Progressive alterations in circular smooth muscle contractility in TNBS-induced colitis in rats.

The present study was designed to investigate inflammation-induced changes in smooth muscle responses to acetylcholine and the tachykinins that may contribute to the abnormal motility associated with inflammatory bowel disease. Colitis was induced in male Sprague-Dawley rats by intrarectal administration of trinitrobenzenesulphonic acid in ethanol. After either 4 h (acute) or 7 days (chronic) the distal colon was taken for in vitro measurement of smooth muscle tension and histological assessment. Acute colitis featured injury and neutrophilic infiltration confined to the mucosa while chronic inflammation showed marked injury, lymphocytic infiltration and muscle thickening. Acute inflammation increased responses to substance P and acetylcholine but decreased responses to neurokinin A. The enhanced response to substance P was dependent on nerves, while the decreased response to neurokinin A reflected a reduction in activity at the level of the smooth muscle. In the saline group, there was evidence of cholinergic interaction with substance P, but not neurokinin A. Substance P modulation of cholinergic nerves was absent in acute inflammation. Responses to all neurotransmitters were decreased in the chronic stage. These data demonstrate progressive changes in the smooth muscle function during acute and chronic colitis that may contribute to the abnormal motility associated with inflammatory bowel disease.

Hyperthermia prevents functional, histological and biochemical abnormalities induced during ileitis.

Inflammatory bowel disease is associated with altered intestinal motility and epithelial damage. Hyperthermia induces heat shock protein expression, components of a basic cellular defence mechanism, and consequently prevents ischaemic damage. Here we investigate whether hyperthermia may prevent altered smooth muscle function as well as underlying inflammation in a model of inflammatory bowel disease. Ileal heat shock protein expression was induced in rats by hyperthermic shock (41.5 degrees C; 5 min). Two hours after heating or sham treatment, ileitis was evoked by TNBS. Ileal samples were taken 4 h later to determine the contractile response of circular muscle strips, and to measure heat shock protein expression, LTB4 generation and damage/inflammation. Ileitis was associated with an increase in the contractile response of circular muscle to substance P but not neurokinin A or nerve stimulation. Hyperthermia induced heat shock protein expression and also prevented this functional change as well as TNBS-induced LTB4 production, subsequent infiltration of neutrophils and epithelial damage. Thus, intestinal inflammation is associated with alterations in tachykinergic control of smooth muscle as well as inflammatory changes. Hyperthermia prevents these changes and induces heat shock protein expression. Pharmacological induction of these proteins may offer a novel clinical strategy in treating both of these aspects of disease.

Tachykinergic neurotransmission is enhanced in small intestinal circular muscle in a rabbit model of inflammation.

Previous electrophysiological studies have shown that tachykinin-mediated excitatory junction potentials are enhanced in a ricin model of inflammatory bowel disease. The present study extends these findings by investigating the contractile response to stimulation of noncholinergic nerves and tachykinin agonists. According to rank order potencies, the rabbit ileal circular muscle was neurokinin (NK)1 preferring, and the response to these agonists was down-regulated by acetylcholine and up-regulated by nitric oxide. In ricin-treated tissue, cholinergic and nitridergic modulation was lost; in the presence of atropine and N-nitro-L-arginine methyl ester, or tetrodotoxin, the response to NK1 and NK2 agonists was enhanced. The noncholinergic response to nerve stimulation was predominantly mediated by NK1 receptors, and the enhanced response of ricin-treated tissue to NK1 agonists probably contributes to the increased response to electrical field stimulation observed under these conditions. Increased tachykinin response and loss of control of this response by acetylcholine and nitric oxide are likely to have profound effects on intestinal motility and could contribute to some of the symptomology of inflammatory bowel disease.

Role of sensory afferents in the myoelectric response to acute enteric inflammation in the rabbit.

