John J. Schalken

Immunocytochemical markers revealing retinal and pineal but not hypothalamic photoreceptor systems in the Japanese quail.

SummaryThe retinal proteins opsin,α-transducin, S-antigen and interstitial retinol-binding protein (IRBP) are essential for the processes of vision. By use of immunocyto-chemistry we have employed antibodies directed against these “photoreceptor proteins” in an attempt to identify the photoreceptor systems (retina, pineal and deep brain) of the Japanese quail. Opsin immunostaining was identified within many outer (basal portion) and inner segments of retinal photoreceptor cells and limited numbers of photoreceptor perikarya. Opsin immunostaining was also demonstrated in limited numbers of pinealocytes with all parts of these cells being immunoreactive. These results differ from previous observations. In contrast to the results obtained with the antibody against opsin, S-antigen andα-transducin immunostaining was seen throughout the entire outer segments and many photoreceptor perikarya of the retina. In the pineal organ immunostaining was seen in numerous pinealocytes in all follicles. These results conform to previous findings in birds. In addition, IRBP has been demonstrated for the first time in the avian retina and pineal organ. These findings underline the structural and functional similarities between the retina and pineal organ and provide additional support for a photoreceptive role of the avian pineal. No specific staining was detected in any other region of the brain in the Japanese quail; the hypothalamic photoreceptors of birds remain unidentified.

A comparison of some photoreceptor characteristics in the pineal and retina

SummaryImmunocytochemistry with a rod-specific antiserum was used to study the post-hatch development (2 days–300 days) of photoreceptor elements within the pineal of the Japanese quail. At all ages staining was restricted to limited numbers of pinealocytes scattered throughout the gland. An enzyme-linked immunosorbent assay (ELISA), with the same rod-specific antibody, was then used to obtain a quantitative measure of rod opsin in total eye and pineal extracts in both the developing retina and pineal. The opsin content of both tissues shows a marked increase during the first 30 days after hatch and then plateaued to 0.84±0.02 nmoles opsin in the eye and 2.20±0.11 pmoles opsin equivalents in the pineal. The increase in opsin in the retina may be associated with continued post-hatch development of the photoreceptors. We then attempted to demonstrate the presence of the rhodopsin chromophore within pineal and retinal extracts using HPLC analysis. In both retinal and pineal extracts, 11-cis retinaldehyde was identified and a light-induced shift from the 11-cis to the all-trans isomer was clearly shown. This analysis also allowed us to calculate the total content of 11-cis and all-trans retinaldehyde (derived from both rod and non-rod photoreceptors) of the eye and pineal (eye: 1.7±0.2 nmoles; pineal: 4.6±0.5 pmoles). In the quail eye, the total amount of retinaldehyde is more than twice the amount of rod-like opsin. This probably reflects the large contribution of cones in the quail retina; the cone pigments will contribute to the retinaldehyde content but are not recognized by the rodspecific antibodies. In the pineal, we also found more than double the concentration of retinaldehyde than we would have predicted from the amount of rod-like opsin. These results, coupled with our immunocytochemical findings, suggest that the quail pineal contains at least two classes of photoreceptor, some ‘rod-like’, others ‘non rod-like’.

Rhodopsin-induced experimental autoimmune uveoretinitis: dose-dependent clinicopathological features.

We have studied the clinicopathological features of experimental autoimmune uveoretinitis (EAU) induced in Lewis rats by injection of different doses of rhodopsin and its illuminated form opsin. Rhodopsin consistently appears to be more pathogenic than opsin. Injected in Freunds complete adjuvant and pertussis adjuvant 50 micrograms of rhodopsin induces a frequency of severe EAU similar to 250 micrograms of opsin. Intensity, frequency and location of ocular inflammation are markedly dose dependent. At high dose (100-250 micrograms), rhodopsin induces severe bilateral uveoretinitis in all animals, which starts with acute inflammation of the anterior eye segment at day 10-12 followed by chorioretinitis (predominantly retinitis) which results in complete elimination of the photoreceptor cells. At low dose (20 micrograms), rhodopsin induces mild transient inflammation in 60% of the animals, mainly consisting of mild posterior retinitis which starts at day 20 and leads to a typical multiple focal destruction of the photoreceptor cells. Intermediate doses cause an intermediate type of disease. Omission of pertussis adjuvant lowers the frequency of severe disease at low doses of rhodopsin, delays its onset and changes its features. The last characteristic has been observed in particular at intermediate doses (50-100 micrograms). In these cases, EAU usually starts by cell infiltration of the vitreous, while the anterior segment is only mildly affected. Without pertussis adjuvant the pathogenicity of opsin is low. Even in both adjuvants severe EAU can only be evoked by a high dose of opsin. Although there exists a marked difference in uveitogenicity between rhodopsin and opsin, the immunogenicity is similar and seems not to be correlated with their pathogenicity.

