Expression of thyroid hormone receptors mRNAs in rat cerebral hemisphere neuronal cultures

Role of thyroid hormones in different aspects of nervous system regeneration in vertebrates

Spontaneous functional recovery from injury in the adult human nervous system is rare and trying to improve recovery remains a clinical challenge. Nervous system regeneration is a complicated sequence of events involving cell death or survival, cell proliferation, axon extension and remyelination, and finally reinnervation and functional recovery. Successful recovery depends on the cell-specific and time-dependent activation and repression of a wide variety of growth factors and guidance molecules. Thyroid hormones (THs), well known for their regulatory role in neurodevelopment, have recently emerged as important modulators of neuroregeneration. This review focuses on the endogenous changes in the proteins regulating TH availability and action in different cell types of the adult mammalian nervous system during regeneration as well as the impact of TH supplementation on the consecutive steps in this process. It also addresses possible differences in TH involvement between different vertebrate classes, early or late developmental stages and peripheral or central nervous system. The available data show that THs are able to stimulate many signaling pathways necessary for successful neurogeneration. They however also suggest that supplementation with T4 and/or T3 may have beneficial or detrimental influences depending on the dose and more importantly on the specific phase of the regeneration process.

Endocrine factors in the hypothalamic regulation of food intake in females: a review of the physiological roles and interactions of ghrelin, leptin, thyroid hormones, oestrogen and insulin

Controlling energy homeostasis involves modulating the desire to eat and regulating energy expenditure. The controlling machinery includes a complex interplay of hormones secreted at various peripheral endocrine endpoints, such as the gastrointestinal tract, the adipose tissue, thyroid gland and thyroid hormone-exporting organs, the ovary and the pancreas, and, last but not least, the brain itself. The peripheral hormones that are the focus of the present review (ghrelin, leptin, thyroid hormones, oestrogen and insulin) play integrated regulatory roles in and provide feedback information on the nutritional and energetic status of the body. As peripheral signals, these hormones modulate central pathways in the brain, including the hypothalamus, to influence food intake, energy expenditure and to maintain energy homeostasis. Since the growth of the literature on the role of various hormones in the regulation of energy homeostasis shows a remarkable and dynamic expansion, it is now becoming increasingly difficult to understand the individual and interactive roles of hormonal mechanisms in their true complexity. Therefore, our goal is to review, in the context of general physiology, the roles of the five best-known peripheral trophic hormones (ghrelin, leptin, thyroid hormones, oestrogen and insulin, respectively) and discuss their interactions in the hypothalamic regulation of food intake.

Thyroid hormone participates in the regulation of neural stem cells and oligodendrocyte precursor cells in the central nervous system of adult rat

Oligodendrocyte development and myelination are under thyroid hormone control. In this study we analysed the effects of chronic manipulation of thyroid status on the expression of a wide spectrum of oligodendrocyte precursor cells (OPCs) markers and myelin basic protein (MBP) in the subventricular zone (SVZ), olfactory bulb and optic nerve, and on neural stem cell (NSC) lineage in adult rats. Hypo- and hyperthyroidism were induced in male rats, by propyl-thio-uracil (PTU) and L-thyroxin (T4) treatment, respectively. Hypothyroidism increased and hyperthyroidism downregulated proliferation in the SVZ and olfactory bulb (Ki67 immunohistochemistry and Western blotting, bromodeoxyuridine uptake). Platelet-derived growth factor receptor alpha (PDGFalpha-R) and MBP mRNA levels decreased in the optic nerve of hypothyroid rats; the same also occurred at the level of MBP protein. Hyperthyroidism slightly upregulates selected markers such as NG2 in the olfactory bulb. The lineage of cells derived from primary cultures of NSC prepared from the forebrain of adult hypo- and hyperthyroid also differs from those derived from control animals. Although no difference of in vitro proliferation of NSCs was observed in the presence of epidermal growth factor, maturation of oligodendrocytes (defined by process number and length) was enhanced in hyperthyroidism, suggesting a more mature state than in control animals. This difference was even greater when compared with the hypothyroid group, the morphology of which suggested a delay in differentiation. These results indicate that thyroid hormone affects NSC and OPC proliferation and maturation also in adulthood.

Bisphenol A exerts thyroid-hormone-like effects on mouse oligodendrocyte precursor cells

We report studies on the mechanism of action of bisphenol A (BPA) on the differentiation of oligodendrocyte precursor cells (OPCs). Our results show that: (1) BPA inhibits the differentiation of OPCs induced by exposure to thyroid hormone (T3). (2) The effect is mediated through various mechanisms via the thyroid hormone receptor (TRbeta1) which is considered to be responsible for OPC differentiation. (3) The action of BPA on OPC differentiation does not involve the FcRgamma-Fyn-myelin basic protein (MBP) cascade as an inducer of OPC differentiation nor does it suppress CREB phosphorylation, which is considered to be induced by the T3-TR complex. (4) The presence of MBP isoforms (21.5, 18.5, 17.0 and 14.0 kDa) was detected in OPCs, and the expression of exon 2-containing isoforms (i.e. 17.0 and 21.5 kDa) was upregulated upon treatment with T3. In contrast, expression of MBP was inhibited by BPA.

