Ultrastructure of the pineal organ of the killifish,Fundulus heteroclitus,with special reference to the secretory function

Summary The pineal organ of the killifish, Fundulus heteroclitus, was investigated by electron microscopy under experimental conditions; its general and characteristic features are discussed with respect to the photosensory and secretory function. The strongly convoluted pineal epithelium is usually composed of photoreceptor, ganglion and supporting cells. In addition to the well-differentiated photosensory apparatus, the photoreceptor cell contains presumably immature dense-cored vesicles (140–220 nm in diameter) associated with a well-developed granular endoplasmic reticulum in the perinuclear region and the basal process. These dense-cored vesicles appear rather prominent in fish subjected to darkness. The ganglion cell shows the typical features of a nerve cell; granular endoplasmic reticulum, polysomes, mitochondria and Golgi apparatus are scattered in the electron-lucent cytoplasm around the spherical or oval nucleus. The dendrites of these cells divide into smaller branches and form many sensory synapses with the photoreceptor basal processes. Lipid droplets appear exclusively in the supporting cell, which also contains well-developed granular endoplasmic reticulum and Golgi apparatus. Cytoplasmic protrusions filled with compact dense-cored vesicles (90–220 nm in diameter) are found in dark-adapted fish. The origin of these cytoplasmic protrusions, however, remains unresolved. Thus, the pineal organ of the killifish contains two types of dense-cored vesicles which appear predominantly in darkness. The ultrastructural results suggest that the pineal organ of fish functions not only as a photoreceptor but also as a secretory organ.We thank Dr. Grace Pickford for the fishes.     

Photoreceptor cells and neural elements with long axonal processes in the pineal organ of the lamprey,Lampetra japonica,identified by use of the horseradish peroxidase method

Summary Horseradish peroxidase (HRP) was applied to the transected end of the pineal tract of the lamprey, Lampetra japonica. Distinct reaction products of HRP were observed in 2 types of cell other than ganglion cells. The first type of cell protrudes a knob-like process into the pineal lumen. This type of cell was clearly identified by electron microscopy as a photoreceptor cell; its outer segment was connected to the ellipsoid through a sensory cilium. The other type of cell was located among photoreceptor and supporting cells. The processes of these cells were thin and slender, and they obviously did not represent photoreceptor, supporting, or conventional ganglion cells. The present results indicate that, in the lamprey, some of the photoreceptor cells of the pineal organ project their axon-like processes toward the posterior commissure, but that there is also another type of cell displaying long axonal projections. HRP-containing cells were distributed randomly over the pineal organ and were occasionally also observed in the parapineal organ.     

Fine structure of the pineal organ in the troglobytic fish,Typhlichthyes subterraneous (Pisces: Amblyopsidae)

Summary The pineal organ of the blind, cave-dwelling fish, Typhlichthyes subterraneous, was examined with both light and electron microscopes. Like the eyes, the pineal in this troglobytic species was found to be regressed. Two cell types, photoreceptor and supportive cells, were described in the pineal epithelium. Although ganglion cells were not identified, small, unmyelinated nerve fibers were present. The photoreceptor cells had degenerated outer segments. Accordingly, it was suggested that the pineal in this species is not likely to function in photoreception. However, the presence of well developed Golgi bodies, clear and dense-cored vesicles, variable amounts of rough endoplasmic reticulum and glycogen particles indicated that both cell types are metabolically active and may play a role in secretion.     

Light and electron microscopic studies on the pineal organ of the dogfish,Scyliorhinus canicula L.

Summary The pineal organ of the dogfish,Scyliorhinus canicula, is a long, thin, tubular structure consisting of an end-vesicle and a stalk. The pineal parenchyma consists of receptor cells, glycogen-storing cells, supporting cells, cells containing dense granules of 1,500–3,000 Å diameter, cytosome-rich cells, and ganglion cells. The latter alledgedly give rise to the diffusely distributed pineal tract which runs to the posterior commissure. A few pineal fibres diverge to the habenular commissure. The receptor cells have well-developed outer segments with morphological features characteristic of the retinal cone. Interaction between receptor cells and ganglion cells take place in neuropil-like areas. Boutons are found which are believed to belong to the receptor cells because of the presence of occasional synaptic rods. The few synapses observed always display synaptic vesicles both pre- and post-synaptically. The functional significance of the reported morphological features is discussed with the aid of the pertinent literature and it is postulated that the pineal organ of the dogfish is a photosensitive organ.Work done with the aid of a research scolarship from the Alexander von Humboldt Foundation, Bad Godesberg, Germany. — The animal material was provided by the Stazione Zoologica di Napoli, Italy, and by the Biologische Anstalt, Helgoland, Germany. — The electron microscope used in this study was placed at the disposal of Prof.Oksche by the Deutsche Forschungsgemeinschaft.     

