More than a century ago, rhythmic propulsive contractile activity was observed in the intestine after blockade of nerve conduction, thus demonstrating a form of peristalsis that appeared to be under myogenic control. During this century, light and electron microscopic investigations provided the hypothesis that interstitial cells of Cajal (ICC) could be the cells of origin for this rhythmicity. In recent years, physiological studies demonstrated a link between the presence of electrical slow wave activity and the presence of ICC. The recognition that the ICC cell membrane harbours the Kit protein sparked rapid advancement in ICC research, and has been essential in the identification of ICC in tissue and in culture through Kit immunohistochemistry and kit mRNA reverse transcriptase polymerase chain reaction (RT-PCR). With these techniques, electrophysiology was carried out on positively identified single ICC in culture. These methods revealed that single ICC generate spontaneous rhythmic inward currents and slow waves in membrane potential, thus providing strong evidence that ICC generate the electrical pacemaker activity for the gut musculature.
In contrast to wild-type mice, homozygotes with mutations of the W locus do not express the functional Kit receptor and are severely deficient in the Auerbach's plexus (AP)-associated subtype of interstitial cells of Cajal (ICC-AP). With a morphologically intact neural and muscular structure, the absence in these mutants of both small-intestinal slow waves and ICC-AP constitutes strong evidence for a key role of ICC-AP as pacemaker cells. In steel-Dickie mutant mice (Sl/Sld), the gene coding for the Kit ligand (stem cell factor) is defective. We examined Sl/Sld mutants and controls with intracellular microelectrode techniques, combined with light and electron microscopy. The absence of the normal Kit ligand (Sl/Sld mice) had very similar effects as the absence of the Kit receptor in viable mice, mutated at the White spotting, W, locus (W/Wv mice), in that neither slow waves, nor Kit receptor immunoreactivity in the region of Auerbach's plexus nor ICC-AP were present in the small intestine. In the Sl/Sld mouse, the smooth muscle cells generated action potentials at variable frequencies from a depolarized cell membrane of -40 to -55 mV. Increasing excitability by K channel blockers created many different patterns of action potential generation and the frequency increased from approximately 16 cpm to 66 cpm. This was in sharp contrast to control mice where action potentials were always restricted to the plateau phase of the slow waves and the slow wave frequency remained constant at approximately 39 cpm. Our data provide further strong support for the identification of ICC-AP as small-intestinal pacemaker cells. In addition, they provide a basis for the understanding of intestinal motor function without pacemaker activity.
A Trichinella spiralis infection produces an acute inflammatory reaction and tissue damage in the mucosa, and, in addition, functional changes occur in the external muscle layers. The aim of the present study was to characterize structural changes in the musculature that occur during early infection, and to identify relationships between immune cells and muscle cells, as part of an ongoing investigation into the immune modulation of motor function in the gut. Rats were infected with T. spiralis larvae and the gut fixed at 12 h, 24 h, 48 h and 6 days post-infection for electron microscopy of the longitudinal muscle. Macrophages and lymphocytes penetrated the longitudinal musculature 12-24 h post-infection. Distinct contacts were observed between specific cell types; cellular protrusions from macrophages or lymphocytes made close apposition contacts with smooth muscle cells. Resident macrophages in the subserosal space, fibroblast-like cells as well as smooth muscle cells showed marked activation during inflammation. Fibroblast-like cells were frequently seen intercalated between lymphocytes and smooth muscle cells, hence they may mediate communication between immune cells and the musculature.
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