An electron microscope observation of the right and the two left portions of the habenular nuclei of the frog

Review of the cytology and connections of the lateral habenula, an avatar of adaptive behaving

The cytology and connections of the lateral habenula (LHb) are reviewed. The habenula is first introduced, after which the cytology of the LHb is discussed mainly with reference to cell types, general topography and descriptions of subnuclei. An overview of LHb afferent connections is given followed by some details about the projections to LHb from a number of structures. An overview of lateral habenula efferent connections is given followed by some details about the projections from LHb to a number of structures. In considering the afferent and efferent connections of the LHb some attention is given to the relative validity of regarding it as a bi-partite structure featuring 'limbic' and 'pallidal' parts. The paper ends with some concluding remarks about the relative place of the LHb in adaptive behaving.

Neuronal connectivity between habenular glutamate-kisspeptin1 co-expressing neurons and the raphe 5-HT system

The habenula, located on the dorsal thalamic surface, is an emotional and reward processing center. As in the mammalian brain, the zebrafish habenula is divided into dorsal (dHb) and ventral (vHb) subdivisions that project to the interpeduncular nucleus and median raphe (MR) respectively. Previously, we have shown that kisspeptin 1 (Kiss1) expressing in the vHb, regulates the serotonin (5‐HT) system in the MR. However, the connectivity between the Kiss1 neurons and the 5‐HT system remains unknown. To resolve this issue, we generated a specific antibody against zebrafish Kiss1 receptor (Kiss‐R1); using this primary antibody we found intense immunohistochemical labeling in the ventro‐anterior corner of the MR (vaMR) but not in 5‐HT neurons, suggesting the potential involvement of interneurons in 5‐HT modulation by Kiss1. Double‐fluorescence labeling showed that the majority of habenular Kiss1 neurons are glutamatergic. In the MR region, Kiss1 fibers were mainly seen in close association with glutamatergic neurons and only scarcely within GABAergic and 5‐HT neurons. Our findings indicate that the habenular Kiss1 neurons potentially modulate the 5‐HT system primarily through glutamatergic neurotransmission via as yet uncharacterized interneurons.

The neuropeptide kisspeptin (Kiss1) play a key role in vertebrate reproduction. We have previously shown modulatory role of habenular Kiss1 in the raphe serotonin (5‐HT) systems. This study proposed that the habenular Kiss1 neurons modulate the 5‐HT system primarily through glutamatergic neurotransmission, which provides an important insight for understanding of the modulation of 5‐HT system by the habenula‐raphe pathway.

Effects of nostril plugging and of habenulectomy on sexual behaviour in the male crested newt

In an attempt to gain some insight into the possible involvement of the habenulae in the control of sexual behaviour in the male crested newt, a comparison was made between the effects of olfactory deprivation by bilateral nostril plugging and of habenulectomy on courtship performance and locomotor activity. Both treatments led to a decrease in spontaneous locomotion and to a drastic abolition of the complex courtship ritual characterized by the sequence of male postures displayed prior to spermatophore deposition. Following nostril plug removal, the animals resumed their normal activities. Unilateral plugging had no effect. These results seem to lend further support to the importance of specific olfactory stimuli in sexual behaviour. The main finding obtained here was the strict comparability between the behavioural changes resulting from habenulectomy and the olfactory-related changes following nostril plugging, linking from a functional point of view the habenulae with the olfactory system. According to recent reports available in the literature, the morphological organization of the habenular nuclei in urodeles still needs further clarification. On the basis of the present results, the possible importance of the habenulae in olfactory integration in the crested newt might be postulated.

Subnuclear development of the zebrafish habenular nuclei requires ER translocon function

The dorsal habenular nuclei (Dh) of the zebrafish are characterized by significant left-right differences in gene expression, anatomy, and connectivity. Notably, the lateral subnucleus of the Dh (LsDh) is larger on the left side of the brain than on the right, while the medial subnucleus (MsDh) is larger on the right compared to the left. A screen for mutations that affect habenular laterality led to the identification of the sec61a-like 1(sec61al1) gene. In sec61al1(c163) mutants, more neurons in the LsDh and fewer in the MsDh develop on both sides of the brain. Generation of neurons in the LsDh occurs more rapidly and continues for a longer time period in mutants than in WT. Expression of Nodal pathway genes on the left side of the embryos is unaffected in mutants, as is the left sided placement of the parapineal organ, which promotes neurogenesis in the LsDh of WT embryos. Ultrastructural analysis of the epithalamus indicates that ventricular precursor cells, which form an epithelium in WT embryos, lose apical-basal polarity in sec61al1(c163) mutants. Our results show that in the absence of sec61al1, an excess of precursor cells for the LsDh exit the ventricular region and differentiate, resulting in formation of bilaterally symmetric habenular nuclei.

