Classical conditioning of the rabbit eyelid response with a mossy-fiber stimulation CS: II. Lateral reticular nucleus stimulation.

1. Studies were done to characterize responses of spinal neurons backfired from the ventrolateral medulla to renal and somatic stimuli. Experiments were performed on 31 cats that were anesthetized with alpha-chloralose. Sixty-six spinal neurons were antidromically activated from the area of the lateral reticular nucleus or the ventrolateral reticular formation just rostral to the lateral reticular nucleus contralateral to the recording site. These cells could not be backfired from the medial reticular formation or from the spinothalamic tract just caudal to the thalamus. 2. Cells were located in laminae I, V, and VII of the T12-L2 segments. Antidromic conduction velocities averaged 35.9 +/- 7.2 m/s. Conduction velocities were unrelated to the projection site or laminar location of the cells. Termination sites of 21 cells were located in antidromic mapping experiments. Terminals were localized to the ventrolateral reticular formation, including the lateral reticular nucleus. 3. Responses to electrical stimulation of the renal nerves were always excitatory. Stimulation of renal A-delta-fibers excited 33 cells. These cells failed to respond to stimulation of renal C-fibers. The other 33 cells responded to both A-delta- and C-fiber stimulation. Latencies to A-delta-fiber stimulation averaged 9 +/- 2 ms, whereas latencies to C-fiber stimulation averaged 57 +/- 10 ms. 4. Renal mechanoreceptors were activated by occlusion of the renal vein or upper portion of the ureter. Renal vein occlusion excited 14 of 32 cells tested. Activity increased from 6 +/- 2 to 14 +/- 4 spike/s. Ureteral occlusion increased activity of 19 of 32 cells from 7 +/- 2 to 16 +/- 5 spikes/s. Cells responding to one of the mechanical stimuli were significantly more likely to receive A-delta-and C-fiber input compared with nonresponding cells. Nonresponders were more likely than responders to receive only A-delta input. 5. All cells received somatic input in addition to renal input. Twelve cells were classified as wide dynamic range, 46 as high threshold, and 8 as Deep. Somatic receptive fields most often included skin and muscle of the left flank and abdomen. Thirty-two cells had bilateral receptive fields, and 22 had inhibitory fields in addition to excitatory fields. 6. These data show that spinal neurons projecting to the ventrolateral medulla receive convergent inputs from the kidney and somatic structures. These cells may participate in a variety of functions including autonomic reflexes of renal origin.

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Evidence for genetically distinct direct and indirect spinocerebellar pathways mediating proprioception

10.1101/2020.08.17.254607 ◽

2020 ◽

Author(s):

Iliodora V. Pop ◽

Felipe Espinosa ◽

Megan Goyal ◽

Bishakha Mona ◽

Mark A. Landy ◽

...

Keyword(s):

Spinal Cord ◽

Granule Cells ◽

Mossy Fiber ◽

Cerebellar Nuclei ◽

Reticular Nucleus ◽

Proprioceptive Information ◽

Lateral Reticular Nucleus ◽

Axon Collaterals ◽

Progenitor Domain ◽

Clarke's Column

AbstractProprioception, the sense of limb and body position, generates a map of the body that is essential for proper motor control, yet we know little about precisely how neurons in proprioceptive pathways develop and are wired. Proprioceptive and cutaneous information from the periphery is sent to secondary neurons in the spinal cord that integrate and relay this information to the cerebellum either directly or indirectly through the medulla. Defining the anatomy of these direct and indirect pathways is fundamental to understanding how proprioceptive circuits function. Here, we use genetic tools in mice to define the developmental origins and unique anatomical trajectories of these pathways. Developmentally, we find that Clarke’s column (CC) neurons, a major contributor to the direct spinocerebellar pathway, derive from the Neurog1 progenitor domain. By contrast, we find that two of the indirect pathways, the spino-lateral reticular nucleus (spino-LRt) and spino-olivary pathways, are derived from the Atoh1 progenitor domain, despite previous evidence that Atoh1-lineage neurons form the direct pathway. Anatomically, we also find that the mossy fiber terminals of CC neurons diversify extensively with some axons terminating bilaterally in the cerebellar cortex. Intriguingly, we find that CC axons do not send axon collaterals to the medulla or cerebellar nuclei like other mossy fiber sources. Altogether, we conclude that the direct and indirect spinocerebellar pathways derive from distinct progenitor domains in the developing spinal cord and that the proprioceptive information from CC neurons is processed only at the level of granule cells in the cerebellum.Significance StatementWe find that a majority of direct spinocerebellar neurons in mice originate from Clarke’s column (CC), which derives from the Neurog1-lineage, while few originate from Atoh1-lineage neurons as previously thought. Instead, we find that spinal cord Atoh1-lineage neurons form mainly the indirect spino-lateral reticular nucleus and spino-olivary tracts. Moreover, we observe that mossy fiber axon terminals of CC neurons diversify proprioceptive information across granule cells in multiple lobules on both ipsilateral and contralateral sides without sending axon collaterals to the medulla or cerebellar nuclei. Altogether, we define the development and the anatomical projections of direct and indirect pathways to the cerebellum from the spinal cord.

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