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.

It is assumed that the neurological impairment is due to severe thyroid hormone deprivation to neurons during a critical phase of development. In agreement with brain hypothyroidism is the finding of delayed myelination on magnetic resonance imaging [13,16]. In vivo 1 H nuclear magnetic resonance (NMR) spectroscopy has also shown altered choline and N-acetylaspartate concentrations similar to those found in congenital hypothyroidism [18]. However, the clinical picture of MCT8 gene mutations does not resemble other conditions due to profound thyroid hormone deficiency during development. For example, neurological cretinism is characterized by mental retardation, deafness and deaf mutism, pyramidal and extrapyramidal dysfunction, and a specific gait disorder [22,23]. This contrasts with the essential features of patients with MCT8 mutations, which according to Schwartz and Stevenson [17] are ''congenital hypotonia, severe cognitive impairment, muscle weakness and abnormal hand positioning.'' The underlying mechanism of neuronal damage in MCT8 mutations remains unknown. In particular, in the cellular contexts, MCT8 may perform some functions besides thyroid hormone transport [24].
In contrast to the severe neurological impairment of patients with MCT8 mutations, only some changes of performance in some behavioral tests have been reported in Mct8KO mice [25].
Mct8 inactivation in mice reproduces the changes of circulating thyroid hormone concentrations observed in the patients, and brain T 3 content is reduced [26,27]. However the mice do not present structural changes in brain that might indicate hypothyroidism. In addition, the expression of most thyroid hormonedependent genes in the cerebral cortex is normal with only a few exceptions [28]. Differences between the human and mouse phenotypes might be due to differences in expression of the specific T 4 transporter OATP1C1/Oatp1c1 [29], which is expressed in the mouse brain capillaries and plasma membrane of the astrocytic end-feet [5], but has low expression in primates [30]. Oatp1c1 would allow T 4 transport through the mouse BBB, even in the absence of Mct8, leading to the production of local brain T 3 by the type 2 deiodinase (D2), thus preventing Central Nervous System damage.
Still, the impact of Mct8 inactivation on brain metabolism and neurotransmitter balance has not been analyzed. In the present work we performed metabolic studies in the brain of Mct8KO mice using 13 C NMR spectroscopy. This approach provides comprehensive information on cerebral energetics and metabolism [31]. In particular, 13 C NMR spectroscopy determination of the 13 C label incorporated in relevant carbons of glutamate, glutamine and GABA after (1-13 C) glucose infusions was shown to reveal the activities of the cerebral tricarboxylic acid (TCA) cycles and the transcellular glutamate-glutamine and glutamate-GABA cycles [32]. We have used Mct8KO mice with deficient T 3 transport to the brain [26], and mice with disruption of the D2 gene (D2KO) and therefore unable to generate T 3 from T 4 locally in the brain [33]. Data were compared with those from mice made hypothyroid or hyperthyroid by pharmacological means. We found that the Mct8KO mice present paradoxical metabolic alterations that cannot be explained solely by deficiency or excess of thyroid hormone supply to the brain.

Ethics Statement
All experimental procedures involving animals were performed following the European Union Council guidelines (directive 2010/ 63/UE) and Spanish regulations (R.D.1201/2005, and Law 32/ 2007), and were approved by the Subcommittee on Bioethics of the Consejo Superior de Investigaciones Científicas (CSIC) with the approval reference numbers SAF2008-01168 and SAF2011-25608. All efforts were made to minimize suffering. Anesthetics were used as indicated.

Animals and genotypes
All experiments were performed with animals 6-7 months of age. Animals were housed under temperature (2262uC) and light (12:12 light-dark cycle; lights on at 7 a.m.) controlled conditions and had free access to food and water. Mct8KO (genotype Mct8 2/y ) mice were generated by Dumitrescu et al [26] using homologous recombination. Experiments were carried out on WT and KO male litter mates derived from heterozygous females crossed with WT males of the C57BL/6J strain. Genotypes were confirmed by PCR of tail DNA (38 cycles at 61uC annealing temperature) using the following primers: Forward common: 5'-ACAGAG-CAAGTTCCAAGACA-3'; reverse WT-specific: 3'-ATA-GAAATCAGGCTTGGGAG-5'; reverse KO-specific: 3'-TTTGTCCTTACGCTGCTCTC-5'. Using this procedure, the WT allele generated a 573 base pairs (bp) PCR product and the null allele a 325 bp product. Male mice deficient in D2 (D2KO; genotype D2 2/2 ) [33]