Selective asymmetry in a conserved forebrain to midbrain projection

How the left and right sides of the brain acquire anatomical and functional specializations is not well understood. The zebrafish has proven to be a useful model to explore the genetic basis of neuroanatomical asymmetry in the developing forebrain. The dorsal diencephalon or epithalamus consists of the asymmetric pineal complex and adjacent paired nuclei, the left and right medial habenulae, which in zebrafish larvae, exhibit differences in their size, neuropil density and patterns of gene expression. In all vertebrates, axons from the medial habenular nuclei project within a prominent fiber bundle, the fasciculus retroflexus, to a shared midbrain target, the interpeduncular nucleus of the ventral tegmentum. However, in zebrafish, projections from the left habenula innervate the dorsal and ventral regions of the target nucleus, whereas right habenular efferents project only to the ventral region. A similar dorsoventral difference in habenular connectivity is found in another teleost species, the highly derived southern flounder, Paralichthys lethostima. In this flatfish, directional asymmetry of the habenular projection appears to be independent of the left-right morphology and orientation that an individual adopts post-metamorphosis. Comparative anterograde labeling of the brains of salamanders, frogs and mice reveals that axons emanating from the left and right medial habenulae do not project to different domains, but rather, they traverse the target nucleus in a complementary mirror image pattern. Thus, although the habenulo-interpeduncular conduction system is highly conserved in the vertebrate brain, the stereotypic dorsoventral topography of left-right connections appears to be a feature that is specific to teleosts.

The interplay between the pineal complex and the habenular nuclei in lower vertebrates in the context of the evolution of cerebral asymmetry

This paper presents an overview on the epithalamus of vertebrates, with particular reference to the pineal and to the asymmetrical organization of the habenular nuclei in lower vertebrates. The relationship between the pineal and the habenulae in the course of phylogenesis is here emphasized, taking data in the frog as example. Altogether the data support the hypothesis, put forward also in earlier studies, of a correlation of habenular asymmetry in lower vertebrates with phylogenetic modification of the pineal complex. The present re-visitation was also stimulated by recent data on the asymmetrical expression of Nodal genes, which involves the pineal and habenular structures in zebrafish. The comparative analysis of data, from cyclostomes to mammals, suggests that transformation of epithalamic structures may play an important role in brain evolution. In addition, in mammals, including rodents, a remarkable complexity has evolved in the organization of the habenulae and their functional interactions with the pineal gland. The evolution of these two epithalamic structures seems to open also new perspectives of knowledge on their implication in the regulation of biological rhythms.

The parapineal mediates left-right asymmetry in the zebrafish diencephalon

The dorsal diencephalon (or epithalamus) of larval zebrafish displays distinct left-right asymmetries. The pineal complex consists of the pineal organ anlage and an unpaired, left-sided accessory organ - the parapineal. The neighboring brain nuclei, the left and right dorsal habenulae, show consistent differences in their size, density of neuropil and gene expression. Mutational analyses demonstrate a correlation between the left-right position of the parapineal and the laterality of the habenular nuclei. We show that selective ablation of the parapineal organ results in the loss of habenular asymmetry. The left-sided parapineal therefore influences the left-right identity of adjacent brain nuclei, indicating that laterality of the dorsal diencephalon arises in a step-wise fashion.

WILSON STEPHEN. Asymmetry in the epithalamus of vertebrates

The epithalamus is a major subdivision of the diencephalon constituted by the habenular nuclei and pineal complex. Structural asymmetries in this region are widespread amongst vertebrates and involve differences in size. neuronal organisation, neurochemistry and connectivity. In species that possess a photoreceptive parapineal organ, this structure projects asymmetrically to the left habenula, and in teleosts it is also situated on the left side of the brain. Asymmetries in size between the left and right sides of the habenula are often associated with asymmetries in neuronal organisation, although these two types of asymmetry follow different evolutionary courses. While the former is more conspicuous in fishes (with the exception of teleosts), asymmetries in neuronal organisation are more robust in amphibia and reptiles. Connectivity of the parapineal organ with the left habenula is not always coupled with asymmetries in habenular size and/or neuronal organisation suggesting that, at least in some species, assignment of parapineal and habenular asymmetries may be independent events. The evolutionary origins of epithalamic structures are uncertain but asymmetry in this region is likely to have existed at the origin of the vertebrate, perhaps even the chordate, lineage. In at least some extant vertebrate species, epithalamic asymmetries are established early in development, suggesting a genetic regulation of asymmetry. In some cases, epigenetic factors such as hormones also influence the development of sexually dimorphic habenular asymmetries. Although the genetic and developmental mechanisms by which neuroanatomical asymmetries are established remain obscure, some clues regarding the mechanisms underlying laterality decisions have recently come from studies in zebrafish. The Nodal signalling pathway regulates laterality by biasing an otherwise stochastic laterality decision to the left side of the epithalamus. This genetic mechanism ensures a consistency of epithalamic laterality within the population. Between species, the laterality of asymmetry is variable and a clear evolutionary picture is missing. We propose that epithalamic structural asymmetries per se and not the laterality of these asymmetries are important for the behaviour of individuals within a species. A consistency of the laterality within a population may play a role in social behaviours between individuals of the species.

