Abstract
BackgroundThe adult mammalian retina is an important model in research on the central nervous system. Many experiments require the combined use of genetic manipulation, imaging, and electrophysiological recording, which make it desirable to use an in vitro preparation. Unfortunately, the tissue culture of the adult mammalian retina is difficult, mainly because of the high energy consumption of photoreceptors.Methods and FindingsWe describe an interphase culture system for adult mammalian retina that allows for the expression of genes delivered to retinal neurons by particle-mediated transfer. The retinas retain their morphology and function for up to six days— long enough for the expression of many genes of interest—so that effects upon responses to light and receptive fields could be measured by patch recording or multielectrode array recording. We show that a variety of genes encoding pre- and post-synaptic marker proteins are localized correctly in ganglion and amacrine cells.ConclusionsIn this system the effects on neuronal function of one or several introduced exogenous genes can be studied within intact neural circuitry of adult mammalian retina. This system is flexible enough to be compatible with genetic manipulation, imaging, cell transfection, pharmacological assay, and electrophysiological recordings.
Highlights
Several features make the retina an appealing model of the mammalian central nervous system
We examined the functional integrity of ganglion cell populations in incubated retinas using extracellular multielectrode recording
To evaluate the localization of fusion proteins in retinal neurons, we show here the expression of several GFP-tagged synaptic markers and of the sodium-channel organizing protein ankyrin-G
Summary
Several features make the retina an appealing model of the mammalian central nervous system. We describe an interphase culture system for adult mammalian retina that allows for the expression of genes delivered to retinal neurons by particle-mediated transfer The retinas retain their morphology and function for up to six days— long enough for the expression of many genes of interest— so that effects upon responses to light and receptive fields could be measured by patch recording or multielectrode array recording. In this system the effects on neuronal function of one or several introduced exogenous genes can be studied within intact neural circuitry of adult mammalian retina. This system is flexible enough to be compatible with genetic manipulation, imaging, cell transfection, pharmacological assay, and electrophysiological recordings
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