Characterization of neural stem cells and their progeny in the adult zebrafish optic tectum

In the adult teleost brain, proliferating cells are observed in a broad area, while these cells have a restricted distribution in adult mammalian brains. In the adult teleost optic tectum, most of the proliferating cells are distributed in the caudal margin of the periventricular gray zone (PGZ). We found that the PGZ is largely divided into 3 regions: 1 mitotic region and 2 post-mitotic regions—the superficial and deep layers. These regions are distinguished by the differential expression of several marker genes: pcna, sox2, msi1, elavl3, gfap, fabp7a, and s100β. Using transgenic zebrafish Tg (gfap:GFP), we found that the deep layer cells specifically express gfap:GFP and have a radial glial morphology. We noted that bromodeoxyuridine (BrdU)-positive cells in the mitotic region did not exhibit glial properties, but maintained neuroepithelial characteristics. Pulse chase experiments with BrdU-positive cells revealed the presence of self-renewing stem cells within the mitotic region. BrdU-positive cells differentiate into glutamatergic or GABAergic neurons and oligodendrocytes in the superficial layer and into radial glial cells in the deep layer. These results demonstrate that the proliferating cells in the PGZ contribute to neuronal and glial lineages to maintain the structure of the optic tectum in adult zebrafish.     

Species-dependent migration of fish hatching gland cells that commonly express astacin-like proteases in common

Two constituent proteases of the hatching enzyme of the medaka ( Oryzias latipes ), choriolysin H (HCE) and choriolysin L (LCE), belong to the astacin protease family. Astacin family proteases have a consensus amino acid sequence of HExxHxxGFxHExxRxDR motif in their active site region. In addition, HCE and LCE have a consensus sequence, SIMHYGR, in the downstream of the active site. Oligonucleotide primers were constructed that corresponded to the above-mentioned amino acid sequences and polymerase chain reactions were performed in zebrafish ( Brachydanio rerio ) and masu salmon ( Oncorynchus masou ) embryos. Using the amplified fragments as probes, two full-length cDNA were isolated from each cDNA library of the zebrafish and the masu salmon. The predicted amino acid sequences of the cDNA were similar to that of the medaka enzymes, more similar to HCE than to LCE, and it was conjectured that hatching enzymes of zebrafish and masu salmon also belonged to the astacin protease family. The final location of hatching gland cells in the three fish species: medaka, zebrafish and masu salmon, is different. The hatching gland cells of medaka are finally located in the epithelium of the pharyngeal cavity, those of zebrafish are in the epidermis of the yolk sac, and those of masu salmon are both in the epithelium of the pharyngeal cavity and the lateral epidermis of the head. However, in the present study, it was found that the hatching gland cells of zebrafish and masu salmon originated from the anterior end of the hypoblast, the Polster, as did those of medaka by in situ hybridization. It was clarified, therefore, that such difference in the final location of hatching gland cells among these species resulted from the difference in the migratory route of the hatching gland cells after the Polster region.     

Protocadherins control the modular assembly of neuronal columns in the zebrafish optic tectum

Cell–cell recognition guides the assembly of the vertebrate brain during development. δ-Protocadherins comprise a family of neural adhesion molecules that are differentially expressed and have been implicated in a range of neurodevelopmental disorders. Here we show that the expression of δ-protocadherins partitions the zebrafish optic tectum into radial columns of neurons. Using in vivo two-photon imaging of bacterial artificial chromosome transgenic zebrafish, we show that pcdh19 is expressed in discrete columns of neurons, and that these columnar modules are derived from proliferative pcdh19⁺ neuroepithelial precursors. Elimination of pcdh19 results in both a disruption of columnar organization and defects in visually guided behaviors. These results reveal a fundamental mechanism for organizing the developing nervous system: subdivision of the early neuroepithelium into precursors with distinct molecular identities guides the autonomous development of parallel neuronal units, organizing neural circuit formation and behavior.     