Pattern of synaptic connections in the pineal organ of the ayu,Plecoglossus altivelis (Teleostei)

Summary Synaptic connections were studied by means of electron microscopy in the sensory pineal organ of the ayu, Plecoglossus altivelis, a highly photosensitive teleost species. Three types of specific contacts were observed in the pineal end-vesicle: 1) symmetrically organized gap junctions between the basal processes of adjacent photoreceptor cells; 2) sensory synapses endowed with synaptic ribbons, formed by basal processes of photoreceptor cells and dendrites of pineal neurons; 3) conventional synapses between pineal neurons, containing both clear and dense-core vesicles at the presynaptic site. Based on these findings, the following interpretations are given: (i) The gap junctions may be involved in an enhancement of electric communication and signal encoding between pineal photoreceptor cells. (ii) The sensory synapses transmit photic signals from the photoreceptor cells to pineal nerve cells. (iii) The conventional synapses are assumed to be involved in a lateral interaction and/or summation of information in the sensory pineal organ. A concept of synaptic relationships among the sensory and neuronal elements in the pineal organ of the ayu is presented.Fellow of the Alexander von Humboldt Foundation, Federal Republic of Germany     

Ultrastructural observations on synaptic ribbons in the pineal organ of the goldfish

Summary Synaptic ribbons in the pineal organ of the goldfish were examined electron microscopically with particular attention to their topography. These structures were formed of parallel membranes, which were poorly preserved with OsO₄ fixation and could be extracted from thin sections with pronase indicating their proteinaceous nature. Synaptic ribbons were closely apposed to the plasma membrane bordering dendrites of ganglion cells, but were also related to processes of both photoreceptor and supportive cells. Their close proximity to invaginations of the plasma membrane and portions of the endoplasmic reticulum suggest that they are involved in the turnover of cytoplasmic membranes. Tubular and spherical organelles of unknown function are also described.     

The sensory innervation of the pineal organ in the lizard,Lacerta viridis,with remarks on its position in the trend of pineal phylogenetic structural and functional evolution

Summary The sensory innervation of the pineal organ of adult Lacerta viridis has been investigated. Some specimens of Lacerta muralis lillfordi were also used. In the pineal epithelium, a small number of nerve cell pericarya of a sensory type are present. They lie either solitary or in small clusters close to the basement membrane. The axons originating from the nerve cell bodies, i. e. the pineal sensory nerve fibers, first course in the intraepithelial nerve fiber layer which is only locally present and contains a restricted number of unmyelinated fibers. In Lacerta viridis, the pineal fibers generally leave the epithelium at the proximal part of the organ proper. They then form small bundles which run along the outer surface of the basement membrane in the leptomeningeal connective tissue covering. At the proximal end of the pineal stalk the single bundles assemble constituting the pineal nerve. In Lacerta muralis the fibers leave the pineal epithelium at the proximal end of the stalk running farther down within the epithelium. Many fibers become myelinated after leaving the pineal epithelium. The pineal nerve runs ventralward in the midplane just caudal to the habenular commissure to which no fibers are given off. Continuing their ventralward course between the habenular commissure and the rostral end of the posterior commissure which is traversed by some of them, the pineal fibers reach the dorsal border of the subcommissural organ. Small separate aberrant pineal bundles traverse the posterior commissure at various more caudal levels. Having reached the dorsal border of the subcommissural organ, part of the pineal fibers continue their ventralward course directly running along the lateral sides of this organ to reach the periventricular nerve fiber layer lateral and ventral to it. A restricted number of fibers first turns in a caudal direction running between the base of the posterior commissure and the base of the subcommissural organ before turning ventralward to reach the periventricular layer. Most probably, pineal fibers do neither join the posterior commissural system nor innervate the subcommissural organ. Once having reached the periventricular layer, some pineal fibers curve in a rostral direction while others, before doing so, send a collateral in a caudal direction. Both, the main fibers and the collaterals, contribute to the formation of the periventricular layer. The sites of termination of the pineal fibers could not be ascertained.From the presence of intraepithelial sensory nerve cell bodies and from literature data on the ultrastructure of pineal neurosensory cells it is concluded that the adult pineal organ of Lacerta has a, although rudimentary, (photo)sensory function. The demonstration by our guest-worker Dr. W. B. Quay, of the intraepithelial presence of a tryptamine compound, probably serotonin, points, moreover, to a secretory function of this organ.In adult Lacerta a well-developed parietal nerve connects the parietal eye with the left lateral habenular nucleus. It traverses the habenular commissure.In gratitude and with admiration this paper is dedicated to Prof. Berta Scharrer and to the memory of Prof. Ernst Scharrer.     

