Physiological response of bovine subcommissural organ to endothelin 1 and bradykinin.

The circumventricular organs (CVOs) regulate certain vegetative functions. Receptors for bradykinin (BDK) and endothelin (ET) have been found in some CVOs. The subcommissural organ (SCO) is a CVO expressing BDK-B2 receptors and secreting Reissner's fiber (RF) glycoproteins into the cerebrospinal fluid. This investigation was designed to search for ET receptors in the bovine SCO and, if found, to study the functional properties of this ET receptor and the BDK-B2 receptor. Cryostat sections exposed to (125)I ET1 showed dense labeling of secretory SCO cells, whereas the adjacent ciliated ependyma was devoid of radiolabel. The binding of (125)I ET1 was abolished by antagonists of ETA and ETB receptors. The intracellular calcium concentration ([Ca(2+)](i)) was measured in individual SCO cells prior to and after exposure to ET1, BDK, or RF glycoproteins. ET1 (100 nM) or BDK (100 nM) caused an increase in [Ca(2+)](i) in 48% or 53% of the analyzed SCO-cells, respectively. RF glycoproteins had no effect on [Ca(2+)](i) in SCO cells. ET and BDK evoked two types of calcium responses: prolonged and short responses. Prolonged responses included those with a constant slow decline of [Ca(2+)](i), biphasic responses, and responses with a plateau phase at the peak level of [Ca(2+)](i). ET1-treated SCO explants contained a reduced amount of intracytoplasmic AFRU (antiserum to RF glycoproteins)-immunoreactive material compared with sham-treated control explants. Our data suggest that ET1 and BDK regulate [Ca(2+)](i) in bovine SCO cells, and that the changes in [Ca(2+)](i) influence the secretory activity of these cells.

The floor plate cells from bovines express the mRNA encoding for SCO-spondin and its translation products.

The floor plate (FP) is a transient structure of the embryonic central nervous system (CNS) which plays a key role in development driving cell differentiation and patterning in the ventral neural tube. The fact that antisera raised against subcommissural organ (SCO) secretion immunostain FP cells and react with high-molecular-mass proteins in FP extracts, prompted us to investigate the expression of a SCO-related polypeptide in FP cells. RNA from bovine FP was analyzed by means of reverse transcriptase polymerase chain reaction (RT-PCR), using primers derived from the 3' end of SCO-spondin which revealed products of 233, 237, 519 and 783 bp. Sequence analysis of the 233 bp PCR fragment confirmed the identity between this FP product and SCO-spondin. FP-translation of the SCO-spondin encoded polypeptide(s) was demonstrated by Western blot analysis and immunocytochemistry, using antisera raised against (i) the glycoproteins secreted by the bovine SCO, and (ii) a peptide derived from the open reading frame of the major SCO secretory protein, SCO-spondin, respectively. Additional evidence pointing to active transcription and translation of a SCO-spondin related gene was obtained in long term FP organ cultures. On the basis of partial sequence homologies of SCO-spondin with protein domains implicated in cell-cell contacts, cell-matrix interactions and neurite outgrowth it is possible to suggest that the SCO-spondin secreted by the FP is involved in CNS development.

The dispersed cell culture as model for functional studies of the subcommissural organ: preparation and characterization of the culture system.

The subcommissural organ (SCO) is an enigmatic secretory gland of the brain, which is believed to be derived from ependymal (glial) precursor cells. We here developed a dispersed cell culture system of the bovine SCO as an approach to functional analyses of this brain gland. Tissue of the bovine SCO obtained from the slaughterhouse was papain dissociated either directly after dissection or after preparation of SCO explants. The latter had been maintained for 4-6 weeks in organ culture. The dispersed cells were cultured for up to 14 days and continuously tested for their secretory state by immunostaining of their secretory product. With respect to the morphology of the SCO cells (shape, processes, nucleus), no difference was found between the culture of freshly dissociated SCOs and that of dissociated SCO explants. In all cases, the dissociation caused a dedifferentiation; typical elongated cells were formed increasingly after 1 day of culture. Thereafter, only the cellular size increased, whereas the shape and the viability of the cells remained unchanged. Proliferating SCO cells were never observed. The culture obtained from fresh SCO tissue contained more glia cells and fibrocytes than the culture prepared from SCO explants. The proliferation of glia cells and fibrocytes was suppressed by blocking the mitotic activity with cytosine-beta-D-arabino furanoside (CAF). The cytophysiological features of the cultured dispersed cells of both origins did not differ as demonstrated by classical histology, by immunocytochemistry for the secretory products of the SCO, by the characteristics of calcium influx into the cytoplasm ([Ca2+]i) and cyclic adenosine monophosphate (cAMP) after stimulation with adenosine-5-triphosphate, substance P or serotonin, and by the activation of the transcription factor cAMP-responsive element-binding protein. Because of the maintenance of their viability, their capacity to release the secretory product into the culture medium, their receptive capacity, and their signal transduction pathways, we conclude that the dispersed cell culture system, especially that obtained from SCO explants, represents an appropriate and useful model for functional studies of the mammalian SCO.