Immunohistochemical evidence for the presence of melatonin in the pineal gland,the retina and the Harderian gland

Summary The presence of melatonin is demonstrated in the pineal gland, the retina and the Harderian gland in some mammalian and non-mammalian vertebrates, using a specific fluorescence labelled antibody technique. Four different potent antibodies against melatonin have been used and compared. In the pineal gland of hamsters, mice, rats and snakes, specific fluorescence, mostly restricted to the cytoplasm of the cells, is detected in pinealocytes. Fluorescence is also detected in the pineal organ of fishes, tortoises and lizards, but it has not been possible, from cryostat sections of fresh tissue, to assert which kind of cell is reacting (photoreceptor cells or interstitial ependymal cells). In the retina, fluorescence is almost exclusively restricted to the outer nuclear layer. In the Harderian gland of mammals and reptiles, fluorescence is localized in the secretory cells of the alveoli and mostly restricted to the cytoplasm surrounding the nucleus. These results are discussed in relation to the concept of melatonin synthesis at extrapineal sites independent of pineal production.Parts of this work have been presented in the Xth Conference of Comparative Endocrinologists, Sorrento, May 20–25, 1979 (Vivien-Roels and Dubois 1980) and the VIth International Congress of Endocrinology, Melbourne, February 10–16, 1980 (Vivien-Roels et al. 1980)The author wishes to thank Professor Lutz Vollrath who has accepted her in his laboratory for a short period, Doctor George M. Bubenik for his suggestions and critical remarks, Dr. L.J. Grota for producing the melatonin diazobenzoic acid-BSA and Dr. Castro for preparing one of the melatonin derivates     

The ontogeny of the retina and optic tectum in Aequidens portalegrensis (Hensel)

External features of the development of fry of the brown acara, Aequidens portalegrensis , are described. There is evidence that thyroxine is a melanophore-concentrating hormone early in larval life. There is also evidence that adrenal corticosteroids are of importance in the growth and development of fry. The development of the retina is described. All structural components of the adult retina are present by 7 days after fertilization, when rods and the capacity for visual accommodation appear. Double cones first appear a day previously; circumstantial evidence suggests that they originate from the incomplete fission of single cones. The development of the optic tectum is similar to amphibians. The pace of tectal differentiation is slower than that of the retina. When the fry become free-swimming (+ 6 days), the wall of the tectum comprises a thick stratum periventriculare with, external to this, a thin stratum corticalis. The stratum corticalis subsequently increases in thickness, concomitant with the migration of individual neurones from the stratum periventriculare. The distinct stratification of the adult optic tectum is not apparent until shortly after the transition to the juvenile phase (+24 days).     

Synaptic mechanisms of spike generation in bursts by neurons of the carp tectum and olfactory bulb

Synaptic mechanisms of burst activity generation in certain neurons of the tectum opticum and mechanisms of generation of stimulation-induced group discharges by certain secondary neurons of the olfactory bulb were analyzed in carp (Cyprinus carpio L.). Spikes of the spontaneous discharge in neurons of the tectum were accompanied by depolarizing after-potentials, which caused the burst discharges of these cells. Evidence is given in support of the synaptic nature of the after-potential; it is suggested that it is generated by a recurrent collateral mechanism. Synaptic bombardment causing the appearance of a group discharge in olfactory bulb neurons and groups of spikes in their spontaneous activity was found to be intermittent in character. These features of unit activity in the olfactory bulb are shown to be connected with the presence of excitatory synaptic interaction between several neurons, probably dendro-dendritic in nature.M. V. Lomonosov Moscow State University. Translated from Neirofiziologiay, Vol. 14, No. 5, pp. 483–490, September–October, 1982.     

Expression of a zebrafish Cathepsin L gene in anterior mesendoderm and hatching gland

 During a differential display-based screen for developmentally regulated genes in zebrafish, we have isolated a cDNA for zebrafish cathepsin L, termed catL. The gene shows abundant expression in the anteriormost cells of the head process which give rise to the polster and later to the hatching gland. Expression of catL persists in these tissues until hatching. catL thus provides a useful marker for very anterior mesendodermal structures in zebrafish. Received: 23 September 1996/Accepted: 29 October 1996     

Histochemical and cytochemical localization of acetylcholinesterase in retina and optic tectum of teleost fish.