Nitric oxide synthase activity reveals an asymmetrical organization of the frog habenulae during development: A histochemical and cytoarchitectonic study from tadpoles to the mature Rana esculenta, with notes on the pineal complex

In the adult frog, structural asymmetry of the left dorsal habenula in respect to the right counterpart has been repeatedly documented in previous studies. In the present investigation, histochemical expression of beta-nicotinamide adenine dinucleotide phosphate (NADPH)-diaphorase activity was examined in the habenulae of the developing and adult Rana esculenta. In tadpoles and during metamorphosis, selective neuropil staining was consistently found within a lateral compartment of the medial subnucleus of the left dorsal habenula. The staining was still present in the same location, but much less intense, in the mature frog, indicating that the neurochemical pattern observed during development was at least in part transient. Thus, the present data point out a peculiar neurochemical pattern of the habenular asymmetry in the frog, suggesting that nitric oxide may be involved in the developmental shaping which leads to an asymmetrical configuration of the habenulae. In addition, NADPH-diaphorase-positive cells were detected in the frontal organ (the extracranial component of the pineal complex in strict relationship with the habenulae in the frog), and labeled fibers were found in the frontal nerve, which arises from the frontal organ. This latter finding supports the postulated relationship of the habenular asymmetry with the occurrence of the frontal organ. The finding of NADPH-diaphorase histochemical reactivity confined to a distinct portion of the medial subnucleus of the left dorsal habenula prompted a reexamination of the cytoarchitecture of the developing and mature habenular complex in the frog. The bicompartmentalization detected with histochemistry in the medial subnucleus of the left dorsal habenula of the developing and adult frog was fully supported by the study of Nissl-stained epithalamic sections. These data point out that the left-right structural differences of the frog habenular complex are more complex than previously believed, and may be subserved by chemically regulated developmental processes.

Asymmetry in the left and right habenulo-interpeduncular tracts in the frog

In the frog Rana esculenta the left dorsal habenula includes a lateral and a medial component, whereas the right dorsal habenula is only represented by one nucleus. The efferents of the habenular nuclei to the interpeduncular nucleus were herein investigated with the retrograde horseradish peroxidase tracing. Injections of cobaltic-lysine complex in the interpeduncular nucleus were also performed. Intensely labeled fibers of the fasciculus retroflexus on the right and left sides of the brain were found to reach the interpeduncular nucleus from the habenular nuclei running prevalently in two routes--one through the medial, and the other through the lateral region of the diencephalon. On the right side, these fibers originated from the entire dorsal habenula. On the left side, the fibers of the medial route derived from the medial habenular subnucleus, while those of the lateral route derived from the lateral habenular subnucleus. In the dorsal habenulae of both sides, a large number of neurons displayed a Golgi-like labeling, while few such cells were detected in the ventral habenulae. Labeled neurons in the right dorsal habenula resembled those labeled in the lateral subnucleus of the left dorsal habenula, while larger and ramified neurons were detected in the left medial subnucleus. The present findings provide the first description of the pathway originating from the medial and the lateral subnucleus of the left dorsal habenula in the frog and point out that projection neurons of the medial habenular subnucleus are morphologically different from those of the other habenular nuclei. The present data indicate that in the frog the habenular asymmetry could underlie distinct functional correlates of the left and right habenulae.

