Morphological transformation of sensory ganglion neurons and satellite cells

The development of sensory ganglion neurons and satellite cells examined by scanning electron microscopy after removal of the connective tissue is reviewed. Sensory neurons are bipolar at early stages of development and later became pseudounipolar. This maturation event starts earlier but proceeds more slowly in chick than in rat embryos. These may due to the difference in the extent and intimacy of satellite cell investments between these two animal species. The neuronal perikaryal projections are observed by scanning electron microscopy after removal of the connective tissue and satellite cells. The morphometric analysis reveals that perikaryal projections are more numerous on the surface of mature pseudounipolar neurons than on that of premature bipolar neurons; they increase in number as the neuronal cell bodies grow larger. This may support the hypothesis that perikaryal projections are structural devices for increasing the neuron-satellite interface and for improving the efficiency of metabolic exchange between these two cell types.The important role of satellite cells in neuronal maturation is discussed.Biomedical Reviews 2000; 11: 39-52

Data from: Expression of taste signal transduction molecules in the caecum of common marmosets

The extraoral presence of taste signal transduction proteins has recently been reported in rodents and humans. Here, we report for the first time the presence of these signal transduction proteins in the caecum of a non-human primate, the common marmoset. Quantitative RT-PCR data on the gene expression of taste signal transduction molecules (gustducin and TRPM5) in common marmosets suggested high expression in the caecum, which was not observed in other non-human primates. Immunohistochemical analysis confirmed the specific presence of gustducin and taste receptors in marmoset caecal cells. These results may relate to the specific feeding behaviour of marmosets, which consume plant exudates, primarily gums

Localization of sympathetic, parasympathetic and sensory neurons innervating the distal ileum of the cattle

After oral challenge of the pathological prion protein, the causative agent of bovine spongiform encephalopathy, the pathogen was first detected in the distal ileum and then deposited in the brain. The present study aims determining the possible neuronal transporting pathways from the ileum to the brain in the cattle using a tracer protein. After horseradish peroxidase was injected into the wall of the distal ileum in the calf, almost all labeled neurons were detected in the celiac and cranial mesenteric ganglion complex. Only a few labeled neurons existed in the caudal mesenteric ganglion and the paravertebral ganglia. They were sympathetic postganglionic neurons. In the dorsal root ganglia T5 to L4, some sensory neurons were found to be labeled. Only a small number of parasympathetic preganglionic neurons were labeled in the dorsal motor nucleus of the vagus nerve. No labeled sensory neurons were found in the nodose ganglion. These results suggest that the pathological prion protein is mainly transported to the spinal cord and brain via the sympathetic nervous system and partially via the sensory neurons in the dorsal root ganglia. The vagus nerve does not seem to contribute to the transport of the pathogen from the ileum directly

RT-qPCR gustducin_English

RT-qPCR gustducin_Englis

RT-qPCR T1RsT2Rs_English

RT-qPCR T1RsT2Rs_Englis