The activity of cholinesterase and its cellular and subcellular localization were investigated in the retina and optic tectum of Eugerres plumieri and in the retina of Carassius carassius by means of radiometric, histochemical, and cytochemical procedures. In both fishes only the presence of acetylcholinesterase could be demonstrated. This study, besides confirming previous findings that acetylcholinesterase is located in the ganglion and amacrine cells of the retina as well as in the inner plexiform layer, in addition provides evidence that the enzyme is also present at the region of photoreceptor synapses between the cell bodies and apposing extensions of the horizontal cells of the same layer. The latter localization may indicate the involvement of a cholinergic mechanism at the functional contacts (transferapses) between the horizontal cells. In the optic tectum of Eugerres plumieri, histochemistry reveals fine distinguishable bands of acetylcholinesterase activity; two of the bands are quite sharply defined, whereas three others have rather a more diffuse appearance. The presence of these bands and their distribution may suggest a widespread distribution of cholinergic elements in the optic tectum.     

Diurnal expressions of four subtypes of melatonin receptor genes in the optic tectum and retina of goldfish

Four subtypes of melatonin receptor genes (Mel(1a) 1.4, Mel(1a) 1.7, Mel(1b), and Mel(1c)) are considered to be expressed to mediate various physiological functions of melatonin in goldfish (Carassius auratus). To examine their tissue distribution and diurnal changes in expression levels, we cloned partial gene fragments for these melatonin receptor subtypes, and established specific RT-PCR and quantitative real-time PCR systems. Mel(1a) 1.4 and Mel(1b) were predominantly expressed in various neuronal and peripheral tissues, while Mel(1a) 1.7 and Mel(1c) were expressed in the restricted tissues. All subtype genes were expressed in the optic tectum, diencephalon, mesencephalon, vagal lobe, retina and spleen. The real-time PCR analyses showed that significant differences among time were observed for Mel(1a) 1.4 in the optic tectum and for Mel(1a) 1.7 and Mel(1b) in the retina. In the retina, the levels of Mel(1a) 1.7 and Mel(1b) mRNAs showed diurnal changes with one peak at ZT24. The present results show differential distribution of four subtypes of melatonin receptor mRNAs in the neuronal and peripheral tissues. However, the expressions of all subtype genes in the retinorecipient brain regions and retina reinforce the role of the melatonin receptor in processing visual information. Furthermore, the present study demonstrates diurnal expressions of the major subtype genes, i.e. Mel(1a) 1.4 in the optic tectum and Mel(1a) 1.7 in the retina.     

The projection of the retina, including the 'red area' on to the optic tectum of the pigeon.

The optic tectum of the pigeon has been mapped physiologically, including much of the inferior surface. There are two separate regions of high magnification factor, the projection areas of the fovea and the middle of the red area in the retina, each of which has a correspondingly high density of neurones in the ganglion cell layer.     

Characterization of transgenic rice plants that express rgp1, the gene for a small GTP-binding protein from rice

 The rgp1 gene, which encodes a small GTP-binding protein from rice, was introduced into rice protoplasts by electroporation. Transformed protoplasts were cultured on liquid protoplast-culture medium for 1 month, and then cells that had proliferated were transferred to a selection medium that contained 50 mg/l hygromycin B. Among 50 colonies that were selected and transferred to regeneration medium, 3 colonies generated shoots. However, two of the three shoots failed to form roots and ceased growing. A single regenerated shoot that formed roots was planted in soil and transferred to a greenhouse. Southern hybridization showed that the regenerated plant harbored a single copy of the introduced gene. The transformant (T₀) plant was shorter than the controls, it developed three times as many tillers as controls, it developed three times as many tillers as control plants but it produced mostly sterile seeds. In a test of hygromycin resistances, viable seeds segregated into resistant and sensitive seedings at a ratio of approximately 1 : 3. The progeny (T₁) plants were short with many tillers, and some produced seeds normally. The T₂ seedlings grew more rapidly than control seedlings for the first 28 days after germination, but control plants subsequently outgrew the T₂ plants. Northern blotting analysis revealed that the rgp1 gene in T₂ plants was expressed consitutively throughout all developmental stages. The results suggest that the observed phenotypic changes were due to expression of the exogenous rgp1 gene. Received: 21 September 1997/Accepted: 31 March 1998     

