Laminar origin of the tecto-thalamic projections in the albino rat

Cells of origin of the tecto-LP (lateroposterior nucleus of the thalamus) projection and the tecto-LGNd (dorsal nucleus of the lateral geniculate body) projection were studied in the albino rat by means of retrograde transport of wheat germ agglutinin conjugated to horseradish peroxidase (WGA-HRP). Tecto-LGNd neurons with small spindle form were located in the stratum griseum superficiale of the superior colliculus (SC), whereas tecto-LP neurons with polygonal shape were found in the stratum opticum of the SC.     

Spermatogonial stem cells in the albino rat

The existence of two classes of spermatogonial stem cells in the rat testis, i.e., reserve type A₀ spermatogonia and renewing, types A₁-A₄ spermatogonia, postulated by Clermont and Bustos-Obregon (′68), was reexamined in a quantitative analysis of type A spermatogonia in both whole mounts of tubules and in radioautographed sections of testes from animals killed at various times, up to 26 days, after one or multiple injections of ³H-thymidine. The cell counts obtained from whole mounts of tubules revealed that the number of isolated type A₀ cells per unit area of limiting membrane remained constant throughout the cycle of the seminiferous epithelium. Paired type A₀ spermatogonia also remained unchanged in number per unit area of basement membrane from stage I to stage VIII of the cycle. The low mitotic index of type A₀ spermatogonia (0.1%) indicated that these cells were not actively involved in the production of spermatogonia or spermatocytes during each cycle of the seminiferous epithelium and thus were considered as reserve stem cells. The type A₁ spermatogonia, which are formed during stage I of the cycle, remained resting until stage IX, when they undertook a series of four successive divisions resulting in the production of new type A₁ and Intermediate-type spermatogonia. An analysis of the labeling indices of type A spermatogonia obtained from cell counts in radioautographed testicular sections after a single or multiple ³H-thymidine injections indicated that the percentages of labeled type A cells corresponded to the percentages of type A₁-A₄ at each stage, whereas the percentages of unlabeled type A cells corresponded to the percentages of type A₀ spermatogonia obtained from counts of cells in whole mounts. This confirmed that type A₀ cells were generally non-proliferative throughout the cycle of the seminiferous epithelium while the type A₁-A₄ spermatogonia underwent complete renewal during each cycle. The present results thus support the concept of the existence of two classes of spermatogonial stem cells in rats.     

Widespread cortical projections of the ventral tegmental area and of other brain stem structures in the cat

Summary Thirty-three cat brains with injections of horseradish peroxidase in various regions of the cerebral cortex were screened for afferent projections from the ventral tegmental area, the locus ceruleus, and the parabrachial nuclei. All three structures were found to project to rather divergent parts of the cortex, including regions in the posterior half of the hemisphere. These results, especially for the ventral tegmental area and, to a lesser degree, for the parabrachial neurons, disagree with most of the target loci of established cortical afferents in the rat. Though our results might be attributed to species differences in the cortical innervation of brain stem structures, we prefer explanations which emphasize different densities in the distribution of brain stem afferents to the cortex, and/or which suggest different cortical targets of catecholaminergic and noncatecholaminergic neurons.Supported in part by grant Ma 795 from the Deutsche Forschungsgemeinschaft (DFG)     

Visual cortical projections to the paraflocculus in the rat

Experimental Brain Research - The visual cortex of the rat was electrically stimulated with monopolar tungsten electrodes to determine the response properties of single neurons in the parafloccular...     

Different corticostriatal projections from two parts of the cortical masticatory area in the rabbit

The cortical masticatory area (CMA) elicits rhythmic jaw movements in response to repetitive stimulation and is involved in the control of mastication. Based on jaw movement patterns, the CMA is divided into two parts. One is the part of the CMA in which a T-pattern similar to jaw movements during food transport in natural mastication is evoked by electrical stimulation. The other is more dorsomedially located, and during chewing a C-pattern similar to jaw movements can be induced. However, it is still not known which region of the putamen receives projections from the CMA and whether projections originate from both parts of the CMA. In this study, electrophysiological and histological experiments were undertaken in rabbits to investigate projections from the CMA to the putamen. Both experiments showed that the ventral region of the putamen received projections from the CMA. The density of the projections from the CMA area inducing the T-pattern seemed to be higher than that from the area inducing the C-pattern. Furthermore, the peak latency of the evoked potentials from stimulation of the CMA area inducing the T-pattern was shorter than that from stimulation of the area inducing the C-pattern. The data obtained from the present study indicate the functional role of the ventral region of the putamen in the regulation of mastication, and further suggest that the corticostriatal pathway is involved in the transition between behavioral jaw movement patterns.     

