision1010003. View

10.

Tsai T, Atorf J, Neitz M, Neitz J, Kremers J . Rod- and cone-driven responses in mice expressing human L-cone pigment. J Neurophysiol. 2015; 114(4):2230-41. PMC: 4600960. DOI: 10.1152/jn.00188.2015. View

11.

Sun H, Macke J, Nathans J . Mechanisms of spectral tuning in the mouse green cone pigment. Proc Natl Acad Sci U S A. 1997; 94(16):8860-5. PMC: 23167. DOI: 10.1073/pnas.94.16.8860. View

12.

Saszik S, Robson J, Frishman L . The scotopic threshold response of the dark-adapted electroretinogram of the mouse. J Physiol. 2002; 543(Pt 3):899-916. PMC: 2290546. DOI: 10.1113/jphysiol.2002.019703. View

13.

Lyubarsky A, Falsini B, Pennesi M, Valentini P, Pugh Jr E . UV- and midwave-sensitive cone-driven retinal responses of the mouse: a possible phenotype for coexpression of cone photopigments. J Neurosci. 1998; 19(1):442-55. PMC: 6782392. View

14.

Adhikari P, Zele A, Cao D, Kremers J, Feigl B . The melanopsin-directed white noise electroretinogram (wnERG). Vision Res. 2019; 164:83-93. DOI: 10.1016/j.visres.2019.08.007. View

15.

Kremers J, Aher A, Parry N, Patel N, Frishman L . Electroretinographic responses to luminance and cone-isolating white noise stimuli in macaques. Front Neurosci. 2022; 16:925405. PMC: 9372266. DOI: 10.3389/fnins.2022.925405. View

16.

Joachimsthaler A, Kremers J . Mouse Cones Adapt Fast, Rods Slowly In Vivo. Invest Ophthalmol Vis Sci. 2019; 60(6):2152-2164. DOI: 10.1167/iovs.18-26356. View

17.

Ryl M, Urbasik A, Gierke K, Babai N, Joachimsthaler A, Feigenspan A . Genetic disruption of bassoon in two mutant mouse lines causes divergent retinal phenotypes. FASEB J. 2021; 35(5):e21520. DOI: 10.1096/fj.202001962R. View

18.

Falk N, Joachimsthaler A, Kessler K, Lux U, Noegel A, Kremers J . Lack of a Retinal Phenotype in a Syne-2/Nesprin-2 Knockout Mouse Model. Cells. 2019; 8(10). PMC: 6830317. DOI: 10.3390/cells8101238. View

19.

Alarcon-Martinez L, Aviles-Trigueros M, Galindo-Romero C, Valiente-Soriano J, Agudo-Barriuso M, de la Villa P . ERG changes in albino and pigmented mice after optic nerve transection. Vision Res. 2010; 50(21):2176-87. DOI: 10.1016/j.visres.2010.08.014. View

20.

Applebury M, Antoch M, Baxter L, Chun L, Falk J, Farhangfar F . The murine cone photoreceptor: a single cone type expresses both S and M opsins with retinal spatial patterning. Neuron. 2000; 27(3):513-23. DOI: 10.1016/s0896-6273(00)00062-3. View