Hiroko Sako

Ipsilateral connections of the anterior cingulate cortex with the frontal and medial temporal cortices in the macaque monkey

The present study was attempted to study ipsilateral corticocortical connections of the anterior part (area 24) of the cingulate cortex of the macaque monkey by means of wheat germ agglutinin-conjugated peroxidase (WGA-HRP) method. In 2 out of 4 Japanese monkeys (Macaca fuscata) that were injected with WGA-HRP into the anterior part of the cingulate cortex, the sites of injection were successfully localized within the cortical regions corresponding to areas 24a and 24b. The results obtained from these monkeys indicate that areas 24a and 24b in the anterior part of the cingulate cortex are reciprocally connected with the prefrontal, premotor, and motor cortical regions, and also with the medial temporal cortical regions. Areas 24a and 24b were strongly connected with the lateral and medial prefrontal cortices and area 6a beta of the premotor cortex, moderately with the remaining premotor cortex, and weakly with the motor cortex. In the medial temporal cortex, areas 24a and 24b were strongly connected with the prosubiculum, entorhinal cortex (area 28), and perirhinal cortex (areas 35 and 36), and weakly with areas TF and TH of the parahippocampal gyrus, throughout their rostrocaudal extent. In addition, areas 24a and 24b projected to the molecular layer of the CAI subfield of Ammons horn and the external pyramidal layer of the presubiculum. Our findings suggest that areas 24a and 24b of the anterior cingulate cortex may constitute relays in the reciprocal pathways between the prefrontal cortex and the hippocampal, entorhinal and/or perirhinal cortical regions.

Development of serotoninergic system in the brain and spinal cord of the chick.

(1) Development of serotonin positive cells and fibers was immunohistochemically studied by the use of an antibody against serotonin. (2) Serotoninergic neurons were first observed in the immature rohmbencephalon raphe nuclei on embryonic day (E)4, where two clusters of serotonin positive neurons were located: one observed at the rostral part of the rohmbencephalon corresponding to the dorsal raphe nuclei had many serotonin positive cells: the other located at the caudal part of the rohmbencephalon corresponding to the medullary raphe nuclei of the adult animals had only a small number of serotoninergic cells. (3) By E8 the number of serotonin positive cells in the brain stem increased, and virtually all the raphe nuclei found in an adult animal were located. (4) Serotonin positive fibers in the marginal layer reached up to the diencephalon and telencephalon on E6 and E8, respectively. (5) Serotonin positive cells were found beside the midline regions in the ventral part of the spinal cord of the embryonic as well as posthatching chick. (6) Because almost all the serotoninergic fibers in the spinal cord originated from the brain stem raphe nuclei, propriospinal serotonin positive cells were considered as phylogenetic vestiges. (7) Serotoninergic fibers were first found in the marginal layer of the cervical and lumbar spinal cord on E6 and E8, respectively. (8) There was a waiting period of a few days before they penetrated into the mantle layer. (9) Terminal arbolization of the serotoninergic fibers started from late embryonic periods (E16 less than), and was maximized within one week of hatching. (10) Thereafter the density of serotonin positive fibers decreased in all the regions of the spinal cord. (11) Developmental changes of the density of serotonin determined with a high performance liquid chromatography were the same as those determined through immunohistochemistry. Namely the density of serotonin increased linearly from E6 to hatching period, and reached the maximum value one week posthatching. (12( The density of the serotonin in the adult spinal cord was about half of the maximum value. (13) It is to say that the densities of serotonin and serotoninergic fibers transiently increased around one week posthatching. (14) Following the transient increase serotoninergic fibers were eliminated from the neuropil, the fibers were localized in the specific regions of the motor nucleus: motor neuron pools of extensor muscles of the hip joint in the lumbosacral spinal cord.(ABSTRACT TRUNCATED AT 400 WORDS)

Developmental changes in serotonin levels in the chick spinal cord and brain.