Brain stem projections to the pulvinar-lateralis posterior complex of the cat

Summary The present experiments were undertaken to define the areas of projection of pretectum and superior colliculus to the pulvinar and n. lateralis posterior, respectively, and to define other brain stem structures projecting to these thalamic nuclei in cats. For this purpose the technique of retrograde transport of horseradish peroxidase (HRP) has been used.After injection of the enzyme in the pulvinar, neurons were labeled in all subdivisions of the pretectal area. The majority of the labeled cells were located in the n. pretectalis posterior and n. tractus opticus although cells filled with HRP were present also in the n. pretectalis anterior pars compacta and area pretectalis medialis. Neurons projecting to the pulvinar were also found in the periaqueductal gray, reticular formation and locus coeruleus.When HRP was injected in the n. lateralis posterior, labeled neurons were present in the II and III subdivisions of the second layer of the superior colliculus. The location of these cells shifted from medial to lateral as the injections were shifted from posterior to anterior within the lateralis posterior. Neurons projecting to this nucleus were also present in the intermediate layers of the superior colliculus, lateral hypothalamus and parabigeminal nucleus.The possible role of the pretectal area and superior colliculus in mediating somesthetic input to the pulvinar and lateralis posterior, respectively, and the role of these structures in the control of ocular movements, are discussed.Abbreviations APM area pretectalis medialis - Cu nucleus cuneiformis - CS nucleus centralis superior - fr fasciculus retroflexus - Gp pontine gray - Hb nucleus habenulae - IC inferior colliculus - LC locus coeruleus - LGB lateral geniculate body - LP lateralis posterior - MGB medial geniculate body - nPA_c nucleus pretectalis anterior pars compacta - nPA_r nucleus pretectalis anterior pars reticularis - nPC nucleus posterior commissurae - nPP nucleus pretectalis posterior - nTO nucleus tractus opticus - PAG periaqueductal gray - PB nucleus parabigeminalis - Pi pulvinar inferior - PO nucleus posterior of the thalamus - Pul pulvinar - Pt pretectum - RF reticular formation - Rtp tegmental reticular nucleus - SC superior colliculus Supported by H. de Jur Foundation and USPHS Grant TWO 2718Present address: Max-Planck-Institut für biophysikalische Chemie, Postfach 968, D-3400 Göttingen, Federal Republic of Germany     

Brain stem projections of rat lumbar dorsal root ganglia studied with choleragenoid conjugated horseradish peroxidase

Summary Brain stem projections from each of the L1–L6 lumbar dorsal root ganglia (DRGs) were investigated in adult rats following DRG injections of choleragenoid-horseradish peroxidase. All these DRGs projected throughout the rostrocaudal extent of the gracile nucleus (Gr). Labeling from L1–L6 DRGs was transported to successively more dorsomedial areas of Gr. Investigation of the Gr projections from the DRGs revealed a somatotopic organization which was most prominent in the middle part of Gr. The cuneate nucleus showed smaller projections from all investigated DRGs. Minor projections to the internal basilar nucleus, external cuneate nucleus, medial vestibular nucleus, ventral cochlear nucleus and trigeminal sensory nuclei were also found from some of the DRGs.Abbreviations AP area postrema - B-HRP choleragenoidhorseradish peroxidase - Cun cuneate nucleus - DRG dorsal root ganglion - ECN external cuneate nucleus - Gf gracile fasciculus - Gr gracile nucleus - MnA median accessory nucleus - MVN medial vestibular nucleus - WGA-HRP wheat germ agglutininhorseradish peroxidase     

Discrimination and conditioning of photic evoked cortical macropotentials in the albino rat

Nine rats were rewarded with lateral hypothalamic brain stimulation for pressing a given bar following enhanced photic evoked components or for pressing another bar following depressed components. Evoking stimulus intensity was constant so that the responses to be discriminated varied due to presumably internal state fluctuations. Most rats learned only to generate one kind of wave and remain on the appropriate bar. Two rats that learned this operant learned additionally to signal trials in which they failed to generate the predominant response. One rat displayed discrimination in the absence of operant production of particular wave types. Specific electrophysiological correlates of these response styles were found and taken as evidence that operant neural conditioning may involve atypical states of the organism. Also discussed in terms of electrophysiological data were (1) the nature of the difficulty of neural discrimination, and (2) antecedents for the various observed response styles.     