Organ culture of the bovine subcommissural organ: evidence for synthesis and release of the secretory material.

The subcommissural organ (SCO) is a brain circumventricular organ formed by ependymal and hypendymal secretory cells. It secretes glycoproteins into the cerebrospinal fluid of the third ventricle where they condense into a thread-like structure known as Reissner's fiber (RF). The present study was designed to investigate whether or not the bovine SCO continues to synthesize and release glycoproteins after a long-term culture. Cultured explants of SCO survive for several months. The content of the secretory granules present in the cultured ependymocytes displayed immunoreactive and lectin-binding properties similar to those of the core glycosylated glycoproteins found in the bovine SCO. The explants actively incorporated (35)S-cysteine. In the cultured ependymocytes, the pattern of distribution of the radioactive label and that of the immunoreactive secretory material was similar, thus indicating that this material has been synthesized during culture. At the ultrastructural level, the cultured tissue exhibited a high degree of differentiation comparable to that of the bovine SCO in situ. A striking finding was the observation of similar results when cerebrospinal fluid was used as a culture medium. The addition of antibodies against RF-glycoproteins into the culture medium allowed visualization, by means of different immunocytochemistry protocols, deposits of extracellular immunoreactive secretory material on the free surface of the cultured ependymocytes, indicating that release of secretory glycoproteins into the culture medium does occur. Primary culture of dispersed SCO ependymocytes, obtained either from fresh or organ cultured bovine SCO, showed that these cells release RF-glycoproteins that aggregate in the vicinity of each cell. The present investigation has shown that: (1) two types of secretory ependymocytes become evident in the cultured SCO; (2) under culture conditions, the SCO cells increase their secretory activity; (3) explants of bovine SCO synthesize RF-glycoproteins and release them to the culture medium; (4) after release these proteins aggregate but do not form a RF; (5) a pulse of anti-RF antibodies into the culture medium blocks the secretion of RF-glycoproteins for several days.

Vertebrate floor plate transiently expresses a compound recognized by antisera raised against subcommissural organ secretion.

Located along the ventral midline of the neural tube, the floor plate (FP) performs an essential role in central nervous system development, especially in the patterning of the ventral region of the neural tube and axonal guidance. Several studies have been directed to the identification of molecules mediating some of the functions of the FP. Most of the models proposed for floor plate actions involve contact-mediated- and/or gradients of diffusible-signals acting throughout the nervous tissue. This report presents and discusses findings showing that the FP cells secrete a novel compound, which is recognized by antisera raised against secretory products of the subcommissural organ (SCO). This immunoreactive compound appears to be very similar to one of the glycoproteins secreted by the SCO. This immunoreactivity is expressed transiently during central nervous system development, and its rostro-caudal extension along the anterior-posterior axis of the FP displays some species variations. However, a constant feature in all species investigated is that this immunoreactive compound is highly expressed in the FP located in the mesencephalic-metencephalic boundary. The distribution of this compound is compatible with basal and apical pathways of release from FP cells. The former might participate in the formation of some brain commissures. The latter might involve the use of the cerebrospinal fluid as a route for performing actions on distant targets, a pathway somehow disregarded by most models accounting for morphogen actions.

Partial sequencing of Reissner's fiber glycoprotein I (RF-Gly I).

