Lamprey Brain Research Articles

In Vivo Transfection of Lamprey Brain Neurons by Gene Gun Delivery of DNA

The lamprey has been used extensively in studies of CNS axon regeneration. Progress in determining molecular mechanisms involved in regeneration will require the ability to manipulate expression of target genes or to introduce new genes, but in vivo neuronal transfection has posed difficulties in the mature intact nervous system of vertebrates, including the lamprey. In this paper we report successful transfection of neurons in the brain of living lampreys by means of a hand-held Helios Gene Gun. Particle-mediated (“gene gun”) gene transfer has been applied to a variety of cell and tissue types but although it has been used in brain slices and dissociated cultured neurons, to our knowledge it has not been reported as a method for transfection of brain cells in a living animal. Gold particles coated with plasmids containing the gene for the reporter β-galactosidase were propelled by helium at 150–200 psi toward the exposed floor of the 4th ventricle. Transfected animals were examined by X-gal histochemistry at various recovery times. β-glactosidase activity was detected as early as 2 days after gene transfer and lasted for at least 6 weeks, the longest time studied. Transgene expression lasted longer in neurons than in glia. The expression product was transported anterogradely into reticulospinal axons and by 6 weeks could be traced into the spinal cord for 8–10 mm caudal to the obex. This raises the possibility of identifying the growth cones of developing or regenerating axons belonging to transfected neurons in functional studies of manipulated genes.

Distribution of choline acetyltransferase-immunoreactive structures in the lamprey brain.

The distribution of cholinergic neurons and fibers was studied immunohistochemically in the brain of two species of lampreys (Petromyzon marinus and Lampetra fluviatilis), by using an antiserum against choline acetyltransferase (ChAT). The results obtained in both species were similar, but there appeared some interspecies differences. In the forebrain, cholinergic cells were present in the striatum, preoptic region, paraventricular nucleus, pineal and parapineal organs, habenula, and pretectum. The cranial nerve motoneurons (III, IV, V, VI, VII, IX, and X), the first and second spino-occipital nerves (so), and the ventral horn of the spinal cord showed a strong ChAT immunoreactivity. Additional cholinergic neurons were observed: the mesencephalic M5 nucleus of Schober, two different cell populations in the isthmic region, the efferent component of the eighth nerve, putative preganglionic parasympathetic cells, cells in the solitary tract nucleus, and the rhombencephalic reticular formation. Cholinergic fibers were widely distributed in the brain. Comparison with previous studies in other vertebrates suggests that major cholinergic pathways, like tectal innervation from the isthmic region, are also present in lampreys. Of particular interest was the prominent projection to the neurohypophysis from cholinergic neurons in the preoptic region and paraventricular nucleus. Present data were analyzed within the segmental paradigm, as was previously done in other vertebrates. Our results reveal that the organization of many cholinergic systems in the lamprey as, for example, in the striatal, preoptic, and isthmic regions, comprises features of the anamniote brain that remain common to all living amniotes studied so far, thus being conservative to a surprisingly high degree. Therefore, the distribution of ChAT-immunoreactive structures in the lamprey brain is, in general, comparable to that previously described in other vertebrate species.

Peculiarities of Ultraviolet Absorption Spectra of Lamprey and Rat Brain Lipid Extracts and Their Correlation with Fatty Acid Composition

The ultraviolet (UV) absorption spectra of rat and lamprey brain lipid extracts have been studied. It was found that in both species the absorption of UV light took place, the shift of the absorption spectra to the more long-wave region being observed in the lamprey brain lipid extract. The established fact indicate the presence of oxidation products of lipids and their diene conjugates in the studied extracts, i.e., the appearance of the conjugated system of unsaturated bonds in the phospholipid molecules. The shift of the spectra to the more long-wave region in lampreys indicates a possible difference in the amount of polyenoic fatty acids in lamprey phospholipids. It was found that in lampreys it is predominantly the products of oxidation of phosphotidylcholine fatty acids, which shift the absorption spectrum to the more long-wave region. These are docosahexaenoic (C22:6 ω3), docosapentaenoic (C22:5 ω3), and eicosapentaenoic acids (C20:5 ω3). It is suggested that the membrane construction itself provides the basis for the energy accumulation.