The development of the corticotectal pathway in the albino rat: transient projections from the visual and motor cortices

In rats ranging in age from the second postnatal day (23rd postconceptional day 23 PCD) to adulthood, we have studied the distribution of corticotectal terminals labelled anterogradely by unilateral injections of horseradish peroxidase (conjugated with wheat germ agglutinin) into the visual or motor cortices. No projection to the contralateral superior colliculus (SC) was observed. The earliest age at which the labelled axons and/or terminals from the visual cortex were observed in the ipsilateral SC was 25 PCD. At this stage the projection only involves the optic layer. From 28 to 34 PCD, the projection involves the optic layer, the intermediate layers and the deep part of superficial gray layer. Between 34 and 40 PCD the projection becomes restricted to the superficial laminae (i.e. adultlike). On the 23 PCD (the earliest age examined) we observed a projection from the motor cortex to the intermediate laminae and to a lesser extent the optic layer of the ipsilateral SC. By 34 PCD only the adult-like projection extending from the brachium to the periaqueductal gray (PAG) is apparent. The disappearance of the transient projections to the intermediate collicular laminae may be the result of withdrawal of ‘misprojecting’ axonal collaterals.     

Descending projections from the subparafascicular thalamic nucleus to the lower brain stem in the rat

Summary In the course of our study on the neuronal connections of the subparafascicular nucleus (SPF) in the rat, descending projections from the SPF to the lower brain stem were examined by using the anterograde tracer PHA-L (Phaseolus vulgaris leukoagglutinin) and retrograde tracer WGA-HRP (horseradish peroxidase conjugated to wheat germ agglutinin). When PHA-L was injected into the magnocellular and/or parvicellular division of the SPF (SPFm and/or SPFp), presumed terminal labeling was seen, bilaterally with an ipsilateral dominance, in the mesencephalic and pontine central gray matter, peripheral shell regions of the inferior colliculus, cuneiform nucleus, and superior olivary complex (mainly in the superior paraolivary nucleus, and additionally in the nuclei of the trapezoid body). A few labeled axon terminals were also seen in the cochlear nuclei bilaterally with a contralateral dominance. In the second set of experiments, WGA-HRP was injected into the inferior colliculus, superior olivary complex, or cochlear nuclei. When WGA-HRP was injected into the peripheral shell regions of the inferior colliculus or the superior olivary complex, many labeled neuronal cell bodies were seen in the SPFm bilaterally with an ipsilateral dominance, and a moderate number of labeled neuronal cell bodies were observed in the SPFp (lateral SPF) bilaterally with an ipsilateral dominance. When WGA-HRP was injected into the cochlear nuclei, a moderate number of labeled neuronal cell bodies were observed in the SPFm and SPFp bilaterally with a contralateral dominance. The results indicate that the SPFm and SPFp (lateral SPF) of the rat send a considerable number of projection fibers to the lower brain stem. The target regions of these projection fibers include the auditory relay nuclei, such as the inferior colliculus, superior olivary complex, and cochlear nuclei.     

Binocular responses of cortical cells and the callosal projection in the albino rat

Four hundred and fifteen cells were recorded in the binocular segment of the visual cortex in the albino rat. Cells encountered were mainly dominated by the contralateral eye. The percentage of binocularly-driven cells increased as the electrode was moved towards the border between areas 17 and 18a. Ninety percent of the cells studied in the region of the border could be driven by electrical stimulation applied at the corresponding site in the opposite hemisphere. Within area 17, however, there were only about 30% of such cells. Through the combined use of electrical stimulation and reversible cortical cooling, two types of contributions by callosal fibres were revealed. One is that the callosal fibres constitute the only inputs from the ipsilateral eye to a cell. The other is that the callosal input provides ipsilateral reinforcement to a binocular cell. These results are compatible with neuroanatomical findings and show that binocularity of visual cortical cells in this animal depends, to a great degree, on the function of callosal fibres.     

Frontal cortical projections from the suprageniculate nucleus in the rat, as demonstrated with the PHA-L method

Frontal cortical projections from the rat suprageniculate nucleus (SG) were investigated by an anterograde tracing using Phaseolus vulgaris-leucoagglutinin (PHA-L). After PHA-L injection into the SG, labeled terminals were found in the frontal and temporal cortical regions. Labeled terminals in the frontal cortex were almost exclusively localized in the medial agranular area, and those in the temporal cortex were mainly localized in the primary and association auditory areas. The labeled terminals in cortices were distributed predominantly in layers I, III and IV. The results suggest that ascending information through the SG projects to the medial agranular area in the frontal cortex as well as to the temporal cortex.     