The bulk of the secretion of the subcommissural organ is formed by glycoproteins that appear to be derived from two precursor forms of 540 and 320 kDa. Upon release into the ventricle, these glycoproteins aggregate to form Reissner's fiber. We report the isolation of three cDNA clones from a cDNA library prepared from bovine subcommissural organ RNA, by using an anti-Reissner's fiber serum for immunoscreening. Inserts of 0.7, 1.2, and 2.5 kb were amplified by the polymerase chain reaction, subcloned into pUC18 vector, and sequenced. Although restriction mapping of the three inserts initially suggested that all of them were derived from the same mRNA, sequence analysis showed that a short non-homologous region was present in the 0.7-kb insert when compared with the 1. 2-kb and 2.5-kb inserts, suggesting that they corresponded to two different, although highly homologous, mRNAs. Northern analyses showed a single mRNA species of approximately 9.5 kb present in the subcommissural organ and missing in the choroid plexus, brain cortex, and liver. In situ hybridization confirmed that the expression of the RNA was restricted to cells of the bovine subcommissural organ. Polyclonal antibodies raised against a synthetic peptide, whose amino-acid sequence was deduced from the 2.5-kb cDNA, reacted specifically with the bovine and rat subcommissural organ-Reissner's fiber complex. In immunoblots of bovine subcommissural organ, this antibody revealed the precursor 540-kDa form and its putative processed form of 450 kDa. It is concluded that the cloned cDNA encodes for the major constitutive glycoprotein of Reissner's fiber, here designated as RF-Gly I. The sequenced region of RF-Gly I displays a high degree of homology with some regions of the von Willebrand factor and certain mucins; it also displays two motifs homologous with repeats present in proteins of the spondin family and other proteins. A core sequence of the RF-Gly I repeats suggests that this molecule displays protein-binding properties.

Floor plate and the subcommissural organ are the source of secretory compounds of related nature: comparative immunocytochemical study.

The subcommissural organ of vertebrates secretes glycoproteins into the third ventricle that condense to form Reissner's fiber (RF). Antibodies raised against the bovine RF-glycoproteins reacted with the floor plate (FP) cells of two teleost (Oncorhynchus kisutch, Sparus aurata) and two amphibian (Xenopus laevis, Batrachyla taeniata) species. At the ultrastructural level, the immunoreactivity was confined to secretory granules, mainly concentrated at the apical cell pole. In the rostro-caudal axis, a clear zonation of the FP was distinguished, with the hindbrain FP being the most, or the only (Batrachyla taeniata), immunoreactive region of the FP. In all the species studied, the caudal FP lacked immunoreactivity. Both the chemical nature of the immunoreactive material and the rostro-caudal zonation of the FP appear to be conservative features. Evidence was obtained that the FP secretes into the cerebrospinal fluid a material chemically related to the RF-glycoproteins secreted by the subcommissural organ. Thus, in addition to being the source of contact-mediated and diffusible signals, the FP might also secrete compounds into the cerebrospinal fluid that may act on distant targets.

Light- and electron-microscopic investigation of the rat subcommissural organ grafted under the kidney capsule, with particular reference to immunocytochemistry and lectin histochemistry.

There is increasing evidence that, in the rat, a serotonin-mediated neural input may have an inhibitory influence on the secretory activity of the subcommissural organ (SCO). In the present investigation the rat SCO was studied 7, 30 and 90 days after transplantation under the kidney capsule, an area devoid of local serotonin-containing nerves. The grafted tissue was examined by use of immunocytochemistry employing a series of primary antisera, lectin histochemistry and transmission electron microscopy. The grafted SCO survived transplantation and contained, in addition to secretory ependymal and hypendymal SCO-cells, also elements immunoreactive with antisera against glial fibrillary acidic protein or S-100 protein. In transplants, SCO-cells produced a material displaying the characteristic immunocytochemical and lectin-binding properties of SCO-cells observed under in-situ conditions. The ependymal cells lined 1-3 small cavities, which contained secretory material. A fully developed structural equivalent of Reissner's fiber was, however, never found. The immunocytochemical and ultrastructural study of the grafted SCO showed an absence of nerve fibers within the graft and suggested a state of enhanced secretory activity. A network of protruding basal lamina structures connected the secretory cells to the newly formed capillaries revascularizing the SCO. One week after transplantation, long-spacing collagen started to appear in expanded areas of such laminar networks and also in the perivascular space. It is suggested (i) that the formation of long-spacing forms of collagen is triggered by factors provided by the SCO-secretory cells, and (ii) that secretory material of the ependymal and hypendymal cells may reach the reticular extensions of the basal lamina. In contrast to the SCO in situ, the grafted SCO-cells showed a positive immunoreaction for neuron-specific enolase. They became surrounded by a S-100-immunoreactive glial sheath that separated them from other transplanted cell types and the adjacent kidney tissue of the host.