The role of sensory afferents in inflammation-induced alterations in myoelectric activity in vivo was investigated in the rabbit small intestine. Isolated ileal loops were implanted with serosal electrodes and exposed to ricin or vehicle after pretreatment with 125 mg/kg of subcutaneous (125 mg over 3 days) or intraluminal (640 microM) capsaicin. After 5 h of myoelectric recording, the loops were prepared for histology and for ex vivo generation of eicosanoids. Capsaicin exacerbated mucosal damage after exposure to ricin but did not alter neutrophil infiltration. Subcutaneous capsaicin alone elevated slow-wave frequency and spike events and transiently suppressed the myoelectric response to ricin. In contrast, intraluminal capsaicin alone did not alter myoelectric activity but produced a sustained inhibition of the response to ricin. Eicosanoid production was unchanged by capsaicin alone. Intraluminal capsaicin blocked increases in leukotriene C4 and prostaglandin E2 during inflammation, an effect that paralleled its inhibition of myoelectric activity. Thus the contribution of sensory afferents to altered motility during acute ileitis involves the release of mucosal inflammatory mediators that influence neural control of smooth muscle.

Effects of antibiotics on epithelial ion transport in the rabbit distal colon in-vitro.

One side-effect of the therapeutic use of antimicrobial agents is respiratory paralysis as a result of inhibition of skeletal neuromuscular transmission; cholinergic neuro-effector motor transmission in the gastrointestinal tract is inhibited by the same classes of antimicrobial agent. Study of the effects of several classes of antibiotic compound on intestinal motility has suggested that antibiotic-induced alterations of intestinal motility may be related to the onset of diarrhoea or the development of antibiotic-associated colitis. These compounds may, however, also initiate or exacerbate diarrhoea by altering control of epithelial function, a possibility that has not previously been rigorously investigated. This series of experiments investigated the effect of six antibiotics on rabbit distal colonic epithelial ion transport. Of all the antibiotics studied, only ampicillin was without effect. Clindamycin, erythromycin, gentamicin and lincomycin, each reduced the response of the epithelium to electrical field stimulation. In addition, the lincosamides clindamycin and lincomycin reduced basal short circuit current and the epithelial response to acetylcholine. Vancomycin had no effect on the response to electrical field stimulation or acetylcholine but enhanced the secretory action of prostaglandin E2. These data suggest that, in addition to their ability to alter intestinal motility, a number of potential antibiotic interactions with the epithelium and its innervation may contribute to the pathogenesis of antibiotic-associated diarrhoea and colitis.

Neural control of mouse small intestinal longitudinal muscle: interactions with inflammatory mediators.

The present study was undertaken to investigate neural control of mouse small intestinal longitudinal muscle. Electrical field stimulation evoked acetylcholine- and neurokinin A-mediated contractile responses, whereas nitric oxide-mediated neurotransmission resulted in relaxation. The inflammatory mediators, histamine and leukotriene D4, contracted the longitudinal muscle preparation. Histamine-evoked contractions resulted from binding to histamine H1 receptors on non-neural cells of the small intestine. Leukotriene D4 played a role in neurokinin A-mediated excitation as the leukotriene D4 receptor antagonist, WY 48,252, reduced the response to nerve stimulation under noncholinergic conditions by almost 80%. In contrast, WY 48,252 had no effect on the response to exogenous neurokinin A, indicating that the response to this neurotransmitter is not mediated by leukotriene D4 release. Subthreshold concentrations of leukotriene D4 did not modify the response to neurokinin A, ruling out a synergistic relationship between these two agonists. Leukotriene D4 did not cause synaptic transmitter release through ganglionic stimulation, because its contractile effect was tetrodotoxin insensitive, and did not contribute to noncholinergic excitation through stimulation of neurokinin A release, as the neurokinin2 receptor antagonist, MEN 10,376, did not alter the response to leukotriene D4. Instead leukotriene D4 may modulate the release of neurokinin A from nerve endings during nerve stimulation.

Changes in enteric neural regulation of smooth muscle in a rabbit model of small intestinal inflammation.

In vitro electrophysiological studies of ileal circular muscle from rabbits with ricin-induced inflammation were performed to investigate whether altered neural control or myogenic activity contributes to previously described changes in in vivo myoelectric activity. Ricin treatment increased mean slow-wave amplitude but not frequency or resting membrane potential. Prolonged electrical field stimulation evoked a hyperpolarization during the stimulus train and a depolarization on cessation of stimulation. In the presence of atropine, the depolarization was larger in ricin-treated tissue than in control tissue, showing that ileitis enhanced noncholinergic excitation. The nitric oxide synthase inhibitor N-nitro-L-arginine methyl ester reduced the hyperpolarization in ricin-treated but not in control tissue, suggesting that inflammation increased nitric oxide-mediated inhibition. Substance P desensitization reduced noncholinergic excitation and mean slow-wave amplitude only in ricin-treated tissue, demonstrating that changes in these parameters during inflammation resulted from increased release of, or sensitivity to, tachykinins. These data suggest that acute ileitis alters tachykinin- and nitric oxide-mediated neurotransmission that may affect the normal pattern of ileal motility and/or sensory reflexes.

