Oil of mustard (OM) is a potent neuronal activator that promotes allodynia and hyperalgesia within minutes of application. In this study, OM was used to induce an acute colitis. We also investigated whether intracolonic OM-induced inflammation alters gastrointestinal (GI) function over a longer time frame as a model of postinflammatory irritable bowel syndrome (PI-IBS). Mice given a single administration of 0.5% OM developed a severe colitis that peaked at day 3, was reduced at day 7, and was absent by day 14. At the peak response, there was body weight loss, colon shrinkage, thickening and weight increases, distension of the proximal colon, and diarrhea. Macroscopic inspection of the distal colon revealed a discontinuous pattern of inflammatory damage and occasional transmural ulceration. Histological examination showed loss of epithelium, an inflammatory infiltrate, destruction of mucosal architecture, edema, and loss of circular smooth muscle architecture. OM administration increased transit of a carmine dye bolus from 58% of the total length of the upper GI tract in untreated age-matched controls to as high as 74% when tested at day 28 post-OM. Mice in the latter group demonstrated a significantly more sensitive response to inhibition of upper GI transit by the mu-opioid receptor agonist loperamide compared with normal mice. OM induces a rapid, acute, and transient colitis and, in the longer term, functional changes in motility that are observed when there is no gross inflammation and thereby is a model of functional bowel disorders that mimic aspects of PI-IBS in humans.
Intracellular recordings of jejunal myenteric neurons with an afterspike hyperpolarization (AH) from Trichinella spiralis-infected animals showed enhanced excitability on days 3, 6, and 10postinfection (PI) compared with uninfected animals. Lower membrane potential, increased membrane input resistance, decreased threshold for action potential discharge, decreased AH amplitude and duration, and increased fast excitatory postsynaptic potential amplitude and duration were characteristic of neuronal recordings from infected animals. Concurrent with electrophysiological changes during T. spiralis infection, increased cytochrome oxidase activity, a marker of neuronal metabolic activity, and the expression of nuclear c-Fos immunoreactivity, an indicator of transcriptional-translational activity, were also observed in myenteric ganglion cells. Double-labeling for calbindin-immunoreactive myenteric neurons revealed that ∼50% of these neurons also expressed increased c-Fos immunoreactivity during T. spiralis infection. Myeloperoxidase activity was significantly higher in the jejunum of T. spiralis-infected guinea pigs on days 3, 6, and 10 PI vs. uninfected counterparts. The expression of c-Fos in calbindin-immunoreactive neurons together with enhanced neuronal electrical and metabolic activity during nematode-induced intestinal inflammation suggests the onset of excitation-transcription coupled changes in enteric neural microcircuits.
SUMMARY1. The actions of forskolin on electrical behaviour of myenteric neurones were investigated with intracellular recording methods in guinea-pig small intestine.2. The actions of forskolin were: membrane depolarization, increased input resistance, suppression of post-spike hyperpolarizing potentials and repetitive spike discharge. These effects occurred always in AH/Type 2 myenteric neurones and never in the cells classified as S/Type 1.3. Reversal potentials for the depolarizing effects were near the estimated potassium equilibrium potential. Analyses based on the 'constant field equation' indicated that the permeability ratios of K+ to other permeant ionic species were reduced by forskolin.4. Pretreatment of the neurones with a phosphodiesterase inhibitor potentiated the effects of forskolin.5. The results suggest that activation of adenylate cyclase by forskolin and subsequent elevation of intraneuronal adenosine 3',5'-phosphate (cyclic AMP) mimic slow synaptic excitation in AH/Type 2 myenteric neurones. They support the possibility that cyclic AMP functions as a second messenger in signal transduction which appears to involve closure of calcium-dependent K+ channels and other membrane changes that lead to depolarization and a dramatic increase in the excitability of the neurones.
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