Somatotopic organization and cortical projections of the ventrobasal complex of the flying fox: an "inverted" wing representation in the thalamus

The present study investigates the somatotopic representation in the somatosensory thalamus of a megachiropteran bat. Using standard microelectrode mapping techniques, representational maps were generated for the ventrobasal (Vb) and posterior (Po) thalamic complexes of the Grey-headed flying fox. Anatomical tracing from neocortical injections provided additional data confirming the somatotopy found physiologically. A full representation of the body surface innervated by the trigeminal and spinal nerves was found. However, in contrast with other mammals, the representations of the forelimb and adjacent thoracic trunk within the thalamus were inverted. This means that the distal portions of the wing membrane and the tips of the digits were represented dorsally in Vb, and the thoracic trunk was represented ventrally. In Po the digit tips were represented in the ventral most portion and the thoracic trunk in the dorsal portion of the nucleus.These results are discussed in relation to similarities of megachiropteran somatosensory thalamic nuclei to those of other mammalian species and in relation to the formation of thalamic somatotopic maps and fiber sorting.     

Extra-lemniscal afferent projections of dorsal spinal cord nuclei to the ventrobasal nuclear complex structure in the contralateral optic thalamus

It has been found that section of half the midbrain tegmentum in cats failed to prevent the afferent somatosensory projections from the foreleg to the ventrobasal nuclear complex of the contralateral thalamus. Specific evoked responses to the stimulation of the contralateral foreleg were recorded in this structure. These specific EP have the same latency as "lemniscal responses" (4-5 ms) and diminish the amplitude and duration of both components of the responses. Simultaneously, we have observed terminal axonal degeneration into the ventrobasal nuclear complex of the thalamus 5-7 days after the section of the contralateral midbrain tegmentum, using the electron microscopy method. All the results obtained indicate that the dorsal column nuclei have extra-lemniscal afferent connections with ventrolateral nuclear complex of the contralateral thalamus. These connections ascend in the back parts of the brainstem ipsilaterally to the corresponding pair of the dorsal column nuclei and rostrally to the midbrain on the contralateral side.     

Striatal input from the ventrobasal complex of the rat thalamus

We have analyzed whether caudal regions of the caudate putamen receive direct projections from thalamic sensory relay nuclei such as the ventrobasal complex. To this aim, the delivery of the retrograde neuroanatomical tracer Fluoro-Gold into the caudal caudate putamen resulted in the appearance of retrogradely labeled neurons in the ventral posteromedial and ventral posterolateral thalamic nuclei. These projections were further confirmed with injections of the anterograde tracers biotinylated dextran amine or Phaseolus vulgaris leucoagglutinin into these thalamic nuclei, by showing the existence of axonal terminal fields located in the caudal striatum. These results support the existence of direct projections linking the thalamic ventrobasal complex and the caudal striatum in the rat, probably via collateralization of thalamocortical axons when passing through the caudate putamen, and therefore supporting the putative involvement of the caudal striatum in sensory-related functions.     

Collateral projections from trigeminal sensory nuclei to ventrobasal thalamus and cerebellar cortex in rats

The retrograde fluorescent labeling technique reveals that trigeminal projections to the ventroposteromedial nucleus of the thalamus (VPM) of the rat originate from the main sensory nucleus (MSN) of the trigeminal and subnuclei interpolaris (V1) and caudalis (Vc) of the spinal trigeminal nucleus. These projections are predominantly contralateral; however, the presence of a few ipsilateral labeled cells in MSN suggests an uncrossed trigeminothalamic pathway. Trigeminocerebellar fibers projecting to the paramedian lobule (PML) of the cerebellar cortex are located in Vi and caudal subnucleus oralis (Vo). This is principally an ipsilateral pathway, but several bisbenzimide-labeled cells are present in contralateral Vi. The most notable finding occurred after paired injections of Evans Blue into VPM and bisbenzimide into PML, demonstrating neurons in Vi with divergent projections to both structures. The presence of this type of projection was not found in mice (Steindler: J. Comp. Neurol. 237:155-175, 1985) and has not been reported in other species.     

Somatotopic representation of climbing fiber projections from limb cutaneous afferents to the paramedian lobule of the cat cerebellum

Climbing fiber projections to the cerebellar paramedian lobule were investigated electrophysiologically by stimulation of bilateral superficial radial nerve (SR) and superficial peroneal nerve (SP) in the cat anesthetized with pentobarbitone. In the medial zone of the paramedian lobule, short latency climbing fiber responses to stimulation of the ipsilateral SR were recorded rostrally from the top caudal part of the intermediate folia and short latency responses to stimulation of the ipsilateral SP were obtained caudally from the bottom caudal part of the folia. In the central zone, long latency responses to stimulation of the bilateral SR and SP were obtained. "Four limbs area" in which these responses were recorded was 1.0-1.2 mm in width. Short latency responses to stimulation of the ipsilateral SR were observed rostrally from this area, and short and long latency responses to stimulation of the ipsilateral SP were distributed caudally from this area. In the lateral zone, short and long latency responses to stimulation of the ipsilateral SR were recorded rostrally from the rostral part of the intermediate folia, and long latency responses to stimulation of the ipsilateral SP were observed caudally from the caudal part of the folia. In the most lateral zone, short and long latency responses to stimulation of the ipsilateral SR were obtained rostrally from the rostral part of the intermediate folia, and long latency responses to stimulation of ipsilateral SP were recorded only in the bottom caudal part of the folia caudally from the caudal part of the folia.     

