Increased Oxidative Metabolism and Neurotransmitter Cycling in the Brain of Mice Lacking the Thyroid Hormone Transporter Slc16a2 (Mct8)

Mutations of the monocarboxylate transporter 8 (MCT8) cause a severe X-linked intellectual deficit and neurological impairment. MCT8 is a specific thyroid hormone (T₄ and T₃) transporter and the patients also present unusual abnormalities in the serum profile of thyroid hormone concentrations due to altered secretion and metabolism of T₄ and T₃. Given the role of thyroid hormones in brain development, it is thought that the neurological impairment is due to restricted transport of thyroid hormones to the target neurons. In this work we have investigated cerebral metabolism in mice with Mct8 deficiency. Adult male mice were infused for 30 minutes with (1-¹³C) glucose and brain extracts prepared and analyzed by ¹³C nuclear magnetic resonance spectroscopy. Genetic inactivation of Mct8 resulted in increased oxidative metabolism as reflected by increased glutamate C4 enrichment, and of glutamatergic and GABAergic neurotransmissions as observed by the increases in glutamine C4 and GABA C2 enrichments, respectively. These changes were distinct to those produced by hypothyroidism or hyperthyroidism. Similar increments in glutamate C4 enrichment and GABAergic neurotransmission were observed in the combined inactivation of Mct8 and D2, indicating that the increased neurotransmission and metabolic activity were not due to increased production of cerebral T₃ by the D2-encoded type 2 deiodinase. In conclusion, Mct8 deficiency has important metabolic consequences in the brain that could not be correlated with deficiency or excess of thyroid hormone supply to the brain during adulthood.     

Changes in hexokinase isoenzymes in regions of rat brain during thyroid deficiency

In this work, activities of hexokinase isoenzymes Type I and Type II were measured in the soluble and particulate fractions from the brain regions (cerebral hemispheres (cerebrum), cerebellum and brain stem) of the thyroidectomized adult rats as well as of the thyroidectomized rats administered with triiodothyronine. Thyroidectomy generally decreased the hexokinase activity associated with particulate and soluble fractions. Hexokinase Type II isoenzyme was more affected than the Type I isoenzyme. Administration of triiodothyronine to the hypothyroid rats abolished the effect of thyroidectomy. Adult brain enzymes have been generally considered not be affected by thyroid hormones. The data obtained in this work are suggestive of an effect of thyroid hormones on hexokinase in the adult brain. Since the effects of thyroidectomy on the energy metabolism of the heart tissue are well known, the heart tissue was also studied for comparison.     

Lithium suppresses elevated behavioural activity and brain catecholamines in developing hyperthyroid rats.

Neonatal hyperthyroidism in rats induced by daily administration of L-triiodothyronine for 30 days since birth resulted in a significant rise in mobility and the metabolism of brain norepinephrine and dopamine. Whereas administration of lithium carbonate (60 mg/kg ip) to normal rats for 6 days produced no effect on spontaneous locomotor activity and increased the synthesis and possibly release of this monoamine in several brain regions, this antimanic drug antagonized the L-triiodothyronine-stimulated increases in mobility as well as norepinephrine and dopamine metabolism of hypothalamus, midbrain, striatum, and cerebral cortex. Furthermore, lithium treatment restored the activity of catechol-O-methyl transferase (EC 2.1.1.6) in young hyperthyroid rats to virtually normal limits. Our data suggest that antiphasic or damping effects of lithium upon mood swings is controlled, at least in part, by catecholaminergic systems in the brain. The interrelationship between brain catecholamines and thyroid hormones seems to be important to our understanding of the action of lithium in affective illness.     