Induction of hypothyroidism and hyperthyroidism
Hypothyroidism was induced in adult male WT and Mct8KO mice by administering 0.02% 1-methyl-2-mercapto-imidazol (MMI, Sigma Chemical Co, St Louis, MO) plus 1% KClO 4 ad libitum in the drinking water for 50 days before sacrifice. Hyperthyroidism was induced in WT mice by administering 10 mg T 3 /100 g BW daily in the drinking water, for the 9 days prior to sacrifice. Since this high dose of T3 was expected to suppress TSH and thyroid secretions, the mice received also in the drinking water a physiological dose of T 4 , 2 mg/100 g BW to maintain T 4 concentrations within normal levels. The rational for this schedule was to keep normal T 4 concentrations in the face of T 3 -induced hyperthyroidism, thus maintaining regulatory events due to extra genomic actions of T 4 [34] or related to T 4 to T 3 conversion by D2 activity [35] This protocol has been validated earlier in experiments involving WT and D3KO mice. The mice treated in this way have highly increased T3 concentrations but normal T 4 , and unchanged brain D2 activity [36]. In all cases mice were killed between 9 a.m. to 12 a.m. after an intraperitoneal injection of a mixture of ketamine 100 mg/kg and medetomidine 0.1 mg/kg).

Measurement of gene expression by quantitative polymerase chain reaction (qPCR)
The cerebral cortex was rapidly dissected out, frozen on dry ice, and kept at 280uC until RNA isolation using the Trizol procedure (Invitrogen, Carlsbad, CA). Complementary DNA was prepared from 250 ng of RNA using the High Capacity cDNA Reverse Transcription kit (Applied Biosystems, Foster City, CA). PCR was performed using a cDNA aliquot synthesized from 5 ng of RNA, with Taqman primers for Hr (hairless) and D1 (type 1 deiodinase) and the Taqman Universal PCR Master Mix, No Amp Erase UNG (Applied Biosystems) on a 7900HT Fast Real-Time PCR System (Applied Biosystems). The PCR program consisted in a hot start of 95uC for 10 min, followed by 40 cycles of 15 sec at 95uC and 1 min at 60uC. PCRs were performed in triplicates, using the 18S gene as internal standard and the 22 DDCt method for analysis.

Infusion protocol and extracts preparation for NMR spectroscopy
Mice were deeply anesthetized with 1-2% isoflurane in 1 L min 21 O 2 through a nose cap, and infused through the jugular with (1-13 C) glucose (8 mmol min 21 g 21 ) during 30 min. The physiological condition of the animal was followed throughout the experiment. Respiratory rate was monitored by a Biotrig system (Bruker Medical GmbH, Ettlingen, Germany), and body temperature was recorded using a rectal probe (Panlab, Barcelona, Spain). Body temperature was maintained at approximately 37uC using a thermostatic blanket and a temperature-regulated circulating water bath. At the end of infusion, brain metabolism was immediately stopped in situ by using a 5-kW microwave fixation system (Muromachi Kikai Co. Ltd., Tokyo, Japan). The brains were then rapidly removed from the skull and immediately frozen in liquid nitrogen. Perchloric acid extracts were prepared from the individual brains, neutralized with KOH, lyophilized, and resuspended in 99.9% 2 H 2 O, as described previously [37,38], prior to performing high-resolution 13 C NMR spectroscopy.

C Nuclear Magnetic Resonance Spectroscopy
High-resolution proton-decoupled 13 C NMR spectra of brain extracts were obtained at 11.9 T (125.13 MHz, 25uC, pH 7.2) with a Bruker AVANCE 500WB NMR spectrometer using a commercial (5 mm) triple resonance probe ( 1 H, 13 C, 2 H) optimized for direct 13 C NMR detection. The acquisition conditions were: p/3 pulses; 30.0 kHz spectral width; 1.09 s acquisition time; 64k words data table; and 6.0 s recycling time. Proton decoupling was only gated during the acquisition using a broad band composite pulse decoupling sequence, and chemical shifts were calibrated with an external reference of dioxane (10% v/v, 67.4 ppm). Resonance assignments were based on literature values and on the addition of internal standards [37]. Spectra deconvolution and multiplet structures were analyzed using the PC-based (Intel Centrino Platform) NMR program, NUTS TM (Acorn, Freemont, CA).
The absolute amount of 13 C incorporated in the different carbons was determined by comparison of the area of the corresponding 13 C resonances with the unchanged myo-inositol resonance areas of each one of the perchloric acid extracts [39,40]. This was possible since myo-inositol had a low turnover and did not become enriched after a 30 min (1-13 C) glucose infusion independently of the thyroid status [38], providing a robust internal reference from which all 13 C enrichments can be derived. The absolute amount of 13 C incorporation in the different carbons and the fractional enrichment was determined as previously described [41,42].

