Cytodifferentiation of the chick pineal gland, with special reference to the photosensory and secretory elements

Developmental morphology of the turkey pineal gland in histological images and 3D models

The histological structure of the avian pineal gland during embryonic life has so far only been studied in chickens. It is known that the pineal organs of hatched chickens and turkeys differ significantly from each other based on their morphology and physiology. The aim of the present study was to investigate the histological structure of the embryonic pineal gland of domestic turkeys. The study was performed on turkey embryos aged 4-28 days. Along with histological analyses, three-dimensional (3D) images of the pineal glands from embryos aged 6-28 days were also obtained. In four-day-old embryos [embryonic day (ED) 4], primary evagination of the pineal gland from the neuroectoderm of the diencephalon was observed. On ED 6, the evagination formed a pineal recess with a thick and folded wall. In the next embryonic stages, the pineal recess was lengthened to the pineal canal, with the lumen opening to the third ventricle. The connection of the pineal lumen with the ventricular lumen was observed in all studied embryos. The first cellular rosettes without the lumen separated from the wall of the pineal recess occurred on ED 6. Several small and round follicles containing their own lumens were visible on ED 8. On ED 10, the pineal parenchyma was composed mainly of small, round follicles. The first oval follicles appeared on ED 12 and branched follicles appeared on ED 16. In some embryos at different stages, follicles formed from secondary evaginations of the diencephalon epithelium were observed. The turkey pineal organ maintained the follicular type of parenchyma without solid cellular aggregates throughout embryonic life. The pineal follicles originated from: 1) rosettes arising from the wall of the pineal canal (from ED 6); 2) an accessory evagination occurring in the neuroectoderm anteriorly and posteriorly to the pineal canal end (from ED 6); 3) direct development in the walls of larger follicles and detaching from them in a manner similar to the budding process (from ED 14); and 4) fusion of smaller follicles into branched ones. The pineal capsule started to develop on ED 6, first as a vascularization and later as a thin mesenchymal outline around the apical part, then at the dorsal and at the end the ventral part of the pineal gland. The pineal stroma was composed of mesenchymal tissue consisting of abundant in cells and blood vessels. The first evagination of the choroid plexus in the diencephalon was observed on ED 8. The attachment of the pineal gland to the dura mater first occurred on ED 16. Finally, the pineal gland of ED 28 embryos consisted of a wide proximal part attached to the dura mater and a narrow distal part that extended into the pineal stalk, which extended to the intercommissural region of the diencephalon. The present study revealed the occurrence of significant morphological differences in the developing embryonic pineal gland of turkeys compared with chickens.

Developmental morphology of the turkey pineal organ. Immunocytochemical and ultrastructural studies

Our previous study showed that the turkey pineal organ, in contrast to that of the chicken, is characterized by a follicular structure throughout the entire period of post-hatching life. Despite the preservation of the follicular organization, the histological structure of the pineal follicles in turkeys changes prominently with age. The present research was performed to investigate the cellular composition and organization of the follicle wall as well as the ultrastructure of parenchymal cells in the turkey pineal organ during the period of post-hatching development. Pineal organs were collected from female turkeys at 2 days, 2 weeks, 4 weeks, 10 weeks, 20 weeks, 30 weeks, 40 weeks, and 56 weeks post-hatching. The organs were prepared for immunocytochemical studies using antibodies against N-acetylserotonin O-methyltransferase (ASMT), glial fibrillary acidic protein (GFAP) and proliferating cell nuclear antigen (PCNA) and for ultrastructural examination. The results showed that regardless of age, the pineal follicle was formed by ASMT-immunopositive cells, among which rudimentary photoreceptor and secretory pinealocytes were identified. The second component of the follicle wall consisted of GFAP-immunopositive cells, as represented by ependymal-like and astrocyte-like cells. Rudimentary photoreceptor pinealocytes and ependymal-like cells formed the inner part of the follicle wall, while secretory pinealocytes and astrocyte-like cells created the outer part. Three forms of the pineal follicle structure characteristic of young (two days to ten weeks), young adult (20-30 weeks) and adult (40-56 weeks) turkeys were distinguished. These forms primarily differed in the relative dimensions of the inner and outer parts of the follicle wall. Ultrastructural studies showed prominent changes in the organization of rudimentary receptor pinealocytes during the investigated period of life. These cells developed until the age of 20 weeks, at which time they appeared as strongly elongated cells with a stratified, highly regular distribution of organelles. In adult turkeys, rudimentary receptor pinealocytes showed pronounced regressive changes; however, we never observed their transformation into cells of the secretory type. Secretory pinealocytes increased in number and size during the post-hatching period, which was especially pronounced after 20 weeks of age. The most prominent changes in the supporting cells included the intensification of GFAP-immunoreactivity due to the accumulation of filaments in the cytoplasm and the development of astrocyte-like cells. The increase in the number of secretory pinealocytes and astrocyte-like supporting cells resulted in the formation of two distinct parts of the follicle wall in the pineal organs of young adult and adult turkeys.

