Rectal prolapse in Winnie mice with spontaneous chronic colitis: changes in intrinsic and extrinsic innervation of the rectum.

Rectal prolapse is associated with diminished anal sensitivity and rectal motor activity. Both sensory and motor functions are controlled by the extrinsic and intrinsic (enteric nervous system) innervation of the gastrointestinal tract. Studies of changes in intestinal innervation in humans and in animal models with rectal prolapse are extremely scarce. The Winnie mouse model of spontaneous chronic colitis closely represents human inflammatory bowel disease and is prone to develop rectal prolapse. We have investigated changes in the myenteric and inhibitory motor neurons and evaluated changes in the density of sensory afferent, sympathetic, and parasympathetic fibers in the rectal colon of Winnie mice with and without rectal prolapse. Our results demonstrate that rectal prolapse in Winnie mice with chronic colitis is correlated with enhanced levels of inflammation, gross morphological damage, and muscular hypertrophy of the rectum. Animals with prolapse have more severe damage to the rectal innervation compared with Winnie mice without prolapse. This includes more severe neuronal loss in the myenteric plexus, involving a decrease in nNOS-immunoreactive neurons (not observed in Winnie mice without prolapse) and a more pronounced loss of VAChT-immunoreactive fibers. Both Winnie mice with and without prolapse have comparable levels of noradrenergic and sensory fiber loss in the rectum. This is the first study providing evidence that the damage and death of enteric neurons, including nitrergic neurons in myenteric ganglia and the loss of cholinergic nerve fibers, are important factors in structural changes in the rectum of mice with rectal prolapse.

Alterations in the distal colon innervation in Winnie mouse model of spontaneous chronic colitis.

The gastrointestinal tract is innervated by extrinsic sympathetic, parasympathetic and sensory nerve fibers as well as by intrinsic fibers from the neurons in myenteric and submucosal ganglia embedded into the gastrointestinal wall. Morphological and functional studies of intestinal innervation in animal models are important for understanding the pathophysiology of inflammatory bowel disease (IBD). The recently established Winnie mouse model of spontaneous chronic colitis caused by a point mutation in the Muc2 mucin gene develops inflammation due to a primary epithelial defect. Winnie mice display symptoms of diarrhea, ulcerations and rectal bleeding similar to those in IBD. In this study, we investigated myenteric neurons, noradrenergic, cholinergic and sensory nerve fibers in the distal colon of Winnie (Win/Win) mice compared to C57/BL6 and heterozygote littermates (Win/Wt) using histological and immunohistochemical methods. All Win/Win mice used in this study had inflammation with signs of mucosal damage, goblet cell loss, thickening of muscle and mucosal layers, and increased CD45-immunoreactivity in the distal colon. The density of sensory, cholinergic and noradrenergic fibers innervating the myenteric plexus, muscle and mucosa significantly decreased in the distal colon of Win/Win mice compared to C57/BL6 and Win/Wt mice, while the total number of myenteric neurons as well as subpopulations of cholinergic and nitrergic neurons remained unchanged. In conclusion, changes in the colon morphology and innervation found in Winnie mice have multiple similarities with changes observed in patients with ulcerative colitis.