Interstitial cells of Cajal in the striated musculature of the mouse esophagus

A key feature of signal processing in the mammalian retina is parallel processing, where the segregation of visual information, e.g., brightness, darkness, and color, starts at the first synapse in the retina, the photoreceptor synapse. These various aspects are transmitted in parallel from the input neurons of the retina, the photoreceptor cells, through the interconnecting bipolar cells, to the output neurons, the ganglion cells. The photoreceptors and bipolar cells release a single excitatory neurotransmitter, glutamate, at their synapses. This parsimony is contrasted by the expression of a plethora of glutamate receptors, receptor subunits, and isoforms. The detailed knowledge of the synaptic distribution of glutamate receptors thus is of major importance in understanding the mechanisms of retinal signal processing. This review intends to highlight recent studies on the distribution of glutamate receptors at the photoreceptor synapses of the mammalian retina.     

Interstitial cells of Cajal in the urethra

The smooth muscle layer of the urethra generates spontaneous myogenic tone that is thought to make a major contribution to urinary continence. The mechanisms underlying generation of tone remain unclear, however recent studies from our laboratory highlighted a role for a specialised population of pacemaker cells which we originally referred to as interstitial cells (IC) and now term ICC. Urethra ICC possess an electrical pacemaker mechanism characterised by rhythmic activation of Ca(2+)-activated Cl(-) channels leading to spontaneous transient inward currents (STICs) under voltage clamp and spontaneous transient depolarisations (STDs) under current clamp conditions. Both STICS and STDs are now known to be associated with spontaneous Ca(2+) oscillations that result from a complex interplay between release of Ca(2+) from intracellular stores and Ca(2+) influx across the plasma membrane. In this review we will consider some of the precise mechanisms involved in the generation of pacemaker activity and discuss how these are modulated by excitatory and inhibitory neurotransmitters.     

Interstitial cells of Cajal in pancreas

We show here (presumably for the first time) a special type of cell in the human and rat exocrine pancreas. These cells have phenotypic characteristics of the enteric interstitial cells of Cajal (ICC). To identify pancreatic interstitial cells of Cajal (pICC) we used routine light microscopy, non-conventional light microscopy (less than 1 mum semi-thin sections of Epon-embedded specimens cut by ultramicrotomy and stained with Toluidine blue), transmission electron microscopy (TEM), and immunocytochemistry. The results showed that pICC can be recognized easily by light microscopy, particularly on semi-thin sections, as well as by TEM. Two-dimensional reconstructions from serial photos suggest a network-like spatial distribution of pICC. pICC represent 3.3+/-0.5% of all pancreatic cells, and seem to establish close spatial relationships with: capillaries (43%), acini (40%), stellate cells (14%), nerve fibres (3%). Most of pICC (88%) have 2 or 3 long processes (tens of mum) emerging from the cell body. TEM data show that pICC meet the criteria for positive diagnosis as ICC (e.g. numerous mitochondria, 8.7+/-0.8% of cytoplasm). Immunocytochemistry revealed that pICC are CD117/c-kit and CD34 positive. We found pICC positive (40-50%) for smooth muscle alpha-actin or S-100, and, occasionally, for CD68, NK1 neurokinin receptor and vimentin. The reactions for desmin and chromogranin A were negative in pICC. At present, only hypotheses and speculations can be formulated on the possible role of the pICC (e.g., juxtacrine and/or paracrine roles). In conclusion, the quite-established dogma: "ICC only in cavitary organs" is overpassed.     