Other procedures
The amino acid content of brain extracts was determined with an automatic amino acid analyzer Biochrom 20 (Pharmacia, Uppsala, Sweden) using a cationic exchange column and precolumn derivatization with ninhydrin [43]. Thyroid hormone determinations were performed as described [44]. Statistical calculations were performed using the Graph-Pad Prism software (http://www.graphpad.com/prism/).

Disruption of the Mct8 gene leads to metabolic changes in the brain suggesting hyperthyroidism
To correlate the lack of Mct8 with altered thyroid hormone transport to the brain we compared the metabolic changes caused by the lack of a functional Mct8 protein with situations of thyroid hormone deficiency or excess. Our approach was to measure whole brain metabolism by 13 C NMR spectroscopy using (1-13 C) glucose as substrate. Thyroid hormones are involved in the developmental timing of expression of many enzymes of intermediary metabolism and in neurotransmitter systems [2] during the postnatal period. Neonatal hypothyroidism causes a delay in many cellular and molecular events, for example expression of myelin genes, which are then normalized in matured animals. Therefore in this study we used adult animals to detect permanent changes induced by Mct8 deficiency.
First we compared Mct8 mutant mice with WT littermates and with hypothyroid mice of the same genotypes. Hypothyroidism was induced by treatment with the antithyroid compounds MMI and KClO 4 which efficiently block thyroid hormone biosynthesis and produce general hypothyroidism. To assess the thyroidal status of the different groups of mice we measured serum T 3 and the expression of 2 sensitive thyroid hormone target genes, D1 in the liver and Hr in the cerebral cortex (Fig. 1A). Two-way ANOVA indicated a significant effect of genotype on serum T 3 (P = 0.0045), which increased by around 100% in the Mct8KO mice. Antithyroid treatment lead also to significant changes of T 3 (P = 0.00049), which decreased by around 50% in mice of both genotypes. Although serum T 4 was not measured in these animals, similar groups showed the characteristic 30-50% reduction of T 4 in the Mct8KO mice [26,27,[45][46][47], and 85% reduction in the hypothyroid mice (not shown). There was a significant effect of genotype (P = 0.0023) and antithyroid drug treatment (P,0.0001) on D1 expression, with an increase in the Mct8KO mice and a pronounced decrease in the hypothyroid mice of the two genotypes. As for Hr expression in the cerebral cortex, there was a significant effect of genotype, with a decrease in the Mct8KO mice (P = 0.0028), but no effect of treatment (P = 0.196). Fig. 2A shows the effects of Mct8 gene disruption and antithyroid treatment on the 13 C fractional incorporation into glutamate C4, glutamine C4, and GABA C2 after infusion of (1-13 C) glucose. There was a significant effect of genotype on the fractional enrichment of 13 C into glutamate C4 (P,0.0001), glutamine C4 (P = 0.00275), and GABA C2 (P,0.0001), with increases in 13 C labeling of the three metabolites in the mutant mice. Antithyroid treatment also led to differences in glutamate C4 (P,0.0001), glutamine C4 (P,0.0001), and GABA C2 (P = 0.0357) enrichments, which were mainly due to effects of hypothyroidism on the Mct8KO mice. The interaction between genotype and treatment was significant, indicating that mice from each genotype responded differently to antithyroid treatment. Treatment of WT mice with antithyroid drugs increased 13 C incorporation into the GABA pool without affecting the glutamate or glutamine pools (Table 1, experiment 1). The same treatment was very effective on the Mct8KO mice, with a reduction in the incorporation of 13 C into all metabolites, which were now similar values of WT mice. There was no difference in amino acids concentrations in the brain extracts (Table 1, experiment 1). In an attempt to define at the molecular level the mechanisms for these changes we measured the expression of relevant enzymes by qPCR: no effects of Mct8 gene inactivation or of hypothyroidism were found on the expression of Gad1 (glutamate decarboxylase), Glud1 (glutamate dehydrogenase), Atp1a3 (Na + K + -ATPase), Gls (glutaminase), Glul (glutamine synthetase), and Gabat (GABA transaminase), nor we found differences in the relative content of both forms of glutamate decarboxylase (GAD65 and GAD67) by western blotting (data not shown).
Assuming that the metabolic changes in the Mct8 mutant mice were due to thyroid hormone deficiency in the brain, in agreement with the deficient T 3 transport and the decreased Hr expression, it was difficult to explain why they were normalized by blocking thyroid hormone synthesis. Paradoxically, the results rather seemed to indicate that the metabolic alterations in the brain of the Mct8KO mice were due to excess thyroid hormone.

