Is a neuronal chain between the pineal body and the retina in rats and hamsters? Transneural tracing studies.

Neuronal chains between the retina and the pineal body were investigated. Transneuronal tracers, retrograde spreading pseudorabies virus (labeled with green fluorescent protein, memGreen-RV) and virus spreading in both ante- and retrograde directions (labeled with red fluorescent protein, Ka-VHS-mCherry-A-RV) were injected into the right eye of vitreous body of intact or bilaterally sympathectomized Wistar male rats. Intact golden hamsters also received memGreen-RV into the eye and Ka-VHS-mCherry-A-RV into the pineal body. Four-five days later the animals were sacrificed. Frozen sections were prepared from the removed structures. In intact rats memGreen-RV resulted in green fluorescent labeling in the trigeminal and the superior cervical ganglia, the lateral horn of the spinal cord, the paraventricular and the suprachiasmatic nuclei, the perifornical region, the ventrolateral medulla, the locus ceruleus, and the raphe nuclei. In sympathectomized rats the labeling was missing from the brainstem but further existed in the hypothalamus. This observation indicates that the hypothalamic labeling is not mediated by the sympathetic system. One labeled neuron in the pineal body was only observed in 2/13 rats. It was independent from the sympathectomy. When the animals received Ka-VHS-mCherry-A-RV the distribution of the labeling was very similar to that of the intact group receiving retrograde virus. In golden hamsters the memGreen-RV labeled structures were seen in similar places as in rats, but virus labeled nerve cell bodies were always seen in the pineal body. Injection of Ka-VHS-mCherry-A-RV into the pineal body of hamsters resulted in labeling of the retina at both sides. It was concluded that the retinopetal neuronal chain in golden hamsters is always present but in rats it is stochastic.

Peripheral autonomic nerves of human pineal organ terminate on vessels, their supposed role in the periodic secretion of pineal melatonin.

Nonvisual pineal and retinal photoreceptors are synchronizing circadian and circannual periodicity to the environmental light periods in the function of various organs. Melatonin of the pineal organ is secreted at night and represents an important factor of this periodic regulation. Night illumination suppressing melatonin secretion may result in pathological events like breast and colorectal cancer. Experimental works demonstrated the role of autonomic nerves in the pineal melatonin secretion. It was supposed that mammalian pineals have lost their photoreceptor capacity that is present in submammalians, and sympathetic fibers would mediate light information from the retina to regulate melatonin secretion. Retinal afferentation may reach the organ by central nerve fibers via the pineal habenulae as well. In our earlier works we have found that the pineal organ developing from lobular evaginations of the epithalamus differs from peripheral endocrine glands and is composed of a retina-like central nervous tissue that is comprised of cone-like pinealocytes, secondary pineal neurons and glial cells. Their autonomic nerves in submammalians as well as in mammalian animals do not terminate on pineal cells, rather, they run in the meningeal septa among pineal lobules and form vasomotor nerve endings. Concerning the adult human pineal there are no detailed fine structural data about the termination of autonomic fibers, therefore, in the present work we investigated the ultrastructure of the human pineal peripheral autonomic nerve fibers. It was found, that similarly to other parts of the brain, autonomic nerves do not enter the human pineal nervous tissue itself but separated by glial limiting membranes take their course in the meningeal septa of the organ and terminate on vessels by vasomotor endings. We suppose that these autonomic vasomotor nerves serve the regulation of the pineal blood supply according to the circadian and circannual changes of the metabolic activity of the organ and support by this effect the secretion of pineal neurohormones including melatonin.

Visual pigment coexpression in all cones of two rodents, the Siberian hamster, and the pouched mouse.

PURPOSE: To decide whether the identical topography of short- and middle-wavelength cone photoreceptors in two species of rodents reflects the presence of both opsins in all cone cells. METHODS: Double-label immunocytochemistry using antibodies directed against short-wavelength (S)-and middle- to long-wavelength (M/L)-sensitive opsin were used to determine the presence of visual pigments in cones of two species of rodents, the Siberian hamster (Phodopus sungorus) and the pouched mouse (Saccostomus campestris) from South Africa. Topographical distribution was determined from retinal whole-mounts, and the colocalization of visual pigments was examined using confocal laser scanning microscopy. Opsin colocalization was also confirmed in consecutive semithin tangential sections. RESULTS: The immunocytochemical results demonstrate that in both the Siberian hamster and the pouched mouse all retinal cones contain two visual pigments. No dorsoventral gradient in the differential expression of the two opsins is observed. CONCLUSIONS: The retina of the Siberian hamster and the pouched mouse is the first example to show a uniform coexpression of M and S cone opsins in all cones, without any topographical gradient in opsin expression. This finding makes these two species good models for the study of molecular control mechanisms in opsin coexpression in rodents, and renders them suitable as sources of dual cones for future investigations on the role and neural connections of this cone type.