Occurrence of an anterior spinal, cerebrospinal fluid-contacting, urotensin II neuronal system in various fish species.

The occurrence of an "extraurophyseal" system of immunoreactive-urotensin II (IR-UII) neurons was determined by immunocytochemical studies in the central nervous system of different fresh- and seawater species of fish. The following general elements were identified as forming part of this system: (a) a midsagittal column of IR-UII neurons located ventral to the central canal, with dendrite-like processes projecting into the cerebrospinal fluid (CSF); (b) a medial plexus of fine beaded IR-UII fibers located ventral to the column of cell bodies; (c) a bilateral or midsagittal, probably ascending, longitudinal bundle of IR-UII beaded fibers varying in location from the ventral to the lateral funiculus; (d) putative IR-UII fiber endings along the ventrolateral surface of the spinal cord; (e) IR-UII fiber distributions (probably terminal) in the ventral horns of the spinal cord and in several brain regions. The occurrence of this system in all fishes examined and the morphological features of this IR-UII system linking the central canal CSF to several CNS regions, as well as to the periphery of the spinal cord, point to an important role for this CSF-contacting anterior spinal IR-UII system in fish.

Pinealocytes immunoreactive with antisera against secretory glycoproteins of the subcommissural organ: a comparative study.

By means of light-microscopic immunocytochemistry two polyclonal antibodies (AFRU, ASO; see p. 470) directed against secretory glycoproteins of the subcommissural organ were shown to cross-react with cells in the pineal organ of lamprey larvae, coho salmon, a toad, two species of lizards, domestic fowl, albino rat and bovine (taxonomic details, see below). The AFRU-immunoreactive cells were identified as pinealocytes of the receptor line (pineal photoreceptors, modified photoreceptors or classical pinealocytes, respectively) either due to their characteristic structural features or by combining AFRU-immunoreaction with S-antigen and opsin immunocytochemistry in the same or adjacent sections. Depending on the species, AFRU- or ASO-immunoreactions were found in the entire perikaryon, inner segments, perinuclear area, and in basal processes facing capillaries or the basal lamina. In most cases, only certain populations of pinealocytes were immunolabeled; these cells were arranged in a peculiar topographical pattern. In lamprey larvae, immunoreactive pinealocytes were observed only in the pineal organ, but not in the parapineal organ. In coho salmon, the immunoreaction occurred in S-antigen-positive pinealocytes of the pineal end-vesicle, but was absent from S-antigen-immunoreactive pinealocytes of the stalk region. In the rat, AFRU-immunoreaction was restricted to S-antigen-immunoreactive pinealocytes found in the deep portion of the pineal organ and the habenular region. These findings support the concept that several types of pinealocytes exist, which differ in their molecular, biochemical and functional features. They also indicate the possibility that the AFRU- and ASO-immunoreactive material found in certain pinealocytes might represent a proteinaceous or peptide compound, which is synthesized and released from a specialized type of pinealocyte in a hormone-like fashion. This cell type may share functional characteristics with peptidergic neurons or paraneurons.

Relationship between urotensin II- and somatostatin-immunoreactive spinal cord neurons of Catostomus commersoni and Oncorhynchus kisutch (Teleostei).

This immunocytochemical study describes the presence of separate immunoreactive (IR)-urotensin II (UII) and IR-somatostatin (SOM) systems in the spinal cord of two species of teleost fish. Both systems are arranged in a close spatial interrelationship in which IR-SOM fibres apparently innervate cerebrospinal fluid (CSF)-contacting IR-UII neurons. Specimens of Oncorhynchus kisutch also display CSF-contacting IR-SOM neurons located in the lateral ependymal walls of the central canal, in addition to CSF-contacting IR-UII neurons located ventrally. It is suggested that, in this species, CSF-contacting IR-SOM and IR-UII neurons perceive different stimuli from the CSF and are integrated in such a way that one peptidergic system may modulate the function of the other.

Co-localization of the immunoreactivities of corticotropin-releasing factor and arginine vasotocin in the brain and pituitary system of the teleost Catostomus commersoni.