Thyroid hormone regulates the expression of alpha-internexin in neurons in culture

Maternal hypothyroidism in the rat compromises alpha-internexin (alpha-IN) expression in early fetal brain. We have therefore examined whether 3,5,3'-triiodothyronine (T3) regulates alpha-IN expression in fetal brain neurons in culture. Cells expressed transcripts encoding T3 nuclear receptor isoforms in a T3-independent manner. alpha-IN protein abundance was increased in cultures treated with 0.1 and 1 nM T3 for 20 h (177 and 185% control, respectively) and in cultures treated with 1 nM T3 for 40 h (131% control). alpha-IN transcript abundance was unaffected by T3 treatment. In conclusion, T3 at a physiological level, stimulates alpha-IN protein, but not mRNA, levels in early differentiating neurons in culture. This supports the hypothesis that maternal thyroid hormone directly regulates early neuronal differentiation.

Basic transcription element-binding protein (BTEB) is a thyroid hormone-regulated gene in the developing central nervous system. Evidence for a role in neurite outgrowth

Thyroid hormone (3,5,3'-triiodothyronine; T(3)) is essential for normal development of the vertebrate brain, influencing diverse processes such as neuronal migration, myelin formation, axonal maturation, and dendritic outgrowth. We have identified basic transcription element-binding protein (BTEB), a small GC box-binding protein, as a T(3)-regulated gene in developing rat brain. BTEB mRNA levels in cerebral cortex exhibit developmental regulation and thyroid hormone dependence. T(3) regulation of BTEB mRNA is neural cell-specific, being up-regulated in primary cultures of embryonic neurons (E16) and in neonatal astrocytes (P2), but not in neonatal oligodendrocytes (P2). T(3) rapidly up-regulated BTEB mRNA in neuro-2a cells engineered to express thyroid hormone receptor (TR) beta1 but not in cells expressing TRalpha1, suggesting that the regulation of this gene is specific to the TRbeta1 isoform. Several lines of evidence support a transcriptional action of T(3) on BTEB gene expression. Overexpression of BTEB in Neuro-2a cells dramatically increased the number and length of neurites in a dose-dependent manner suggesting a role for this transcription factor in neuronal process formation. However, other T(3)-dependent changes were not altered; i.e. overexpression of BTEB had no effect on the rate of cell proliferation nor on the expression of acetylcholinesterase activity.

Regional changes in beta1 thyroid hormone receptor immunoreactivity in rat brain after thyroidectomy

Quantitative [125I]protein G-based immunohistochemistry was used to map the distribution of beta1 thyroid hormone receptor (TRbeta1) in normal and thyroidectomized adult rat brain, using a previously characterized polyclonal antibody. The distribution of TRbeta1-like immunoreactivity in normal brain was largely but not perfectly concordant with previous accounts of TRbeta1 mRNA distribution in rat brain. Thyroidectomy resulted in increased immunolabeling in most brain regions (mean increase: 14%, range: -4% to +25%), with statistically significant effects being observed in 9 of the 36 brain regions examined. Brain regions showing the most pronounced effects included the habenular nucleus (+22%), the oriens layer of the hippocampal CA3 region (+24%), and the lateral geniculate nucleus of the thalamus (+23%). These results demonstrate that the TRbeta1 protein in brain is capable of plastic changes in response to adult-onset alterations in TH levels. The observed pattern of brain regional receptor changes following thyroidectomy may provide clues for functional effects of thyroid function alterations in adults.

Oligodendrocyte maturation and progenitor cell proliferation are independently regulated by thyroid hormone

The development of oligodendrocyte progenitor cells is regulated by epigenetic factors which control their proliferation and differentiation. When oligodendrocyte progenitor cells, purified on a Percoll centrifugation gradient from neonate rat brain, are cultured in serum-free medium in the presence of platelet-derived-growth factor (PDGF), they divide and their differentiation is delayed. Triiodothyronine (T3) treatment of progenitor cells blocks their proliferation and induces their differentiation into oligodendrocytes. T3 also induces morphological differentiation of oligodendrocytes as indicated by the marked increase in the length of oligodendrocyte processes. To determine whether the effects of T3 on progenitor cell proliferation and oligodendrocyte maturation are causally related, or instead, are independent, we examined the influence of T3 on secondary cultures of postmitotic oligodendrocytes. We show that T3 increases morphological and functional maturation of postmitotic oligodendrocytes as indicated by a well developed network of branched processes and by the expression of myelin/oligodendrocyte glycoprotein (MOG) and glutamine synthetase (GS). T3 increases glutamine synthetase activity and its message level after a lag period of 24-48 h, and these levels increase through a posttranscriptional event. In contrast, no effect of T3 was observed on myelin basic protein (MBP) gene expression as determined by Northern blot analysis. Our results indicate that thyroid hormones participate in the control of the progenitor cell proliferation and differentiation as well as in oligodendrocyte maturation and that these two T3-regulated events are independent.