Effects of hyperthyroidism and of D2 inactivation
Prompted by the above results we next evaluated the effect of hyperthyroidism. Hyperthyroid WT mice were produced by treatment with high doses of T 3 and a physiological dose of T 4 for several days. This treatment led to a 6-fold increase of circulating T 3 and normal concentrations of T 4 (Fig. 1B). In agreement with the increased circulating T 3 , liver D1 and cerebral cortex Hr expression were increased in the hyperthyroid mice 3and 6-fold respectively. As shown in Fig. 2B, again the Mct8KO mice showed increased 13 C fractional incorporation into glutamate C4, glutamine C4 and GABA C2. Hyperthyroidism increased 13 C incorporation into glutamine, but had no effect on glutamate or GABA. Therefore, the changes induced by the absence of a functional Mct8 were not replicated in the hyperthyroid mice. There was no effect of hyperthyroidism on amino acids concentrations (Table 1, experiment 2).
In parallel to the effect of hyperthyroidism we also evaluated the effect of inactivating the D2 gene. D2 is an astrocytic enzyme that generates T 3 from T 4 . The activity of this enzyme is increased in the brain of the Mct8KO mice, and partially compensates for the lack of T 3 uptake from the circulation [26,27]. We have previously shown that D2 gene inactivation in the Mct8KO mice induces a state of brain hypothyroidism on P21 similar to thyroid hormone deprivation [28]. To analyze the possible contribution of increased T 3 production from T 4 in the brain from Mct8KO mice we included in the study the mice deficient in D2 (D2 2/2 ), and the double knockout mice for Mct8 and D2 (Mct8 2/y D2 2/2 ). Absence of D2 increased incorporation of 13 C into glutamine but had no effect on glutamate and GABA. In mice deficient in Mct8 and D2 there was increased 13 C incorporation into glutamate C4 and GABA C2, as in the Mct8KO. It was noteworthy that 13 C labeling in glutamine C4 was not detected in these mice. Again, there was no difference in amino acids concentrations in the brain extracts (

Discussion
Previous studies on the effects of hypothyroidism on brain metabolism using NMR spectroscopy have been done in adult and neonatal rats. Adult onset hypothyroidism decreased metabolism of (1,2-13 C 2 ) acetate, and reduced the incorporation of the label into cerebral metabolites [38], indicating that hypothyroidism reduced the consumption of acetate by the glial cycle, and reduced its metabolism in the glial and neuronal TCA cycles. More recently, Martinez et al. [48] have also found that neonatal hypothyroidism decreases the flux of glucose into the glutamate, glutamine and GABA pools. In agreement with a depression of cerebral metabolism by hypothyroidism, phosphofructokinase and pyruvate kinase activities decrease in the cerebral hemispheres and cerebellum of hypothyroid rats [49].
In contrast, we found that disruption of the Mct8 gene induces a generalized increased of neuronal metabolism. 13 C incorporation from glucose to the glutamate, glutamine, and GABA pools was increased, without changes in absolute pool values. Glutamatergic activity appears to be coupled to glucose oxidation. Therefore, the data revealed an increased neuronal glucose oxidation through the TCA cycle. Thyroid hormone deprivation of the mutant mice normalized the altered parameters, suggesting that the alterations of brain metabolism were a consequence of excess of thyroid hormones. Indeed, some behavioral traits of Mct8KO mice have been recently interpreted as signs of brain hyperthyroidism [25]. However, this interpretation is difficult to reconcile with what is known on the thyroid status of the brain of Mct8KO mice. The brain of these animals is in a state of hypothyroidism partially compensated by increased local production of T 3 due to the elevated activity of D2 [26][27][28]. This is the reason why on P21 most thyroid hormone dependent genes have normal expression in the cerebral cortex, with a few exceptions, including Hr, a sensitive marker of thyroid hormone action. In the present study we found that the expression of Hr was also decreased in the Mct8KO mice, in agreement with previous findings [28,45].  Table 1. Amino acids concentrations in brain extracts (mmol g 21 wet weight).