The peroxidase-antiperoxidase immunocytochemical procedure was used to study the distribution of ovine corticotropin-releasing factor (CRF) and arginine vasotocin (AVT) immunoreactivities sequentially in the same sections or in adjacent sections of the brain and pituitary of Catostomus commersoni. It was found that all CRF-immunoreactive (IR) neurons in the nucleus preopticus (NPO) also contained AVT immunoreactivity. Co-localization of both immunoreactivities was also observed in fibres forming the preoptic-pituitary tract and in the neurohypophyseal digitations, the IR-CRF and IR-AVT fibres projecting mainly to the neurointermediate lobe (NIL) of the pituitary. An additional population of exclusively IR-AVT neurons and fibres in the NPO, preoptic-pituitary tract and NIL was also observed. Exclusive CRF-immunostaining was found in neurons of the nucleus lateralis tuberis (NLT), in fibres distributed in some diencephalic nuclei and in the neurohypophyseal digitations in the region of the rostral pars distalis (RPD). These results suggest that CRF- and AVT-like substances, present in NIL fibres (probably originating in the NPO), may have an integrated role in the release of the cell products from the pars intermedia, and that the control of corticotrops in the rostral pars distalis, innervated exclusively by IR-CRF fibres (probably originating in the NLT), does not require a simultaneous presence of CRF- and AVT-like substances.

The distribution of 'extraurophyseal' urotensin I-immunoreactivity in the central nervous system of Catostomus commersoni after urophysectomy.

The occurrence and distribution of the fish neuropeptide urotensin I-immunoreactive (IR-UI) perikarya and fibres was investigated by peroxidase-anti-peroxidase immunohistochemistry in paraffin and vibratome sections of the central nervous system of urophysectomized and control fishes. IR-UI neurones not described previously were found in the area ventralis telencephali pars dorsalis, in the area pretectalis and in two unidentified brainstem nuclei of control and urophysectomized fishes. In urophysectomized fishes a 4-fold increase in the number of parvocellular IR-UI neurons was observed in the nucleus lateralis tuberis, whereas no significant differences were seen in other IR-UI neuronal groups. A functional relationship between IR-UI 'extraurophyseal' (i.e. brain) and caudal neurosecretory systems is suggested.

Extraurophyseal distribution of urotensin II immunoreactive neuronal perikarya and their processes.

The use of the unlabeled antibody enzyme method on serially adjacent sections permitted the demonstration of urotensin II (UII) and urotensin I (UI) immunoreactivities colocalized in most of the cells of the caudal neurosecretory system of Catostomus commersoni. The study of the upper regions of the central nervous system from the spinal cord anterior to the fifth preterminal vertebral region up to and including the brain stem revealed the presence of UII immunoreactivity in cerebrospinal fluid-contacting neurons, located ventral to the central canal along the entire length of the spinal cord and medulla. Beaded nerve fibers were observed projecting to the ventrolateral surface of the spinal cord and also forming a seemingly ascending immunoreactive-UII longitudinal bundle directed toward the brain. The presence of this "extraurophyseal" system of immunoreactive-UII cells and fibers suggests that the UII peptide may be released in upper regions of the central nervous system in response to stimuli conveyed via the cerebral spinal fluid. Thus, separate functions may be postulated for the urophyseal and the cerebral spinal fluid-contacting urotensin II systems.

Localization of urotensin I- and corticotropin-releasing factor-like immunoreactivity in the central nervous system of Catostomus commersoni.

The distribution of urotensin I (UI) and corticotropin-releasing factor (CRF) immunoreactive (IR) structures was studied in the central nervous system (CNS) of the white sucker using the peroxidase-antiperoxidase immunocytochemical procedure. The close sequence homology between both peptides resulted in a high degree of crossreactivity. This was resolved by saturating the antisera solutions with heterologous antigens and specificity tests were done by adding excess of homologous peptides. UI immunoreactivity was seen in all of the identifiable caudal spinal cord neurosecretory cells, in their processes projecting to the urophysis, in thin beaded fibres coursing along the spinal cord, in brain stem, hypothalamus, proximal pars distalis and, especially, in the telencephalon. Some IR-UI specific and IR-CRF specific parvocellular neurons were also identified in the caudo-ventral tuberal region and ventral telencephalon. The IR-CRF was mainly present in parvocellular and magnocellular perikarya of the nucleus preopticus and in the preoptic-neurohypophysial pathway. Dense networks of IR-CRF reacting beaded fibres were also located in the lateral and posterior recessus nuclei. In the pituitary, IR-CRF fibre bundles were seen mainly in the neurointermediate lobe and in the rostral pars distalis. The cells of origin of the extraurophyseal system of IR-UI fibres in the sucker CNS have not been identified. The distribution of CRF immunostaining correlates well with the documented knowledge of CNS structures involved in the control of ACTH secretion in the goldfish. The probability of the occurrence of two UI-CRF related molecules, or of two different forms resulting from a common precursor molecule, forming two separate neuronal systems in the sucker CNS seems likely.

