Traumatic spinal cord injury (SCI) leads to disruption of sensory, motor and autonomic function, and triggers structural, physiological and biochemical changes that cause reorganization of existing circuits that affect functional recovery. Propriospinal neurons (PN) appear to be very plastic within the inhibitory microenvironment of the injured spinal cord by forming compensatory circuits that aid in relaying information across the lesion site and, thus, are being investigated for their potential to promote locomotor recovery after experimental SCI. Yet the role of PN plasticity in autonomic dysfunction is not well characterized, notably, the disruption of supraspinal modulatory signals to spinal sympathetic neurons after SCI at the sixth thoracic spinal segment or above resulting in autonomic dysreflexia (AD). This condition is characterized by unmodulated sympathetic reflexes triggering sporadic hypertension associated with baroreflex mediated bradycardia in response to noxious yet unperceived stimuli below the injury to reduce blood pressure. AD is frequently triggered by pelvic visceral distension (bowel and bladder), and there are documented structural relationships between injury-induced sprouting of pelvic visceral afferent C-fibers. Their excitation of lumbosacral PN, in turn, sprout and relay noxious visceral sensory stimuli to rostral disinhibited thoracic sympathetic preganglionic neurons (SPN) that manifest hypertension. Herein, we review evidence for maladaptive plasticity of PN in neural circuits mediating heightened sympathetic reflexes after complete high thoracic SCI that manifest cardiovascular dysfunction, as well as contemporary research methodologies being employed to unveil the precise contribution of PN plasticity to the pathophysiology underlying AD development.
To determine molecular changes that correlate with long-term physiological changes after spinal cord injury associated with spasticity, we used a complete transection model with an injury at sacral spinal level S2, wherein tail spasms develop in rats weeks to months post-injury. Using Illumina and nanopore sequencing, we found that from 12,266 expressed genes roughly 11% (1,342) change expression levels in the rats with spasticity. The transcription factor PU.1 (Spi-1 proto-oncogene) and several of its known regulated genes were upregulated during injury, possibly reflecting changes in cellular composition. In contrast to widespread changes in gene expression, only a few changes in alternative exon usage could be detected because of injury. There were more than 1,000 changes in retained intron usage, however. Unexpectedly, most of these retained introns have not been described yet but could be validated using direct RNA nanopore sequencing. In addition to changes from injury, our model allowed regional analysis of gene expression. Comparing the segments rostral and caudal to the injury site in naïve animals showed 525 differentially regulated genes and differential regional use of retained introns. We did not detect changes in the serotonin receptor 2C editing that were implicated previously in this spinal cord injury model. Our data suggest that regulation of intron retention of polyadenylated pre-mRNA is an important regulatory mechanism in the spinal cord under both physiological and pathophysiological conditions.
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