Effects of rotavirus on epithelial transport in rabbit small intestine.

The present study investigated changes in small intestinal epithelial transport in rabbits infected with rotavirus. The crypt depth-villus height ratio was increased in infected ileal tissue as a result of a significant increase in crypt depth and patchy shortening of the villi. Similar villus damage was seen in the jejunum. Despite these histological changes, basal fluid absorption by both the ileum and jejunum of infected animals was unaltered. Values for basal short-circuit current and resistance were similar; however, the increase in short-circuit current evoked by prostaglandin E2 was significantly smaller in rotavirus-infected tissues than in controls. The apparent Vmax for electrogenic glucose and alanine uptake by the jejunum was significantly increased following inoculation with rotavirus. Reduced responsiveness to the secretory effect of prostaglandin E2 and increased nutrient uptake may limit diarrhea that would otherwise be expected to occur as a result of the changes in mucosal architecture. This has important implications on the clinical treatment of rotavirus diarrhea, suggesting that oral rehydration therapy, which depends on the active transport of nutrients, may provide a more effective treatment than the use of cyclooxygenase inhibitors.

A novel in vitro technique to study extrinsic neural control of rabbit colonic muscle and epithelial function.

A novel in vitro technique capable of simultaneously measuring distal colonic epithelial potential difference and muscle contraction is described. Under basal conditions, oscillations in both muscle tone and potential difference were observed. Pelvic nerve stimulation was shown to evoke strong "duration" contractile responses in both the longitudinal and circular muscle layers. Additionally, tonic changes in potential difference extending beyond the train of stimuli were observed, suggesting for the first time that colonic ion transport may be influenced by the pelvic nerves. However, it was unclear whether these were direct effects or indirect actions resulting from muscle contractions causing mechanical stimulation of nerves of the submucosal plexus. Lumbar colonic nerve stimulation inhibited spontaneous contractile activity and reduced basal tone in both muscle layers. However, there was no consistent effect of sympathetic nerve stimulation on transepithelial potential difference. Each of the muscle and epithelial effects of sympathetic nerve stimulation was mimicked by exogenous norepinephrine. Based on these data, it is concluded that colonic function is strongly influenced by the extrinsic innervation. Furthermore, relatively long-term modulation of epithelial function can be achieved by short bursts of pelvic nerve activity.

Defective modulation of colonic secretomotor neurons in a rabbit model of colitis.

The present in vitro study was conducted to investigate possible alterations in the control of colonic electrolyte transport in an experimental model of colitis. Intrarectal administration of trinitrobenzenesulfonic acid induced a colitis-like inflammation in the rabbit distal colon. Responses to amiloride and residual short-circuit current after this treatment were unchanged, suggesting that the absorptive and secretory mechanisms remained intact. Electrical field stimulation and vasoactive intestinal polypeptide, a candidate secretomotor neurotransmitter, both elicited similar responses in control and colitic tissue. This suggests that communication at the neuroepithelial junction was unimpaired. In untreated tissue, the effects of prostaglandin E2 (PGE2) and of acetylcholine were attenuated by tetrodotoxin, suggesting, therefore, that both play a role in the modulation of secretomotor neurons. In addition, PGE2 had an appreciable direct epithelial effect. Responses to both of these agonists were absent in colitis. The effects of N6,2'-O-dibutyryladenosine 3',5'-cyclic monophosphate were unchanged in colitis, suggesting that altered PGE2 responsiveness may involve changes in epithelial receptor number, affinity, or in their ability to mediate an increase in adenosine 3',5'-cyclic monophosphate levels. It is concluded that this rabbit model of colitis exhibits 1) defects in the modulation of secretomotor neurons by acetylcholine and PGE2 and 2) an attenuated epithelial response to PGE2.