FOREIGN EYE TRANSPLANTS: Do They Work?

Paul Pietsch and Carl W. Schneider
Indiana University, Bloomington, Indiana, USA and Department of Psychology, Indiana University of Pennsylvania, Indiana, Pennsylvania, USA

Web contact: pietsch@indiana.edu

key words: eye transplants, optic reflexes, xenoplatic transplanting, xenografts, salamanders, axolotls, Ambystoma, optic nerve regeneration, skin pigmentation, camouflage reaction
Abstract. A transplanted eye of a different species can reinstate the optically evoked camouflage reaction in a salamander (Ambystoma) larva whose own eyes had previously been removed. Usually complete,the recovery was equal in quality, frequency and magnitude to bilaterally enucleated controls with one of their own eyes reimplanted (autografts). The observations confirm Stone's thesis that an eye can work in host of a foreign species.
During the 1930's, L. S. Stone and his associates at Yale xenografted the eyes of various urodele amphibians and reported that the host would eventually see. Depending on the species,the grafted eye reportedly could endow the recipient with better visual acuity than the animal exhibited preoperatively (see especially Stone, 1930; Stone and Ellison, 1940; additional references and review in Jacobson, 1970).

Stone, of course, did not lack in critics. Indeed, even his most ardent admirers had to admit that his criteria for vision (behaviorally based) were not rigorous. A review of the literature indicated to us that the quality of the evidence had not substantially improved during the years since Stone's reports. We undertook the present investigation to see if Stone's fundamental thesis could be substantiated in tests involving reflex reactions rather than behavior, per se, and for this purpose turned the visually evoked, neuro-endocrine skin camouflage reactions of Ambystoma larvae (Pietsch and Tokarski, 1992). The latter reaction was discovered early in this century (Laurens, 1914) and we have more recently employed it to assess vision in ectopically transplanted eyes (Pietsch and Schneider, 1985).

In nature, salamander larvae would stand little chance of escaping the swift and vicious predators that share their native waters except for the marvelously attuned adaptive reactions of their skin pigmentation. (For general treatment of amphibian pigmentation see Bagnara and Hadley, 1973). When placed against a brightly reflecting background an Ambystoma larva with at least one functional eye will blanch within about thirty minutes. When transferred to a dark receptacle the same animal's will gradually darken. If its eyes are removed, however, the animal, if illuminated, will invariably darken whether the container is black, white, transparent or of a wide variety of colors; i.e., in the eyeless condition, dermal pigmentation patterns are independent of the photic background. (The animal will blanch in total darkness.) The direct effectors of the changes are a class of dermal melanophores that redistribute melanosomes to and from peripherally extended cytoplasmic processes (dendrites) and the cell soma with the net cumulative effect of altering the animal's surface reflectance. Readily visible under the stereoscopic microscope, these cells can be non-invasively monitored during prolonged intervals and can be rated according to a conventionally employed pigmentation index (Hogben and Slome, 1931). Since the changes occur gradually over some minutes they can readily be photographed.

In the present investigation, we sought to find out first if a xenoplastic eye could revive the camouflage reactions; if so, with what frequency and how well vis-a-vis recipients of an autografted eye?

Procedures

Animals and Environment

The experiments were conducted with Ambystoma opacum, A. punctatum,(maculatum), A. tigrinum and A. mexicanum (the axolotl), all young, free-feeding larvae at the outset. Prospective host animals were segregated into individual finger bowls as embryos. All animals were maintained in 1/20th Holtfreter's solution, changed daily, and were feed daily rations of newly hatched brine shrimp. The room housing the animals was air-conditioned; lighting, with General Electric FC12T fluorescent lamps, was automatically controlled with the timer set to deliver alternating 12-h cycles of light and darkness during the course of the investigation.

