Rhythmic ganglion cell activity in bleached and blind adult mouse retinas

doi:10.1371/journal.pone.0106047

. 2014 Aug 25;9(8):e106047.

doi: 10.1371/journal.pone.0106047. eCollection 2014.

Rhythmic ganglion cell activity in bleached and blind adult mouse retinas

Jacob Menzler¹, Lakshmi Channappa², Guenther Zeck²

Affiliations

¹ Neurochip Research Group, Natural and Medical Sciences Institute at the University Tübingen, Reutlingen, Germany; Helmholtz Zentrum München, Deutsches Forschungszentrum für Gesundheit und Umwelt, Neuherberg, Germany.
² Neurochip Research Group, Natural and Medical Sciences Institute at the University Tübingen, Reutlingen, Germany.

PMID: 25153888
PMCID: PMC4143350
DOI: 10.1371/journal.pone.0106047

Rhythmic ganglion cell activity in bleached and blind adult mouse retinas

Jacob Menzler et al. PLoS One. 2014.

. 2014 Aug 25;9(8):e106047.

doi: 10.1371/journal.pone.0106047. eCollection 2014.

Authors

Jacob Menzler¹, Lakshmi Channappa², Guenther Zeck²

Affiliations

¹ Neurochip Research Group, Natural and Medical Sciences Institute at the University Tübingen, Reutlingen, Germany; Helmholtz Zentrum München, Deutsches Forschungszentrum für Gesundheit und Umwelt, Neuherberg, Germany.
² Neurochip Research Group, Natural and Medical Sciences Institute at the University Tübingen, Reutlingen, Germany.

PMID: 25153888
PMCID: PMC4143350
DOI: 10.1371/journal.pone.0106047

Abstract

In retinitis pigmentosa--a degenerative disease which often leads to incurable blindness--the loss of photoreceptors deprives the retina from a continuous excitatory input, the so-called dark current. In rodent models of this disease this deprivation leads to oscillatory electrical activity in the remaining circuitry, which is reflected in the rhythmic spiking of retinal ganglion cells (RGCs). It remained unclear, however, if the rhythmic RGC activity is attributed to circuit alterations occurring during photoreceptor degeneration or if rhythmic activity is an intrinsic property of healthy retinal circuitry which is masked by the photoreceptor's dark current. Here we tested these hypotheses by inducing and analysing oscillatory activity in adult healthy (C57/Bl6) and blind mouse retinas (rd10 and rd1). Rhythmic RGC activity in healthy retinas was detected upon partial photoreceptor bleaching using an extracellular high-density multi-transistor-array. The mean fundamental spiking frequency in bleached retinas was 4.3 Hz; close to the RGC rhythm detected in blind rd10 mouse retinas (6.5 Hz). Crosscorrelation analysis of neighbouring wild-type and rd10 RGCs (separation distance <200 µm) reveals synchrony among homologous RGC types and a constant phase shift (∼70 msec) among heterologous cell types (ON versus OFF). The rhythmic RGC spiking in these retinas is driven by a network of presynaptic neurons. The inhibition of glutamatergic ganglion cell input or the inhibition of gap junctional coupling abolished the rhythmic pattern. In rd10 and rd1 retinas the presynaptic network leads to local field potentials, whereas in bleached retinas additional pharmacological disinhibition is required to achieve detectable field potentials. Our results demonstrate that photoreceptor bleaching unmasks oscillatory activity in healthy retinas which shares many features with the functional phenotype detected in rd10 retinas. The quantitative physiological differences advance the understanding of the degeneration process and may guide future rescue strategies.

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Conflict of interest statement

Competing Interests: The authors have declared that no competing interests exist.

Figures

**Figure 1. Identification of RGCs using the high-density multi transistor array.**
(A) Four consecutive electrical images acquired every 100 µsec reveal the occurrence and propagation of action potentials along the proximal axon. The electrical images were obtained after calculating the spike triggered average over more than thirty spikes. Visualization of the axon identifies a ganglion cell (Methods). Scale bar: 200 µm. (B) Typical light responses of four RGCs in wild-type retinas. The histograms were calculated for repeated stimulus presentations. (binsize: 5 ms).

