Ulrich Rauch scite author profile

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.

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Pharmacological evidence for a K_ATP channel in renin‐secreting cells from rat kidney

Russ

Rauch

Quast

1999

The Journal of Physiology

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Openers of the ATP‐sensitive potassium channel (KATP channel) increase and blockers decrease renin secretion. Here we report the effects of levcromakalim (LCRK, a channel opener) and glibenclamide (GBC, a blocker) on membrane potential, whole‐cell current and the cytoplasmic Ca2+ concentration of renin‐secreting cells (RSC). Studies were performed on afferent arterioles from the kidney of Na+‐depleted rats. As monitored with the fluorescent oxonol dye DiBAC4(3), LCRK (0.3 and 1 μm) induced a hyperpolarization of ≈15 mV which was abolished by GBC (1 μm). Whole‐cell current‐clamp experiments showed that RSC had a membrane potential of −61 ± 1 mV (n= 16). LCRK (1 μm) induced a hyperpolarization of 9.9 ± 0.2 mV (n= 16) which, in the majority of cells, decreased slowly with time. Capacitance measurements showed a strong electrical coupling of the cells in the preparation. At −60 mV, LCRK induced a hyperpolarizing current in a concentration‐dependent manner with an EC50 of 152 ± 31 nm and a maximum current of about 200 pA. Application of GBC (1 μm) produced no effect; however, when applied after LCRK (300 nm), GBC inhibited the opener‐induced hyperpolarizing current with an IC50 of 103 ± 36 nm. LCRK (0.3 and 1 μm) did not significantly affect the cytoplasmic Ca2+ concentration either at rest or after stimulation by angiotensin II. The data show that LCRK induces a GBC‐sensitive hyperpolarizing current in rat RSC. This current presumably originates from the activation of KATP channels which pharmacologically resemble those in vascular smooth muscle cells. The stimulatory effect of KATP channel opening on renin secretion is not mediated by a decrease in intracellular Ca2+ concentration.

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Expression of Intermediate Filament Proteins and Neuronal Markers in the Human Fetal Gut

Rauch

Klotz

Maas-Omlor

et al. 2006

J Histochem Cytochem.

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The human enteric nervous system (ENS) derives from migrating neural crest cells (NCC) and is structured into different plexuses embedded in the gastrointestinal tract wall. During development of the NCC, a rearrangement of various cytoskeletal intermediate filaments such as nestin, peripherin, or alpha-internexin takes place. Although all are related to developing neurons, nestin is also used to identify neural stem cells. Until now, information about the prenatal development of the human ENS has been very restricted, especially concerning potential stem cells. In this study the expression of nestin, peripherin, and alpha-internexin, but also of neuronal markers such as protein gene product (PGP) 9.5 and tyrosine hydroxylase, were investigated in human fetal and postnatal gut. The tissue samples were rapidly removed and subsequently processed for immunohistochemistry or immunoblotting. Nestin could be detected in all samples investigated with the exception of the 9th and the 12th week of gestation (WOG). Although the neuronal marker PGP9.5 was coexpressed with nestin at the 14th WOG, this could no longer be observed at later time points. Alpha-internexin and peripherin expression also did not appear before the 14th WOG, where they were coexpressed with PGP9.5. This study reveals that the intermediate filament markers investigated are not suitable to detect early neural crest stem cells.

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Ulrich Rauch

Pancreatic Neuropathy Results in “Neural Remodeling” and Altered Pancreatic Innervation in Chronic Pancreatitis and Pancreatic Cancer

Neural invasion in pancreatic cancer: A mutual tropism between neurons and cancer cells

Isolation and cultivation of neuronal precursor cells from the developing human enteric nervous system as a tool for cell therapy in dysganglionosis

Nerve Growth Factor and Artemin Are Paracrine Mediators of Pancreatic Neuropathy in Pancreatic Adenocarcinoma

The microenvironment in chronic pancreatitis and pancreatic cancer induces neuronal plasticity

Differentiation of neurospheres from the enteric nervous system

Pharmacological evidence for a K_ATP channel in renin‐secreting cells from rat kidney

Expression of Intermediate Filament Proteins and Neuronal Markers in the Human Fetal Gut

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Ulrich Rauch

Pancreatic Neuropathy Results in “Neural Remodeling” and Altered Pancreatic Innervation in Chronic Pancreatitis and Pancreatic Cancer

Neural invasion in pancreatic cancer: A mutual tropism between neurons and cancer cells

Isolation and cultivation of neuronal precursor cells from the developing human enteric nervous system as a tool for cell therapy in dysganglionosis

Nerve Growth Factor and Artemin Are Paracrine Mediators of Pancreatic Neuropathy in Pancreatic Adenocarcinoma

The microenvironment in chronic pancreatitis and pancreatic cancer induces neuronal plasticity

Differentiation of neurospheres from the enteric nervous system

Pharmacological evidence for a KATP channel in renin‐secreting cells from rat kidney

Expression of Intermediate Filament Proteins and Neuronal Markers in the Human Fetal Gut

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Pharmacological evidence for a K_ATP channel in renin‐secreting cells from rat kidney