Antón Barreiro-Iglesias

Neurochemical characterization of sea lamprey taste buds and afferent gustatory fibers: Presence of serotonin, calretinin, and CGRP immunoreactivity in taste bud bi‐ciliated cells of the earliest vertebrates

Neuroactive substances such as serotonin and other monoamines have been suggested to be involved in the transmission of gustatory signals from taste bud cells to afferent fibers. Lampreys are the earliest vertebrates that possess taste buds, although these differ in structure from taste buds in jawed vertebrates, and their neurochemistry remains unknown. We used immunofluorescence methods with antibodies raised against serotonin, tyrosine hydroxylase (TH), γ‐aminobutyric acid (GABA), glutamate, calcitonin gene‐related peptide (CGRP), neuropeptide Y (NPY), calretinin, and acetylated α‐tubulin to characterize the neurochemistry and innervation of taste buds in the sea lamprey, Petromyzon marinus L. For localization of proliferative cells in taste buds we used bromodeoxyuridine labeling and proliferating cell nuclear antigen immunohistochemistry. Results with both markers indicate that proliferating cells are restricted to a few basal cells and that almost all cells in taste buds are nonproliferating. A large number of serotonin‐, calretinin‐, and CGRP‐immunoreactive bi‐ciliated cells were revealed in lamprey taste buds. This suggests that serotonin participates in the transmission of gustatory signals and indicates that this substance appeared early on in vertebrate evolution. The basal surface of the bi‐ciliated taste bud cells was contacted by tubulin‐immunoreactive fibers. Some of the fibers surrounding the taste bud were calretinin immunoreactive. Lamprey taste bud cells or afferent fibers did not exhibit TH, GABA, glutamate, or NPY immunoreactivity, which suggests that expression of these substances evolved in taste buds of some gnathostomes lines after the separation of gnathostomes and lampreys. J. Comp. Neurol. 511:438–453, 2008.

Dopamine and γ-aminobutyric acid are colocalized in restricted groups of neurons in the sea lamprey brain: insights into the early evolution of neurotransmitter colocalization in vertebrates

Since its discovery, the possible corelease of classic neurotransmitters from neurons has received much attention. Colocalization of monoamines and amino acidergic neurotransmitters [mainly glutamate and dopamine (DA) or serotonin] in mammalian neurons has been reported. However, few studies have dealt with the colocalization of DA and γ‐aminobutyric acid (GABA) in neurons. With the aim of providing some insight into the colocalization of neurotransmitters during early vertebrate phylogeny, we studied GABA expression in dopaminergic neurons in the sea lamprey brain by using double‐immunofluorescence methods with anti‐DA and anti‐GABA antibodies. Different degrees of colocalization of DA and GABA were observed in different dopaminergic brain nuclei. A high degree of colocalization (GABA in at least 25% of DA‐immunoreactive neurons) was observed in populations of the caudal rhombencephalon, ventral isthmus, postoptic commissure nucleus, preoptic nucleus and in granule‐like cells of the olfactory bulb. A new DA‐immunoreactive striatal population that showed colocalization with GABA in about a quarter of its neurons was observed. In the periventricular hypothalamus, colocalization was observed in only a few cells, despite the abundance of DA‐ and GABA‐immunoreactive neurons, and no double‐labelled cells were observed in the paratubercular nucleus. The frequent colocalization of DA and GABA reveals that the dopaminergic populations of lampreys are more complex than previously reported. Double‐labelled fibres or terminals were observed in different brain regions, suggesting possible corelease of DA and GABA by these lamprey neurons. The present results suggest that colocalization of DA and GABA in neurons appeared early in vertebrate evolution.