Stress-Related Changes in Cerebral Catecholamine and Indoleamine Metabolism: Lack of Effect of Adrenalectomy and Corticosterone

The concentrations of catecholamine and indoleamine metabolites were measured in intact and adrenalectomized mice to determine whether adrenal hormones mediate or modulate the stress-induced responses. Thirty minutes of footshock resulted in significant increases of the ratios of the dopamine (DA) catabolite, dihydroxyphenylacetic acid (DOPAC), to DA in prefrontal cortex, nucleus accumbens, striatum, hypothalamus, and brainstem, and of homovanillic (HVA)/DA ratios in nucleus accumbens, striatum, amygdala, and hypothalamus. Ratios of 3-methoxy-4-hydroxyphenylethyleneglycol to norepinephrine (NE) were also increased in prefrontal cortex, nucleus accumbens, septum, amygdala, hypothalamus, hippocampus, and brainstem. The concentration of NE was decreased in amygdala. 5-Hydroxyindoleacetic acid (5-HIAA)/5-hydroxytryptamine (5-HT, serotonin) ratios and free tryptophan were also increased in every brain region. Very similar data were obtained from mice restrained for 30 min. Adrenalectomy resulted in increased HVA/DA ratios in prefrontal cortex and striatum, and 5-HIAA/5-HT in septum. The stress-related changes were largely similar in adrenalectomized mice. Significant interactions between adrenalectomy and footshock treatment occurred in prefrontal cortical DOPAC/DA and hypothalamic NE which was depleted only in adrenalectomized mice, suggesting tendencies for these measures to be more responsive in adrenalectomized mice. Corticosterone administration (0.5-2.0 mg/kg s.c.) which resulted in plasma concentrations in the physiological range did not alter the concentrations of the cerebral metabolites measured in any region. We conclude that adrenal hormones do not mediate cerebral catecholamine or indoleamine metabolism in stress, although adrenalectomy may affect HVA and 5-HIAA metabolism, and there was a tendency for catecholamines to be more sensitive to stress in adrenalectomized animals.     

Glucose metabolism in isolated fat cells: enhanced response of larger adipocytes from older rats to epinephrine and adrenocorticotropin.

The effects of insulin and of two lipolytic hormones (epinephrine and ACTH1) on the rate and pattern of glucose metabolism were compared during incubation of isolated fat cells, obtained from epididymal fat pads of rats of varying age and degrees of adiposity. Glucose metabolism and the intracellular free fatty acid levels were expressed on a per cell basis and in relation to adipocyte size. The data for total glucose metabolism show that, in contrast to the declining insulin effect observed with adipocyte enlargement, the stimulation of glucose uptake and metabolism by these lipolytic hormones was significantly greater in the larger fat cells from the older fatter rats than in the smaller ones from the younger leaner rats. Lipolytic hormones suppressed, whereas insulin enhanced, fatty acid synthesis; moreover the lipolytic hormones stiumlated glucose ce effect of epinephrine on the intracellular free fatty acid levels was greater in the small fat cells than in the large ones; this effect of epinephrine was markedly curtained by the presence of glucose in the incubation medium, making it unlikely that acceleration of glucose metabolism by the lipolytic stimulus was mediated by an elevation of the intracellular free fatty acid level. The present results show a markedly enhanced capacity of the large adipocytes to accelerate glucose metabolism in response to these liplytic hormones. Thus, in contrast to prevailing notions of declining hormonal responsiveness with expanding fat cell size in older and more obese animals, this study documents an instance of increased hormonal response in enlarged adipocytes and points to the need for a more comprehensive reevaluation of the various hormonal effects in adipocytes of different size.     

Action of thyroid hormones at the cellular level: the mitochondrial target.

Thyroid hormones exert profound effects on the energy metabolism. An inspection of the early and more recent literature shows that several targets at the cellular level have been identified. Since their effects on the nuclear signalling pathway have already been well-defined and extensively reviewed, this article focuses on the regulation of mitochondrial activity by thyroid hormones. Mitochondria, by virtue of their biochemical functions, are a natural candidate as a direct target for the calorigenic effects of thyroid hormones. To judge from results coming from various laboratories, it is quite conceivable that mitochondrial activities are regulated both directly and indirectly. Not only triiodo-L-thyronine, but also diiodothyronines are active in regulating the energy metabolism. They influence the resting metabolism in rats with 3,5-diiodo-L-thyronine seeming to show a clearer effect.     