Analysis of the human, bovine and rat 33-kDa proteins and cDNA in retina and pineal gland

A monoclonal antibody (mAb) was produced against a bovine retinal 33-kDa protein. Several clones of 33-kDa protein were isolated from each library of cDNA from human, bovine and rat retinas and rat pineal gland by mAb screening and by hybridization with cDNA probes. Each of the four cDNA sequences was determined and amino acid (aa) sequences were deduced from the nucleotide sequences. The latter were nearly identical in rat retina and rat pineal gland (99.6%) and were similar in human, bovine and rat retina (more than 87%). Each of these cDNAs had one long ORF and encoded 245 or 246 aa. The deduced aa sequences in rat retina and rat pineal gland were virtually identical and the sequences in human, bovine and rat retina were highly homologous (more than 88%). The predicted Mr for each of these proteins was 28,246 in the human, 28,176 in bovine, 28,143 in rat retina, and 28,129 in rat pineal gland. Each of the sequences has a putative site for phosphorylation by A kinase; we have confirmed that the putative site is Ser73. These results show that the 33-kDa proteins in the retina and pineal gland have the same sequences and the same phosphorylation site and suggest that the functional role of this protein is the same in the retina and pineal gland.     

Effect of optic chiasmotomy upon serotonin concentration in the pineal gland of the monkey

The concentration of serotonin within the pineal gland of the monkey exhibits a 24-hour rhythm, being higher during the hours of light and falling during the hours of darkness. Chiasmotomies were performed upon male cynomolgus monkeys (Macaca irus) to ascertain whether the intrapineal concentration of serotonin is dependent upon information passing from the eyes by means of nerve fibers that cross in the optic chiasma. After two weeks, the operated animals, whether killed in the light or the dark, showed a significant reduction in intrapineal serotonin compared with controls; however, the concentration of serotonin in operated animals killed during hours of light was comparable with that of control animals killed during the corresponding hours of darkness. The results indicate that the intrapineal concentration of serotonin is dependent upon information transmitted from the eyes by means of nerve fibers which cross in the optic chiasma; it is possible that these fibers are also components of the accessory optic tracts. It also is suggested that during hours of light, uncrossed fibers of retinal origin may participate in the regulation of the intrapineal serotonin concentration of this monkey.     

Temporal-spatial characterization of chicken clock genes: circadian expression in retina,pineal gland,and peripheral tissues

The molecular core of the vertebrate circadian clock is a set of clock genes, whose products interact to control circadian changes in physiology. These clock genes are expressed in all tissues known to possess an endogenous self-sustaining clock, and many are also found in peripheral tissues. In the present study, the expression patterns of two clock genes, cBmal1 and cMOP4, were examined in the chicken, a useful model for analysis of the avian circadian system. In two tissues which contain endogenous clocks--the pineal gland and retina--circadian fluctuations of both cBmal1 and cMOP4 mRNAs were observed to be synchronous; highest levels occurred at Zeitgeber time 12. Expression of these genes is also rhythmic in several peripheral tissues; however, the phases of these rhythms differ from those in the pineal gland and retina: in the liver the peaks of cMOP4 and cBmal1 mRNAs are delayed 4-8 h and in the heart they are advanced by 4 h, relative to those in the pineal gland and retina. These results provide the first temporal characterization of cBmal1 and cMOP4 mRNAs in avian tissues: their presence in avian peripheral tissues indicates they may influence temporal features of daily rhythms in biochemical, physiological, and behavioral functions at these sites.     

Arylalkylamine N-acetyltransferase gene expression in retina and pineal gland of rats under various photoperiods

The present study examines how the circadian oscillators in the retina and the suprachiasmatic nucleus (SCN) respond to changes in photoperiod. Arylalkylamine N-acetyltransferase (aa-nat) gene expression studied by quantitative RT-PCR revealed that in adult Sprague-Dawley rats kept under different light-dark (LD) cycles for two weeks the temporal pattern of AA-NAT mRNA expression was identical in retina and pineal gland. In both tissues, the time span between the onset of darkness and the nocturnal rise in AA-NAT mRNA expression was 3 h under LD 20:4, 6 h under LD 12:12, and 15 h under LD 4:20. As aa-nat expression in the pineal gland is regulated by the circadian oscillator in SCN, the results suggest that the photoperiodic differences accompanying the seasons of the year are imprinted in more than one oscillator and that this may accentuate the important message regarding 'time of year.'     