The pineal complex of the three-spined stickleback,Gasterosteus aculeatus L.

Summary The pineal complex of the three-spined stickleback (Gasterosteus aculeatus L.) was investigated by light and electron microscopy, as well as fluorescence histochemistry for demonstration of catecholamines and indolamines. The pineal complex of the stickleback consists of a pineal organ and a small parapineal organ situated on the left side of the pineal stalk. The pineal organ, including the entire stalk, is comprised mainly of ependymal-type interstitial cells and photoreceptor cells with well-developed outer segments. Both unmyelinated and myelinated nerve fibres are present in the pineal organ. Nerve tracts from the stalk enter the habenular and posterior commissures. A small bundle of nerve fibres connects the parapineal organ and the left habenular body. The presence of indolamines (5-HTP, 5-HT) was demonstrated in cell bodies of both the pineal body and the pineal stalk, and catecholaminergic nerve fibres surround the pineal complex.     

A pineal ganglion associated with the pineal tract in the domestic fowl

Summary A ganglion-like aggregate consisting of acetyl-cholinesterase-positive neurons was demonstrated in the pineal organ of the domestic fowl by means of light and electron microscopy. This ganglion is located in juxtaposition with the pineal tract at the posterior (caudal) aspect of the pineal stalk. Numerous large and small neurons formed the ganglion in 40-day-old domestic fowl. Some of these nerve cells established direct neuro-neuronal contacts, others were surrounded by satellite cells. These ganglion cells displayed axo-somatic and axo-dendritic synapses. The above-mentioned cluster of nerve cells may be considered as a pineal ganglion. Its central or peripheral nature is open to discussion. Send offprint requests to: Dr. K. Wake, Department of Anatomy, Faculty of Medicine, Tokyo Medical and Dental University, Yushima, Bunkyo-ku, 113, Japan     

Structure of the parapineal organ of the adult rainbow trout,Salmo gairdneri Richardson

Summary The parapineal organ of the teleost Salmo gairdneri Richardsonsu1 was investigated with the light and electron microscopes. It is a small cell mass, 0.1–0.3 mm in diameter, containing a narrow lumen and consistently situated to the left of the pineal stalk and dorsal to the left habenular nucleus. It is connected with the habenular nucleus through a conspicuous parapineal tract. The parapineal organ continues to grow at least until the fish reaches sexual maturity and shows no sign of cellular degeneration at the age of two years.The parapineal tissue consists of supporting cells and nerve cells; the latter give rise to the axons of the parapineal tract. Furthermore, a small number of receptor cells of the type existing in the pineal organ is present. No morphological evidence was obtained to suggest a sensory or secretory function of the parapineal organ.The existence of the parapineal organ in the adult pike, Esox lucius, L., and of a connection between the pineal tract and the habenular commissure in Salmo gairdneri is briefly reported. The results are discussed in the light of existing literature.Work done with the aid of a research scholarship from the Alexander von Humboldt Foundation, Bad Godesberg, Germany. —The electron microscope used in this study was placed at the disposal of Prof. Oksche by the Deutsche Forschungsgemeinschaft. —I wish to thank Prof. Oksche for the facilities made available at his institute and for his helpful interest in my work.     