**Figure 2. RGC spike train properties in bleached, disinhibited and *rd10* retinas.**
A) Rasterplot of spontaneous RGC activity recorded in C57BL/6 retinas in darkness. Each tick represents one action potential. B) Activity recorded from the same cells shown in (a) after 2 hrs of illumination. C) Histogram of the fundamental frequency of 65 rhythmic RGCs measured in three bleached retinas. D) Rasterplot of spontaneous RGC activity recorded in C57BL/6 RGCs in darkness before disinhibition. E) Activity recorded from the same cells shown in (D) after exposure to light and the application of inhibitory receptor blockers (strychnine and gabazine). F) Histogram of the fundamental frequency of 111 RGCs measured in four disinhibited retinas. G) Average RGC maintained activity measured in wt retinas in darkness, in bleached condition and in disinhibited condition and average maintained activity of *rd10* RGCs. H) Rasterplot of spontaneous RGC activity recorded from *rd10* retinas. I) Histogram of the fundamental frequency of 32 rhythmic RGCs evaluated from three *rd10* retinas.

**Figure 3. Pair-wise spike correlation properties in bleached and dystrophic retinas.**
(A) Spatial locations of 53 identified RGCs in one bleached C57/Bl6 retina. Symbols denote OFF RGCs (filled triangle), ON RGCs (open triangles), and physiologically unidentified RGCs (open circles). The rhythmic RGCs are marked with filled grey circles. (B) Cross-correlogramm of the spike trains recorded from two rhythmic OFF RGCs (gray) and a pair of one rhythmic ON and a rhythmic OFF RGCs (black). The OFF-OFF pair fires in synchrony (zero time lag), while RGCs of different polarity display a phase shift. The time lag of the central peak is marked with a dashed line. The rhythmic activity is reflected in the auxiliary peaks of the CC. (C) Dependency of the CC time lag shift for RGC pairs and the cell separation. The legend for the three cell type combinations is given in subplot (F). The hatched area illustrates that RGC pairs separated by less than 200 µm do not display arbitrary lags. This area is drawn for comparison in the following subplots as well. (D–F) Time shift of the central peak in the CCs computed for rhythmic RGC pairs in disinhibited retinas (D), *rd10* retinas (E) and rd1 retinas (F). The open symbol denotes unknown RGC cell type.

**Figure 4. Rhythmic RGC spiking is abolished by ionotrophic glutamate receptor blocker or by gap junction blockers in bleached and in *rd10* retinas.**
(A1 & A2) DNQX (20 µM) prevents rhythmic RGC activity in bleached retinas (A1) and in rd10 retinas (A2). (B) The gap junction blocker MFA (100 µM) inhibits rhythmic spiking in bleached (B1) and in *rd10* retinas (B2). White lines mark the 100 Hz low-pass signal for each trace.

**Figure 5. Rhythmic RGC spiking and strong stationary LFPs emerge during application of glycinergic and GABAergic receptor blockers in bleached mouse retinas.**
A) Extracellular voltage traces recorded on two different sensors on the multi-transistor-array. The upper trace shows activity recorded from an ON RGC, the lower trace shows activity recorded from an OFF RGC. (B) Local field potentials recorded on the whole sensor array at the two time points marked in (A). The symbols mark the position of the sensors shown in (A). C) Power spectral density evaluated for the two sensors reveals a maximum at the frequency of ∼6 Hz. (D) The amplitude of the PSD (as shown in C) measured at all sensors at the maximal frequency. Scale bars in (B) and (D): 200 µm.

**Figure 6. Rhythmic spiking and weak stationary LFPs in the ganglion cell layer of adult *rd10* mouse retinas.**
A) Calibrated voltage traces recorded on two selected sensors. The sensor positions are marked in panel (B). The rhythmic spiking of the two RGCs is not in phase. B) Local field potentials measured at the time points marked in (A). (C) Power spectral density evaluated at the two sensors reveals the fundamental rhythm at ∼7 Hz. (D) The amplitude of the PSD (as shown in C) measured at all sensors at the maximal frequency. Scale bars in (B) and (D): 200 µm.