Eye and heart morphogenesis are dependent on melatonin signaling in chick embryos

Calmodulin is vital for chick embryos morphogenesis in the incubation time 48-66 h when the rudimentary C-shaped heart attains an S-shaped pattern and the optic vesicles develop into optic cups. Melatonin is in the extraembryonic yolk sac of the avian egg; melatonin binds calmodulin. The aim of this study was to investigate the function of melatonin in the formation of the chick embryo optic cups and S-shaped heart, by pharmacological methods and immunoassays. Mel1a melatonin receptor immunofluorescence was distributed in the optic cups and rudimentary hearts. We separated embryonated chicken eggs at 48 h of incubation into basal, control and drug-treated groups, with treatment applied in the egg air sac. At 66 h of incubation, embryos were excised from the eggs and analyzed. Embryos from the basal, control (distilled water), melatonin and 6-chloromelatonin (melatonin receptor agonist) groups had regular optic cups and an S-shaped heart, while those from the calmidazolium (calmodulin inhibitor) group did not. Embryos from the luzindole (melatonin receptor antagonist) and prazosin (Mel1c melatonin receptor antagonist) groups did not have regular optic cups. Embryos from the 4-P-PDOT (Mel1b melatonin receptor antagonist) group did not have an S-shaped heart. Previous application of the melatonin, 6-chloromelatonin or forskolin (adenylate cyclase enhancer) prevented the abnormal appearance of chick embryos from the calmidazolium, luzindole, prazosin and 4-P-PDOT groups. However, 6-chloromelatonin and forskolin only partially prevented the development of defective eye cups in embryos from the calmidazolium group. The results suggested that melatonin modulates chick embryo morphogenesis via calmodulin and membrane receptors.

Morphological studies of the pineal gland in the common gull (Larus canus) reveal uncommon features of pinealocytes

The avian pineal is a directly photosensory organ taking part in the organization of the circadian and seasonal rhythms. It plays an important role in regulation of many behavior and physiological phenomena including migration. The aim of the study was to investigate morphology of the pineal organ in the common gull (Larus canus). The light and electron microscopic studies were performed on the pineals of juvenile birds living in natural conditions of the Baltic Sea coast, which have been untreatably injured during strong storms in autumn and qualified for euthanasia. The investigated pineals consisted of a wide, triangular, superficially localized distal part and a narrow, elongated proximal part, attached via the choroid plexus to the intercommissural region of the diencephalon. The accessory pineal tissue was localized caudally to the choroid plexus. Based on the histological criteria, the organ was classified as the solid-follicular type. Two types of cells of fotoreceptory line were distinguished: rudimentary-receptor pinealocytes and secretory pinealocytes. Both types of cells were characterized by unusual features, which have been not previously described in avian pinealocytes: the presence of paracrystalline structures in the basal processes and their endings, the storage of glycogen in the form of large accumulations and the arrangement of mitochondria in clusters. Further studies on other species of wild water birds dwelling in condition of cold seas are necessary to explain if the described features of pinealocytes are specific for genus Larus, family Laridae or a larger group of water birds living in similar environmental conditions.