Acetylcholinesterase-containing nerve cells and their distribution in the pineal organ of the goldfish,Carassius auratus

Summary Histochemically, an intense acetylcholinesterase (AChE) reaction has been observed in the perikarya of the nerve cells and in the neuropil formations of the pineal organ in the goldfish, Carassius auratus. A group of AChE-rich nerve cells has also been observed between the caudal end of the pineal stalk and the habenular ganglion. No component of the complex revealed butyrylcholinesterase (BuChE) activity.Two different types of nerve cells were recognized on the basis of their size, AChE activity and distribution. Type I cells are characterized by large perikarya possessing a moderate AChE activity and by the presence of an extensive AChE-rich neuropil formation in their vicinity; they are restricted to the rostro-lateral regions of the pineal vesicle. Type II cells are situated in the medio-rostral area of the pineal vesicle and along the entire length of the stalk, and are smaller than Type I cells; they show an intense AChE activity in their perikarya.The neuropil formations in the medio-rostral area of the pineal vesicle are almost as large as those in the vicinity of the Type I cells; they exhibit a strong AChE activity. In the rostral half of the vesicle several sensory cells are associated with each nerve cell, while in the caudal portion only a few cells are apposed to each nerve cell. Thus, the ratio of the number of sensory cells to that of AChE-containing nerve cells in the anterior half of the pineal vesicle is high when compared with the remaining area. In the anterior half of the vesicle the outer segments of the sensory cells are more distinct and their inner segments possess a higher AChE activity than those in the posterior region and the stalk. A gradation in the degree of development of neuropil formations along the pineal axis is remarkable; their size and AChE activity gradually diminish in a caudal direction. In view of the structural specialization of the rostral region of the pineal organ, it has been argued that its terminal portion is more photosensitive.This work was supported by a fellowship from the Alexander von Humboldt Foundation, Federal Republic of Germany.     

The structure of the pineal organ of the bluefin tuna, Thunnus thynnus

The pineal organ of the bluefin tuna was studied using light and electron microscopy. The pineal, an evagination in the diencephalic pallium, consists of a distal expanded end-organ and a stalk. A pineal nerve connects this end-organ to the habenular area of the diencephalon. The tissues above the pineal are modified for light transmission. Supporting cells are the most numerous type seen in the pineal tissue. The cytoplasm often contains glycogen, while the golgi apparatus is seldom seen. The plasma membrane is a complex of folded membranes interdigitating with adjacent cells. The sensory cells are characterized by a basal nucleus, a constricted neck region, and an ellipsoid region that is capped distally by lamellae. Sensory cells have the basic appearance of retinal photoreceptors. The lamellae are more disorganized than those of retinal rods, and some lamellae appear to be discharged from the cell. This study indicates that the pineal may function to deliver photoperiodic stimuli to the central nervous system, through the transmission of nerve impulses.     

Melatonin modulates the neural activity in the photosensory pineal organ of the trout: Evidence for endocrine-neuronal interactions

Summary Hormonal and neural signals transmitted from the pineal organ to the brain in cold-blooded vertebrates presumably convert information about the ambient illumination into signals which may be used to mediate photoperiodic and circadian responses. The possible intrapineal function of melatonin was investigated by recording intra- and extracellularly from photoreceptors and second-order neurons in the isolated superfused pineal organ of the trout (Salmo gairdneri). Melatonin added through the perfusion bath to the explanted pineal organ caused a dose-related and reversible inhibition of ganglion cells of the luminance type whereas the hormone did not significantly affect the membrane potential of photoreceptors and their light-evoked response. The observed effects seem to be independent from photoperiod and adaptation conditions. These results suggest that melatonin provides a feedforward signal to intrapineal neurons regulating the neural output of the organ.Laboratory of Fish Biology, School of Agriculture, Nagoya University, Chikusa, Nagoya 464 Japan     

Responses of pineal photoreceptors in the brook and rainbow trout

Summary Electron microscopy of the pineal receptor cells in light- and dark-adapted brook trout, Salvelinus fontinalis and the rainbow trout, Salmo gairdneri, revealed no significant differences in the tubular and filamentous elements of the inner segment, neck and supranuclear regions. However, changes in synaptic relations between the photoreceptor and nerve cell were induced by light and darkness. In the light-adapted state, the synaptic relationship between axon terminals and photoreceptor basal processes predominates, while in darkness the synapses between photoreceptor basal processes and ganglion cell dendrites are more prominent. Further, in darkness, the photoreceptor basal processes show a number of synaptic vesicles and synaptic ribbons. These findings suggest that the sensory function of the fish pineal is enhanced during darkness but inhibited by light, and that the synaptic relationships are involved in the control of sensory activity in the pineal photoreceptor and ganglion cells. These results corroborate those of electrophysiological studies in that the maximal spontaneous discharge frequency of the ganglion cells occurs in the dark, and it also shows a burst when light is removed. The typical chemical synapse between the axon terminal and the photoreceptor basal process in light seems to function as an inhibitor.The authors thank Dr. Mary Ann Klyne for her assistance in several aspects of this work. Financial assistance was provided by the NSERC of Canada and the Ministry of Education of Québec     