Operations

Surgical procedures were carried out under a stereoscopic microscope on Petri dish lids lined with Vermont marble clay. Animals were anesthetized in 1:5000 MS 222 (tricaine methanesulfonate) dissolved in 1/20th Holtfreter's salt solution. For transplantations, the host was bilaterally enucleated and, with "pillows" of clay, was positioned with one orbit facing obliquely upward; decussating insect pins were used to truss the host gently against the clay base. A prospective donor was transferred alongside the host via a large-mouth pipette. The donor eye, orthotopic to the awaiting host orbit, was carefully excised with an asymmetrical flap of periorbital skin left attached to the globe; the intent was to transplant the eye orthopositionally, using the asymmetry of the skin flap to maintain visible orientation while the organ was in transit. The stump of the transplant's optic nerve was aimed at the host's optic foramen; the skin flap was smooth down onto sticky wounded host tissues to hold the eye temporarily in place; then the eye was secured with Stultz Bruecke: a straddle-bridge graft cover made of transparent Tygon and straightened safety pins; the Bruecke which straddled the head and anchored into the clay, was pressed gently but snugly against the donor cornea. The animal was kept immobile for 2-3 hours postoperatively, after which it was transferred to a white Styrofoam cup containing freshly mixed 1/20 Holtfreter's solution, and thus individually maintained, except when undergoing the dark testing described below. The experiments had to be conducted over several operating seasons, months (and, in a few cases, years) apart and, therefore, were organized into volleys, each volley containing, in addition to the transplantees: unilaterally enucleated animals (One-Eyed); bilaterally enucleated animals with no eye transplant (Eyeless); Unoperated. In a given all hosts were siblings; all, including Unoperated, were anesthetized and revived concurrently; all were kept individually, but in the same rack, and except during inspection under the microscope or photomacrography, were exposed to approximately the same luminance levels during the entire investigation. The latter was facilitated by transferring the rack rather than individual cups.

Lighting conditions

The ambient illumination (800-1000 Lux) was several orders of magnitude above the threshold for the camouflage reactions (see Pietsch and Schneider, 1985). In some experiments, however, a specially constructed light chamber was used. In the chamber the bottom of the Styrofoam cup (where a given animal spent most of its time) exhibited luminances of 360 (+/- 10 s.d.) Nits, as measured with a Tektronix luminance probe. The lamp in the chamber was of the type used in the room (General Electric FC12T); the chamber was on the room's light-dark cycle (duty cycle). The light chamber was also used to test the dark camouflage reactions of some animals; the latter subjects were placed in brown cups whose luminances measured 10 Nits in the light chamber. (Brown cups induced a partial darkening; the rationale in chosing them, over black, was to be able to distinguish at a glance the difference between a true camouflage reaction and the darkening due to the eyeless condition.)

Data collection and evaluation

Animals were observed daily for from 3-5 months postoperatively, and photographic records were obtained periodically during the intervening intervals. Bright and dark reactions were judged by direct examination of melanophores under the stereoscopic microscope; in the fully blanched condition the cells assume the form of widely spaced punctate dots on a bright to pale yellow field; in the fully darkened state the neighboring melanophores appear to spread into progressively expanding spots, until they touch and create confluent tigroid patches. (See Pietsch and Tokarski, 1992 for electron microscopy of dermal melanophores.) In quantitative evaluations, the subject's pigmentation (HS) index (Hogben and Slome, 1931) was ascertained, in which 1 represents the state of the melanophores during maximum blanching (contracted pigment spot) and 5 the confluent patches the cells exhibit when the animal appears maximally darkened to the naked eye. Statistical data were processed on a VAX 8800 digital computer with RS/1 and Speakeasy software

Results

All Unoperated subjects blanched in white cups when illuminated either in ambient light or in the light chamber; their appearances are represented by the subject in Figure 1. The same was true of all One-Eye (unilaterally enucleated) subjects. Figure 2 is representative of all Eyeless subjects (bilaterally enucleated), whether illuminated in ambient light or in the light chamber, and also of each transplant recipients for about 4 weeks postoperatively; i.e., the transplant recipients initially reacted as the eyeless animals, which at first they were.

Recipients of both autoplastic or xenoplastic transplants recovered the camouflage reaction as early as 4 and as late as 8 weeks postoperatively or else never showed a camouflage reaction again. The qualitative aspects of these trends are illustrated by Figures 3-8 (the quantitative features findings will be described below): Figure 3 shows an A. opacum larva with the eye of an A. tigrinum , an animal whose camouflage reactions had recovered by 5 weeks postoperatively; the subject of Figure 4, by way of contrast, is an A. opacum larva with an autoplastically grafted eye, also at 5 weeks, but whose camouflage reactions never recovered during the remaining several months of its life.