Distribution of glycine immunoreactivity in the brain of adult sea lamprey (Petromyzon marinus). Comparison with γ‐aminobutyric acid

The distribution of glycinergic cells in the brain of nonmammalian vertebrates is still unknown. Lampreys are the most primitive extant vertebrates, and they may provide important data on the phylogeny of this system. Here, we studied for the first time the distribution of glycine immunoreactivity in the sea lamprey brain and compared it with γ‐aminobutyric acid (GABA)‐ergic populations. Most glycine‐immunoreactive neurons were found at midbrain and hindbrain levels, and most of these cells did not exhibit GABA immunoreactivity. We describe glycine‐immunoreactive cell populations in the olfactory bulbs, the preoptic nucleus, and the thalamus of the sea lamprey, which is in striking contrast to their lack in the mammalian forebrain. We also observed glycine‐immunoreactive populations in the optic tectum, the torus semicircularis and the midbrain tegmentum, the isthmus, the octavolateral area, the dorsal column nucleus, the abducens nucleus, the trigeminal motor nucleus, the facial motor nucleus, and the rhombencephalic reticular formation. In these populations, colocalization with GABA was observed in only some cells of the tegmental M5 nucleus, ventral isthmus, medial octavolateral nucleus, dorsal column nucleus, and lateral reticular region. The present results allow us to conclude that the distribution of glycine‐immunoreactive cells changed notably from lamprey to mammals, with a decrease in glycinergic populations in the forebrain and a specialization of brainstem cell groups. Although knowledge of the glycinergic populations in lampreys is important for understanding the early evolution of this system, there is a notable gap of information regarding its organization in brains of other nonmammalian vertebrates. J. Comp. Neurol. 507:1441–1463, 2008.

Descending brain-spinal cord projections in a primitive vertebrate, the lamprey: cerebrospinal fluid-contacting and dopaminergic neurons.

We used Neurobiotin as a retrograde tract tracer in both larval and adult sea lampreys and observed a number of neuronal brainstem populations (mainly reticular and octaval populations and some diencephalic nuclei) that project to the spinal cord, in agreement with the results of previous tracer studies. We also observed small labeled neurons in the ventral hypothalamus, the mammillary region, and the paratubercular nucleus, nuclei that were not reported as spinal projecting. Notably, most of the labeled cells of the mammillary region and some of the ventral hypothalamus were cerebrospinal fluid‐contacting (CSF‐c) neurons. Combined tract tracing and immunocytochemistry showed that some of the labeled neurons of the mammillary and paratubercular nuclei were dopamine immunoreactive. In addition, some CSF‐c cells were labeled in the caudal rhombencephalon and rostral spinal cord, and many were also dopamine immunoreactive. Results with other tracers (biotinylated dextran amines, horseradish peroxidase, and the carbocyanine dye DiI) also demonstrated that the molecular weight or the molecular nature of the tracer was determinant in revealing diencephalic cells with very thin axons. The results show that descending systems afferent to the spinal cord in lampreys are more varied than previously reported, and reveal a descending projection from CSF‐c cells, which is unknown in vertebrates. The present results also reveal the existence of large differences between agnathans and gnathostomes in the organization of the dopaminergic cells that project to the spinal cord. J. Comp. Neurol. 511:711–723, 2008.

Serotonin and GABA are colocalized in restricted groups of neurons in the larval sea lamprey brain: insights into the early evolution of neurotransmitter colocalization in vertebrates

Colocalization of the classic neurotransmitters serotonin (5‐HT) and γ‐aminobutyric acid (GABA) (or the enzyme that synthesizes the latter, glutamate decarboxylase) has been reported in a few neurons of the rat raphe magnus‐obscurus nuclei. However, there are no data on the presence of neurochemically similar neurons in the brain of non‐mammalian vertebrates. Lampreys are the oldest extant vertebrates and may provide important data on the phylogeny of neurochemical systems. The colocalization of 5‐HT and GABA in neurons of the sea lamprey brain was studied using antibodies directed against 5‐HT and GABA and confocal microscopy. Colocalization of the neurotransmitters was observed in the diencephalon and the isthmus. In the diencephalon, about 87% of the serotonergic cells of the rostral tier of the dorsal thalamus (close to the zona limitans) exhibited GABA immunoreactivity. In addition, occasional cells double‐labelled for GABA and 5‐HT were observed in the hypothalamic tuberal nucleus and the pretectum. Of the three serotonergic isthmic subgroups already recognized in the sea lamprey isthmus (dorsal, medial and ventral), such double‐labelled cells were only observed in the ventral subgroup (about 61% of the serotonergic cells in the ventral subgroup exhibited GABA immunoreactivity). An equivalence between these lamprey isthmic cells and the serotonergic/GABAergic raphe cells of mammals is suggested. Present findings suggest that serotonergic/GABAergic neurons are more extensive in lampreys than in the rat and probably appeared before the separation of agnathans and gnathostomes. Cotransmission by release of 5‐HT and GABA by the here‐described lamprey brain neurons is proposed.