Functional organization of auditory projections to somatosensory cortical areas in cats

The functional properties of fibers transmitting auditory impulses to somatosensory areas S_I and S_II were studied in anesthetized and waking animals by the evoked potentials method. The thresholds of evoked potentials in areas S_I and S_II are 15–35 dB higher than those of evoked potentials in the auditory projection areas. Tonotopical localization is absent in somatic areas. Experiments on anesthetized animals showed that the spread of impulses relating to acoustic stimuli of different frequencies into areas S_I and S_II is effected through area A_I and its connections with the above zones. Another pathway probably also participates in the conduction of impulses from clicks. Analysis of the time constants of the first positive potential suggested that the interneuronal organization of auditory projections to area A_I is less complex than that of projections to the somatosensory areas. Comparison of amplitudes of evoked potentials of different projection zones in area S_I showed that the projection of the head receives more auditory impulses than the projection zone of the forelimbs, confirming the morphological data published previously.     

Somatotopic organization of the vestibulospinal tract in the toad

The origin of the vestibulospinal projection in the toad has been investigated by using the method of the retrograde axonal transport of HRP injected at various levels of the spinal cord. The vestibulospinal projection, in this species, was found to be somatotopically organized, since neurons projecting to the cervical segments of the spinal cord were located within the rostromedial part of the ventral vestibular nucleus and those neurons projecting to the lumbosacral segments of the spinal cord were located within the caudolateral part of that nucleus. This pattern of organization of the vestibulospinal projection in amphibia is similar to that described in mammals and birds.     

A combined horseradish peroxidase and Golgi study on the afferent connections of the ventrobasal complex of the thalamus in the cat

Summary Afferent connections to the ventrobasal complex (VB) of the thalamus were studied by means of retrograde transport of horseradish peroxidase (HRP) and by the Golgi-method. After HRP-injection into the VB, peroxidase-positive cells were observed contralaterally in the dorsal column nuclei (DCN), in the trigeminal nuclei and in the lateral cervical nucleus (LCN), and ipsilaterally in the somatosensory I (SI) and II (SII) cortical areas. Labeled cells of different shape and size were compared with neurons impregnated by the Golgi-technique. On the basis of HRP-labeling it is concluded that cells projecting to the VB are different in size and shape even within one region and that they correspond to the relay or efferent neurons observed in the Golgimaterial.     

Sources of cortical,hypothalamic and spinal serotonergic projections: Topical organization in the dorsal raphe nucleus

A study was made of retrograde axon transport of luminescent stains (primulin, fluoro-gold, fast blue, and nuclear yellow) from the spinal cord, the frontal cortex and lateral hypothalamus to various neuron groups of the periventricular gray matter of the midbrain and the dorsal tegmentum of the pons Varolii. Two large groups of serotonergic neurons are localized in the dorsomedial area of the dorsal raphe nucleus where projections to the thoracic segments of the spinal cord originate. Some of these neurons form divergent axon collaterals to the frontal cortex. Our data indicate that the antinociceptive effect of stimulating the "purely analgesic zone" of the midbrain periventricular gray matter may be due to direct involvement of the dorsal raphe nucleus in the descending control of impulsation induced by nociceptive stimulation at the spinal cord level. The neurotransmitter and neuromodulator role of separate cortical and hypothalamic projections of serotonin-containing neurons in the dorsal raphe nucleus is discussed.A. M. Gorky Medical Institute, Donetsk. A. A. Bogomolets Institute of Physiology, Ukrainian Academy of Sciences, Kiev. Translated from Neirofiziologiya, Vol. 24, No. 1, pp. 87–96, January–February, 1992.     

Coding processes involved in the cortical representation of complex tactile stimuli

To understand how information is coded in the primary somatosensory cortex (S1) we need to decipher the relationship between neural activity and tactile stimuli. Such a relationship can be formally measured by mutual information. The present study was designed to determine how S1 neuronal populations code for the multidimensional kinetic features (i.e. random, time-varying patterns of force) of complex tactile stimuli, applied at different locations of the rat forepaw. More precisely, the stimulus localization and feature extraction were analyzed as two independent processes, using both rate coding and temporal coding strategies. To model the process of stimulus kinetic feature extraction, multidimensional stimuli were projected onto lower dimensional subspace and then clustered according to their similarity. Different combinations of stimuli clustering were applied to differentiate each stimulus identification process. Information analyses show that both processes are synergistic, this synergy is enhanced within the temporal coding framework. The stimulus localization process is faster than the stimulus feature extraction process. The latter provides more information quantity with rate coding strategy, whereas the localization process maximizes the mutual information within the temporal coding framework. Therefore, combining mutual information analysis with robust clustering of complex stimuli provides a framework to study neural coding mechanisms related to complex stimuli discrimination.     