Cajal细胞与胃肠起搏

存在于胃肠平滑肌内的Cajal间质细胞（ＩＣＣ）与胃肠道运动的发生和控制密切相关。ＩＣＣ可自发激活并产生节律性去极化慢波（ＳＷ）,经由ＩＣＣ形成的网络传向平滑肌细胞,并向远端扩布。平滑肌细胞缺乏产生ＳＷ活动的必要离子基础,但对于由ＩＣＣ传来的ＳＷ产生反应,使ＳＷ增强或诱发动作电位和收缩活动。因此,ＩＣＣ不仅是胃肠ＳＷ活动的起搏者,也是ＳＷ的传播者,同时对神经递质等生物活性物质影响平滑肌收缩起着居间调制作用。     

Interstitial cells of Cajal mediate excitatory sympathetic neurotransmission in guinea pig prostate

Morphological and functional studies have confirmed that interstitial cells of Cajal (ICCs) are involved in many enteric motor neurotransmission pathways. Recent investigations have demonstrated that human and guinea pig prostate glands possess a distinct cell type with morphological and immunological similarities to ICCs. These prostate ICCs have a close relationship with nerve bundles and smooth muscle cells. Prostate smooth muscle tone is largely induced by stimulation from the sympathetic nervous system, which releases excitatory norepinephrine (NE) to act on the α1-adrenoceptor. We have performed morphological and functional experiments to determine the role of ICCs in sympathetic neurotransmission in the guinea pig prostate based on the hypothesis that prostate ICCs act as mediators of sympathetic neurotransmission. Immunohistochemistry revealed many close points of contact between ICCs and sympathetic nerve bundles and smooth muscle cells. Double-labeled sections revealed that α1-adrenoceptor and the gap junction protein connexin 43 were expressed in prostate ICCs. Surprisingly, prostate ICCs co-expressed tyrosine hydroxylase and dopamine β-hydroxylase, two markers of sympathetic neurons. Functionally, the application of NE evoked a large single inward current in isolated prostate ICCs in a dose-dependent manner. The inward current evoked by NE was mediated via the activation of α1-adrenoceptors, because it was abolished by the non-specific α-adrenoceptor antagonist, phentolamine and the specific α1-adrenoceptor antagonist, prazosin. Thus, ICCs in the guinea pig prostate are target cells for prostate sympathetic nerves and possess the morphological and functional characteristics required to mediate sympathetic signals.     

Interstitial cells of Cajal and electrical activity in ganglionic and aganglionic colons of mice

An antibody directed against Kit protein was used to investigate the distribution of interstitial cells of Cajal (ICC) within the murine colon. The ICC density was greatest in the proximal colon and decreased along its length. The distribution of the different classes of ICC in the aganglionic colons of lethal spotted (ls/ls) mice was found to be similar in age-matched wild-type controls. There were marked differences in the electrical activities of the colons from ls/ls mutants compared with wild-type controls. In ls/ls aganglionic colons, the circular muscle was electrically quiescent compared with the spontaneous spiking electrical activity of wild-type tissues. In ls/ls aganglionic colons, postjunctional neural responses were greatly affected. Inhibitory junction potentials were absent or excitatory junction potentials inhibited by atropine were observed. In conclusion, the distribution of ICC in the ganglionic and aganglionic regions of the colons from ls/ls mutants appeared similar to that of wild-type controls. The electrical activity and neural responses of the circular layer are significantly different in aganglionic segments of ls/ls mutants.     

Interstitital cells of Cajal in the human stomach: distribution and relationship with enteric innervation

Interstitial cells of Cajal (ICC) are distributed throughout the gastrointestinal muscle coat with a region-specific location, and are considered to be pace-maker and/or mediators of neurotransmission. Little is known about their shape, size, distribution and relationships with excitatory and inhibitory nerves in human stomach. With this aim, we labeled the ICC, using c-Kit immunohistochemistry, followed by a quantitative analysis to evaluate the distribution and area occupied by these cells in the circular and longitudinal muscle layers and at the myenteric plexus level in the human fundus, corpus and antrum. Furthermore, by NADPH-d histochemistry and substance P (SP) immunohistochemistry, we labeled and quantified nitric oxide (NO)-producing and SP-containing nerves and evidenced their relationships with the ICC in these three gastric regions. In the fundus, the ICC appeared as bipolar cells and in the corpus and antrum they mainly appeared as multipolar cells, with highly ramified processes. The networks formed by ICC differed in the three gastric regions. The ICC number was significantly higher and cell area smaller in the fundus compared to the corpus and antrum. The area occupied by the ICC was significantly higher at the myenteric plexus level compared with circular and longitudinal muscle layers. Everywhere, NADPH-d-positive nerves were more numerous than SP-positive ones. Both kinds of fibers were closely apposed to the ICC in the corpus and antrum. In conclusion, in the human stomach, the ICC have region-specific shape, size and distribution and in the corpus and antrum have close contact with both inhibitory and excitatory nerves. Presumably, as suggested for laboratory mammals, these differences are in relationship with the motor activities peculiar to each gastric area.     