Morphology of the pineal organ in the salamander Ensatina eschscholtzi

The pineal organ of Ensatina eschscholtzi, a terrestrial and secretive species of salamander of the family Plethodontidae, is a photoreceptive structure lying on the dorsal surface of the diencephalon. The pineal is flattened with a broad lumen and consists of three cell types: photoreceptors, supportive cells, and neurons. Pineal photoreceptors are typical vertebrate photoreceptors and possess outer segment formations which, however, are frequently contorted and disorganized. Sloughing of apical portions of outer segments and vesiculation along the lateral edges of outer segment membrane disks are consistently observed and presumed to represent mechanisms of outer segment membrane recycling. Photoreceptors have basal processes which synapse with neural dendrites. Synapses between photoreceptor basal processes are occasionally observed. All synapses are characterized by synaptic ribbon structures of variable number, size, and configuration. Dense-core vesicles are occasionally observed mingled with clear synaptic vesicles within photoreceptor basal processes. Supportive cells within the pineal function in phagocytosis and recycling of shed outer segment membrane material, and neurons are localized at the lateral margins of the organ. The latter send axons into the ipsilateral side of the dorsal diencephalon. The pineal organ of Ensatina shows marked variation in overall size (cell total), cell type proportions, absolute neuron number, and ratio of photoreceptor number to neuron number for individual pineals. None of these morphological parameters is correlated with body size, sex, or season, and it is assumed that such variability represents significant variation in photosensory capabilities. It is suggested that the pineal organ of Ensatina is a partially degenerate photoreceptive structure.     

Post-natal development of the pineal organ in the hamsters Phodopus sungorus and Mesocricetus auratus

Summary In Phodopus sungorus, as in other mammals, the pineal organ forms an important link in the transduction of photoperiodic information to the endocrine system. The sympathetic innervation, via the superior cervical ganglion, controls the metabolism of serotonin and melatonin in the pineal, which in turn is involved in the control of the gonads. In the present study, the post-natal development of this system was investigated. Specimens 1, 5, 10, and 15 days post partum (p.p.) and adults were treated with monoamine-oxidase-inhibitor and perfused under ether anesthesia via the aorta with a buffer containing glyoxylic acid, formaldehyde and Mg⁺⁺. The brains were then dissected out and treated according to Falck-Hillarp for fluorescence microscopy and microspectrofluorometry. Day 1: The nervi conarii had reached the pineal capsule, but only in a few cases was the pineal organ invaded and then only by a few fibers. Day 5: A rich green-fluorescing net of fibers was present in the entire organ, stalk and lamina intercalaris. No 5-HT fluorescence was observable. Day 10: Similar to the stage at 5 days a rich green-fluorescing nerve fiber net was observed throughout the pineal and a yellow fluorescence in the pineal perikarya. Day 15: The general appearance resembles the adult. The nerve fibers are masked by the intense yellow fluorescence of the pineal perikarya. Fading of the latter, however, allows the catecholamine fluorescence to be seen. Golden hamsters at an age of 15 days p.p. show a similar appearance to Phodopus at an age of 15 days. Microspectrofluorometric determinations indicated the catecholamine to be noradrenaline, and confirmed a 5-HT/5-HTP origin of the yellow fluorescence appearing between day 5 and day 10. The amount of 5-HT/5-HTP was considerably less at day 10 than at day 15 or in adults. Sympathectomy by extirpation of the superior cervical ganglion abolished the catecholamine fluorescence completely in the pineal body, stalk and lamina intercalaris.Supported by grants from the Swedish Natural Science Research Council (to P. Meurling and Th. van Veen), and the Royal Physiographic Society of Lund     

Microvasculature of the pineal organ of the rainbow trout (Salmo gairdneri)

Summary The angioarchitecture of the pineal organ of the rainbow trout (Salmo gairdneri) was investigated by means of the corrosion-cast preparation method and scanning electron microscopy. Two main arteries (aa. epiphyseales) supply the pineal parenchyma. They emerge from the aa. cerebri anteriores and run in the fissure between the prosencephalon and the mesencephalon. After entering the pineal stalk, the aa. epiphyseales branch off into several arterioles, most of which extend to the pineal end-vesicle where they give rise to a lobular, bilaterally symmetric capillary network. Capillaries establishing the main portion of the pineal vessels appear widened in comparison to those supplying other portions of the brain and resemble capillaries in other endocrine organs. In Salmo gairdneri, no specialized system of portal vessels appears to exist between the pineal organ and other portions of the brain.     