Connecting brains to robots: an artificial body for studying the computational properties of neural tissues.

We have created a hybrid neuro-robotic system that establishes two-way communication between the brain of a lamprey and a small mobile robot. The purpose of this system is to offer a new paradigm for investigating the behavioral, computational, and neurobiological mechanisms of sensory-motor learning in a unified context. The mobile robot acts as an artificial body that delivers sensory information to the neural tissue and receives command signals from it. The sensory information encodes the intensity of light generated by a fixed source. The closed-loop interaction between brain and robot generates autonomous behaviors whose features are strictly related to the structure and operation of the neural preparation. We provide a detailed description of the hybrid system, and we present experimental findings on its performance. In particular, we found (a) that the hybrid system generates stable behaviors, (b) that different preparations display different but systematic responses to the presentation of an optical stimulus, and (c) that alteration of the sensory input leads to short- and long-term adaptive changes in the robot responses. The comparison of the behaviors generated by the lamprey's brain stem with the behaviors generated by network models of the same neural system provides us with a new tool for investigating the computational properties of synaptic plasticity.

Physiological activation of presynaptic metabotropic glutamate receptors increases intracellular calcium and glutamate release.

Activation of metabotropic glutamate receptors (mGluRs) has diverse effects on the functioning of vertebrate synapses. The cellular mechanisms that underlie these changes, however, are largely unknown. The role of presynaptic mGluRs in modulating Ca(2+) dynamics and regulating neurotransmitter release was investigated at the vestibulospinal-reticulospinal (VS-RS) synapse in the lamprey brain stem. Application of the specific Group I mGluRs antagonist 7-(hydroxyimino) cyclopropa[b]chromen-1a-carboxylate ethyl ester (CPCCOEt) reduced the amplitude of consecutive high-frequency evoked excitatory postsynaptic currents (EPSCs). A series of experiments using techniques of electrophysiology and calcium imaging were carried out to determine the cellular mechanisms by which this phenomenon occurs. Concentration-dependent increases in the pre- and postsynaptic [Ca(2+)](i) were seen with the application of mGluR agonists. Similarly, high-frequency stimulation of axons caused a Group I mGluR-dependent enhancement in presynaptic Ca(2+) transients. Application of mGluR agonist caused a depolarization of the presynaptic elements, while thapsigargin decreased the high-frequency stimulus- and agonist-induced rises in [Ca(2+)](i). These data suggest that both membrane depolarization and the release of Ca(2+) from intracellular stores potentially play a role in mGluR-induced Ca(2+) signaling. To determine the effect of this modulation of Ca(2+) dynamics on spontaneous glutamate release, miniature EPSCs were recorded from postsynaptic reticulospinal neurons. A potent Group I mGluR agonist, (S)-homoquisqualic acid, caused a large increase in the frequency of events. These results demonstrate the presence of presynaptic Group I mGluRs at the VS-RS synapse. Activation of these receptors leads to a rise in [Ca(2+)](i) and enhances the spontaneous and evoked release of glutamate. Taken together, these studies highlight the importance of synaptic activation of these facilitatory autoreceptors in both short-term plasticity and synaptic transmission.

The Distribution of Lamprey GnRH-III in Brains of Adult Sea Lampreys (Petromyzon marinus)