Glutamate
Glutamine GABA It is known that tissues other than the brain are in a hyperthyroid state in Mct8KO mice. It might be possible that extracerebral, mainly hepatic (1-13 C) glucose metabolism have contributed to the changes observed in the brain. However, extracerebral glucose metabolism (mainly hepatic) would generate mainly (3-13 C) lactate, (3-13 C) alanine or 13 C labeled amino acids. The permeability of these secondary metabolites through the BBB is known to be smaller than that of (1-13 C) glucose. At the high (1-13 C) glucose concentrations used in our study it is safe to maintain that the 13 C NMR results are dominated by the cerebral metabolism of (1-13 C) glucose and that extracerebral sources of (3-13 C) lactate and 13 C amino acids do not contribute appreciably to the 13 C patterns observed. It is also unlikely that the changes observed are secondary to changes in expression of glucose transporters, since at the high (1-13 C) glucose concentrations used, glucose metabolism in the brain is known not to be limited by the transport capacity.
On the other hand, the metabolic changes induced by Mct8 deficiency are different from those observed after inducing hyperthyroidism by pharmacological means. Hyperthyroidism increased the 13 C fractional incorporation into glutamine C4, but not into glutamate C4 and GABA C2 as in the Mct8KO. On the other hand, disruption of the D2 gene did not alter the metabolic flux through glutamatergic and GABAergic neurotransmissions. D2 encodes an enzyme responsible for the local production of T 3 from T 4 in brain. Under normal conditions, this pathway provides around 50% of brain T 3 . In mice with D2 deficiency, T 3 from the circulation is enough to compensate the expression of many thyroid hormone-dependent genes. However, since the uptake of circulating T 3 depends on the normal expression of Mct8, absence of both, D2 and Mct8 as in the Mct8D2KO mice, results in brain hypothyroidism [28]. In this situation, we found that the changes of glutamate and GABA 13 C labeling were the same as in the single Mct8 deficiency. These results reduce the possibility that the lack of Mct8 would have produced an increased T 3 production through D2 activity responsible for the metabolic changes.
At present we lack a mechanistic explanation for many of the effects of Mct8 inactivation or of other genetic manipulations such as the increased glutamine C4 in the D2KO, or its lack of detection in the Mct8D2KO mice. The molecular and cellular bases of the effects of Mct8 inactivation remain to be clarified. Despite this, it is clear that the metabolic changes induced by Mct8 deficiency in the brain could not be correlated with the overall deficiency or excess of thyroid hormone supply to brain. We do not favor the explanation that Mct8 might perform thyroid hormone-independent actions in the brain [24]. For example, the possibility that Mct8 could transport a hitherto unidentified metabolite, important for brain metabolism, seems unlikely in view of the narrow substrate specificity of Mct8 [50].
The adult Mct8KO mice studied in this work might actually display a more pronounced brain hypothyroidism than that attained by adult onset antithyroid treatment of the WT mice. Indeed, Hr, a very sensitive T 3 target gene was altered in the brain of adult Mct8KO mice and not in the adult hypothyroid WT mice. This is in agreement with the lower sensitivity of the adult brain in comparison to the postnatal brain, to hypothyroidism-related changes of gene expression [51]. (This study described the results of microarray analysis of the adult rat striatum comparing hypothyroid rats with hypothyroid rats treated with T 3 , either in Figure 3. Thyroid hormone transport and metabolism, and neurotransmitter cycling in astrocytes and neurons. T 4 crosses the bloodbrain barrier and is delivered to the astrocytes through the Oatp1c1 transporter, a 12-transmembrane protein localized in the micro capillary endothelial cells, and in the astrocytic end-feet. Astrocytes express the type 2 deiodinase (D2), localized in the endoplasmic reticulum. This enzyme catalyzes the phenolic ring deiodination of T 4 to produce the active hormone T 3 . T 3 acts genomically on astrocytes and neurons. The transporters facilitating the passage of T 3 from astrocytes to neurons have not been defined. Most likely they consist of a combinatorial mixture of different transporters depending upon age and cell type. T 3 and T 4 cross the blood-brain barrier through Mct8, reaching the neurons from the interstitial fluid through Mct8, and possibly by other transporters. Neurons express the type 3 deiodinase (D3) a plasma membrane protein, which catalyzes the tyrosil ring deiodination of T 4 and T 3 to produce the inactive metabolites rT 3 and T 2 , respectively. In astrocytes and neurons, glutamate