Controlled locomotion in the mesencephalic cat: distribution of facilitatory and inhibitory regions within pontine tegmentum

Mori, Shigemi; Nishimura, H.; Kurakami, C.; Yamamura, Takeyasu; Aoki, Mamoru

doi:10.1152/jn.1978.41.6.1580

Cited by 114 publications

(57 citation statements)

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“…The locations of the cell bodies in the lower brain stem that are capable of initiating locomotion correspond to the MLR fiber terminations reported previously (Steeves and Jordan, 1984) and to the site where cooling to block synapse transmission reversibly abolished locomotion produced by electrical stimulation of the classical MLR (Shefchyk et al, 1984). The present study extends the MRF region previously shown to be capable of generating locomotion when electrically stimulated (Mori et al, 1978(Mori et al, , 1980Garcia-Rill and Skinner, 1987) and shows that an area from the midline to L2 can be stimulated electrically to induce locomotion. This confirms the previous finding by Mori et al (1978) that midline stimulation is effective for production of locomotion, but it is in contrast to the report by Garcia-Rill and Skinner (1987) who claim that midline stimulation does not produce locomotion.…”

Section: Mlr-reticulospinal Pathwaysupporting

confidence: 87%

“…The present study extends the MRF region previously shown to be capable of generating locomotion when electrically stimulated (Mori et al, 1978(Mori et al, , 1980Garcia-Rill and Skinner, 1987) and shows that an area from the midline to L2 can be stimulated electrically to induce locomotion. This confirms the previous finding by Mori et al (1978) that midline stimulation is effective for production of locomotion, but it is in contrast to the report by Garcia-Rill and Skinner (1987) who claim that midline stimulation does not produce locomotion. The fact that the electrical threshold for the initiation of locomotion by stimulation of the MRF is higher than that observed for the MLR (Mori et al, 1980) or PLS (this study) suggests that a larger volume of tissue must be stimulated to produce locomotion, possibly due to a more diffuse distribution of neurons within the reticular formation.…”

Section: Mlr-reticulospinal Pathwaysupporting

confidence: 82%

“…2). This region is more extensive than the P3-P9 MRF regions previously shown to be capable of producing locomotion when electrically stimulated (Mori et al, 1978(Mori et al, , 1980. The effective PLS sites included the lateral tegmental field (FTL) medial and ventral to the spinal nucleus of the fifth nerve as previously described (Mori et al, 1977;Shik and Yagodnitsyn, 1977) but also included the spinal nucleus of the fifth nerve (5SM, BP).…”

Section: Electrically Induced Locomotionmentioning

confidence: 86%

“…This has been suggested to explain the effects of ventral tegmental field stimulation described by coworkers (1978, 1980) which produces increased hindlimb extensor activity and locomotion when electrically stimulated. Postural adjustments prior to the onset of locomotion have previously been reported during stimulation of the MLR (Mori et al, 1980;Garcia-Rill et al, 1985) and its reticular formation projection sites (Mori et al, 1978(Mori et al, , 1980(Mori et al, , 1982. Thus, while the MLR relays its descending command signal for locomotion, it may also influence parallel postural systems also located in the MRF.…”

Section: Mlr-reticulospinal Pathwaymentioning

confidence: 87%

“…As summarized by Jordan (1986) reticulospinal cells in the MRF then produce locomotion by pathways traveling in the ventral lateral funiculus (VLF) of the spinal cord. Electrical stimulation of the MRF can produce locomotion (Mori et al, 1978(Mori et al, , 1980Garcia-Rill and Skinner, 1987) and cells in this region show increased metabolic activity during MLR-evoked fictive locomotion . The direct evidence implicating the involvement of cells in the MRF in the mediation of locomotion includes the observation that cooling restricted areas in the MRF to block synaptic transmission can reversibly abolish both spontaneous and MLR-evoked locomotion (Shefchyk et al, 1984) and the finding that injections of cholinergic agonists or substance P into the MRF can elicit locomotion (Garcia-Rill and Skinner, 1987).…”

mentioning

confidence: 99%

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Locomotion produced in mesencephalic cats by injections of putative transmitter substances and antagonists into the medial reticular formation and the pontomedullary locomotor strip

1988

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The purpose of this study was to determine the distribution of cells in the medial reticular formation (MRF) and the pontomedullary locomotor strip (PLS), which can induce locomotion when activated. Controlled microinjections of neuroactive substances (Goodchild et al., 1982) into the MRF or PLS were made in order to activate cell bodies in those areas. The ability of trigeminal receptive field stimulation to induce locomotion before and after drug infusion into the PLS was also assessed since the PLS and the spinal nucleus of the trigeminal nerve are similar in their anatomical distribution. Experiments were performed on precollicular-postmamillary decerebrate cats walking on a treadmill. Injections of glutamic acid (GA; 500 nmol) into the MRF produced locomotion that was antagonized by infusion of glutamic acid diethyl ester into the same spot. Decreases in the current threshold for locomotion produced by electrical stimulation of the MRF were observed when the MRF was infused with either GA (40–80 nmol), DL- homocysteic acid (DL-HCA; 200 nmol), or picrotoxin (PIC; 15 nmol). Injections of GA (100 nmol), DL-HCA (700 nmol), PIC (10–50 nmol), and substance P (2 nmol) into the PLS also produced locomotion. Locomotion produced by injections of PIC into the PLS was blocked by infusion of equal amounts of muscimol or GABA. Effective PLS injection sites were all confined to the trigeminal spinal nucleus or immediately ventral and medial to this in the adjacent lateral reticular formation. Trigeminal nerve peripheral field stimulation evoked locomotion after microinjection of PIC into the PLS, although this same facial stimulus was not effective prior to drug injection. We conclude that the MRF and PLS regions of the cat brain stem contain cells that produce locomotion when chemically stimulated, and we suggest that the PLS is closely related to or synonymous with the spinal nucleus of the trigeminal nerve. Furthermore, we suggest that stimulation of trigeminal afferents is analogous to stimulation of segmental afferent pathways in the production of locomotion (Sherrington, 1910; Jankowska et al., 1967; Afelt, 1970; Budakova, 1972; Grillner and Zangger, 1979).