Colocalization of dopamine and GABA in spinal cord neurones in the sea lamprey

In this study, double immunofluorescence methods were used to investigate possible colocalization of the neurotransmitters dopamine [DA] and GABA in rostral spinal cord neurones in the upstream migrating adult sea lamprey (Petromyzon marinus). Double immunofluorescence revealed that all the DA-immunoreactive (ir) cerebrospinal fluid-contacting (CSF-c) cells, approximately 30% of the medioventral DA-ir cells, and most of the DA-ir cells located in the grey lateral to the central canal were also GABA-ir. The results also revealed some DA-ir cells located dorsally to the central canal, which increases the number of dopaminergic cell types known in lamprey. Double-labelled fibres were mainly distributed in the ventral column, and double-labelled boutons contacted some dorsal GABA-ir CSF-c cells, as well as some non-CSF-c GABA-ir cells and ventromedial dendrites of motoneurones. The findings reveal colocalization of dopamine and GABA in some cells and fibres, which suggests co-release of these substances in some synaptic terminals. Although dopaminergic/GABAergic CSF-c cells have been reported in some other vertebrates, the other double-labelled spinal populations appear exclusive to lampreys.

Development and organization of the descending serotonergic brainstem-spinal projections in the sea lamprey.

The organization and development of the descending spinal projections from serotonergic rhombencephalic neurons in the larval sea lamprey were investigated by double labeling, tract-tracing methods and immunocytochemistry against serotonin. The results showed that two serotonergic populations of the isthmic and vagal reticular regions present reticulospinal neurons from the beginning of the larval period. Of the three serotonergic subpopulations recognized in the isthmic reticular group [Abalo, X.M., Villar-Cheda, B., Meléndez-Ferro, M., Pérez-Costas, E., Anadón, R., Rodicio, M.C., 2007. Development of the serotonergic system in the central nervous system of the sea lamprey. J. Chem. Neuroanat. 34, 29-46], only two - the medial and ventral subpopulations - project to the spinal cord, with most of the projecting cells in the caudal part of the medial isthmic subpopulation. Occasional cells projecting to the spinal cord were observed in the ventral subpopulation. The vagal reticular serotonergic nucleus situated in the caudal rhombencephalon also presents cells with descending projections. The early development of the brainstem serotonergic projections to the spinal cord appears to be a conserved trait in all vertebrates studied. Although a serotonergic hindbrain-spinal projection system appears to have been present before the divergence of agnathans and gnathostomes, no serotonergic cells were observed in the raphe region in lamprey. Moreover, proportionally more rostral hindbrain serotonergic cells contribute to the spinal serotonergic projections in the sea lamprey than in jawed vertebrates.

Development of glycine immunoreactivity in the brain of the sea lamprey: Comparison with γ-aminobutyric acid immunoreactivity