The fish neuropeptide urotensin I: its physiology and pharmacology.

Significant structural and biological homologies between urotensin I (UI), ovine hypothalamic corticotropin releasing factor (oCRF) and the frog skin peptide sauvagine (SVG) have been investigated and compared in fishes and mammals. In mammals, urotensin and the related peptides exert uniquely selective mesenteric vasodilatation, oCRF having approximately equal to 4% the activity of the other two. All three peptides are equipotent in stimulation of ACTH secretion in the rat in vivo and in vitro. UI is significantly more potent than the other two related peptides in stimulation of ACTH secretion in the goldfish pituitary. Immunocytochemical demonstration of UI not only in the caudal spinal cord but also in the brain, mainly in the lateral tuberal region and of an oCRF-like substance in the preoptic nucleus and pituitary, suggests that ACTH secretion in fishes may be controlled by two similar but distinct UI- or oCRF-like peptides.

Immunocytochemistry and ultrastructure of the neuropil located ventral to the rat supraoptic nucleus.

The neuropil located ventral to the SON was investigated by the use of immunoperoxidase staining for neurophysins, oxytocin and vasopressin, and electron microscopy. The study was performed in six groups of rats: 1) control; 2) infusion of isotonic saline into the CSF; 3) infusion of hypertonic saline into the CSF; 4) drinking hypertonic saline for 4 days; 5) same as group 4 but injection of colchicine into the CSF on second day of dehydration; 6) salt loading for 3 months. In the control rats the ventral neuropil contained a few immunoreactive processes, the general morphology of which was completely different from that of the neurosecretory axons emerging from the SON at its dorsal aspect. In rats of groups 3 to 6 the ventral processes (VP) became loaded with neurosecretory granules, whereas the perikarya and axons were depleted. Based on their general morphology and reactivity pattern it is suggested that the VP are dendrites. Most of these "dendrites" were embedded in a glial cushion formed by the processes of a particular type of marginal glia. Some of these "dendrites" enveloped an arteriole penetrating the optic tract. All VP were rich in synaptic contacts. The possibility that the VP of neurosecretory cells may be functionally related to the subarachnoid CSF and the arteriolar blood flow is discussed.

Neurophysin pathways in the normal and hypophysectomized rat.

The hypothalamo-extrahypophyseal neurophysin pathways (HEH) and the three hypothalamic nuclei secreting neurophysins, the supraoptic (SON), paraventricular (PVN) and suprachiasmatic (SCN) nuclei, of normal and hypophysectomized rats were studied by application of the immunoperoxidase procedure. Eight well-defined HEH pathways were recognized. Their main sites of projection were: lateral septum and subfornical organ (1 and 2); tractus diagonalis (3); medial nucleus of the amygdala and lateral ventricle (4); nucleus periventricularis thalami, nucleus habenulae lateralis and periaqueductal gray (5); periaqueductal gray, pineal organ, collicular recess and subependymal region of the fourth ventral (6); dorsomedial nucleus and premammillary area (7); perimammillary region, corpus trapezoideum, ventral surface of medulla oblongata, nucleus tractus solitarii, nucleus commissuralis, substantia gelatinosa and formatio reticularis lateralis of the medulla oblongata and spinal cord (8). Neurophysin fibers of unknown origin were found in the frontal cerebral cortex. It was noted that in pathway 5 the amount of immunostainable material undergoes changes with age. The three neurophysin-secreting nuclei reacted differently following hypophysectomy. Among the HEH pathways the only one that seemed to be affected by hypophysectomy was that innervating the lateral septum. It is suggested that the neurons that survive hypophysectomy either do not project to the neural lobe or, alternatively, display axon collaterals projecting outside the neural lobe. Such a neuronal population could be the origin of the HEH pathways.