AI Article Synopsis
- The study examined the expression of a protein called neuroendocrine secretory protein 55 (NESP55) in the rat spinal cord, finding it in motoneurons, autonomic neurons, and interneurons throughout various segments.
- NESP55 was notably present in regions like the ventral horn and dorsal horn, with most NESP55-positive neurons being cholinergic, indicating a specific functional role.
- The research highlighted that NESP55's distribution and cellular expression patterns differ between spinal motoneurons and autonomic neurons, suggesting its involvement in different secretory pathways within these cells.
Article Abstract
The immunohistochemical expression of a novel chromogranin-like protein, neuroendocrine secretory protein 55 (NESP55), in the rat spinal cord was investigated. NESP55-immunoreactive cells were detected in the ventral horn, intermediate laminae, and deep dorsal horn, comprising motoneurons, autonomic neurons, and interneurons throughout all spinal segments. Within laminae I-II of the dorsal horn, one or two NESP55-positive cells were often seen. Nerve fibers also contained NESP55 immunoreactivity (IR) and were particularly prominent in the ventral horn. No nerve terminals/varicosities appeared to contain NESP55 in any spinal lamina. Double-staining experiments revealed that a high proportion of the NESP55-positive neurons were cholinergic. Moreover, NESP55-IR in the motoneurons was evenly distributed in the whole cytoplasm with a finely granular appearance. In contrast, the fluorescent material in the preganglionic neurons was concentrated in the perinuclear region and largely overlapped with the trans-Golgi network marker TGN38. Our data provide detailed morphological information on the distribution of NESP55-IR in the rat spinal cord. Also, the differential intracellular expression of NESP55-IR in the spinal motoneurons and autonomic neurons suggests that NESP55 may be processed into different secretory granules and may be involved in both constitutive and regulated pathways in these neurons.
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| http://dx.doi.org/10.1002/cne.21562 | DOI Listing |
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