Muscle hypertrophy and neuroplasticity in the small bowel in short bowel syndrome.

Short bowel syndrome (SBS) is a severe, life-threatening condition and one of the leading causes of intestinal failure in children. Here we were interested in changes in muscle layers and especially in the myenteric plexus of the enteric nervous system (ENS) of the small bowel in the context of intestinal adaptation. Twelve rats underwent a massive resection of the small intestine to induce SBS. Sham laparotomy without small bowel transection was performed in 10 rats. Two weeks after surgery, the remaining jejunum and ileum were harvested and studied. Samples of human small bowel were obtained from patients who underwent resection of small bowel segments due to a medical indication. Morphological changes in the muscle layers and the expression of nestin, a marker for neuronal plasticity, were studied. Following SBS, muscle tissue increases significantly in both parts of the small bowel, i.e., jejunum and ileum. The leading pathophysiological mechanism of these changes is hypertrophy. Additionally, we observed an increased nestin expression in the myenteric plexus in the remaining bowel with SBS. Our human data also showed that in patients with SBS, the proportion of stem cells in the myenteric plexus had risen by more than twofold. Our findings suggest that the ENS is tightly connected to changes in intestinal muscle layers and is critically involved in the process of intestinal adaptation to SBS.

The Surgical Treatment of Toxic Megacolon in Hirschsprung Disease.

OBJECTIVES: Enterocolitis remains the most significant cause of morbidity and mortality in Hirschsprung disease (HD). It could progress into toxic megacolon (TM)-acute dilatation of the colon as accompanying toxic complication of Hirschsprung enterocolitis. It is a devastating complication, especially in infants with so far undiagnosed HD. METHODS: A retrospective analysis of medical records of 4 infants with TM was performed. The diagnosis TM was determined on the basis of clinical information (abdominal pain or tenderness, abdominal distension, diarrhea, bloody diarrhea, and constipation), plain x-rays of the abdomen (segmental or total colonic dilation), and the presence of such criteria (fever, high heart rate, increased white blood cell count, C reactive protein, anemia, dehydration, electrolyte disturbances, hypotension). Surgical management and outcome was evaluated by retrospective chart review. RESULTS: The median duration of symptoms characteristic for TM was 3 days. Toxic megacolon was seen as the first manifestation of previously unknown HD in 3 patients; in 1 newborn, the contrast radiograph was suggestive of HD. In all patients, conservative treatment was failed. Three patients were treated with surgical decompression and ileostomy only. In all these cases, severe complications occurred, consequently 2 of them died. In 1 patient, a resection of the transverse dilated colon additionally was performed. This patient had no complications in postoperative period and survived. CONCLUSIONS: Because of the high mortality in patients with TM that were treated medically or with colonic decompression, a resection of massively distended part of the colon should be performed.

The human gastrointestinal tract, a potential autologous neural stem cell source.

Stem cell therapies seem to be an appropriate tool for the treatment of a variety of diseases, especially when a substantial cell loss leads to a severe clinical impact. This is the case in most neuronal cell losses. Unfortunately, adequate neural stem cell sources are hard to find and current alternatives, such as induced programmed stem cells, still have incalculable risks. Evidence of neurogenesis in the adult human enteric nervous system brought up a new perspective. In humans the appendix harbors enteric neuronal tissue and is an ideal location where the presence of neural stem cells is combined with a minimal invasive accessibility. In this study appendices from adults and children were investigated concerning their neural stem cell potential. From each appendix tissue samples were collected, and processed for immunohistochemistry or enteric neural progenitor cell generation. Free-floating enteric neurospheres (EnNS's) could be generated after 6 days in vitro. EnNS's were either used for transplantation into rat brain slices or differentiation experiments. Both transplanted spheres and control cultures developed an intricate network with glia, neurons and interconnecting fibers, as seen in primary enteric cultures before. Neuronal, glial and neural stem cell markers could be identified both in vitro and in vivo by immunostaining. The study underlines the potential of the enteric nervous system as an autologous neural stem cell source. Using the appendix as a potential target opens up a new perspective that might lead to a relatively unproblematic harvest of neural stem cells.