Figure 5 is a view at higher magnification of a camouflage-competent A. tigrinum recipient of an A. opacum eye. Compare its pigment spots with those of the One-Eyed subject. A. tigrinum larva in Figure 6. Figure 7 is a close up of an Eyeless A. tigrinum presented here as a frame of reference for the subject in Figure 8: an A. tigrinum that, although it received an autoplastic eye transplant, never recovered the camouflage reactions. The point is that success and failure was not confined to the recipients of foreign eyes but attended autotransplants as well. Animals that recovered the bright reaction were tested for the dark phase of the response by placing them in brown cups for 24 hours whereupon they darkened to the same extent as concomitantly tested One-Eyed and Unoperated subjects of the volley. Figure 9 shows a record photograph of a brown-tested pair: an Unoperated A. opacum and a sibling that served as the recipient of an A. tigrinum eye. The partially darkened animals of the brown tests were re-tested in white cups for the bright reaction. The transplant recipients regained the bright color as rapidly as the One-Eye and Unoperated subjects. Figure 10 illustrates re-testing in white cups; this is the same pair as in Figure 9.

During both brown-testing and bright re-testing, animals judged not to have recovered the camouflage were indistinguishable from the Eyeless subjects (see Fig. 11).

The incidence and extent of recovery of xenografts versus autografts was judged in an experimental series involving A. punctatum as the host of either its own eye or that of an A. tigrinum larva. In this series all hosts had developed simultaneously through the same Harrison stages; the donor A. tigrinum had come from one clutch of eggs; operations were performed in groups of 12 daily over a period of a week; at 8 weeks postoperatively all surviving animals were examined, tested for camouflage reactions and rated for HS pigmentation index. The latter results are summarized in Table 1.

Of 22 A. punctatum larvae with an A. tigrinum eye, 18 were able to brighten in a white cup (attain an HS index of 2.5 or less); 4 reacted as the Eyeless animals in the series. Of 22 autograft recipients, 17 regained the camouflage reaction, but 5 failed to show recovery.

The HS indices of all 22 Xenograft and 22 Autograft subjects generated means of 2.09 (+/-1.0 s.d.) and 2.20 (+/-1.1 s.d.), respectively and a t-value of 0.36, which indicated no significant differences between the means. However, the latter data included indices from animals that had not recovered the camouflage reactions, thus falsely elevating the means. For a more faithful comparison, the HS pigmentation scores for non-responding transplantees were excluded and the analysis repeated; these t-values appear in the right-hand columns of Table 1.

The mean values for Xenograft, Autograft and One-Eye were similar, and their t-values indicate no significant difference at the 0.05 level. The means for the latter three types of subjects were somewhat greater than those for Unoperated, suggesting, perhaps, an extra natural eye may deliver a greater degree of brightening. (The latter point is currently being reexamined, but is not directly relevant to the present investigation.)0 Eyeless animals generated a mean HS index appreciably (4-fold) and significantly higher than those of the transplant group.

Animals of the latter series presented an opportunity to conduct a well-controlled, independent test of the premise that the camouflage reactions are causally related to the eye. Animals were formed into paired groups representing Xenograft or autograft recipients whose HS indices were similar to Unoperated and One-Eyed values. The test group also included pairs of Unoperated and One-Eyed animals. All animals were simultaneously anesthetized; one member of each pair was enucleated (bilaterally in the case of the previously Unoperated) but the other member, which would serve as the control, was not. The animals were removed from the anesthetic, placed in white cups and examined some hours later. All control pair members exhibited the normal blanching reaction whereas their enucleated partners had appreciably darkened; the melanophores of the latter were identical whether the enucleated animal had borne a xenogenically transplanted eye or its own natural eyes (cf. figs. 12 and 13).

Finally, experiments with A. tigrinum as the donor provided direct evidence of the general health of the xenogenically transplanted eye during the study. Because of seasonal differences in A. opacum and A tigrinum, the latter eyes were comparatively small at time of the operation, the donors being much younger than the hosts. However, A. tigrinum larvae eventually become much larger than A. opacum (or A. punctatum ). After grafting, A. tigrinum eyes grew appreciably in the host site, the extent of which may be judged by comparing Figure 3 with Figures 9 or 10, where the same subject can be seen at 5 and 10 weeks postoperatively.