Thyroid hormones and mitochondria

Because of their central role in the regulation of energy-transduction, mitochondria, the major site of oxidative processes within the cell, are considered a likely subcellular target for the action that thyroid hormones exert on energy metabolism. However, the mechanism underlying the regulation of basal metabolic rate (BMR) by thyroid hormones still remains unclear. It has been suggested that these hormones might uncouple substrate oxidation from ATP synthesis, but there are no clear-cut data to support this idea. Two iodothyronines have been identified as effectors of the actions of thyroid hormones on energy metabolism: 3',3,5-triiodo-L-thyronine (T3) and 3,5-diiodo-L-thyronine (T2). Both have significant effects on BMR, but their mechanisms of action are not identical. T3 acts on the nucleus to influence the expression of genes involved in the regulation of cellular metabolism and mitochondria function; 3,5-T2, on the other hand, acts by directly influencing the mitochondrial energy-transduction apparatus. A molecular determinant of the effects of T3 could be uncoupling protein-3 (UCP-3), while the cytochrome-c oxidase complex is a possible target for 3,5-T2. In conclusion, it is likely that iodothyronines regulate energy metabolism by both short-term and long-term mechanisms, and that they act in more than one way in affecting mitochondrial functions.     

Differences in simultaneous cylic adenosine monophosphate concentrations of various rat tissue after heroin administration.

Opiate administration has profound effects on neurotransmitter metabolism and neuroendocrine functions. Since cAMP is an intracellular metabolite common to the actions of many of the involved compounds stimulating distinct and specific membrane receptors, cAMP concentrations representative of in vivo conditions in heroin-treated and control animals were determined. Rats were sacrificed by immersion in liquid nitrogen 30 min after heroin injection. Tissue samples, dissected without thawing, were assayed by radioimmunoassay to determine cAMP/mg of protein. Comparisons between treated animals and sham-injected controls revealed significant cAMP concentration increases in hypothalamus, cerebral cortex, cerebellum, adrenal medulla, adrenal cortex, and liver (P less than 0.0005). Cyclic AMP concentrations in heart, skeletal muscle, kidney, and fat were not significantly different from controls. The increased tissue cAMP concentrations associated with the altered physiology of heroin administration apparently represent a pattern of integrated responses to the combination of opiate receptor binding and effects on neurotransmitter metabolism and circulating hormones.     

Effect of Thyroid Hormones on Benzodiazepine Receptors in Neuron-Enriched Primary Cultures

The effect of administration of thyroid hormones on central benzodiazepine receptors was investigated using neuron-enriched primary cultures obtained from the neopallium of 16-day-old embryonic rats. Addition of L-triiodothyronine for 3 days decreased the maximal number of benzodiazepine receptor binding sites without any change in affinity at 10(-5) and 10(-6) M. L-Thyroxine administered for 3 days had the same effect at 10(-5) M. No significant change was observed over periods of less than 3 days, a finding indicating that this inhibition was not a direct in vitro effect. This down-regulation seems to be a direct modulatory effect of thyroid hormones on cerebral cortical neurons. Addition for 3 days of D-thyroxine and D-triiodothyronine, which are physiologically inactive isomers of the thyroid hormones, did not induce any significant alterations in benzodiazepine receptors. The decrease in number of cerebral cortical neuronal benzodiazepine receptors due to L-isomers of thyroid hormones may be related to the convulsions and anxiety observed in thyrotoxicosis in humans.     

Influence of fasting and hormone deficiency on myocardial glycogen levels in rats.

This study was undertaken because of uncertainties regarding the influence of hormones on myocardial glycogen metabolism of fed and fasted rats. The results indicate that adrenal hormones exert a stabilizing effect on myocardial glycogen levels in fed animals but are not necessary for synthesis to occur. Hypophysectomy eliminates the glycogen increase that occurs from fasting in normal animals while insulin deficiency leads to elevated glycogen stores in both fed and fasted conditions. These findings suggest that changes in myocardial glycogen metabolism are the results of a synergetic relationship between a variety of hormonal and nutritional factors.     