FGF2 deficit during development leads to specific neuronal cell loss in the enteric nervous system.

The largest part of the peripheral nervous system is the enteric nervous system (ENS). It consists of an intricate network of several enteric neuronal subclasses with distinct phenotypes and functions within the gut wall. The generation of these enteric phenotypes is dependent upon appropriate neurotrophic support during development. Glial cell line-derived neurotrophic factor (GDNF) and fibroblast growth factor-2 (FGF2) play an important role in the differentiation and function of the ENS. A lack of GDNF or its receptor (Ret) causes intestinal aganglionosis in mice, while fibroblast growth factor receptor signaling antagonist is identified as regulating proteins in the GDNF/Ret signaling in the developing ENS. Primary myenteric plexus cultures and wholemount preparations of wild type (WT) and FGF2-knockout mice were used to analyze distinct enteric subpopulations. Fractal dimension (D) as a measure of self-similarity is an excellent tool to analyze complex geometric shape and was applied to classify the subclasses of enteric neurons concerning their individual morphology. As a consequence of a detailed analysis of subpopulation variations, wholemount preparations were stained for the calcium binding proteins calbindin and calretinin. The fractal analysis showed a reliable consistence of subgroups with different fractal dimensions (D) in each culture investigated. Seven different neuronal subtypes could be differentiated according to a rising D. Within the same D, the neurite length revealed significant differences between wild type and FGF2-knockout cultures, while the subclass distribution was also altered. Depending on the morphological characteristics, the reduced subgroup was supposed to be a secretomotor neuronal type, which could be confirmed by calbindin and calretinin staining of the wholemount preparations. These revealed a reduction up to 40 % of calbindin-positive neurons in the FGF2-knockout mouse. We therefore consider FGF2 playing a more important role in the fine-tuning of the ENS during development as previously assumed.

The microenvironment in the Hirschsprung's disease gut supports myenteric plexus growth.

INTRODUCTION: The transplantation of neural crest derived stem cells (NCSC) is a potent alternative for the treatment of Hirschsprung's disease (HSCR). Cells to be transplanted should find an appropriate microenvironment to survive and differentiate. Influences of HSCR-smooth-muscle-protein extracts upon isolated myenteric plexus cells, dissociated dorsal root ganglia and NCSC were studied in vitro to investigate the quality of this microenvironment effects. METHODS: Postnatal human gut from children undergoing colonic resection due to HSCR was divided in segments. Smooth muscle was dissected and homogenized. Glial-cell-line-derived-neurotrophic-factor (GDNF) and transforming-growth-factor-ß-1 (TGFß-1) concentration were measured in the homogenates from the individual segment using ELISA. Myenteric plexus and dissociated dorsal root ganglia (DRG) cultures, as well as NCSCs were exposed to protein extracts derived from ganglionic and aganglionic HSCR segments, and their effect upon neurite outgrowth, survival, and branching was evaluated. RESULTS AND CONCLUSIONS: The amount of the factors varied considerably between the individual segments and also from patient to patient. Four major expression patterns could be detected. While all extracts tested lead to a significant increase in neurite outgrowth compared to the control, extracts from proximal segments tended to have more prominent effects. In one experiment, extracts from all individual segments of a single patient were tested. Neurite outgrowth, neuronal survival, and branching pattern varied from segment to segment, but all HSCR-muscle-protein extracts increased neuronal survival and network formation. Smooth muscle protein from aganglionic bowel supports the survival and outgrowth of myenteric neurons and NCSCs and is so an appropriate target for neural stem cell treatment.

Smooth muscle proteins from Hirschsprung's disease facilitates stem cell differentiation.