Immunocytochemical evidence of molecular photoreceptor markers in cerebellar medulloblastomas

With the use of antisera against bovine retinal S‐antigen and bovine opsin the authors demonstrate that in cerebellar medulloblastomas certain tumor cells display immunocytochemical properties characteristic of retinal photoreceptors and pinealocytes. S‐antigen‐like and opsin‐like immunoreactions occur in nine of 28 medulloblastomas investigated. All tumors displaying S‐antigen‐like immunoreactive neoplastic cells also contain opsin‐like immunoreactive cells; however, the opsin‐like immunoreactive cells were less frequent than the S‐antigen‐like immunoreactive cells throughout all positive cases. The immunoreactive cells displayed several long processes. Generally, both S‐antigen and opsin‐like immunoreactive cells considerably vary in number among individual tumors. The results indicate that certain neoplastic cells of medulloblastoma are capable of expression of photoreceptor‐specific proteins and, thus, may be closely related to tumor cells of retinoblastoma and pineocytomas previously shown to bind antisera against retinal S‐antigen and opsin. No S‐antigen and opsin‐like immununoreaction was found in malignant teratomas and germinomas of the pineal gland, oat cell tumors, astrocytomas, ependymomas, oligodendrogliomas, glioblastomas, gangliogliomas, gangliocytoma, ganglioneuroblastomas, neuroblas‐tomas, and esthesioneuroblastoma.

Enzyme-linked immunosorbent assay for quantitative determination of the visual pigment rhodopsin in total-eye extracts.

A versatile, multispecies enzyme-linked immunosorbent assay for the rod visual pigment (rhod)opsin has been developed. For this quantitative inhibition assay a monospecific polyclonal antiserum is used which is elicited in rabbits against bovine rod outer-segment membranes. Detergent concentrations as high as 1.0% can be used in the assay with only a slight loss in sensitivity. The assay allows quantitative determination of the apoprotein opsin with a detection level of about 0.04 pmol per sample by using standards prepared by illumination of spectrophotometrically determined amounts of rhodopsin. The antiserum shows considerable cross-reactivity with opsin from several species (mouse, rat, quail, monkey and man). The high degree of monospecificity and cross-reactivity of the antiserum already allowed quantitation of opsin content in crude eye extracts of mouse, rat and quail with a sensitivity comparable to that of bovine opsin. Similar types of multispecies immunoassays for quantitation of highly conserved membrane proteins can be developed using the described approach, requiring only a monospecific antiserum elicited against an easily accessible species and crude tissue extracts both for coating and as a source of the inhibitory antigen.

Rhodopsin-induced experimental autoimmune uveoretinitis in monkeys.

We present the first evidence that purified rhodopsin can induce experimental autoimmune uveoretinitis (EAU) in monkeys. Injection of a highly purified lipid-free rhodopsin preparation provokes severe chorioretinitis with concomitant anterior uveitis. The onset of disease is earlier, its frequency is higher, and the inflammation is considerably more severe than in EAU induced under similar conditions by opsin. The first inflammatory cells are observed in the ciliary body and pars plana. Within a few days the inflammation extends into the anterior chamber, choroid, and retina. Retinitis predominates in the central area, while chorioretinitis is observed in the periphery, both accompanied by damage to and elimination of the photoreceptor cells. The monkeys develop high cellular and humoral immune responses against rhodopsin and opsin. The cellular response maximum just precedes the onset of EAU. This may indicate that cellular immunity has an important role in the pathogenesis of rhodopsin-induced EAU.

