Hypophysiotropic thyrotropin-releasing hormone (TRH) neurons, the central regulators of the hypothalamus-pituitary-thyroid axis, are located in the hypothalamic paraventricular nucleus (PVN) in a partly overlapping distribution with non-hypophysiotropic TRH neurons. The distribution of hypophysiotropic TRH neurons in the rat PVN is well understood, but the localization of these neurons is unknown in mice. To determine the distribution and phenotype of hypophysiotropic TRH neurons in mice, double- and triple-labeling experiments were performed on sections of intact mice, and mice treated intravenously and intraperitonially with the retrograde tracer Fluoro-Gold. TRH neurons were located in all parts of the PVN except the periventricular zone. Hypophysiotropic TRH neurons were observed only at the mid level of the PVN, primarily in the compact part. In the this part of the PVN, TRH-neurons were intermingled with oxytocin and vasopressin neurons, but based on their size, the TRH neurons were parvocellular and did not contain magnocellular neuropeptides. Co-localization of TRH and CART were observed only in areas where hypophysiotropic TRH neurons were located. In accordance with the morphological observations, hypothyroidism increased TRH mRNA content of neurons only at the mid level of the PVN. These data demonstrate that the distribution of hypophysiotropic TRH neurons in mice is vastly different from the pattern in rats, with a dominant occurrence of these neurosecretory cells in the compact part and adjacent regions at the mid level of the PVN. Furthermore, our data demonstrate that the organization of the PVN is markedly different in mice and rats.
Nissl-staining is a widely used method to study morphology and pathology of neural tissue. After standard immunocytochemistry, the Nissl-staining labels only the nucleus of neurons and the characteristic staining of the neuronal perikarya is absent or very weak. We hypothesized that the RNA degradation during the immunocytochemical treatment results in the loss of cytoplasmic staining with Nissl-dyes. To test this hypothesis, we used RNAse-free conditions for all steps of immunostaining. To further prevent the RNA-degradation by RNAse contaminations, the RNAse inhibitor heparin was added to all antibody-containing solutions. The efficiency of Nissl-staining after standard and RNAse-free double-labeling immunocytochemistry was compared using antibodies against c-Fos and neuropeptide Y (NPY) on tissues of rats refed after three days of fasting. After standard immunocytochemistry, the Nissl-staining labeled the nuclei of neurons and only very faintly the cytoplasm of these cells. The RNAse-free treatment did not alter the distribution of immunoreaction signal, but preserved the staining of neuronal perikarya by the Nissl-dyes. In conclusion, the RNAse-free conditions during immunocytochemistry, allows the labeling of neuronal perikarya by Nissl-dyes. The described method facilitates the mapping of immunocytochemical signals and makes possible the light microscopic examination of the innervation of neurons identified by their nuclear protein content.
The type 2 deiodinase (D2) activates thyroid hormone and constitutes an important source of 3,5,3',-triiodothyronine in the brain. D2 is inactivated via WSB-1 mediated ubiquitination but can be rescued from proteasomal degradation by USP-33 mediated deubiquitination. Using an in silico analysis of published array data, we found a significant positive correlation between the relative mRNA expression levels of WSB-1 and USP-33 in a set of 56 mouse tissues (r = 0.08; P < 0.04). Subsequently, we used in situ hybridization combined with immunocytochemistry in rat brain to show that in addition to neurons, WSB-1 and USP-33 are differently expressed in astrocytes and tanycytes, the two main D2 expressing cell types in this tissue. Tanycytes, which are thought to participate in the feedback regulation of TRH neurons express both WSB-1 and USP-33, indicating the potential for D2 ubiquitination and deubiquitination in these cells. Notably, only WSB-1 is expressed in glial fibrillary acidic protein-positive astrocytes throughout the brain. Although developmental and environmental signals are known to regulate the expression of WSB-1 and USP-33 in other tissues, our real-time PCR studies indicate that changes in thyroid status do not affect the expression of these genes in several rat brain regions, whereas in the mediobasal hypothalamus, changes in gene expression were minimal. In conclusion, the correlation between the relative mRNA levels of WSB-1 and USP-33 in numerous tissues that do not express D2 suggests that these ubiquitin-related enzymes share additional substrates besides D2. Furthermore, the data indicate that changes in WSB-1 and USP-33 expression are not part of the brain homeostatic response to hypothyroidism or hyperthyroidism.
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