Circadian melatonin production develops faster in birds than in mammals

The development of circadian rhythmicity of melatonin biosynthesis in the pineal gland starts during embryonic period in birds while it is delayed to the postnatal life in mammals. Daily rhythms of melatonin in isolated pinealocytes and in intact pineal glands under in vivo conditions were demonstrated during the last third of embryonic development in chick embryos, with higher levels during the dark (D) than during the light (L) phase. In addition to the LD cycle, rhythmic temperature changes with the amplitude of 4.5°C can entrain rhythmic melatonin biosynthesis in chick embryos, with higher concentrations found during the low-temperature phase (33.0 vs 37.5°C). Molecular clockwork starts to operate during the embryonic life in birds in line with the early development of melatonin rhythmicity. Expression of per2 and cry genes is rhythmic at least at day 16 and 18, respectively, and the circadian system operates in a mature-like manner soon after hatching. Rhythmic oscillations are detected earlier in the central oscillator (the pineal gland) than in the peripheral structures, reflecting the synchronization of individual cells which is necessary for detection of the rhythm. The early development of the circadian system in birds reflects an absence of rhythmic maternal melatonin which in mammals synchronizes physiological processes of offspring. Developmental consequences of modified development of circadian system for its stability later in development are not known and should be studied.

LIM homeodomain proteins Islet-1 and Lim-3 expressions in the developing pineal gland of chick embryo by immunohistochemistry

LIM homeodomain proteins Islet-1 and Lim-3 expression and their role in nervous tissue and endocrine glands have been reported; however, nothing is known concerning Islet-1 and Lim-3 expression in the developing pineal gland of the chick embryo. The aim of the present study was to determine the ontogeny of Islet-1 and Lim-3 expression in the developing pineal gland of chick embryo using immunohistochemistry. The results showed that Islet-1 and Lim-3 immunopositive cells were first detected in the pineal evagination of chick embryos at day 4 (E4) and E4.5 of incubation, respectively. In the later developing stages, both Islet-1 and Lim-3 immunopositive cells were consistently detected in the follicular and parafollicular pinealocytes throughout the pineal gland. The relative percentage of Islet-1 immunopositive (Islet-1+) cells relative to the total cells was about 6% at E4.5, and then kept increasing (P < 0.05) and reached about 40% by E12.5; this was followed by no obvious changes until the chicks were newly hatched. The change in Lim-3 immunopositive (Lim-3+) cell number was parallel to that of Islet-1, although Lim-3+ cell were significantly fewer than Islet-1+ cell numbers from E4.5 to E8.5 (P < 0.05). Dual immunohistochemical staining results showed that almost all the Lim-3+ cells expressed Islet-1 at every stage examined, and about 90% of Islet-1+ cells were proliferating cell nuclear antigen negative. These results suggest that both Islet-1 and Lim-3 may be involved in regulating the development and functional maturation of the pineal gland, although further studies are required in elucidating the functional roles of Islet-1 and Lim-3 and the related mechanisms.

Evolution of photosensory pineal organs in new light: the fate of neuroendocrine photoreceptors

Pineal evolution is envisaged as a gradual transformation of pinealocytes (a gradual regression of pinealocyte sensory capacity within a particular cell line), the so-called sensory cell line of the pineal organ. In most non-mammals the pineal organ is a directly photosensory organ, while the pineal organ of mammals (epiphysis cerebri) is a non-sensory neuroendocrine organ under photoperiod control. The phylogenetic transformation of the pineal organ is reflected in the morphology and physiology of the main parenchymal cell type, the pinealocyte. In anamniotes, pinealocytes with retinal cone photoreceptor-like characteristics predominate, whereas in sauropsids so-called rudimentary photoreceptors predominate. These have well-developed secretory characteristics, and have been interpreted as intermediaries between the anamniote pineal photoreceptors and the mammalian non-sensory pinealocytes. We have re-examined the original studies on which the gradual transformation hypothesis of pineal evolution is based, and found that the evidence for this model of pineal evolution is ambiguous. In the light of recent advances in the understanding of neural development mechanisms, we propose a new hypothesis of pineal evolution, in which the old notion 'gradual regression within the sensory cell line' should be replaced with 'changes in fate restriction within the neural lineage of the pineal field'.