Expression of thyroid hormone receptor isoforms in rat oligodendrocyte cultures. Effect of 3,5,3'-triiodo-L-thyronine

3,5,3'-Triiodo-L-thyronine (T3) acts at the genomic level by interacting with nuclear T3 receptors (T3Rs). We have used double immunostaining to follow the expression of T3Rs and oligodendrocytes (OL) lineage markers in rat secondary cultures consisting of 85-90% OL. Using antibodies against different synthetic peptides of T3Rs (alpha common: alpha 1 + alpha 2 and beta 1) we find that alpha-T3R is expressed in both O-2A progenitors and in mature OL, while beta 1-T3R is expressed only in mature OL. In cultured OL, beta 1-T3R mRNA is upregulated the most by T3. OL exhibit more numerous and longer processes when treated by T3.

Insulin stimulates thyroid hormone receptor alpha gene expression in cultured bovine aortic endothelial cells

Thyroid hormones and insulin regulate numerous cell processes and potentially interact through the transcriptional regulation of key genes. For instance, thyroid hormones stimulate the transcription of the fatty acid synthase and malic enzyme genes in chick embryonic hepatocytes, while insulin amplifies these effects. It is possible that insulin augments these actions of thyroid hormone by stimulating production of the thyroid hormone nuclear receptor (TR). In these studies, we examined the regulation of TR production/gene expression by insulin in bovine aortic endothelial cells (BAEC). We demonstrate that insulin significantly stimulates the gene expression of the TR alpha receptor, from BAEC. Insulin causes a maximal threefold induction above control TR alpha steady state mRNA levels in time and dose-related fashion in these cells. The increased mRNA mainly resulted from a twofold increase in transcription, as determined by nuclear run on. Insulin also increases thyroid receptor number and thyroid hormone binding, determined by Scatchard analysis of competitive inhibition binding studies. An established observation is that insulin can synergistically augment thyroid hormone-induced transcriptional activation of several important genes. It has also been previously determined that thyroid hormone action correlates closely to TR nuclear receptor number. Therefore, our studies, which show that insulin stimulates TR alpha production, suggests a potential mechanism whereby insulin can augment thyroid hormone transcriptional action.

Overexpression of the beta 1 thyroid receptor induces differentiation in neuro-2a cells

To determine the functions of the alpha 1 and beta 1 thyroid hormone receptors (TRs) in neural differentiation, we have established stable transfected neuronal cell lines (Neuro-2a) that overexpress either TR alpha 1 or TR beta 1. 3,5,3'-Triiodothyronine (T3) treatment of cells that overexpress TR beta 1 blocks proliferation by an arrest of cells in G0/G1 and induces morphological and functional differentiation of Neuro-2a cells as indicated by the marked increase in the number of perisomatal filopodia-like neurites and in acetylcholinesterase (AChE) activity. The effect on AChE activity was dose-dependent, and the time-course analysis reveals that this effect occurs after 24 hr of T3 treatment, with a maximal increase occurring after 48 hr of treatment. The increase of AChE activity is paralleled by an increase of AChE mRNAs. Last, we present evidence that shows that the effects of T3 on differentiation are independent of its effect on proliferation. T3 had no effect on the differentiation of Neuro-2a cells that overexpressed TR alpha 1. Our results indicate that TR beta 1 may play a key role in the effects of T3 in neuroblastoma cell differentiation.

Thyroid hormone up-regulates thyroid hormone receptor beta gene expression in rat cerebral hemisphere astrocyte cultures

Oligonucleotide probes complementary to specific regions of three thyroid receptor cDNAs were used to study the effects of thyroid hormone on the expression of the mRNAs encoding two alpha (alpha 1 and alpha 2) and one beta-thyroid (beta 1) receptors isoforms in rat cerebral hemisphere astrocyte cultures. Both genes are expressed by type 1 astrocytes. The levels of the alpha 1-, alpha 2-, and beta 1-mRNAs did not significantly change between day 8 and day 22, in cultures grown in the absence of thyroid hormone. L-triiodothyronine (L-T3) treatment of the cultures increased the levels of beta 1-mRNAs by fivefold without changing either the levels of the alpha 1- and alpha 2-mRNAs or L-T3 binding capacity. The effect of L-T3 on beta 1-mRNAs was observed after 4 h of treatment and was independent of protein synthesis, suggesting that this effect is likely to be a direct one. Treatment of the cultures by cytosine arabinosine, a drug that kills dividing cells, specifically decreased level of the alpha 1- and alpha 2-mRNAs by 60% and 38%, respectively. Finally, by immunocytochemistry, we showed that the beta 1 receptor-immunoreactivity was either located in the perinuclear region and the cytoplasm or in the nuclei of astrocytes. Taken together with previous data obtained in neuronal cultures where no effect of L-T3 was observed on the levels of the beta 1-mRNAs, our findings indicate that the beta 1 gene is differentially regulated in neurons and astrocytes.(ABSTRACT TRUNCATED AT 250 WORDS)