Brainstem projections from the lateral hypothalamic area in the rat, as studied with autoradiography

Descending projections from the lateral hypothalamic area to the brainstem were studied, using [3H]-amino acid autoradiography, in the rat. Two main ipsilateral paths were reorganized. One is the periventricular fiber system projecting to the midbrain central gray. The other is a fiber system which eventually descends the central tegmental field, projecting strongly to the dorsal raphe nucleus, medial and lateral parabrachial nuclei, nucleus reticularis parvocellularis, solitary nuclei and dorsal motor nucleus of the vagus nerve. Sparse projections were observed to the nuclei raphe magnus, obscurus and pallidus, group B3 (or the ventrolateral subpial group) and spinal trigeminal nucleus.     

Corticonigral projections from area 6 in the raccoon

Summary The corticonigral projections from area 6 in the raccoon were investigated using the autoradiographic tracing method. Injections of tritiated proline and leucine were made into either medial or lateral area 6 subdivisions. Uniformly distributed silver grains were observed overlying the ipsilateral substantia nigra pars compacta (SNc) while more restricted foci of label indicative of fiber labeling were present in the substantia nigra pars reticulata (SNr). Autoradiographic label was also present in the substantia nigra pars lateralis (SNl), the retrorubral area and the ventral tegmental area of Tsai. The existence of corticonigral projections from area 6 may serve to modulate SNc activity as a whole and provide an important substrate for the cerebral control of movement.Abbreviations cp cerebral peduncle - IP interpeduncular nucleus - PG pontine gray - R red nucleus - RR retrorubral area - SNc substantia nigra, pars compacta - SNl substantia nigra, pars lateralis - SNr substantia nigra, pars reticularis - VTA ventral tegmental area     

Organization of retrosplenial cortical projections to the laterodorsal thalamic nucleus in the rat

The organization of the projections from the retrosplenial cortex (areas 29a--d) to the laterodorsal thalamic nucleus (LD) was examined in the rat with axonal transport of the cholera toxin B subunit and biotinylated dextran amine. The results showed that an area of the retrosplenial cortex provides ipsilateral projections to a distinct part of the LD at the level of its rostral two-thirds. The projections originate from layer VI and, to a lesser extent, layer V cells of the retrosplenial cortex. Area 29a and area 29b project, respectively, to the dorsolateral and the dorsomedial part of the LD. Area 29c projects to the ventromedial two-thirds of the LD, in a topographic pattern such that the rostral part of area 29c projects more ventromedially within the projection field than the caudal part of area 29c. Area 29d projects to the ventrolateral two-thirds of the LD in a topographic pattern similar to area 29c; the rostral part of area 29d projects more ventromedially within the projection field than the caudal part. These precise topographic projections from the retrosplenial cortex to the LD may constitute part of the circuitry underlying spatial navigation and various memory and emotional functions.     

Corticostriate projections from area 6 in the raccoon

Summary Corticostriate projections from area 6 in the raccoon were studied using the autoradiographic tracing method. Following injections of tritiated amino acids into two different cytoarchitectonic subdivisions of area 6, widespread and dense anterograde label was found in both the ipsilateral and contralateral caudate nucleus and putamen. The densest label was located adjacent to the internal capsule in the lateral part of the head of the caudate nucleus. This bilateral projection pattern from area 6 to the caudate nucleus and putamen is consistent with the hypothesis that the neostriatum maintains a close anatomical and functional relationship with area 6.     

Brain stem afferents to visual cortical areas 17, 18 and 19 in the cat, demonstrated by horseradish peroxidase

The origins of brain stem projections to the cytoarchitectonically different areas 17, 18 and 19 of the cat's visual cortex were studied following small horseradish peroxidase (HRP) injections. Labelled cells were counted in a dopaminergic nucleus (nucleus linearis rostralis (NLR)), other catecholaminergic nuclei (locus coeruleus, parabrachialis nuclei and nucleus subcoeruleus) and serotonergic nuclei (nucleus raphe dorsalis (NRD) and nucleus centralis superior (NCS)). Area 18 receives afferents from more locus coeruleus cells than either of areas 17 or 19. The number of labelled cells in the catecholaminergic nuclei far exceeds that in the serotonergic nuclei.