In the sea lamprey, Petromyzon marinus, two forms of GnRH, lamprey GnRH-I and -III, have been demonstrated to be neurohormones regulating the pituitary–gonadal axis. The objective of the present study was to determine the distribution of lamprey GnRH-III in the brains of adult sea lampreys and to compare it to the distribution of lamprey GnRH-I. For this purpose, two kinds of immunostaining were employed: one was a single immunostaining by one of two GnRH antibodies using two successive sections; the other was double immunostaining of a single section. A dense accumulation of neuronal cells immunoreactive (ir) to antisera against either lamprey GnRH-I or -III was found in the arc-shaped preoptico-anterior hypothalamic area. Additional smaller numbers of irGnRH cells were found in the periventricular zone of the posterior hypothalamus. In the above-mentioned locations, the distribution of both irGnRH-I and -III cells was intermixed and very similar, but the cells exhibiting GnRH-III immunoreactivity were distinctly different from those exhibiting GnRH-I immunoreactivity. The relative numbers of irGnRH-III cells were larger than those of irGnRH-I cells in the preoptico-anterior hypothalamic area, and more than 90% of GnRH cells in the posterior hypothalamus were irGnRH-III cells. Both irGnRH-I and -III cells projected their fibers primarily into the neurohypophysis. The relative densities of the accumulated irGnRH-III fibers were similar to those of irGnRH-I fibers in the anterior neurohypophysis but higher than those of irGnRH-I fibers in the posterior neurohypophysis. The present study provides further immunocytochemical data to the already compelling physiological evidence that indicates that both lamprey GnRH-I and -III act through the hypothalamic–pituitary–gonadal axis to modulate reproductive processes in the sea lamprey.

Expression of the netrin receptor UNC-5 in lamprey brain: modulation by spinal cord transection.

The sea lamprey recovers from spinal cord transection by a process that involves directionally specific regeneration of axons. The mechanisms underlying this specificity are not known, but they may involve molecular cues similar to those that guide the growth of spinal cord axons during development, such as netrins and semaphorins. To test the role of guidance cues in regeneration, we cloned netrin and its receptor UNC-5 from lamprey central nervous system (CNS) and studied their expression after spinal cord transection. In situ hybridization showed that (1) mRNA for netrin is expressed in the spinal cord, primarily in neurons of the lateral gray matter and in dorsal cells; (2) mRNA for UNC-5 is expressed in lamprey reticulospinal neurons; (3) following spinal cord transection, UNC-5 message was dramatically downregulated at two weeks, during the period of axon dieback; (4) UNC-5 message was upregulated at three weeks, when many axons are beginning to regenerate; and (5) axotomy-induced expression of UNC-5 occurred primarily in neurons whose axons regenerate poorly. Because the UNC-5 receptor is thought to mediate the chemorepellent effects of netrins, netrin signaling may play a role in limiting or channeling the regeneration of certain neurons. These data strengthen the rationale for studying the role of developmental guidance molecules in CNS regeneration.

Role of glutamate receptor subtypes in the lamprey respiratory network

The respiratory role of glutamate receptors was investigated in the isolated lamprey brain preparation by analyzing the changes in respiratory activity induced by bath application of specific antagonists of ionotropic and metabotropic glutamate receptors. The results show that these antagonists differentially affect the pattern of breathing and provide the first evidence that both ionotropic and metabotropic glutamate receptors are involved in neurotransmission within the lamprey respiratory network.

Immunohistochemical Distribution of Neuropeptide Y-Related Substance in the Brain and Hypophysis of the Arctic Lamprey, Lethenteron japonica

The distribution of neuropeptide Y (NPY)-like immunoreactivity in the brain and hypophysis of the arctic lamprey, Lethenteron japonica, was studied by the use of polyclonal anti-synthetic porcine NPY antibody. Immunoreactivity was found throughout the brain, with varied densities among different areas. NPY-positive cell bodies were located in the dorsal pallium of the telencephalon; in the preoptic area, the thalamus, and the hypothalamus of the diencephalon; in the tegmentum of the mesencephalon; and in the octavolateralis nucleus, the middle reticular nucleus, and the vagal motor nucleus of the rhombencephalon. The majority of the NPY-positive cells in the thalamus and in the hypothalamus appeared as cerebrospinal fluid-contacting neurons. NPY-positive fibers were widely distributed in the brain and locally dense in the ventromedial part of the lateral pallium, in the posterior part of the interpeduncular nucleus, and in the raphe region. Conversely, they were less dense or well scattered in the olfactory bulb, the lateral pallium except for its ventromedial part, and the optic tectum. NPY-positive innervation in the neurohypophysis was evident, suggesting that involvement of NPY-related substance in the hypothalamo-hypophysial system had occurred in an early stage of vertebrate evolution.