Immunoassay of rod visual pigment (opsin) in the eyes of rds mutant mice lacking receptor outer segments

In 020/A mice, homozygous for the retinal degeneration slow (rds) gene, the photoreceptor cells fail to develop outer segments, and in the absorption spectra of retinal extracts the rhodopsin peak is lacking. Application of an enzyme-linked immunoassay using antisera against bovine opsin shows, however, that opsin is present in the homozygous mutant retina (0.010 nmol/eye) at 3% of the level of the normal retina (0.38 nmol/eye) of Balb/c mice. In the retina of heterozygous mice the opsin level (0.19 nmol/eye) is about half of the normal. Detection of opsin in the rds mutant retina demonstrates the functional basis for the reported electroretinographic response and light-mediated reduction in cyclic nucleotide levels in this mutant.

Development and degeneration of retina in rds mutant mice: immunoassay of the rod visual pigment rhodopsin

Development and loss of photoreceptor cells in mice, afflicted by the rds (retinal degeneration slow) gene, was analyzed by measuring the ocular visual pigment content as rhodopsin (spectroscopy) and opsin (immunoassay). With regard to the postnatal age, where opsin was just detectable, and to the initial rate of opsin synthesis, the mutants did not strongly deviate from the normal animals. The final maximal visual pigment level was, however, about half of normal for the heterozygous mutants and about 3% of normal for the homozygous mutants, both in the pigmented and in the albino strain. In the pigmented normal or heterozygous mutant the (rhod)opsin levels remain stable up to at least 1 year of age. For the corresponding albino animals this was only observed up to 9 months of age. Thereafter the level declines. In the homozygous mutants, maximal opsin levels were observed at about 3 weeks postnatal. Subsequently, this level gradually declined to about 40% in the pigmented and about 15% in the albino mutant. The results indicate that the rds gene does not directly affect the biosynthetic pathways of opsin. The physiological effect of the rds gene is aggravated by photodamage for which the albino animal is particularly susceptible.

Experimental autoimmune uveoretinitis in rats induced by rod visual pigment: rhodopsin is more pathogenic than opsin

The rod visual pigment, rhodopsin, and its illuminated form, opsin, were used to induce experimental autoimmune uveoretinitis in rats. Rhodopsin appears to be more pathogenic than opsin. A dose of 250 μg rhodopsin injected in Freunds complete adjuvant and pertussis adjuvant induces nongranulomatous inflammation with higher frequency, which starts earlier and is more severe than that induced by opsin. Two weeks postinjection, the mean score of rhodopsin-injected animals is more than twice as high as that of opsin-injected animals. The high pathogenicity of rhodopsin appears to be related to the biochemical integrity of the protein and depends on its state of illumination. The levels of the immune responses (both cellular and humoral) measured at day 10 postinjection do not account for the pronounced difference in pathogenicity between rhodopsin and opsin. The developmental patterns of severe uveoretinitis induced by rhodopsin or opsin were histologically evaluated and appear to be similar. In both cases we observed dense mononuclear and polymorphonuclear cell infiltrations in the retina and anterior uvea. Only in the severe stages does the choroid become involved. However, rhodopsin causes more pronounced involvement of the ciliary body, pars plana, and anterior chamber. The inflammation finally results in total elimination of the photoreceptor cell layer.

A radioimmunoassay specific for opsin

A radioimmunoassay is developed for bovine opsin using a rabbit antiserum against bovine rod outer segment membranes. The assay is specific for opsin. Rhodopsin, bacteriorhodopsin and hemoglobin do not show cross-reaction. It can be carried out rapidly, has a sensitivity of 0.01 pmol bovine opsin and gives accurate results, even in the presence of a large excess of rhodopsin. Under the conditions described, the assay can be used to measure bovine opsin and rhodopsin in each others presence by running a sample before and after illumination, with a sensitivity 2000-times higher than with spectrophotometric methods. The opsin content of rather crude preparations such as bovine retina homogenates can be accurately determined. Rabbit and mouse opsin can also be assayed with a reasonable degree of accuracy using the same rabbit antiserum.