Comparative ultrastructure and cytochemistry of the avian pineal organ

The breeding of birds is expected to solve problems of nourishment for the growing human population. The function of the pineal organ synchronizing sexual activity and environmental light periods is important for successful reproduction. Comparative morphology of the avian pineal completes data furnished by experiments on some frequently used laboratory animals about the functional organization of the organ. According to comparative histological data, the pineal of vertebrates is originally a double organ (the "third" and the "fourth eye"). One of them often lies extracranially, perceiving direct solar radiation, and the other, located intracranially, is supposed to measure diffuse brightness of the environment. Birds have only a single pineal, presumably originating from the intracranial pineal of lower vertebrates. Developing from the epithalamus, the avian pineal organ histologically seems not to be a simple gland ("pineal gland") but a complex part of the brain composed of various pinealocytes and neurons that are embedded in an ependymal/glial network. In contrast to organs of "directional view" that develop large photoreceptor outer segments (retina, parietal pineal eye of reptiles) in order to decode two-dimensional images of the environment, the "densitometer"-like pineal organ seems to increase their photoreceptor membrane content by multiplying the number of photoreceptor perikarya and developing follicle-like foldings of its wall during evolution ("folded retina"). Photoreceptor membranes of avian pinealocytes can be stained by antibodies against various photoreceptor-specific compounds, among others, opsins, including pineal opsins. Photoreceptors immunoreacting with antibodies to chicken pinopsin were also found in the reptilian pineal organ. Similar to cones and rods representing the first neurons of the retina in the lateral eye, pinealocytes of birds possess an axonal effector process which terminates on the vascular surface of the organ as a neurohormonal ending, or forms ribbon-containing synapses on pineal neurons. Serotonin is detectable immunocytochemically on the granular vesicles accumulated in neurohormonal terminals. Pinealocytic perikarya and axon terminals also bind immunocytochemically recognizable excitatory amino acids. Peripheral autonomic fibers entering the pineal organ through its meningeal cover terminate near blood vessels. Being vasomotor fibers, they presumably regulate the blood supply of the pineal tissue according to the different levels of light-dependent pineal cell activity.

Immunocytochemical identification of pinopsin in pineal glands of chicken and pigeon

Pinopsin is a blue-sensitive photoreceptive molecule possibly involved in photic entrainment of the circadian pacemaker in the chicken pineal gland. To characterize pinopsin as a circadian photoreceptor, antibodies were raised against the C-terminal portion of pinopsin. As expected from the divergence of the amino acid sequence of this region, the resultant antibody cross-reacted with neither chicken rhodopsin nor red-sensitive cone pigment (chicken red). In Western blot analysis, the antibody stained a single band of 42-kDa protein in a detergent-extract of chicken pineal membranes, suggesting that pinopsin (calculated molecular weight, 38187) might be glycosylated and/or palmitoylated. Immunocytochemical examination of pineal sections of the chicken and the pigeon with this antibody revealed strong positive images for most of the membrane structures in the lumen of the follicles. This antibody also stained string- and bulb-shaped structures of the chicken parafollicular cells, the morphology of which resembles those of retinal photoreceptor cells. In contrast to the predominant distribution of pinopsin, a monoclonal antibody specific for chicken red stained a smaller number of membrane structures in the lumen of chicken pineal follicles. These results strongly suggest that the chicken pineal gland contains at least two types of photoreceptive molecules, pinopsin (major) and chicken red (minor). We show that the former molecule is localized in parafollicular pinealocytes and in the outer segments of pinealocytes that make contact with the follicular lumen.

