This article provides a description of how to dissect and record from the isolated retinal preparation in mouse. In particular, we describe how to record light responses from a fluorescently labeled ganglion cell population and subsequently identify and analyze its morphology.
The first steps in vertebrate vision take place when light stimulates the rod and cone photoreceptors of the retina 1. This information is then segregated into what are known as the ON and OFF pathways. The photoreceptors signal light information to the bipolar cells (BCs), which depolarize in response to increases (On BCs) or decreases (Off BCs) in light intensity. This segregation of light information is maintained at the level of the retinal ganglion cells (RGCs), which have dendrites stratifying in either the Off sublamina of the inner plexiform layer (IPL), where they receive direct excitatory input from Off BCs, or stratifying in the On sublamina of the IPL, where they receive direct excitatory input from On BCs. This segregation of information regarding increases or decreases in illumination (the On and Off pathways) is conserved and signaled to the brain in parallel.
The RGCs are the output cells of the retina, and are thus an important cell to study in order to understand how light information is signaled to visual nuclei in the brain. Advances in mouse genetics over recent decades have resulted in a variety of fluorescent reporter mouse lines where specific RGC populations are labeled with a fluorescent protein to allow for identification of RGC subtypes 2 3 4 and specific targeting for electrophysiological recording. Here, we present a method for recording light responses from fluorescently labeled ganglion cells in an intact, isolated retinal preparation. This isolated retinal preparation allows for recordings from RGCs where the dendritic arbor is intact and the inputs across the entire RGC dendritic arbor are preserved. This method is applicable across a variety of ganglion cell subtypes and is amenable to a wide variety of single-cell physiological techniques.
Animal Use Statement: Animals were cared for in accordance with guidelines described in Guide for the Care and Use of Laboratory Animals, using protocols approved by the University of Minnesota Institutional Animal Care and Use Committee.
1) Preparation of solutions
2) Isolation of retina from mouse
Dissection tools needed: 1 #2 Forceps, 2 #5 Forceps, ophthalmologic scissors
3) Treatment of retina with enzyme mixture and mounting in recording chamber
4) Localization of EGFP expressing ganglion cells and light stimulation
5) Analysis of anatomy of recorded ganglion cells
Filling with neurobiotin allows for more detailed morphological analysis of ganglion cells following recording. Tip: If specific correlations between a recorded ganglion cell and detailed morphology is desired, it may be best to record and fill only one RGC per preparation.
Representative Results
If the retina is healthy and the dissection was successful, individual ganglion cells should be visible under DIC at high magnification (Figure 1A). Unhealthy retinas will have large, granulated nuclei and should be discarded. If the synaptic response of a given ganglion cell is intact, then the cell should respond at light onset or offset with action potentials and, in the case of an intrinsically-photosensitive ganglion cell (Figure 1B) , a sustained depolarization.
Figure 1. Localization, recording, and staining of a fluorescently labeled retinal ganglion cell. (A) GFP positive RGC visualized under epifluorescent illumination at 40X magnification (left panel) and under DIC illumination (right panel). (B) Synaptic light response of an M2 intrinsically photosensitive retinal ganglion cell recorded in whole-cell current clamp mode from fluorescently labeled RGC. (C) M1 intrinsically photosensitive retinal ganglion cell that was identified under epifluorescence, targeted for whole-cell recording, filled with neurobiotin, and then processed for immunohistochemistry.
This technique is applicable to any retinal ganglion cell recordings from an isolated retina. Though in the mouse line used above intrinsically photosensitive, melanopsin-expressing RGCs are labeled with EGFP2, 5, this protocol is readily transferable to other fluorescently labeled RGC lines or can be generalized to record from randomly selected RGCs as well. This technique is particularly valuable because the dendritic arbor of each RGC and its respective input neurons are left entirely intact. Recordings can readily be performed in current or voltage clamp modes, cell-attached or loose-patch configuration, or can even be used for nucleated patch, inside- or outside-out patch configurations from retinal ganglion cell membranes. This technique could be readily adapted to record from fluorescently labeled displaced amacrine cells 7 or even non-displaced amacrine cells 8 One limitation of the utilization of fluorescence to localize ganglion cells is that the retina must always be exposed to light for RGC identification prior to recording. Thus, this preparation may not be suitable for recording rod-mediated responses unless exogenous chromophore is included in the bath solution and/or the eyecup and retinal pigmented epithelium are left attached to the retina 9. If the goal is to record rod-mediated light responses, then special precautions must be taken to avoid bleaching of the photopigment rhodopsin. Dissection must be performed under infrared light conditions (i.e. 10).
To perform a successful dissection, it is important that the dissection be performed as rapidly as possible. It is especially important that the vitreous be successfully removed with the forceps. If the vitreous is remaining, then following enzyme digestion the retina will be covered with a gooey film making successful patching difficult. To obtain good recordings, it is particularly critical that the retina is well-oxygenated, meaning that the extracellular solution is being vigorously bubbled and the flow rate is sufficiently high through the chamber. It is also important to minimize light exposure of the tissue once the retina is isolated from the eyecup.
This work was supported in part by grants from the NIH R01EY012949, R21EY018885, T32 EY0707133. We thank Darwin Hang for his technical assistance.
Material Name | Tipo | Company | Catalogue Number | Comment |
---|---|---|---|---|
Ames’ Medium | Sigma | A1420 | ||
Collagenase | Whorthington Biochemical | LS005273 | ||
Hyaluronidase | Whorthington Biochemical | LS002592 | ||
Sodium Bicarbonate | Sigma | S5761 | ||
AlexaFluor 594 Hydrazyde | Invitrogen | A10442 | ||
Neurobiotin | Vector Laboratories | SP1120 | ||
Electrodes | Sutter Instruments | BF120-69-10 | ||
Forceps | Fine Science Tools | 11252-30 | ||
Ophthalmologic Scissor | Fine Science Tools | 15000-00 | ||
Streptavidin 594 | Invitrogen | S32356 | ||
Vectashield | Vector Laboratories | H-1000 | ||
Goat Serum | Jackson ImmunoResearch | 005-000-001 | ||
Triton X-100 | Sigma | T8787 | ||
Paraformaldehyde | Electron Microscopy Sciences | 19210 |