Discussion

The results of this investigation demonstrate first, a transplanted eye can fully reinstate the camouflage reactions in a bilaterally enucleated host of a foreign species; secondly, the had an equal chance of success and worked as well as an animal's own reattached eye. Regeneration of the optic nerve doubtless underlies the present observations; the regenerative capacity of Ambystoma nerve fibers is well known (see references in Schneider and Pietsch, 1967; Pietsch and Schneider, 1985). The latter investigators partially characterized the camouflage circuitry by means of ablation experiments; interruption of the basilar optic tract (Herrick, 1941; Jakway and Riss, 1972) canceled the bright reaction; if the latter pathway were kept intact, the reaction could be blocked by lesions simultaneously inflicted in the isthmus (hindbrain-forebrain juncture) and in the pretectal area, but not in one of either of these locations by itself. While some uncertainties do exist about these pathways, the point germane to the present discussion is that the route followed by the regenerating optic nerve fibers must have been complex and circuitous. That a small percentage of failures occurred even among autotransplants is thus not surprising. Indeed that the camouflage reaction can be reestablished at all seems remarkable, even for the larval salamander.

The present results support Stone's general thesis (that the optic nerves can functionally regrow into a foreign brain). But they do not furnish direct evidence of whether vision, qua vision, recovered concurrent with the camouflage reactions. We are currently investigating this question and will defer the discussion of this issue until all the data are available. It is worthy of note at this juncture that several diverse optic pathways course through the brain of the salamander (see references in Pietsch and Schneider, 1985)

A discursive morphological investigation of the regenerated camouflage circuitry would be difficult, but nevertheless feasible with contemporary methods (e.g., HRP); such investigations would be instructive in terms of the relationship of the recovery of a neural function to the reconstruction of a particular morphological pattern. Also, a small but significant percentage of transplant recipients failed to recover the camouflage reactions even though the eye remained healthy and grew normally. A comparison between recovered and unrecovered animals could yield useful information about the anatomy of the camouflage network.

References

Bagnara, J. T. and Hadley, M. E. Chromatophores and color changes (Prentice-Hall, Englewood Cliffs, 1973).

Herrick, C. J. Development of the optic nerve of Amblystoma. J. Comp. Neurol. 74:473-534 (1941).

Herrick, C. J. The brain of the tiger salamander (University of Chicago Press, Chicago, 1948).

Hogben, L. T. and Slome, D. The pigmentary effector system. VI. The dual character of endocrine coordination in amphibian colour change. Proc. Roy. Soc. B 109:10-53 (1931).

Jacobson, M Developmental neurobiology (Holt, Rinehart and Winston, New York, Chicago, London, Sidney, 1970).

Jakway, J. S. and Riss, W. Retinal projections in the tiger salamander, Ambystoma tigrinum. Brain, Behav. Evol. 5:401-442 (1972).

Laurens, H. The reactions of normal and eyeless amphibian larvae to light. J. Exp. Zool. 16:194-210 (1914).

Pietsch, P. and Schneider, C. W. Vision and the skin camouflage reactions of Ambystoma larvae: the effects of eye transplants and brain lesions. Brain Res. 340: 37-60 (1985)

Pietsch, P. and Schneider, C. W. Transplanted eyes of foreign donors can reinstate the optically activated skin camouflage reactions in bilaterally enucleated salamanders (Ambystoma) Brain Behav Evol 32: 364-370 (1988).

Pietsch, P. and Tokarski, T.R. The dermal melanophore of the larval salamander, Ambystoma tigrinum. Cytobios 69: 107-131 (1992).

Schneider, C. W. and Pietsch, P. The effects of addition and subtraction of eyes on learning in salamander larvae. Brain Res. 8:271-280 (1968)

Stone, L.S. Heteroplastic transplantation of eyes between larvae of two species of Amblystoma. J. Exp. Zool. 55:193-261 (1930).

Stone, L.S. and Ellison, F. S. Exchange of eyes between adult hosts of Amblystoma punctatum and Triturus viridescens. Proc. Soc. Exp. Biol. Med. 45:181-182 (1940).