Hydroxyindole-O-methyltransferase gene expression in the pineal gland of chicken embryo: development of messenger RNA levels and regulation by serum

Hydroxyindole-O-methyltransferase (HIOMT), the enzyme which catalyzes the final step of melatonin biosynthesis, constitutes a marker of the functional differentiation of pineal cells. In addition, a day/night rhythm of HIOMT mRNA concentration, previously described in the chicken pineal gland [6], would suggest that HIOMT gene transcription is one output of the circadian system that controls pineal function. The study sought to monitor the developmental expression of HIOMT mRNA in the chick pineal gland and to investigate a possible role of instructive signals in this differentiation process. RT-PCR analysis indicated that HIOMT mRNA is expressed at embryonic day 8 (E8). At E12, HIOMT mRNA became detectable on northern blots and traces of HIOMT activity could be measured. HIOMT mRNA concentration increased 100-fold between E14 and day 10 post-hatch, then levelled off. A day/night rhythm of HIOMT mRNA concentration was readily observed in the pineal gland of 2-day-old chicks. Pineal glands isolated on minimum culture medium at E11 stopped developing HIOMT gene expression. However, the addition of serum to the culture medium restored HIOMT mRNA concentration to the levels observed in vivo. The data suggest that the functional differentiation of melatoninergic cells observed during the second week of embryonic life may be controlled [correction of controled] by serum factors.

Phototransduction-related circadian changes in indoleamine metabolism in the chick pineal gland in vivo

The purpose of this study was to examine the day/night levels of pineal melatonin and its rate limiting enzyme N-acetyltransferase (NAT) in relationship to the ratio of 11-cis- to all-trans-retinal. Three-week-old chicks were placed in 12:12 light:dark (LD 12:12) cycle for one week, pineals were collected during the light phase at 1500 (i.e., after 10 hr light), during the dark phase at 1900 (i.e., 2 hr after dark), at 2100 (i.e., 4 hr after dark), and at 2300 (i.e., 6 hr after dark) and after light extension to 1900. The results show that light-sensitive 11-cis-retinal in the chick pineal has the same diurnal rhythm as NAT and melatonin; all constituents increased within 2 hr of darkness onset (at 1900) and reached their peak after 4 hr of dark. All values were lowest during the light phase at 1500. Low values for 11-cis-retinal, NAT, and melatonin were also seen in the group of chicks which experienced light extension to 1900. The data indicate that in vivo light plays a major role in triggering rhodopsin-bound 11-cis-retinal production within 2-4 hr after darkness onset; this change likely serves as the signal for the subsequent formation of the hormonal product of the pineal gland, melatonin.

Long-term effects of constant light or darkness on chicken pineal hydroxyindole-O-methyltransferase expression: biochemical and cellular aspects

1. Chickens kept in constant light, as opposed to constant darkness, display a twofold increase in the activity of pineal hydroxyindole-O-methyltransferase (HIOMT), the last acting enzyme in the melatonin pathway. 2. Using an immunological approach, we presently show that this regulation of HIOMT activity reflects changes in the concentration of a single molecular form of the enzyme protein (a 38 kDa polypeptide). Immunohistofluorescence indicates that these concentration changes concurrently affect modified photoreceptors and pinealocyte-like cells in the chicken pineal organ. 3. Together, the present data support the hypothesis that environmental lighting might regulate the expression of the HIOMT gene.

Development of day-night rhythmicity in "synaptic" ribbon numbers in the pinealocytes of posthatch chicks kept under either natural photoperiodic conditions or continuous illumination

Pineal synaptic ribbons (SR) undergo characteristic changes over a period of 24 hr under natural photoperiodic conditions in various vertebrates, being low in number during daytime and elevated at night. During posthatch development of chicks, the rhythmicity of SR numbers is reported to appear at the age of about 2 weeks. Because the influence of external light during the growth phase of chicks on the development of day-night rhythmicity in SR numbers is unknown, we studied day-night differences in SR numbers in the pinealocytes of chicks at the posthatch ages of 15, 17, and 19 days; chicks had previously been kept under natural photoperiodic conditions or continuous illumination. Under natural photoperiodic conditions a statistically significant nocturnal (midnight) rise in SR numbers over the value of midday was seen in the pineal of 17- and 19-day-old chicks, but not in 15-day-old chicks. SR numbers in the pinealocytes of continuously illuminated chicks did not show any day-night rhythmicity on days either 15 or 17, but exhibited significant day-night differences on day 19 posthatch. These findings suggest that continuous illumination, which is known to dampen circadian rhythmicity of melatonin secretion in the chick pineal, causes a delay, but not a total suppression of the mechanism involved in the ontogenic development of diurnal rhythmicity in SR numbers in the pinealocytes of chicks.