Developmental changes in 5-hydroxytryptamine (5-HT) and 5-hydroxyindoleacetic acid (5-HIAA) in the developing chick spinal cord and brain were examined using high-performance liquid chromatography with electrochemical detection and immunohistochemistry. On embryonic day (E)6 only small amounts of 5-HT (0.086 ng) and 5-HIAA (0.0144 ng) were found in the spinal cord. By contrast, large amounts of 5-HT (x30) and 5-HIAA (x60) were detected in non-neuronal tissue outside the spinal cord; a similar distribution of 5-HT was also detected by immunohistochemistry. Up to E10, the highest concentrations of 5-HT in the spinal cord were found in the cervical region, followed by the thoracic and lumbar regions. In embryos older than E16, as well as in posthatched chicks, however, the highest and lowest concentrations of 5-HT were found in the lumbar and thoracic spinal cord, respectively. The concentration of spinal cord 5-HT reached maximal values on posthatching day (P)7, after which there was a marked decrease. By P120, 5-HT levels in the spinal cord decreased to the same level as on E10-E16. Concentrations in the brain, however, gradually increased with development. The basic pattern of development of 5-HIAA was similar to that of 5-HT.

Differential innervation of specific motor neuron pools by serotoninergic fibers in the chick spinal cord

A new technique in which cholera toxin subunit B conjugated to horseradish peroxidase is injected in chick muscles followed by perfusion with Zambonis fixative for serotonin immunocytochemistry allows one to visualize immunoreactive fibers and retrogradely labelled motoneurons in alternate sections. Using these procedures, we have found that there is a differential innervation by serotoninergic fibers of motoneuron pools that project to specific muscles or muscle groups. Dense clusters of serotonin-positive fibers were located in the motoneuron pools of extensors of the hip joint consisting of the lateral iliotibialis, ischioflexorius, iliofibularis, accessorius and caudilioflexorius muscles.

The pattern of distribution of serotoninergic fibers in the anterior horn of the chick spinal cord

SummaryThe pattern of distribution of serotonin positive fibers in the motor nuclei of the chick spinal cord was examined immunohistochemically by using an antiserum against serotonin. A dense aggregation of serotoninergic fibers was located around anterior horn cells in the cervical spinal cord. In the brachial spinal cord, serotoninergic fibers were densely aggregated in the medial motor column and in the parts of the lateral motor column. There were two regions of serotonin immunoreactivity in the lateral motor column of the brachial spinal cord; one located in the ventromedial regions where a dense aggregation of serotoninergic fibers was found, and the reminder of the lateral motor column where only a few serotoninergic fibers were observed. The region containing a dense cluster of serotoninergic fibres around profiles of motoneuron somata and proximal dendrites appears to correspond to motor neuron pools of flexor muscles. In the thoracic spinal cord a high density of serotoninergic fibers was found in the motor nucleus. In the lumbosacral spinal cord (segments LS1–LS8) serotoninergic fibers were not observed in the medial motor column. However, there were five regions in the lateral motor column, where a high density of serotoninergic fibers was found. These very likely correspond to motor neuron pools of muscles which extend the hip joint.

Topographical organization of the afferent connections of area 24 from the insular and temporal cortices in the macaque monkey

The presubiculum (PreS) plays a role of the interface between the medial entorhinal cortex (MEA) and the anterior thalamic nuclei as well as the subiculum. We reported that the layer III cells of PreS projected to MEA, while the layer II cells concerned with the associational connection in PreS. In this study, further analysis was made using the WGA-HRP and PHA-L method. The association cells were widely distributed in the PreS including area 29e, and the majority were in the temporal half. The cells in the septal PreS projected far to the temporal PreS, while the cells in the temporal PreS terminated mostly within the temporal portion. Transversely, the association cells were located densely in the mid and distal parts (far from the subiculum), but very few in the proximal part. As to the reciprocal connection between the MEA and layer III of PreS, the following topography was observed: 1) the septal PreS was connected with the lateral MEA, and the temporal PreS with the medial MEA, and 2) the distal PreS connected with the septal MEA and the proximal PreS with the temporal MEA.