The data in this article were first published in Pietsch and Schneider, 1988.
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APPENDIX (figures):

Brueckeimage
image
Figures 1-4 --from left to right :
1. Unoperated A. opacum.
2. Eyeless (bilaterally enucleated) A. opacum.
3. Xenograft (blanch competent): successful blanching reaction in an A. opacum 85 days after bilateral enucleation and transplantation of left eye of an A. tigrinum to its left orbit.
4. Xenograft (blanch incompetent): identical to that in fig. 3 but with permanent failure of blanching reaction; host here was sibling of host in fig. 3; transplant operation performed during same session as case in fig. 3.
[primary magnification for figs. 1-4 = 7.6 x]
Figures 5-8 'Close-in' view of skin *[primary mag. = 16.2 x]
image
--from left to right:
5. Xenograft (blanch competent): an A. tigrinum with an A. opacum right eye (cf. with fig. 6); 72 days postoperatively.
6. One-Eyed: A. tigrinum; from same volley as subject in fig. 5.
7. Eyeless A. tigrinum; 72 days postoperatively.
8. Autograft (blanch incompetent) A. tigrinum; 65 days postoperatively; 77 percent of autograft subjects became blanch competent, but when members of this group did fail, as had the exhibited animal, their pigmentation was identical to that of their Eyeless counterparts (compare with fig. 7).
---- *individual spots in figs. 5 and 6 are the melanosome-containing perikaryons of individual dermal melanophores. In figs. 7 and 8, the melansomes have dispersed into the pigment cells' dendrites, reducing the bright intercell intervals and apparently converting the distributed dots (of 5 and 6) into the tigroid patches of 7 and 8.
image
Figures 9,10 show the same subjects, both siblings from the same volley: A. opacum larvae, one an unoperated control, the other the enucleated recipient in its left orbit of A. tigrinum eye. In 9, the latter is on the left side; both subjects were receiving a "brown" test at the time the record photograph was taken; i.e., had spent the previous 4 days in a brown cup (which partially darkens the animal), in order to evaluate the "darkening" phase of their camouflage reactions; fig. 9 was taken 141 days postoperatively. In fig. 10, at 184 days postoperatively, the two subjects were undergoing a bright test (had been in a white polystyrene cup) just prior to the photograph. The apparent darkness of the subjects in 10 is a result of pigmentation and shadows in the brain and deep tissues, visible (under the stereomicroscope) because the pigment spots have contracted. Note, though, that the changes in the size of the dermal pigment spots are of the same magnitude in both subjects; this was true throughout their life. Notice, however, the differences in the comparative size of the eyes, more noticeable in 10 than in 9, doubtless because of the 41 days of additional growth. The Xenograft subject is the same animal shown in figure 3, at 85 days postoperatively; i. e., three months earlier. A. tigrinum grows more rapidly and attains greater size than A. opacum.Ideally, a transplant should exhibit the growth potential of donor.
Figure 11image
Here we see fully darkened A. opacums, the one on the left the recipient of the left of an A. tigrinum, the animal on the right an Eyeless control. The photo is useful first or all for comparison with fig. 10; it also faithfully represents the few eye-transplant recipients in which the camouflage reaction never recovered. The animal on the left, the recipient of the foreign eye, is a sibling of the subject of fig. 10; belong to the same operational volley; was also maintained in a white for the 184 day observation period; and was like 10 in all respects except that it never recovered the camouflage reaction. It was being photographed here within a few minutes of fig. 10. The animal on the right is an Eyeless A. opacumcontrol.
Figures 12 and 13. Confidence Test

image

Fig. 12 shows two A. punctatum, each a host of an A. tigrinum eye, and both having fully recovered the camouflage reaction prior to the test. On the afternoon of the photograph, the eye of the animal on the left was removed while that of the animal on the right was left in place. The animals were place in a white cup, wherein the animal on the left darkened while the one on the right blanched (cf. with the eyeless animal on the fight in fig. 13). The animal on the left in 13 is an unoperated control A. punctatumin the same volley as the subjects in 12 [primary mag. 7.6 x].

Carl W. Schneider is a Professor Emeritus at Indiana University of Pennsylvania, Indiana, Pennsyvania.