Identification of fast spurts of pyridine nucleotide oxidation evoked by light stimulation in the isolated perfused vertebrate retina

Longer lasting electroretinographic recordings from the isolated and superfused murine retina

BACKGROUND

Analysis of retinal signaling in mutant mice has become a powerful tool for studying retinal function and disease. Previous attempts to record from isolated mouse retina have been limited to short time periods (about 90 min). It would be desirable to achieve longer-lasting recordings comparable to those that have been performed in larger vertebrates such as rat, rabbit, cat, and bovine (up to 10 h). We performed a series of recordings from isolated mouse retina under a number of different conditions in order to determine the optimal parameters for this species.

METHODS

We used a superfused vertebrate retina assay, for which the murine retina had to be isolated with specific tools. Subsequently, the ERG recordings were optimized for nutrient solution, incubation temperature, and flash light intensity.

RESULTS

To improve the sensitivity and stability of photoreceptor and retinal network responses from the isolated and superfused murine retina, two different nutrient solutions from rat (physiological Ca(2+)) and bovine (reduced Ca(2+) but increased phosphate buffering capacity) were used. Further, a temperature reduced to 27.5 degrees C, a light intensity ten-fold increased (63 mlux), and an increased flow rate (2 ml/min) provided conditions under which the b-wave response was stable for more than 3 hours. Well-known Ca(2+) channel antagonists (isradipine and NiCl(2)) were tested for their potency to antagonize transretinal signalling.

CONCLUSION

In conclusion, the isolated murine retina can be used as a pharmacological testing system, which provides the additional advantage of selective gene inactivation for better understanding of retinal signalling.

The dihydropyridine isradipine inhibits the murine but not the bovine A-wave response of the electroretinogram

PURPOSE

In order to record light-evoked responses from photoreceptor cells and the higher neuronal retinal network, the isolated vertebrate retina represents a sensitive tool for basic research of retinal function and for testing the toxicity of ocular therapeutics. In the past, this in vitro technique was optimized for frog and bovine retina; it should be transferred now to the isolated murine retina because the model could allow for functional testing of genes involved in retinal signalling using wild-type and gene-inactivated mice. Thus, alterations in the electroretinogram (ERG) may reveal differences in retinal information processing because of the inactivation of a specific gene.

METHODS

We used a superfused vertebrate retina assay to test bovine and murine retina.

RESULTS

In order to evaluate the sensitivity of the ERG recording technique from the isolated murine retina, we first determined the light intensity response and the stability of the a-wave amplitude during ERG recording, which did not differ between the species. However, testing the dihydropyridine sensitivity of the a-wave, we found that the murine a-wave was highly sensitive towards racemic isradipine (8-25 nM) but the bovine retina a-wave was not. A similar species-dependent difference was observed for mibefradil (10 muM).

CONCLUSION

Murine and bovine retina differ with respect to transretinal signalling. At the level of photoreceptor cells, the ERG/a-wave is modulated by isradipine-sensitive voltage-gated Ca(2+) channels, which trigger feedback signalling to photoreceptors.

Different states of energy metabolism in the vertebrate retina can be identified by stimulus-related changes in near UV transmission

BACKGROUND

Our aim was to identify different states of energy metabolism in the perfused isolated vertebrate retina by simultaneous recordings of light-evoked changes of transretinal potential (TRP) and spectroscopic changes related to oxidation of pyridine nucleotides.

METHODS

Isolated retinas were obtained from R.esc. and superfused. For each setting, three experiments were performed. Eighteen retinas were used. TRP as a response to light stimulation was recorded simultaneously with stimulus-induced transmission shift at 350 nm. These responses were recorded under normal conditions, under withdrawal of oxygen and glucose, and after addition of electron transport inhibitors and uncouplers of oxidative phosphorylation.

RESULTS

Under normal conditions, TRP was strongly correlated with transmission shift after light stimulation. Without oxygen, amplitudes of stimulus-related TRP decreased and response related increase of transmission at 350 nm was reduced. The retina showed a much higher general absorption of the analyzing light. During glucose lack, an overall increase in transmission at 350 nm could be observed. The addition of Amytal yielded a specific reduction of the OFF components. Cyanide attenuated the ON and OFF components. Dinitrophenol yielded a considerable loss of the electrical ON response. Transmission change was affected less than electrical signal. Chlorophenylhydrazine induced a reproducible reduction of electrical responses, with a relative increase of transmission shift at 350 nm.

CONCLUSION

In the isolated perfused retina, different states of energy metabolism and their specific impact on neuroretinal responses can be examined by simultaneous recordings of stimulus-related neuronal activity and spectroscopic changes.