Influence of light and darkness on the ultrastructure of the pineal organ in the blind cave fish,Astyanax mexicanus

Ultrastructural changes of the pineal organ were investigated in the blind cave fish, Astyanax mexicanus, kept under continous artificial light (5000 lux), in continuous darkness, and under natural light conditions. The pineal end-vesicle of the fish kept under natural photoperiod consisted of photoreceptor cells and supporting cells mixed with a few ganglion cells. The photoreceptor cells possessed well-developed outer segments with regularly arranged lamellar membranes. The supporting cells contained a number of lipid droplets and large globular cisternae filled with fine granules. In the fish kept under continuous light or in darkness, the pineal end-vesicle displayed a dilated lumen, and the outer segments of the receptors showed signs of degeneration. Furthermore, alterations of cell organelles were observed in the photoreceptor and supporting cells.     

Vascular permeability (problem of the blood-brain barrier) in the pineal organ of the rainbow trout,Salmo gairdneri

Summary The problem of the blood-brain barrier in the pineal organ of the rainbow trout, Salmo gairdneri, was investigated following intraperitoneal or intracardial injections of several tracers and dyes with different molecular weights. As demonstrated at the light-microscopic level, repeated injections of trypan blue or horseradish peroxidase (HRP) resulted in an accumulation of these substances in the pineal epithelium (parenchyma). By use of the electron microscope, HRP was found in electron-dense bodies, probably lysosomes, in (i) the endothelial cells and perivascular macrophages 4 h after intraperitoneal injection, (ii) the supporting cells and intrapineal or luminal macrophages 8 h after injection, and (iii) the receptor cells 24 h after injection of the tracer. Ferritin particles penetrated the fenestrated endothelium of pineal capillaries. They were confined to vesicles, vacuoles and the smooth endoplasmic reticulum of the supporting cells as well as to the synaptic vesicles and the smooth endoplasmic reticulum of the pineal photoreceptors. The intercellular passage of tannic acid mixed with the fixative was blocked at the luminal junctional complex separating the pineal lumen from the basal portion of the pineal epithelium. The passive intercellular transport of substances with high molecular weight from the bloodstream to the cerebrospinal-fluid compartment is thus prevented. However, no blood-brain barrier exists for exogenously administered proteins, which are rapidly taken up by pineal cells and actively transported in a transcellular manner.The findings on the blood-brain barrier of the pineal organ of the rainbow trout are discussed with particular reference to the endocrine capacity of pineal sensory organs.Fellow of the Alexander von Humboldt Foundation, Federal Republic of Germany.     

Cholinergic and GABAergic neuronal elements in the pineal organ of lampreys, and tract-tracing observations of differential connections of pinealofugal neurons

The putative cholinergic and GABAergic elements of the pineal organ of lampreys were investigated with immunocytochemistry to choline acetyltransferase (ChAT) and γ-aminobutyric acid (GABA), and by acetylcholinesterase (AChE) histochemistry. For comparison we also carried out immunocytochemistry to serotonin (5-HT) and a tract-tracing investigation of the two types of projecting cells, i.e., ganglion cells and long-axon photoreceptors. Most photoreceptors were ChAT-immunoreactive (ChAT-ir) and AChE-positive, while ganglion cells and the pineal tract were ChAT-negative and AChE-negative or only faintly positive. These results strongly suggest the presence of a cholinergic system of photoreceptors in the lamprey pineal organ. GABA-ir fibers that appear to originate from faintly to moderately stained ganglion cells were observed in the pineal stalk. Immunocytochemistry to 5-HT indicated the presence of two types of 5-HT-ir cells, bipolar cells and ganglion-like cells. The connections of the ganglion cells and long-axon photoreceptors were also studied by application of DiI to the pineal stalk in fixed brains or of biotinylated dextran amine (BDA) to one of the main targets of pinealofugal fibers (optic tectum or mesencephalic tegmentum) in isolated brains in vitro. Some long-axon photoreceptors and ganglion cells were labeled from the optic tectum. However, BDA application to the tegmentum exclusively labeled ganglion cells in the pineal organ. These results indicate that the two morphological types of afferent pineal neuron have different projections. No labeled cells were observed in the parapineal organ in BDA experiments, indicating that this organ and the pineal organ are involved in different neural circuits.