Somatotopic representation of action words in human motor and premotor cortex

Since the early days of research into language and the brain, word meaning was assumed to be processed in specific brain regions, which most modern neuroscientists localize to the left temporal lobe. Here we use event-related fMRI to show that action words referring to face, arm, or leg actions (e.g., to lick, pick, or kick), when presented in a passive reading task, differentially activated areas along the motor strip that either were directly adjacent to or overlapped with areas activated by actual movement of the tongue, fingers, or feet. These results demonstrate that the referential meaning of action words has a correlate in the somatotopic activation of motor and premotor cortex. This rules out a unified "meaning center" in the human brain and supports a dynamic view according to which words are processed by distributed neuronal assemblies with cortical topographies that reflect word semantics.     

Intrinsic innervation in the tracheal smooth muscle of the large flying fox (Pteropus vampyrus): an immunohistochemical study

Structure and innervation of the trachea of the large flying fox (Pteropus vampyrus) were examined by mean hematoxylin-eosin staining and immunohistochemical methods. The tracheal rings were predominantly comprised of bone with a small amount of hyaline cartilage. Bone contained bone marrow and hyaline cartilage attached at the ends of the tracheal rings. The tracheal rings in the anterior third of the trachea were connected at each end with connective tissue to almost form a ring. A narrow membranous wall comprising a single layer of smooth muscle was present in the middle third, while inner and outer layers of smooth muscle were present in the posterior third. Protein gene product 9.5 (PGP 9.5)-, nitric oxide synthase (NOS)-, galanin- and vasoactive intestinal peptide (VIP)-immunoreactive nerve fibers were present in the epithelium, lamina propria, smooth muscle layer and tunica adventitia. In the tunica adventitia, many PGP 9.5- and NOS-immunoreactive neurons were found singly or in small ganglia, while some VIP- and galanin-immunoreactive neurons were observed. A few PGP 9.5- and NOS-immunoreactive neurons were found in the submucosal layer. These results suggest that the trachea of the large flying fox has a rigid structure of tracheal rings and that the posterior two-thirds of the trachea probably contract via the actions of smooth muscles innervated with peptidergic or nitrenergic neurons that are located in tracheal ganglia, whereas the anterior third is non-mobile.     

Fit females and fat polygynous males: seasonal body mass changes in the grey-headed flying fox

When females and males differ in their timing of maximum reproductive effort, this can result in sex-specific seasonal cycles in body mass. Such cycles are undoubtedly under strong selection, particularly in bats, where they affect flying ability. Flying foxes (Old World fruit bats, Pteropus spp.) are the largest mammals that can sustain powered flight and therefore face critical trade-offs in managing body reserves for reproduction, yet little is known about body mass dynamics in this group. I investigated body mass changes in relation to reproductive behaviour in a large colony of grey-headed flying foxes (Pteropus poliocephalus). In this polygynous mammal, females were predicted to maximise reproductive effort during lactation and males during the breeding season. As predicted, female body condition declined during the nursing period, but did not vary in relation to sexual activity. By contrast, males accumulated body reserves prior to the breeding season, but subsequently lost over 20% of their body mass on territory defence and courtship, and lost foraging opportunities as they also defended their day roost territories at night. Males in better condition had larger testes, particularly during territory establishment, prior to maximum sexual activity. Thus, the seasonality of female mass reflected the high metabolic load that lactation imposes on mothers. However, male mass followed a pattern akin to the "fatted male phenomenon", which is commonly observed in large polygynous mammals with seasonal reproduction, but not in bats. This shows the importance of body reserves for reproduction in flying foxes, despite their severe constraints on body mass.     

The relationship between complex vesicles, dense-cored vesicles and dense projections in cortical synaptosomes

Cortical synaptosomes fixed in unbuffered OsO4 and glutaraldehyde have been block-stained with phosphotungstic acid (PTA) in order to investigate the relationship between complex vesicles and dense projections. It is concluded that the shell of the complex vesicles contributes to the formation of dense projections and that, in addition, there is a correspondence between this shell and the previously described presynaptic network. The process by which complex vesicles become associated with dense projections appears to be accentuated by electrical stimulation of the synaptosomes.     

The primary structure of the hemoglobin of an Indian flying fox (Cynopterus sphinx, Megachiroptera)

The hemoglobin of the Indian flying fox Cynopterus sphinx contains only one component. In this work, we are presenting its primary structure. The globin chains were separated by high-performance liquid chromatography and the sequences determined by automatic liquid and gas-phase Edman degradation of the chains and their tryptic peptides, as well as of the peptide obtained by acid hydrolysis of the Asp-Pro bond in the beta-chains. The alpha-chains show 14 and the beta-chains 19 exchanges compared with the human alpha- and beta-chains, respectively. In the alpha-chains one amino-acid exchange involves an alpha 1/beta 1 contact. In the beta-chains one heme contact, three alpha 1/beta 1- and one alpha 1/beta 2-contacts are exchanged. The functional and evolutionary aspects of these findings are discussed.