The contribution of axoplasmic flow in optic nerve and protein synthesis within the optic tectum to synaptic membrane proteins of the chick optic tectum

In the 5-day-old chick, radioactive leucine was incorporated into proteins of synaptosomal and subsynaptosomal fractions both by fast axoplasmic flow and synthesis within the optic tectum. The distribution of radioactivity in subsynaptosomal fractions suggested that both pathways contribute to the protein constituents of each fraction. The relative contributions to each fraction were similar except for the supernatant proteins, for which fast axoplasmic flow contributed less than the synthesis within the optic tectum. The qualitative contribution of fast flow and synthesis within the optic tectum to the synaptic membrane fraction was distinctive. Fast axoplasmic flow preferentially labelled the high molecular weight proteins, whereas synthesis within the optic tectum labelled a larger percentage of smaller molecular weight proteins.     

A model of olfactory adaptation and sensitivity enhancement in the olfactory bulb

It has been suggested that the olfactory bulb, the first processing center after the sensory cells in the olfactory pathway, plays a role in olfactory adaptation, odor sensitivity enhancement by motivation and other olfactory psychophysical phenomena. In a mathematical model based on the bulbar anatomy and physiology, the inputs from the higher olfactory centers to the inhibitory cells in the bulb are shown to be able to modulate the response, and thus the sensitivity of the bulb to specific odor inputs. It follows that the bulb can decrease its sensitivity to a pre-existing and detected odor (adaptation) while remaining sensitive to new odors, or increase its sensitivity to interested searching odors. Other olfactory psychophysical phenomena such as cross-adaptation etc. are discussed as well.     

Expression of S-antigen in retina, pineal gland, lens, and brain is directed by 5'-flanking sequences.

S-antigen (S-Ag) is an abundant protein of the retina and pineal gland that elicits experimental autoimmune uveitis and pinealocytis in several animal species. To study the elements regulating the expression of S-Ag, we generated transgenic mice expressing the chloramphenicol acetyl transferase (CAT) gene under the control of a 1.3-kilobase pair 5'-flanking segment of the mouse S-Ag gene. While all of the transgenic mice expressed CAT activity in the retina, in some animals CAT activity was also detected in the pineal gland, lens, and brain. Immunoblotting, polymerase chain reaction-mediated detection of RNA, and immunocyto-staining of transgenic tissues with antibodies to CAT and S-Ag established that the profile of expression of the transgene corresponded to that of S-Ag; both proteins were detectable in retinal photoreceptor cells, pinealocytes, lens fiber and epithelial cells, the cerebellum, and the cerebral cortex. These results indicate that S-Ag is expressed in a wider spectrum of the cell types than previously recognized and that a 1.3-kilobase pair S-Ag promoter segment contains sufficient information to direct appropriate tissue-specific gene expression in transgenic mice.     

Photoreceptors of the retina and pinealocytes of the pineal gland share common components of signal transduction

Light absorbed by retinal photoreceptors triggers a cascade of reactions that initiate cGMP hydrolysis, cation channel closure and membrane hyperpolarization. Down-regulation of the cascade involves additional proteins that interfere with amplification along the cascade. Pinealocytes are activated by norepinephrine during the dark phase of the day/night cycle. Mature pinealocytes of the mammalian pineal express the known photoreceptor proteins that are implicated in down-regulation of the visual cascade, but the cascade components that produce cGMP hydrolysis and membrane hyperpolarization are absent. Pinealocytes accumulate cyclic AMP minimally when norepinephrine activates their beta adrenergic receptors alone, but the response is potentiated by the simultaneous activation of their alpha-1 adrenergic receptors. A model is proposed whereby phosducin, a phosphoprotein that binds the beta, gamma subunit of G-proteins, could modulate the synthesis of cyclic AMP by buffering the amount of beta, gamma G-protein subunits that are available for activating adenylate cyclase.Special issue dedicated to Dr. Frederick E. Samson.