The development of glycine immunoreactivity in the brain of the sea lamprey was studied by use of immunofluorescence techniques at embryonic to larval stages. Glycine distribution was also compared with that of γ‐aminobutyric acid (GABA) by use of double immunofluorescence. The first glycine‐immunoreactive (ir) cells appeared in the caudal rhombencephalon of late embryos, diencephalon of early prolarvae, and mesencephalon of late prolarvae, in which glycine‐ir cells were observed in several prosencephalic regions (preoptic nucleus, hypothalamus, ventral thalamus, dorsal thalamus, pretectum, and nucleus of the medial longitudinal fascicle), mesencephalon (M5), isthmus, and rhombencephalon. In larvae, glycine‐ir populations were observed in the olfactory bulbs, preoptic nucleus and thalamus (prosencephalon), M5 and oculomotor nucleus (mesencephalon), dorsal isthmic gray, isthmic reticular formation, and various alar and basal plate rhombencephalic populations. No glycine‐ir cells were observed in the larval optic tectum or torus semicircularis, which contain glycine‐ir populations in adults. A wide distribution of glycine‐ir fibers was observed, which suggests involvement of glycine in the function of most lamprey brain regions. Colocalization of GABA and glycine in prolarvae was found mainly in cell groups of the diencephalon, in the ventral isthmic group, and in trigeminal populations. In larvae, colocalization of GABA and glycine was principally observed in the M5 nucleus, the reticular formation, and the dorsal column nucleus. The present results reveal for the first time the complex developmental pattern of the glycinergic system in lamprey, including early glycine‐ir populations, populations transiently expressing glycine, and late‐appearing populations, in relation to maturation changes that occur during metamorphosis. J. Comp. Neurol. 512:747–767, 2009.

Late proliferation and photoreceptor differentiation in the transforming lamprey retina

Lamprey eyes exhibit dual retinal development, with highly different larval and adult phases. Here, cell proliferation and photoreceptor differentiation was investigated in late larvae and during transformation (occurring several years after egg hatching) by using immunohistochemistry against the proliferating cell nuclear antigen (PCNA) and opsins. In large larvae proliferating cells are mainly located in the lateral retina, a wide undifferentiated region, whereas opsin immunoreactivity revealed only a single type of photoreceptors in the very small central retina. In premetamorphic larvae, retinal cell proliferation increases considerably, but at metamorphosis it becomes progressively restricted to the periphery of the lateral retina. Proliferating (PCNA-immunoreactive) cells were mainly observed in the inner nuclear layer but also in the outer plexiform layer and outer nuclear layer, suggesting that the latter proliferating cells migrate to the outer nuclear layer and differentiate into photoreceptors. In the lateral retina, first photoreceptors expressing opsins were observed at middle metamorphic stages, and outer and inner segments were present at latter stages. Some immature photoreceptors were also observed in postmetamorphic retina. Unlike teleost and amphibian retinas, no proliferating cells were observed in the retina after metamorphosis, indicating that the retinal growth after this period is due to cellular reorganization and increase in cell size.

New insights on the neuropeptide Y system in the larval lamprey brain: neuropeptide Y immunoreactive neurons, descending spinal projections and comparison with tyrosine hydroxylase and GABA immunoreactivities

Lampreys are useful models for studying the evolution of the nervous system of vertebrates. Here we used immunofluorescence and tract-tracing methods to study new aspects of the neuropeptide Y-immunoreactive (NPY-ir) system in larval sea lampreys. NPY-ir neurons were observed in brain nuclei that contain NPY-ir cells in other lamprey species. Moreover, a group of NPY-ir cells that migrated away the periventricular layer was observed in the lateral part of the dorsal hypothalamus, which suggests a role for NPY in feeding behavior in lampreys. We also report NPY-ir cells in the dorsal column nucleus, which appears to be unique among vertebrates, and in the habenula. A combination of tract-tracing and immunohistochemical labeling demonstrated the presence of spinal projecting NPY-ir reticular cells in the anterior rhombencephalic reticular formation, and the relationships between the NPY-ir system and the reticulospinal nuclei and some afferent systems. The colocalization of catecholamines and GABA in lamprey NPY-ir neurons was investigated by double immunofluorescence methods. Colocalization of tyrosine hydroxylase (TH) and NPY immunoreactivities was not observed in any brain neuron, although reported in amphibians and mammals. The frequent presence of NPY-ir terminals on TH-ir cells suggests that NPY modulates the activity of some dopaminergic nuclei in lampreys. Colocalization of NPY and GABA immunoreactivities was frequently observed in neurons of different rhombencephalic and diencephalic NPY-ir populations. These results in lampreys suggest that the coexpression of NPY and GABA in neurons appeared early on in the brains of vertebrates.