Angiotensin-converting enzyme activity in isolated brain microvessels.

The localization of angiotensin-converting enzyme (kininase II; ACE) in bovine cerebral cortex was studied by mechanically isolating microvessels from surrounding brain parenchyma. ACE specific activity, as assayed by generation of L-histidyl-L-leucine from the synthetic substrate hippuryl-L-histidyl-L-leucine, was enriched approximately 30 times in microvessels compared to homogenates of intact cerebral cortical gray matter. The nonapeptide 9a, SQ20,881), the orally active anti-hypertensive drug, 2-D-methyl-3-mercaptopropanoyl-L-proline (SQ14,225), and the vasoactive peptides bradykinin and angiotensin II inhibited this activity in a dose-dependent fashion. Brain microvessel ACE required chloride for optimal activity, was potentiated by cobalt nitrate, and was inhibited by the chelating agents EDTA and o-phenanthroline. Enzymatic generation of histidyl-leucine also was observed with the naturally occurring decapeptide substrate angiotensin I. In addition, microvessels obtained from bovine cerebellar cortex, hippocampus and corpus striatum, as well as from the cerebral cortex of Sprague-Dawley rats, were enriched in ACE activity. The presence of angiotensin-converting enzyme in brain microvessels suggests that cellular components of the blood-brain barrier may participate in the metabolism of peptide hormones such as angiotensin I and bradykinin within the central nervous system.     

Conjugated plant hormones: Structure,metabolism and function

Book reviews

Conjugated plant hormones: Structure, metabolism and functionK. Schreiber, H.R. Schütte and G. Sembdner (Eds.), proceedings of the international symposium on conjugated plant hormones. Structure, metabolism and function. Berlin: VEB Deutscher Verlag der Wissenschaften, 1987. 405 pages     

Thyroid Hormone Receptors in the Developing Rat Brain

It is widely believed that the adult mammalian brain is insensitiveto thyroid hormones unlike the neonatal brain which is criticallydependent on these hormones for the development of normal structureand function. Recent studies have demonstrated the presenceof limited capacity, high affinity, triiodothyronine (T3) bindingnuclear sites in tissues that are considered responsive to thyroidhormones. Furthermore, there is evidence from studies on peripheraltissues that these T3 binding sites act as true receptors ininitiating thyroid hormone action. This report examines whetherthe higher sensitivity of neonatal brain to thyroid hormonesand the purported decline in sensitivity in adulthood are relatedto changes in the concentration and affinity characteristicsof thyroid hormone receptors in rat cerebral nuclei. Analysisof Scatchard plots of in vitro T3 binding data indicate thatcerebral nuclei from adult rats contain T3 specific nuclearbinding sites at a concentration comparable to that presentduring the period when the brain is critically dependent onthe presence of thyroid hormones and exceed that in the liver,a tissue generally considered thyroid sensitive. Neonatal thyroidectomysignificantly increased the number of binding sites. The resultsshow that the apparent unresponsiveness of the cerebral cortexof adult rats to thyroid hormones is not due to the absenceor a low density of T3 nuclear binding sites. The significanceof these results is discussed.     

真菌激素研究进展

真菌种类繁多,与人类健康、工农业生产和生态系统物质循环的关系非常密切。真菌合成多种性激素、植物激素和动物激素,这些内源激素以及来自动植物产生的外源激素能够被真菌感知,并影响真菌的生长发育、子实体形成、代谢、致病性和共生性等。然而,对真菌激素的合成和信号转导途径,及其起源和进化还知之不多。建立真菌激素学将极大地促进对真菌激素的研究和应用。     

Effects of soybean isoflavones, probiotics, and their interactions on lipid metabolism and endocrine system in an animal model of obesity and diabetes