Direct anticancer activity of gonadotropin-releasing hormone-III.

In previous studies GnRH-III, a variant of the hypothalamic neurohormone GnRH, was isolated from the brain of the sea lamprey and structurally characterized. GnRH-III is a hypothalamic neurohormone in both female and male sea lampreys. In the present work biological activities of GnRH-III in mammalian systems were examined. In superfused rat pituitary cells, GnRH-III at 1 nM to 100 nM neither induced LH-secretion nor inhibited the LH-secretion elicited by native GnRH and elicited LH release only at 1 microM. At high dose (500 microg/day) in vivo, GnRH-III behaved as a GnRH agonist, though, it was 1000-fold less active than ovurelin. The in vitro and in vivo results were in good agreement in showing that GnRH-III is only a weak agonist of the endocrine activity of GnRH. GnRH-III specifically bound to receptors on cancer cells and recognized not only the high-, but also the low-affinity binding sites. GnRH-III significantly suppressed growth of human cancer cells which have GnRH receptors. The inhibitory effect of GnRH-III on growth of cancer cells was specific and direct since the peptide did not have endocrine activity in the concentration range found to be effective in anticancer assays. GnRH-III inhibited equally the growth of ER-positive and -negative breast and TeR-positive and negative prostate cells.

Modulation of pre- and postsynaptic calcium dynamics by ionotropic glutamate receptors at a plastic synapse.

This study was conducted to assess the role of ionotropic glutamate receptors in the modulation of calcium dynamics on both sides of a vertebrate plastic synapse. Retrograde labeling of neuronal elements with high-affinity calcium-sensitive dyes was used in conjunction with confocal imaging techniques in an in vitro lamprey brain stem preparation. A prolonged calcium transient was measured both pre- and postsynaptically in response to a period of high-frequency ("tetanic") stimulation to the vestibulospinal-reticulospinal synapse. The ionotropic glutamate receptor antagonists 6-cyano-7-nitroquinoxaline-2,3-dione (10 microM) and D,L-2-amino-5-phosphonopentanoate (D,L-AP5; 100 microM) reduced the calcium signal in both compartments of the synapse. The presynaptic D,L-AP5-sensitive component was enhanced markedly by the removal of Mg2+ from the superfusate. Increasing the extracellular stimulus intensity progressively augmented the presynaptic calcium signal, suggesting the recruitment of excitatory axo-axonic inputs onto these fibers. Further, the presence of an excitatory amino acid-mediated presynaptic potential underlying a component of the Ca2+ signal was demonstrated by electrophysiological recordings from vestibulospinal axons. Bath application of agonist, in the presence of tetrodotoxin (1 microM), confirmed the existence of N-methyl-D-aspartate receptors at the presynaptic element capable of modulating calcium levels. The postsynaptic Ca2+ response, which is known to be necessary for long-term potentiation (LTP) induction at this synapse, was localized to areas of the dendritic tree that correlated with the location of known synaptic inputs; thus the synaptically activated rise in postsynaptic calcium may confer the synapse specificity of LTP induction previously demonstrated. In summary, we have demonstrated the existence of physiologically activated presynaptic ionotropic glutamate receptors that are capable of modulating levels of intracellular calcium and have highlighted the importance of receptor-mediated increases in postsynaptic calcium for neuronal plasticity in the lamprey.

Brain and Pituitary Hormones of Lampreys, Recent Findings and their Evolutionary Significance

SYNOPSIS. Lampreys of the Class Agnathan are of particular importance in understanding endocrinological relationships since they represent one of the oldest lineages of extant vertebrates, which evolved over 550 million years ago. In this review, agnathans are considered to be paraphyletic in origin, with the modern agnathans classified into two groups, myxinoids (hagfish) and petromyzonids (lamprey). Recent paleontological analysis of modern groups suggests that the jawed vertebrates are more closely related to lampreys than either is to the hagfishes. It has been proposed that there have been two periods of gene duplication during the course of vertebrate evolution, one of which occurred close to the origin of the vertebrates. This paper will summarize the most recent information on the structure and function of newly identified hormones and genes of the brain (lamprey GnRH-I and -III, somatostatin-14; neuropeptide Y-related peptide and a lamprey tachykinin) and pituitary (ACTH, MSH-A, MSH-B, NHF-nasohypophysial factor, POM, and POC) in lampreys. In addition, these data provide further information for the prediction of gene duplication during the early development of vertebrates and increases our understanding of the molecular evolution and functional diversity of these hormones.