膀胱ICC细胞的研究现状和展望

膀胱ICC细胞(Interstitial cells of Cajal in bladder)早在上个世纪已被发现,与胃肠道ICC细胞同族,膀胱ICC以自发电活动为特性,源于胞内贮存钙离子释放和钙激活的氯同道开放引起自发短暂去极化。膀胱ICC细胞起初被理解为起搏细胞,其自发的电活动作为起搏器引起下游平滑肌的收缩,这种假说尚缺乏立足的直接证据,目前认为ICC细胞仅仅是膀胱平滑肌收缩活动的调节器,与上皮-传入神经以及神经-平滑肌的信号传递密切相关。病理状态下ICC细胞的作用似乎比生理状态下更为突出,例如膀胱过度活动症,多篇文献报道膀胱过度活动症患者膀胱的ICC细胞数目比正常增多,而且其平滑肌的收缩对酪氨酸激酶受体(tyrosine kinase receptor,c-Kit)拮抗剂格列卫更加敏感。未来膀胱ICC细胞的研究集中在阐明病理及生理状态下ICC的作用机制和信号通路。     

Distinct roles of nitric oxide synthases and interstitial cells of Cajal in rectoanal relaxation

Nitric oxide (NO) relaxes the internal anal sphincter (IAS), but its enzymatic source(s) remains unknown; neuronal (nNOS) and endothelial (eNOS) NO synthase (NOS) isoforms could be involved. Also, interstitial cells of Cajal (ICC) may be involved in IAS relaxation. We studied the relative roles of nNOS, eNOS, and c-Kit-expressing ICC for IAS relaxation using genetic murine models. The basal IAS tone and the rectoanal inhibitory reflex (RAIR) were assessed in vivo by a purpose-built solid-state manometric probe and by using wild-type, nNOS-deficient (nNOS-/-), eNOS-deficient (eNOS-/-), and W/W(v) mice (lacking certain c-Kit-expressing ICC) with or without L-arginine or N(omega)-nitro-L-arginine methyl ester (L-NAME) treatment. Moreover, the basal tone and response to electrical field stimulation (EFS) were studied in organ bath using wild-type and mutant IAS. In vivo, the basal tone of eNOS-/- was higher and W/W(v) was lower than wild-type and nNOS-/- mice. L-arginine administered rectally, but not intravenously, decreased the basal tone in wild-type, nNOS-/-, and W/W(v) mice. However, neither L-arginine nor L-NAME affected basal tone in eNOS-/- mice. In vitro, L-arginine decreased basal tone in wild-type and nNOS-/- IAS but not in eNOS-/- or wild-type IAS without mucosa. The in vivo RAIR was intact in wild-type, eNOS-/-, and W/W(v) mice but absent in all nNOS-/- mice. EFS-induced IAS relaxation was also reduced in nNOS-/- IAS. Thus the basal IAS tone is largely controlled by eNOS in the mucosa, whereas the RAIR is controlled by nNOS. c-Kit-expressing ICC may not be essential for the RAIR.     