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References

1. Luo DG, Yau KW (2005) Rod sensitivity of neonatal mouse and rat. J. Gen. Physiol. 126: 263–269. - PMC - PubMed
1. Chang B, Hawes NL, Hurd RE, Davisson MT, Nusinowitz S, et al. (2002) Retinal degeneration mutants in the mouse. Vis. Res. 42: 517–525. - PubMed
1. Stasheff SF (2008) Emergence of sustained spontaneous hyperactivity and temporary preservation of OFF responses in ganglion cells of the retinal degeneration (rd1) mouse. J. Neurophys. 99: 1408–1421. - PubMed
1. Stasheff SF, Shankar M, Andrews MP (2011) Developmental time course distinguishes changes in spontaneous and light-evoked retinal ganglion cell activity in rd1 and rd10 mice. J. Neurophysiol. 105: 3002–3009. - PubMed
1. Borowska J, Trenholm S, Awatramani GB (2011) An Intrinsic Neural Oscillator in the Degenerating Mouse Retina. J. Neurosci. 31: 5000–5012. - PMC - PubMed

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Grants and funding

This study was supported by a grant of the German Ministry for Research and Education (BMBF, FKZ: 1312038) to LC and GZ and by a grant from the Pro Retina Network of RP patients to JM. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

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[1] Luo DG, Yau KW (2005) Rod sensitivity of neonatal mouse and rat. J. Gen. Physiol. 126: 263–269. - PMC - PubMed

[2] Luo DG, Yau KW (2005) Rod sensitivity of neonatal mouse and rat. J. Gen. Physiol. 126: 263–269. - PMC - PubMed

[3] Chang B, Hawes NL, Hurd RE, Davisson MT, Nusinowitz S, et al. (2002) Retinal degeneration mutants in the mouse. Vis. Res. 42: 517–525. - PubMed

[4] Chang B, Hawes NL, Hurd RE, Davisson MT, Nusinowitz S, et al. (2002) Retinal degeneration mutants in the mouse. Vis. Res. 42: 517–525. - PubMed

[5] Stasheff SF (2008) Emergence of sustained spontaneous hyperactivity and temporary preservation of OFF responses in ganglion cells of the retinal degeneration (rd1) mouse. J. Neurophys. 99: 1408–1421. - PubMed

[6] Stasheff SF (2008) Emergence of sustained spontaneous hyperactivity and temporary preservation of OFF responses in ganglion cells of the retinal degeneration (rd1) mouse. J. Neurophys. 99: 1408–1421. - PubMed

[7] Stasheff SF, Shankar M, Andrews MP (2011) Developmental time course distinguishes changes in spontaneous and light-evoked retinal ganglion cell activity in rd1 and rd10 mice. J. Neurophysiol. 105: 3002–3009. - PubMed

[8] Stasheff SF, Shankar M, Andrews MP (2011) Developmental time course distinguishes changes in spontaneous and light-evoked retinal ganglion cell activity in rd1 and rd10 mice. J. Neurophysiol. 105: 3002–3009. - PubMed

[9] Borowska J, Trenholm S, Awatramani GB (2011) An Intrinsic Neural Oscillator in the Degenerating Mouse Retina. J. Neurosci. 31: 5000–5012. - PMC - PubMed

[10] Borowska J, Trenholm S, Awatramani GB (2011) An Intrinsic Neural Oscillator in the Degenerating Mouse Retina. J. Neurosci. 31: 5000–5012. - PMC - PubMed

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Rhythmic ganglion cell activity in bleached and blind adult mouse retinas

Affiliations

Rhythmic ganglion cell activity in bleached and blind adult mouse retinas

Authors

Affiliations

Abstract

Conflict of interest statement

Figures

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Cited by

References

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Grants and funding

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Abstract

Conflict of interest statement

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