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Section: Mlr-reticulospinal Pathwaysupporting

confidence: 87%

Section: Mlr-reticulospinal Pathwaysupporting

confidence: 82%

Section: Electrically Induced Locomotionmentioning

confidence: 86%

Section: Mlr-reticulospinal Pathwaymentioning

confidence: 87%

mentioning

confidence: 99%

See 3 more Smart Citations

Locomotion produced in mesencephalic cats by injections of putative transmitter substances and antagonists into the medial reticular formation and the pontomedullary locomotor strip

1988

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Descending projections of the posterior nucleus of the hypothalamus:Phaseolus vulgaris leucoagglutinin analysis in the rat

Vertes

Crane

1996

J. Comp. Neurol.

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No previous report in any species has systematically examined the descending projections of the posterior nucleus of the hypothalamus (PH). The present report describes the descending projections of the PH in the rat by using the anterograde anatomical tracer, Phaseolus vulgaris leucoagglutinin. PH fibers mainly descend to the brainstem through two routes: dorsally, within the central tegmental tract, and ventromedially, within the mammillo-tegmental tract and its caudal extension, ventral reticulo-tegmental tracts. PH fibers were found to distribute densely to several nuclei of the brainstem. They are (from rostral to caudal) 1) lateral/ ventrolateral regions of the diencephalo-mesopontine periaqueductal gray (PAG); 2) the peripeduncular nucleus; 3) discrete nuclei of pontomesencephalic central gray (dorsal raphe nucleus, laterodorsal tegmental nucleus, and Barrington's nucleus); 4) the longitudinal extent of the central core of the mesencephalic through meduallary reticular formation (RF); 5) the ventromedial medulla (nucleus gigantocellularis pars alpha, nucleus raphe magnus, and nucleus raphe pallidus); 6) the ventrolateral medulla (nucleus reticularis parvocellularis and the rostral ventrolateral medullary region); and 7) the inferior olivary nucleus. PH fibers originating from the caudal PH distribute much more heavily than those from the rostral PH to the lower brainstem. The PH has been linked to the control of several important functions, including respiration, cardiovascular activity, locomotion, antinociception, and arousal/wakefulness. It is likely that descending PH projections, particularly those to the PAG, the pontomesencephalic RF, Barrington's nucleus, and parts of the ventromedial and ventrolateral medulla, serve a role in a PH modulation of complex behaviors involving integration of respiratory, visceromotor, and somatomotor activity.

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Organization of the projections from the pericruciate cortex to the pontomedullary reticular formation of the cat: A quantitative retrograde tracing study

1997

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Dextran-amines were used as retrograde tracers to investigate the organization of cortical projections to different cytoarchitectonic regions of the pontomedullary reticular formation of the cat. Injections into the nucleus reticularis pontis oralis resulted in labelling of neurones in the proreus cortex and area 6a beta of the premotor cortex, with little labelling in the motor cortex (area 4). This labelling was predominantly ipsilateral to the injection site. In contrast, injections into the nucleus reticularis pontis caudalis (NRPc), nucleus reticularis gigantocellularis (NRGc), and nucleus reticularis magnocellularis (NRMc) resulted in bilateral labelling--primarily in areas 6a beta, 6a gamma, and in the rostromedial region of area 4--with little labelling in the proreus cortex. In general, the cortical projections to the caudal NRGc and the NRMc were larger than those to the NRPc. More than 25% of the total projections to each of the latter three reticular regions arose from the medial part of area 4. Labelling in the hindlimb regions of area 4 was largest following the NRMc injections and smallest after injections in the NRPc. The projections to the NRPc originated from more medial parts of areas 4 and 6 than did the projections to the caudal region of the NRGc. These results suggest that areas 4 and 6 may be able to differentially activate different regions of the pontomedullary reticular formation depending on the movement that is made and perhaps also on the context of that movement.

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Controlled locomotion in the mesencephalic cat: distribution of facilitatory and inhibitory regions within pontine tegmentum

Cited by 114 publications

References 0 publications

Locomotion produced in mesencephalic cats by injections of putative transmitter substances and antagonists into the medial reticular formation and the pontomedullary locomotor strip

Locomotion produced in mesencephalic cats by injections of putative transmitter substances and antagonists into the medial reticular formation and the pontomedullary locomotor strip

Descending projections of the posterior nucleus of the hypothalamus:Phaseolus vulgaris leucoagglutinin analysis in the rat

Organization of the projections from the pericruciate cortex to the pontomedullary reticular formation of the cat: A quantitative retrograde tracing study

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