Development of c‐kit immunopositive interstitial cells of Cajal in the human stomach

Interstitial cells of Cajal (ICC) include several types of specialized cells within the musculature of the gastrointestinal tract (GIT). Some types of ICC act as pacemakers in the GIT musculature, whereas others are implicated in the modulation of enteric neurotransmission. Kit immunohistochemistry reliably identifies the location of these cells and provides information on changes in ICC distribution and density. Human stomach specimens were obtained from 7 embryos and 28 foetuses without gastrointestinal disorders. The specimens were 7–27 weeks of gestational age, and both sexes are represented in the sample. The specimens were exposed to anti‐c‐kit antibodies to investigate ICC differentiation. Enteric plexuses were immunohistochemically examined by using anti‐neuron specific enolase and the differentiation of smooth muscle cells (SMC) was studied with anti‐α smooth muscle actin and anti‐desmin antibodies. By week 7, c‐kit‐immunopositive precursors formed a layer in the outer stomach wall around myenteric plexus elements. Between 9 and 11 weeks some of these precursors differentiated into ICC. ICC at the myenteric plexus level differentiated first, followed by those within the muscle layer: between SMC, at the circular and longitudinal layers, and within connective tissue septa enveloping muscle bundles. In the fourth month, all subtypes of c‐kit‐immunoreactivity ICC which are necessary for the generation of slow waves and their transfer to SMC have been developed. These results may help elucidate the origin of ICC and the aetiology and pathogenesis of stomach motility disorders in neonates and young children that are associated with absence or decreased number of these cells.     

Visualization of interstitial cells of Cajal in the mouse colon by vital staining

Interstitial cells of Cajal (ICCs) are believed to be a major element in generating the spontaneous rhythm of the gastrointestinal tract. A prominent problem in the study of these cells has been the difficulty in observing them in intact tissues. We used the lipophilic dye DiI to stain ICCs in the submucosal-circular muscle border of freshly dissected mouse colon. The placement of small DiI crystals in this area resulted in the labeling of ICC-like cells. Two main morphological cell types, viz., bipolar and multipolar, were noted. Bipolar cells had two primary processes emerging from the poles of an elongated soma. The mean length of these processes was 78.7 μm. These cells constituted 42.3% of the sample (n=105). Multipolar cells (54.3% of total) had a less elongated soma and extended 3–6 main processes whose mean length was 56.3 μm. These processes showed no preferred direction. The length of the primary processes of bipolar cells was 40% greater than that of multipolar cells (P<0.02). Three cells (2.9%) had only one primary process. The DiI stain could be converted into a stable electron-opaque product. Electron-microscopic observations showed that these cells had the typical appearance of ICCs reported in previous studies. This staining method should be useful for physiological investigations of ICCs in gastrointestinal tissues. Received: 16 September 1997 / Accepted: 11 November 1997     

Cajal间质细胞与慢性假性结肠肠梗阻关系的研究进展

Cajal间质细胞(interstitial cells of cajal,ICC)主要分布在胃肠道平滑肌细胞与神经纤维之间,是一类特殊的间质细胞,它是胃肠运动的起搏细胞,具有产生、传导慢波,调节胃肠道平滑肌运动的功能。而慢性假性肠梗阻是由于胃肠神经抑制,毒素刺激或肠壁平滑肌本身病变,导致的肠壁肌肉运动功能减弱,临床上具有肠梗阻的症状和体征,但无肠内外机械性肠梗阻因素存在,故又称动力性肠梗阻,按病程有急性和慢性之分,麻痹性肠梗阻和痉挛性肠梗阻属于急性假性肠梗阻,深入研究Cajal间质细胞,对进一步认识胃肠运动的生理及胃肠动力疾病的发生机制有重要意义。     

CD34 immunoreactivity and interstitial cells of Cajal in the human and mouse gastrointestinal tract