An immunocytochemical study of encephalic photoreceptors in three species of lamprey

The extraretinal and extrapineal photoreceptors of three species of adult lamprey, sea lamprey (Petromyzon marinus), river lamprey (Lampetra fluviatilis) and silver lamprey (Ichthyomyzon unicuspis) were studied using antibodies raised against photoreceptor rod and cone opsins, alpha-transducin and arrestin. In all three species cells in the pineal organ (P), parapineal organ (PP), nucleus preopticus (T5), nucleus commissurae postopticae (D8), nucleus ventralis hypothalami (D10) and nucleus dorsalis hypothalami (D11) were labelled by one or more of the anti-opsin antibodies. In addition, anti-arrestin antibodies labelled cells within the D8 and anti-alpha-transducin antibodies labelled cells within the pineal complex and hypothalamus (primarily D8 and/or D10). A more variable and species dependent pattern of opsin, arrestin and alpha-transducin labelling was observed within the nucleus commissurae postinfundibularis (D12) in an area comprising the nucleus dorsalis thalami pars subhabenularis (D4sh) and nucleus dorsalis thalami pars caudalis/nucleus commissurae posterioris (D4c/M1), and in the proximity of the second Müller cells in the ventrocaudal diencephalon (2.MZ/M6). The majority of the neurons labelled within the pineal and parapineal organs and hypothalamus were periventricular with clear cerebrospinal fluid contacts (CSF-contacting neurons). Labelled neurons in the epithalamic (D4sh and D4c/M1) and caudal diencephalon (2.MZ/M6) had no obvious ventricular contacts. We speculate that the "primitive" vertebrate brain of lampreys represents an ancestral condition in which different populations of encephalic photoreceptors are associated with different behavioural and physiological responses. Image-forming vision needs an eye, but irradiance detection does not require a specialised organ. Rather the photoreceptors could be closely associated with their effector systems within the brain.

Immunocytochemical localization of dopamine and its synthetic enzymes in the central nervous system of the lampreyLampetra fluviatilis

The distribution of dopamine (DA)-containing cell bodies, fibers, and terminals in the brain and spinal cord of Lampetra fluviatilis was investigated by immunohistochemical means. In order to distinguish dopaminergic neurons from those using other catecholamines as the primary neurotransmitter, the distribution of dopamine-immunoreactive structures was compared to that of cell bodies, fibers, and terminals labelled with antibodies directed against the enzymes tyrosine hydroxylase (TH), aromatic L-amino acid decarboxylase (AADC), dopamine beta-hydroxylase (DBH), and phenylethanolamine-N-methyl transferase (PNMT). We define dopaminergic neurons as those that are simultaneously DA, TH, and AADC immunoreactive and at the same time DBH and PNMT nonreactive. The overall concentrations of dopamine, noradrenaline, and adrenaline and some of their metabolites were also measured via high-performance liquid chromatography of whole-brain extracts. Our results revealed the presence of 10 populations of dopaminergic neurons in the brain of the lamprey in the olfactory bulb, preoptic area, hypothalamus, rhombencephalon, and spinal cord. In addition, uniquely DA-immunoreactive neurons, in contact with the cerebrospinal fluid, were observed in the hypothalamus and spinal cord. Chromatography indicated that dopamine exists in considerably higher concentrations than noradrenaline in the lamprey brain, whereas adrenaline is absent, the latter finding being supported by our failure to observe any PNMT-immunoreactive cell bodies, fibers, or terminals. The dopaminergic system of the lamprey appears to share many features not only with that of other anamniotes but also with that of amniotes; however, as in teleosts, dopaminergic neurons in the midbrain corresponding to the substantia nigra, the retrorubral area, and the ventral tegmental area of other species do not exist in the lamprey.