The effects of soybean isoflavones with or without probiotics on tissue fat deposition, plasma cholesterol, and steroid and thyroid hormones were studied in SHR/N-cp rats, an animal model of obesity, and were compared to lean phenotype. We tested the hypothesis that probiotics by promoting the conversion of isoflavone glycosides to their metabolically active aglycone form will have a synergistic effect on body fat, cholesterol metabolism, and the endocrine system. Obese and lean SHR/N-cp rats were fed AIN-93 diets containing 0.1% soy isoflavone mixture, 0.1% probiotic mixture, or both together. Different fat tissues were teased and weighed. Plasma was analyzed for cholesterol and steroid and thyroid hormones. In both phenotypes, isoflavones lowered fat deposition in several fat depots. Probiotics alone had no significant effect on fat depots. Isoflavones lowered total, LDL, and HDL cholesterol in lean rats, but in obese rats isoflavones lowered only total and LDL cholesterol. Isoflavones also lowered many of the steroid hormones involved in lipid metabolism but had no significant effect on thyroid hormones. Probiotics had no significant effect on cholesterol or hormones. Thus, our data show that soy isoflavones also lower plasma cholesterol and that this hypocholesterolemic effect appears to be due in part to the modulation of steroid hormones. Probiotics do not seem to enhance the effect of isoflavones.     

Effects of hypothyroidism on RNA synthesis in the adult rat brain

In this study we investigated the effects of hypothyroidism on adult brain RNA synthesis. Our data show that in the cerebral hemispheres of hypothyroid rats there is a decrease in microsomal RNA content and microsomal [³H]uridine incorporation. Sucrose gradient analysis revealed that these changes are mainly associated with free ribosomes and subunits and reflect changes in rRNA. The above changes are accompanied by a decrease in RNA polymerase I activity. All of the above mentioned changes returned to normal after thyroxine (T₄) treatment. In contrast to RNA polymerase I, RNA polymerase II activity was not affected. However, electrophoretic analysis of the in vitro poly(A)⁺RNA translation products revealed that hypothyroidism affects a few mRNAs. These results indicate that thyroid hormones have a role in adult brain tissue metabolism.     

Regulation of Metamorphosis-Associated Changes in the Lipid Metabolism of Selected Vertebrates

SYNOPSIS. The life histories of many vertebrates include complex,postembryonic developmental pathways that involve morphologicaland physiological changes that adapt juveniles to a new habitat.A survey of such developmental pathways, including lamprey metamorphosis,salmonid smoltification, and anuran metamorphosis, reveals acommon strategy of lipid metabolism consisting of two distinctphases. The first phase is characterized by lipid accumulationin storage sites and resultsfrom lipogenesis prevailing overlipolysis. The second phase is characterized by lipid depletionfrom storage sites and results from lipolysis prevailing overlipogenesis. Regulation of lipid deposition and lipid mobilizationis essential for ensuring availability of lipid during timesof need. Lipogenesis is promoted by insulin and, in lampreyand anurans, also by thyroid hormones. Lipolysis is promotedby a number of hormones, including prolactin, growth hormone,adrenocorticotropic hormone, corticosteroids, somatostatins,and thyroid hormones. The coordinate regulation of development-associatedchanges in lipid metabolism results from interactions amonghormones and other internal and environmental cues.     

A pilot study on alterations of brain chromosomal protein phosphorylation by steroids during ageing.

The modulatory effects of the steroid hormones estradiol-17 beta and hydrocortisone on phosphorylation of chromosomal proteins of the cerebral hemispheres (CH) of young and old rats was studied in vitro. The results indicate that the extent of phosphorylation decreases in both histone and non-histone-chromosomal (NHC) protein fractions as the age proceeds. Besides, both the hormones stimulate phosphorylation in young as well as old rats. However the pattern of stimulation shown by estradiol differs from that by hydrocortisone. In addition the extent of stimulation by these hormones is significantly reduced in old rats. Modulation of phosphorylation as provoked by these two hormones seems to play an important role in differential gene expression during ageing.