is produced in the TCA cycle after glycolysis. Astrocytes can also use the lactate produced by neurons as substrate. Astrocyes express the enzyme glutamine synthetase (GS), which produces glutamine from glutamate. Neurons express the phosphate-activated glutaminase (GLS), which converts glutamine back to glutamate. In GABAergic neurons the enzyme glutamic acid decarboxylase (GAD) converts glutamate to GABA. GABA is degraded in astrocytes and neurons by GABA transaminase (GABA-T), with the formation of succinic acid semialdehyde. This metabolite enters the TCA cycle after conversion to succinic acid by succinic semialdehyde dehydrogenase (SSADH). Membrane transporters for glucose and neurotransmitters have not been added for clarity. doi:10.1371/journal.pone.0074621.g003 a high single dose (SD) to induce hyperthyroidism, or with daily replacement doses (RD) to reach euthyroidism. Whereas the SD treatment resulted in expression changes of many genes, the result of RD treatment was modest. In particular Hr expression was increased in the SD groups and did not change in the RD groups. These experiments were compatible with the view that the adult rat striatum is more responsive to hyperthyroidism than to hypothyroidism in terms of gene expression). The Mct8 deficiency in the Mct8KO mice was present from early embryonic stages in contrast to the adult-onset hypo or hyperthyroidism in the WT used for comparison. Brain responses to thyroid hormones may have been altered permanently in the Mct8KO mice, which show signs of T 3 deficiency and excess at different stages of life [25][26][27]46]. Therefore, it is possible that the lack of Mct8 might have triggered a compensatory increase of brain metabolism as a response to the sustained hyperthyroidism in the liver and other tissues or to the chronic impairment of T 3 uptake in the brain. Further investigation into the molecular mechanisms for this metabolic response will be important to define the physiopathology of the brain alterations present in MCT8 deficiency.
Finally, figure 3 illustrates the parallelisms between thyroid hormone and neurotransmitter transport and metabolism, indicating specifically the cooperation between astrocytes and neurons in both processes. In late postnatal and adult WT mice, about 50% of the T 3 present in the brain parenchyma originates in the astrocytes by the D2-catalyzed phenolic ring deiodination [33]. The rest of brain T 3 mostly enters the brain from the circulation through Mct8 present in the BBB. Thyroid hormones may also reach the brain parenchyma in limited amounts through the cerebrospinal fluid [52]. On the other hand, circulating T 4 crosses the BBB through the specific T 4 transporter Oatp1c1, in addition to Mct8. Oatp1c1 is also present in the astrocytic end-feet, facilitating direct delivery of T 4 to the D2-expressing astrocytes. In Mct8KO animals, the absence of T 3 transport through the BBB is compensated by an increased production of T 3 from T 4 in the astrocytes. The absence of Mct8 apparently does not result in the restriction of astrocytic T 3 delivery to neurons possibly through alternative transporters [28]. However, as shown in this paper, the absence of Mct8 leads to dramatic alterations of neurotransmitter metabolism, with increased cycling of glutamate, glutamine, and GABA. At present, it is uncertain whether this is a consequence of the changes in the T 4 and T 3 cellular fluxes brought about by the absence of Mct8-mediated transport, and/or whether they are related to changes in the expression of enzymes. Indeed, changes in the intercellular flux of T3 caused by D2 deficiency lead to selective changes in genes regulated negatively by thyroid hormone by as yet unknown mechanisms [28,36]. On the other hand we failed to detect changes in Gls, Atp1a3, Glud1, Gad1, Glul, and Gabat expression using the whole cerebral cortex, but changes affecting in a restrictive fashion specific cell groups or regions cannot be discarded. In relation to the increased rate of GABA production, it is worth mentioning that succinic semialdehyde dehydrogenase (SSADH) deficiency in humans and mice, with accumulation of GABA and gamma-hydroxybutyrate (GHB) causes severe neurodevelopmental impairment [53]. Whether an increased GABA cycling contributes to the phenotypic manifestations of MCT8 deficiency in humans is an intriguing possibility deserving further exploration.
In summary, Mct8 deficiency in mice results in profound alterations of brain metabolism, consisting of increased oxidative metabolism and neurotransmitter cycling which could not be correlated with thyroid hormone deficiency or excess. While the mechanisms leading to this situation are still unclear, these data could be relevant to explain the physiopathology of the profound neurological impairment present in MCT8 mutations.