Site-specific pathophysiology in a neonatal mouse model of gastroparesis

Early-life events impact maturation of the gut microbiome, enteric nervous system, and gastrointestinal motility. We examined three regions of gastric tissue to determine how maternal separation and gut microbes influence the structure and motor function of specific regions of the neonatal mouse sto...

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Bibliographic Details
Published in:Neurogastroenterology and motility 2023-11, Vol.35 (11), p.e14676-e14676
Main Authors: Edwards, Price T, Soni, Krishnakant G, Conner, Margaret E, Fowler, Stephanie W, Foong, Jaime P P, Stavely, Rhian, Cheng, Lily S, Preidis, Geoffrey A
Format: Article
Language:English
Subjects:
Animals
Animals, Newborn
Carbachol
Dextran
Digestive system
Disease Models, Animal
Enteric nervous system
Fluorescein isothiocyanate
Gastric Emptying
Gastric motility
Gastrointestinal tract
Gastroparesis
Intestinal microflora
Light microscopy
Maternal Deprivation
Mice
Mice, Inbred C57BL
Microbiomes
Muscle contraction
Myenteric plexus
Myenteric Plexus - pathology
Neonates
Pathophysiology
Sampling
Stomach
Structure-function relationships
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Summary:Early-life events impact maturation of the gut microbiome, enteric nervous system, and gastrointestinal motility. We examined three regions of gastric tissue to determine how maternal separation and gut microbes influence the structure and motor function of specific regions of the neonatal mouse stomach. Germ-free and conventionally housed C57BL/6J mouse pups underwent timed maternal separation (TmSep) or nursed uninterrupted (controls) until 14 days of life. We assessed gastric emptying by quantifying the progression of gavaged fluorescein isothiocyanate (FITC)-dextran. With isolated rings of forestomach, corpus, and antrum, we measured tone and contractility by force transduction, gastric wall thickness by light microscopy, and myenteric plexus neurochemistry by whole-mount immunostaining. Regional gastric sampling revealed site-specific differences in contractile patterns and myenteric plexus structure. In neonatal mice, TmSep prolonged gastric emptying. In the forestomach, TmSep increased contractile responses to carbachol, decreased muscularis externa and mucosa thickness, and increased the relative proportion of myenteric plexus nNOS+ neurons. Germ-free conditions did not appreciably alter the structure or function of the neonatal mouse stomach and did not impact the changes caused by TmSep. A regional sampling approach facilitates site-specific investigations of murine gastric motor physiology and histology to identify site-specific alterations that may impact gastrointestinal function. Delayed gastric emptying in TmSep is associated with a thinner muscle wall, exaggerated cholinergic contractile responses, and increased proportions of inhibitory myenteric plexus nNOS+ neurons in the forestomach. Gut microbes do not profoundly affect the development of the neonatal mouse stomach or the gastric pathophysiology that results from TmSep.
ISSN:1350-1925
1365-2982
1365-2982
DOI:10.1111/nmo.14676