Molecular and cellular aspects of hydroxyindole-O-methyltransferase expression in the developing chick pineal gland

The pineal gland influences circadian activity and seasonal breeding through the production of an indolic hormone, melatonin. The terminal step of melatonin biosynthesis is catalyzed by hydroxyindole-O-methyltransferase (HIOMT). Using an antibody directed against HIOMT, we examined the differentiation of the melatoninergic phenotype in the developing chick pineal gland. HIOMT first appeared 4 days before hatch and rose linearly until the 7th day posthatch. This was correlated with an increased immunoreactivity of the 38 kDa enzyme on Western blots and with an accelerated rate of HIOMT biosynthesis as demonstrated by [35S]methionine labeling. Immunocytochemistry revealed a growing number of HIOMT-positive cells between day 2 before hatch and day 15 posthatch. Until hatching HIOMT was expressed almost exclusively in modified photoreceptors. Parafollicular pinealocytes became HIOMT-positive mostly after hatching. Their different timings of functional differentiation emphasize the existence of two populations of melatonin-producing cells in the chick pineal gland.

Structural and functional differentiation of the embryonic chick pineal organ in vivo and in vitro. A scanning electron-microscopic and radioimmunoassay study

The development of sensory structures in the pineal organ of the chick was examined by means of scanning electron microscopy from embryonic day 10 through day 12 post-hatching. At embryonic day 10, the wall of the tubules within the pineal primordium is composed of cells with unspecialized luminal surface. Differentiation of sensory structures starts at embryonic day 12 when pinealocytes and supporting cells can be distinguished. Pinealocytes are recognized by virtue of an inner segment only rarely endowed with a cilium, whereas supporting cells exhibit numerous short microvilli. Further differentiation of the sensory apparatus is achieved by development of an oval-shaped, biconcave swelling at the tip of the cilium, 1 x 2 microns in size, and a collar of long microvilli at the base of the inner segment. Membrane specializations of sensory cilia, however, were not detected. Since during embryonic life new tubules and follicles are continuously formed, all stages of differentiation of sensory structures are found in the chick pineal organ during the second half of the incubation period and the first two weeks after hatching. In 200-microns-thick Vibratome sections of chick-embryo pineal organs cultured in medium BM 86 Wissler for periods up to 13 days the cytodifferentiation parallels the development in vivo. Using an organ-culture system the 24-h release of melatonin into the culture medium was measured by means of radioimmunoassay after solid-phase extraction. At embryonic day 10, the 24-h secretion of melatonin was at the lower range of detection of the RIA (5 pg). The rapid increase in 24-h secretion in melatonin until hatching (approximately 50 micrograms) is approximated by an exponential curve.

Ontogeny of N-acetyltransferase activity rhythm in pineal gland of chick embryo

1. N-acetyltransferase was present in pineal glands of 14-day-old chick embryos though no rhythm either in LL, DD or LD 12:12 was observed in this age. 2. Daily rhythm in pineal NAT activity was found in 18-day-old embryos incubated under LD 12:12 and LD 16:8 but no NAT rhythm was detected in DD or LL. 3. NAT rhythm persists for 2 days in constant darkness and it may be circadian in nature. 4. Presence of melatonin (85 +/- 8 pg/mg tissue) was detected in pineals of 18-day-old chick embryos.

Cytochemical demonstration of lysosomes in the chicken pineal gland: changes induced by light-dark cycle

Light and electron microscopic demonstrations for acid phosphatase (AcPase) activity in the chicken pineal gland were studied with special reference to the changes induced by the light-dark cycle. AcPase-positive lysosomes and Golgi cisternae and vesicles located in the pinealocyte in the light period are well developed and more numerous than in the dark period. In a few cases, a type of lysosome wrapping mechanism is present in the pinealocyte during the light period. Therefore, the lysosomes in the chicken pinealocyte appear active during the light period. In addition, the lysosomes may have functional relationships with the lipid-like inclusions seen in the dark period.