Optic Nerve transection is a widely used model of adult CNS injury. Ninety percent of retinal ganglion cells (RGCs) whose axons are completely transected (axotomy) die within 14 days after axotomy. This model is easily amenable to experimental manipulations and highly reproducible.
Retinal ganglion cells (RGCs) are CNS neurons that output visual information from the retina to the brain, via the optic nerve. The optic nerve can be accessed within the orbit of the eye and completely transected (axotomized), cutting the axons of the entire RGC population. Optic nerve transection is a reproducible model of apoptotic neuronal cell death in the adult CNS 1-4. This model is particularly attractive because the vitreous chamber of the eye acts as a capsule for drug delivery to the retina, permitting experimental manipulations via intraocular injections. The diffusion of chemicals through the vitreous fluid ensures that they act upon the entire RGC population. Moreover, RGCs can be selectively transfected by applying short interfering RNAs (siRNAs), plasmids, or viral vectors to the cut end of the optic nerve 5-7 or injecting vectors into their target, the superior colliculus 8. This allows researchers to study apoptotic mechanisms in the desired neuronal population without confounding effects on other bystander neurons or surrounding glia. An additional benefit is the ease and accuracy with which cell survival can be quantified after injury. The retina is a flat, layered tissue and RGCs are localized in the innermost layer, the ganglion cell layer. The survival of RGCs can be tracked over time by applying a fluorescent tracer (3% Fluorogold) to the cut end of the optic nerve at the time of axotomy, or by injecting the tracer into the superior colliculus (RGC target) one week prior to axotomy. The tracer is retrogradely transported, labeling the entire RGC population. Because the ganglion cell layer is a monolayer (one cell thick), RGC densities can be quantified in flat-mounted tissue, without the need for stereology. Optic nerve transection leads to the apoptotic death of 90% of injured RGCs within 14 days postaxotomy 9-11. RGC apoptosis has a characteristic time-course whereby cell death is delayed 3-4 days postaxotomy, after which the cells rapidly degenerate. This provides a time window for experimental manipulations directed against pathways involved in apoptosis.
1. Surgical Technique
2. Anesthesia
3. Surgical Approach
4. Accessing the Optic Nerve
5. Closing and Recovery
6. Representative Results:
Transection of the optic nerve results in the loss of 90% of injured RGCs within 14 days postaxotomy 9-11. The main mechanism of RGC death is apoptosis 9, 12. The normal density of RGCs is approximately 2500 cells/mm2. Epifluorescence or confocal imaging can be used to visualize retrogradely labeled RGCs after axotomy. RGC apoptosis is delayed by approximately 4 days after axotomy, leaving a time window for experimental manipulations. At 1 day after axotomy and retrograde labeling with Fluorogold, RGC cell bodies in the ganglion cell layer of the retina and axon fascicles in the nerve fiber layer of the retina are clearly visible when imaging a flatmounted preparation (Fig 1a). By 14 days after axotomy, the majority of RGCs have died, and a few remaining RGCs are interspersed between retinal microglia (Fig 1b). When RGCs undergo apoptosis, microglia phagocytose the dead cells and as a result become transcellularly labeled with the fluorescent tracer that was used to label the RGCs 13, 14. The appearance of the tracer in the phagosomes of microglia is different from that in surviving RGCs. Microglia contain the tracer in highly concentrated and extremely bright phagosomes that are relatively large and scattered throughout their cytoplasm (Fig 1c). RGCs have a more diffuse pattern of staining (Fig 1c) with small punctate vesicles that have been retrogradely transported down their axons filing the cell cytoplasm. These vesicles are much smaller and have less intense fluorescence allowing one to differentiate surviving RGCs from microglia. Furthermore, microglia have much smaller cell bodies and tend to have a stellate or amoeboid morphology as opposed to RGCs that have relatively large and rounded cell bodies. The dendritic trees of RGCs can also help differentiate them from the short bright processes of microglia, when quantifying cell survival. Cell survival can be quantified in different regions of the retina and the density (cells/mm2) can be extrapolated from the area of the corresponding micrographs, since RGCs are found in a monolayer within the ganglion cell layer.
Figure 1. Epifluorescence micrographs of Fluorogold labeled RGCs after axotomy and application of the tracer to the optic nerve stump. (A) 1 day after axotomy RGCs and their axon fascicles are labeled with the tracer in a fine punctate manner. (B) By 14 days after axotomy, 90% of RGCs have died and brightly labeled microglia that have phagocytosed dead cells are also labeled with the tracer. (C) Higher magnification illustrating the difference between RGCs and microglia (red arrowheads) at 14 days postaxotomy. Scale bar in A and B is 50 μm. Scale bar in C is 25 μm.
There are many variations of this surgical procedure and several of the steps in this protocol are not necessary. It is only necessary to retract the muscles that overlie the optic nerve in order to gain access to the nerve. However, this results in a very limited working space around the nerve making the critical final stages of transection more difficult. In certain situations it is desirable to transfect the cells from the optic nerve stump and the increased access space afforded by retracting all of the extraocular muscles and the lacrimal gland is beneficial in this instance.
The most critical steps in the protocol are Steps 4.3-4.6. It is important not to damage the vasculature around the optic nerve head. The nerve should be transected 1.5-2.0 mm from the back of the eye in order to avoid any damage to the ophthalmic artery which penetrates the nerve within one millimeter of the eye and feeds blood to the inner retina. Thus, by maintaining a small working distance from the back of the eye damage to the ophthalmic artery can be avoided. The retina is normally transparent and blood vessels can be clearly demarcated. If the retinal blood supply is damaged the retina will degenerate leading to a milky-white flocculent appearance. The vitreous chamber of the eye and the lens will typically cloud over as well, with the eye shrinking in size over time.
With practice, all of the steps in the full surgical procedure can be accomplished in 10-15 minutes per eye, once the initial entry cuts have been made. The procedure can also be accomplished from a lateral approach to the orbit and either route is highly amenable to procedural modifications based on the preferences of the researcher. This model has a highly reproducible time course of cell death and there are several ways to target the retina globally or to directly target injured RGCs in order to test the effects of experimental treatments on cell survival.
The authors have nothing to disclose.
PDK is supported by a CIHR operating grant (MOP 86523)
Material Name | Type | Company | Catalogue Number | Comment |
---|---|---|---|---|
Stereotaxic Frame | Stoelting, Kopf, WPI | |||
Rat Gas Mask | Stoelting, Kopf, WPI | |||
Anesthesia System | VetEquip | 901806 | ||
Isoflurane (PrAErrane) | Baxter Corp | DIN 02225875 | ||
Surgical Microscope | WPI, Zeiss, Leica | |||
Fluorogold -(Hydroxystilbamidine bis(methanesulfonate) | Sigma | 39286 | ||
Gelfoam | Pharmacia & Upjohn | |||
Tears Naturale P.M. | Alcon | |||
Proviodine | Medline | MDS093945H | ||
Vannas spring scissors | Fine Science Tools | 15000-00 | ||
Fine tip Dumont forceps | Fine Science Tools | 11252-00 | ||
Micro surgical hook | Fine Science Tools | 10062-12 | ||
Eye dressing serrated forceps | Fine Science Tools | 11152-10 | ||
Dumont #7b sharp curved serrated forceps | Fine Science Tools | 11270-20 | ||
Cauterizer | Fine Science Tools | 18010-00 |