Metamorphosis of spinal-projecting neurons in the brain of the sea lamprey during transformation of the larva to adult: normal anatomy and response to axotomy.

The spinal projecting system of the sea lamprey (Petromyzon marinus) has been used extensively in studies of axonal regeneration in both larvae and adults. However, little is known about the changes that are undergone by this system during metamorphosis. In order to determine the developmental changes in the size of the descending spinal projection and in the morphology of its neurons, larval, transforming, and adult lamprey brains were labeled by retrograde transport of horseradish peroxidase (HRP) injected into the spinal cord at 25% of body length. Examination of brain wholemount preparations revealed that the total number of labeled neurons doubled during metamorphosis. Most of this increase could be explained by elongation of reticulospinal axons from the rostralmost segments of the spinal cord to locations caudal to the injection site. There were no additions or deletions of either identified reticulospinal neurons or of reticulospinal nuclear groups between the larval and the adult stages. The proportions of Müller and Mauthner cells that were labeled reached a maximum of 93% during the early stages of metamorphosis. Axons of these neurons are known to project almost the entire length of the cord, even in larvae. Therefore, the efficiency of retrograde transport appears to be greater during metamorphosis than during larval or adult stages. While changes in efficiency of retrograde transport could account for some of the apparent increase in reticulospinal neuron numbers between larvae and animals undergoing metamorphosis, this could not contribute to the further increase in the apparent size of the reticulospinal system in the adult, since efficiency of retrograde labeling in these animals was lower than that at earlier stages. With retrograde labeling, a significant increase was seen in the profusion of dendritic arborization of some Müller and Mauthner cells during the early stages of metamorphosis. This correlated with an increase in the incidence of extreme axonal die-back, as indicated by the presence of retraction bulbs within the brainstem. However, intracellular injection of Neurobiotin in untransected animals showed similar degrees of dendritic arborization at all examined stages of development. Therefore, the dendritic profusion did not reflect developmental changes in neuronal morphology but rather reflected an increased sensitivity to axotomy during metamorphosis. We conclude that, during the transformation of the lamprey from the large larval to the adult form, there is little change in either the size or the dendritic morphology of the identified giant reticulospinal neurons. With respect to the smaller reticulospinal neurons, the distance of projection of many of their axons increases during metamorphosis, but there is very little increase in the number of reticulospinal neurons.

Urotensin II from the River Lamprey (Lampetra fluviatilis), the Sea Lamprey (Petromyzon marinus), and the Paddlefish (Polyodon spathula)

Urotensin II was isolated from extracts of the whole brain of the river lamprey (Lampetra fluviatilis) and the sea lamprey (Petromyzon marinus). The primary structure of the peptide from both species is the same (Asn-Asn-Phe-Ser-Asp-Cys-Phe-Trp-Lys-Tyr-Cys-Val) and this amino acid sequence is identical to that of urotensin II from the dogfish and skate. Consistent with previous morphological studies indicating that the Agnatha lack a caudal neurosecretory system, urotensin II was not detected in an extract of P. marinus spinal cord. The data suggest that the urotensin II may have functioned in the earliest vertebrates as a neurotransmitter/neuromodulator in the central nervous system rather than as a neurohormone of the caudal neurosecretory system. Urotensin II was also isolated from an extract of the spinal cord of a chondrostean fish, the paddlefish (Polyodon spathula). The primary structure of the paddlefish urotensin II (Gly-Ser-Thr-Ser-Glu-Cys-Phe-Trp-Lys-Tyr-Cys-Val) is the same as that of another chondrostean, the sturgeon (Acipenser ruthenus). The study provides further evidence for a widespread distribution of urotensin II in vertebrate species and suggests that the primary structure of the peptide is better conserverd in these phylogenetically ancient fish than in teleosts.