Diencephalic asymmetries

Structural asymmetry in diencephalic regions has been reported in a number of studies since the pioneering observations by Kemali and Braitenberg, Atlas of the frog's brain. Springer Verlag: 1969. Anatomical differences between the left and right habenulae have been identified in many lower vertebrate species. While there are few reports of structural asymmetry in the dorsal thalamus, there is evidence that asymmetrical thalamofugal projections can be induced in the visual system of chicks by lateralized sensory stimulation prior to hatching. Finally, there have been consistent reports of differences between and right sides of the hypothalamus in their sensitivity to the effects of circulating gonadal hormones in rats. In most cases, these asymmetries are sex-linked and correspond to a lateralization of function. Although the significance of these diencephalic asymmetries is still enigmatic, their existence indicates that asymmetry is not a phylogenetically recent feature of the brain, and the left-right differences in the brain may be mediated by a common ontogenetic mechanism and may underlie the development of highly specialized functions.

Organization of the serotoninergic system in the brain of two amphibian species, Ambystoma mexicanum (Urodela) and Typhlonectes compressicauda (Gymnophiona)

An immunocytochemical investigation was made of the distribution of serotonin (5-HT) in the brain of larval and adult Ambystoma mexicanum and adult Typhlonectes compressicauda. Immunoreactive perikarya can be identified in the caudal diencephalon (paraventricular organ and infundibular nucleus), in the ventral mesencephalon (interpeduncular nucleus) and in the raphe of the rhombencephalon. Immunopositive fibers and terminal arborizations are widely distributed, extending from the whole telencephalon to the spinal lemniscus area. However, the retinorecipient structures of the thalamus and mesencephalon are either very weakly innervated (Ambystoma) or completely immunonegative (Typhlonectes). The habenular system also exhibits very few 5-HT-positive structures. The major serotoninergic neuron clusters, in both Urodela and Gymnophiona, tend to gather, from the paraventricular organ to the raphe, on both sides of the sagittal plane, showing no tendency to "lateralization". A new interpretation of the limited development of the serotoninergic system in amphibians is given.

Naloxone-reversible analgesia induced by electrical stimulation of the habenula in the rat

During a previous study of the nucleus parafascicularis (Pf), cells were recorded in the lateral habenula (HbL) which exhibited response patterns to peripheral noxious stimuli similar to those recorded in the Pf. In order to study the possible role of the habenular complex (Hb) in pain processing, we investigated the effect of electrical stimulation of the Hb on the tail-flick latency. For each series of experiments, the Hb of 15 female rats was implanted unilaterally, with bipolar electrodes, on either the right or left side. A week later, the animals were submitted to measurements of tail-flick latency, every 10 min, for a period of 3 h. The amount of analgesia was estimated by the percentage increase in latency. Five intensities of current (50, 100, 200, 300 and 400 microA) were used for stimulation during 60 s, at 50 Hz and 0.5-ms pulse width. A group of animals were given naloxone i.p. (1 mg/kg) 40 min after Hb stimulation at 200 microA to study the reversibility of the analgesia. A second group had their Hb destroyed by coagulation and the effect on tail-flick latency was checked once a week for 4 weeks. The results of these experiments clearly demonstrate Hb stimulation-induced analgesia, the maximum of which occurs 60-80 min after stimulation and then decreases slowly. The maximal amount of analgesia increases with the intensity of current up to 200 microA, without any behavioral side effects. At 300 microA, the analgesia is not significantly different from the one induced at 200 microA. However at 400 microA, behavioral side effects (fear, escape) appear and the analgesia is weaker. Two-hundred microA appears to be the most efficient current intensity and induces an average of 80% increase in tail-flick latency. The group which was given naloxone exhibited a dramatic and complete reversal of analgesia. The group which had their Hb destroyed did not show any difference from the control group a week after surgery. During the following weeks, both lesioned animals and controls exhibited a habituation-like analgesia, without any significant difference (the index of analgesia was 45.73 +/- 23.65% for the lesioned rats and 51.82 +/- 29.18% for the controls), which was not naloxone reversible. A review of the literature does not provide an explantation for Hb-induced analgesia.(ABSTRACT TRUNCATED AT 400 WORDS)

The dorsal diencephalic conduction system: a review of the anatomy and functions of the habenular complex

The first part of this paper is an attempt to sketch an outline of the anatomy of the dorsal diencephalic conduction system by reviewing experimental evidence establishing the afferent and efferent connections of the habenular complex. This system provides an alternative to the descending medial forebrain bundle for the conduction of information from the limbic forebrain to limbic midbrain areas. The second part is a critical examination of experiments using ablation or electrical and chemical stimulation techniques which are concerned with the behavioural functions of the habenular complex. The habenula has been shown to play an important role in a diverse set of behavioural systems, which include olfaction, ingestion, mating, endocrine function, aversive motivation, and brain stimulation. Anatomical and behavioural support is presented for the view that the dorsal diencephalic conduction system provides an opportunity for interaction of activity in motivational systems with movement systems in the striatum and midbrain.