Immunoreactivity for the tyrosine kinase receptor Kit (Kit-ir) is an established marker for the interstitial cells of Cajal (ICC) of the gut. Recently, the presence of CD34 immunoreactivity (CD34-ir) has been reported in Kit-ir ICC around the myenteric plexus in human small intestine. Conversely, we observed that CD34-ir labeled Kit-negative fibroblast-like cells, closely adjacent to, but distinct from, the Kit-ir ICC. The existence of cells expressing both CD34-ir and Kit-ir remains controversial. CD34-ir and Kit-ir were studied by high-resolution confocal microscopy on cryostat sections of human and murine gut as well as murine whole-mounts, using specific antibodies raised to human and murine CD34, respectively. CD34-ir labeled numerous cells in all parts of the gut, in man and in mouse. CD34-ir was consistently observed in Kit-negative cells, distinct from the closely adjacent Kit-ir ICC. Thin processes of both cell types intermingled extensively, often at the limit of resolution for light microscopy. CD34-ir was also observed in Kit-negative mesenchymal cells in the submucosa, in capillaries and in mesothelial cells. CD34-ir is not a marker for Kit-ir ICC in the human and murine gut. No CD34-ir, Kit-ir-expressing cells were encountered. Conversely, CD34-ir cells, closely adjacent to, but distinct from, Kit-ir ICC were consistently identified. The intimate relationship between these cells may offer an alternative explanation for reports of CD34 and Kit co-localization. The ontogeny and function of CD34-ir cells in the gut, as well as the origin of gastrointestinal stromal tumors, remain unclear.     

Interstitial cells of Cajal,macrophages and mast cells in the gut musculature: morphology,distribution, spatial and possible functional interactions

• ? Introduction
• ? Identification of the cells
  • ‐ ICC
  • ‐ Macrophages
    • ‐ Activation
    • ‐ Identification
  • ‐ Mast cells
    • ‐ Activation
    • ‐ Identification
• ? Cell distribution
  • ‐ ICC in rodent gastrointestinal tract
  • ‐ ICC in human gastrointestinal tract
  • ‐ Macrophages in rodent gastrointestinal tract
  • ‐ Macrophages in human gastrointestinal tract
  • ‐ Mast cells in rodent gastrointestinal tract
  • ‐ Mast cells in human gastrointestinal tract
• ? Inflammation
  • ‐ Models of inflammation
    • ‐ LPS administration
    • ‐ Surgical anastomosis
    • ‐ Ileal obstruction
    • ‐ Post‐operative ileus
    • ‐ Helminth infections
  • ‐ Inflammatory bowel disease
  • ‐ Achalasia
• ? Diabetes mellitus
  • ‐ NOD/LtJ mice
  • ‐ STZ‐DM rats
• ? Conclusions

Interstitial cells of Cajal (ICC) are recognized as pacemaker cells for gastrointestinal movement and are suggested to be mediators of neuromuscular transmission. Intestinal motility disturbances are often associated with a reduced number of ICC and/or ultrastructural damage, sometimes associated with immune cells. Macrophages and mast cells in the intestinal muscularis externa of rodents can be found in close spatial contact with ICC. Macrophages are a constant and regularly distributed cell population in the serosa and at the level of Auerbach’s plexus (AP). In human colon, ICC are in close contact with macrophages at the level of AP, suggesting functional interaction. It has therefore been proposed that ICC and macrophages interact. Macrophages and mast cells are considered to play important roles in the innate immune defence by producing pro‐inflammatory mediators during classical activation, which may in itself result in damage to the tissue. They also take part in alternative activation which is associated with anti‐inflammatory mediators, tissue remodelling and homeostasis, cancer, helminth infections and immunophenotype switch. ICC become damaged under various circumstances – surgical resection, possibly post‐operative ileus in rodents – where innate activation takes place, and in helminth infections – where alternative activation takes place. During alternative activation the muscularis macrophage can switch phenotype resulting in up‐regulation of F4/80 and the mannose receptor. In more chronic conditions such as Crohn’s disease and achalasia, ICC and mast cells develop close spatial contacts and piecemeal degranulation is possibly triggered.