Differential actions of lamprey peptide methionine-tyrosine at Y 1 and Y 2 neuropeptide Y receptors

Peptide methionine-tyrosine (PMY), a peptide of the neuropeptide Y (NPY) superfamily isolated from the brain and intestine of the sea lamprey, had the same maximum effect but was 11-fold less potent than pig NPY in inhibiting field-stimulated contraction of the rat vas deferens, an effect mediated through the Y 2 receptor. In contrast, PMY produced a 9-fold greater maximum effect but was 3-fold less potent than pig NPY in contracting the guinea pig mesenteric artery, an effect mediated through the Y 1 receptor. Molecular modelling has suggested that the conformation of PMY is appreciably different from NPY only in the β-turn region of the molecule (residues 9–14). Our data suggest, therefore, that modifications in this region of NPY may useful in the design of receptor selective analogs.

Diffusion between the Neurohypophysis and the Adenohypophysis of Lampreys, Petromyzon marinus

Horseradish peroxidase (HRP), a protein that can be visualized by appropriate histochemical procedures, was injected into the third ventricle of the brain of adult lampreys, Petromyzon marinus. Within 5 to 15 min HRP had passed through the neurohypophysis, which forms the floor of the third ventricle. It appeared at this time to have diffused throughout the connective tissue separating the adenohypophysial follicles from the neurohypophysis and from each other. This observation would indicate that it is possible for neurosecretory peptides like gonadotropin-releasing hormone to diffuse from the brain (neurohypophysis) to the adenohypophysis and thus regulate its secretory activity in lampreys.

NADPH‐Diaphorase in the central nervous system of the larval lamprey (Lampetra planeri)

The distribution of nitric oxide synthase (NOS) in the lamprey brain was studied by using reduced nicotinamide-adenine-dinucleotide phosphate (NADPH)-diaphorase histochemistry to further elucidate the evolution of neurons synthesizing nitric oxide. Intense labeling of fibers and/or neurons was found in portions of the lamprey central nervous system, such as the olfactory system, the pineal organ, the habenular region, the nervus stato-acousticus (N. VIII), the brainstem, and the spinal cord, and also in the adenohypophysis. Labeled giant cells located at the floor of the 3rd and 4th ventricle were recognized as reticulospinal neurons. Mauthner and Müller cells were identified according to morphological criteria. Eight pairs of Müller cells and one pair of Mauthner cells were labeled by NADPH histochemistry. None of these cells had, as yet, been described to display NOS activity in any vertebrate. The massive staining of these cells and the apparent lack of labeling, e.g., in teleost fishes, may be a histochemical correlate to already known differences of functions served by these cells in different species. In addition, our results suggest that the nitric oxide (NO) system has appeared early in vertebrate evolution.

A Method for in Situ Hybridization in Wholemounted Lamprey Brain: Neurofilament Expression in Larvae and Adults

Nonisotopic in situ hybridization (NISH) using both cDNA and cRNA probes is rapidly gaining favor over autoradiographic methods. Typically, either biotinylated or digoxigenin-labeled probes are used to detect mRNAs in sectioned tissue or in cultured cells. With a few exceptions, most applications of NISH in wholemount preparations have been limited to Drosophila embryos. A protocol developed for NISH in whole adult Drosophila CNS was extended to wholemounted larval and adult lamprey brain preparations. Digoxigeninlabeled RNA probes were transcribed from cloned fragments of a lamprey neurofilament (NF180) cDNA. Hybridization with these probes, and comparisons with Nissl-stained wholemounts and wholemounts retrogradely labeled by injections of tracer into the spinal cord, demonstrated that NF180 mRNA was expressed in only a subset of neurons in the lamprey CNS. These included primarily neurons with long axons that project out of the brainstem, e.g., reticulospinal neurons and cranial motor neurons. Metamorphosis from the larval to the adult form was accompanied by an increase in the number of neurons expressing NF180 and in the apparent level of NF expression as judged by the intensity of labeling. For example, in the oculomotor and trochlear nuclei, expression of NF180 was seen in postmetamorphic young adult lampreys but not in larvae. In the trigeminal motor nucleus, both the number of neurons expressing NF180 and the intensity of the hybridization labeling increased with metamorphosis. The ability to do NISH in lamprey brain wholemounts eliminates the need for serial reconstructions and thus facilitates the study of selected gene expression during metamorphosis and regeneration.