BACKGROUND AND AIMS: The transplantation of neural crest derived stem cells (NCSC's) is a potent alternative for the treatment of Hirschsprung's disease (HSCR). Cells to be transplanted should find an appropriate microenvironment to survive and differentiate. To investigate the quality of this microenvironment, effects of HSCR-smooth-muscle-protein extracts upon NCSC's were studied in vitro. METHODS: Postnatal human gut from children undergoing colonic resection due to HSCR was divided in segments. Smooth muscle was dissected and homogenized. Glial-cell-line-derived-neurotrophic-factor (GDNF) concentration was measured in the homogenates from the individual segment using ELISA. NCSC's were exposed to protein extracts derived from ganglionic and aganglionic HSCR segments, and their effect upon neurite outgrowth, survival and branching was evaluated. RESULTS: The amount of the factors varied considerably between the proximal and distal segments, and also from patient to patient. While extracts from proximal segments tended to have more prominent effects, all HSCR-muscle-protein extracts increased neuronal survival and network formation. CONCLUSION: Muscle protein from aganglionic bowel supports the survival and outgrowth of NCSC's and is so an appropriate target for neural stem cell treatment.

Proteome analysis of isolated myenteric plexus reveals significant changes in protein expression during postnatal development.

The enteric nervous system in vertebrates is the most complex part of the peripheral nervous system. Concerning chemical coding, ultrastructure and neuronal circuits, it is more similar to the central than to the peripheral nervous system. Its networks, the myenteric and submucous plexus are integrated in the gut wall. The enteric nervous system is a system of high plasticity, which not only changes during pre- and postnatal development, but also with disease or changing dietary habits. The Aim of this study was to elucidate changes in protein expression during the first two postnatal weeks in the rat myenteric plexus. Colonic and duodenal myenteric plexus from newborn (P1) and fourteen-day old (P14) Sprague-Dawley rats was isolated following a procedure that combines enzymatic digestion and mechanical agitation. The neuronal tissue was collected and processed for two-dimensional gel electrophoresis (2-DE). The obtained 2-D gels were stained with silver for image analysis or with colloidal Coomassie for subsequent protein identification. Gels from the various samples showed a high degree of consistence concerning protein-spots found in all preparations. Nevertheless, there was a number of proteins that were clearly detected in one sample but not, or only in significantly smaller amounts in the other. Several differentially expressed proteins in the postnatal myenteric plexus were identified with MALDI-TOF mass spectrometry. Especially stathmin, polyubiquitin and heterogeneous nuclear ribonucleoprotein seem to play an important role in pre- and postnatal development. 2-DE combined with mass spectrometry can help to identify pathological relevant proteins in the enteric nervous system, and so deliver a valuable tool for the early diagnosis of also central nervous system diseases by using biopsies from the gut.

Differentiation of neurospheres from the enteric nervous system.

The enteric nervous system (ENS) derives from neural crest cells, which migrate from the neural tube into the developing gut. The neuronal and glial precursor cells migrate mainly from the oral towards the anal end of the gastrointestinal tract. So far, knowledge about the multipotent influences upon the ENS development, especially its neurotrophic support, derives mainly from knock-out models. The in vitro technique of isolating enteric neuronal precursor cells allows to study the effects of various factors upon their appropriate development in more detail. We therefore adapted the method of growing neurospheres, which are agglomerates of neuronal precursor cells and differentiated neurones and glial cells, from the central nervous system (CNS) for the ENS. The gut of NMRI mice at E12 were dissected, mildly dissociated and plated in 25-cm(2) culture flasks. The cultures were maintained in N1 supplemented DMEM/F12 medium with the appropriate neurotrophin cocktails (bFGF, GDNF, Neurturin, CNTF). After several days in culture most of the cells die, while the surviving cells form clusters from which domes, and later spheres arise. The spheres could be harvested and processed for further experiments. First investigations revealed, that the amount of precursor cells was much less in enteric neurospheres as seen in corresponding cultures from the CNS. We found about 43% HNK-1-NCAM+ in enteric and approximately 90% Nestin-+ cells in midbrain neurospheres. Differentiation studies of the enteric neurospheres showed that especially ciliary neurotrophic factor (CNTF) increased the number of enteric neurones (PGP positive), while the amount of HNK-1 precursor cells decreased under the influence of all tested neurotrophins but GDNF. The culture of the freshly dissociated enteric neurospheres in a three-dimensional matrix yielded a secondary network which allows to investigate the pattern formation of the ENS. The generation of enteric neurospheres and the following differentiation and 3D culture in vitro can increase our knowledge of the amount and time point of neurotrophic as well as the ECM-protein influence upon the appropriate development of the ENS.