Excitotoxicity and focal cerebral ischemia induce truncation of the NR2A and NR2B subunits of the NMDA receptor and cleavage of the scaffolding protein PSD-95

The N-methyl-D-aspartate receptor (NMDAR) is central to physiological and pathological functioning of neurons. Although promising results are beginning to be obtained in the treatment of dementias, clinical trials with NMDAR antagonists for stroke, trauma and neurodegenerative disorders, such as Hungtinton's disease, have failed before. In order to design effective therapies to prevent excitotoxic neuronal death, it is critical to characterize the consequences of excessive NMDAR activation on its expression and function. Previous data have reported partial downregulation of the NR1 and NR2B receptor subunits in response to excitotoxicity and cerebral ischemia. However, the effect of NMDAR overactivation on NR2A, a subunit fundamental to synaptic transmission and neuronal survival, is still elusive. In this study, we report the rapid and extensive proteolytic processing of NR2A, together with the scaffolding protein postsynaptic density-95 (PSD-95), induced by excitotoxic stimulation of cortical neurons in vitro and by transient focal cerebral ischemia. Processing of the C terminus of NR2A is irreversibly induced by brief agonist exposure of NR2B-containing receptors, and requires calcium influx and the activity of calpain, also responsible for PSD-95 cleavage. The outcome is a truncated NR2A subunit that is stable and capable to interact with NR1 at the surface of neurons, but lacking the structural domains required for association with scaffolding, downstream signaling and cytoskeletal proteins. Therefore, a rapid and significant uncoupling of synaptic NMDARs from downstream survival pathways is expected to occur during ischemia. This novel mechanism induced by excitotoxicity helps to explain the failure of most therapies based on NMDAR antagonists.

Transforming growth factor-beta1 induces collagen synthesis and accumulation via p38 mitogen-activated protein kinase (MAPK) pathway in cultured L(6)E(9) myoblasts

Transforming growth factor-beta (TGF-beta) plays a pivotal role in the extracellular matrix accumulation observed in chronic progressive tissue fibrosis, but the intracellular signaling mechanism by which TGF-beta stimulates this process remains poorly understood. We examined whether mitogen-activated protein kinase (MAPK) routes were involved in TGF-beta1-induced collagen expression in L(6)E(9) myoblasts. TGF-beta1 induced p38 and extracellular signal-regulated kinase (ERK) 1/2 phosphorylation whereas no effect on Jun N-terminal kinase phosphorylation was observed. Biochemical blockade of p38 but not of the ERK MAPK pathway abolished TGF-beta1-induced alpha(2)(I) collagen mRNA expression and accumulation. These data indicate that TGF-beta1-induced p38 activation is involved in TGF-beta1-stimulated collagen synthesis.

Up‐regulation of endoglin, a TGF‐β‐binding protein, in rats with experimental renal fibrosis induced by renal mass reduction

BACKGROUND

The central process in chronic renal failure is the progressive accumulation of extracellular matrix in the glomeruli and in the tubulo-interstitial space, resulting in renal fibrosis. Transforming growth factor-beta1 (TGF-beta1) up-regulation plays a major role in the genesis of renal fibrosis. Endoglin is a membrane glycoprotein that binds TGF-beta1 and TGF-beta3 with high affinity. An increased level of endoglin immunostaining has been demonstrated previously in biopsies from patients with chronic progressive renal disease. We have assessed the expression of endoglin in the rat 5/6th renal mass reduction (RMR) model.

METHODS

One, 3 and 5 months after RMR, mean arterial pressure and renal function were measured, animals were sacrificed, renal fibrosis was evaluated quantitatively and the expression of endoglin was assessed by western blot, northern blot and immunohistochemistry.

RESULTS

RMR induced a progressive increase in mean arterial pressure and urinary protein excretion. Renal corpuscular area, and mesangial and interstitial fibrosis increased with time after RMR. Immunohistochemical staining for endoglin demonstrated its expression mainly on the endothelial surface of major vessels. In kidneys 1 and 3 months after RMR, the expression of endoglin in renal corpuscles was limited to Bowman's parietal epithelium. In rats 5 months after RMR, the immunoexpression in glomerular endothelium was more marked. Northern blot analysis revealed that rats with RMR showed an increase in the expression of mRNA for endoglin, only at 5 months after RMR. Western blot analysis gave a different time course: a marked increase in the first month, a decrease in the 3rd month and a further increase in the 5th month after RMR.

CONCLUSIONS

The present study demonstrates increased endoglin expression in rats with severe hypertension and renal damage. This increased endoglin expression coincides with the period of higher renal damage and renal dysfunction.

Endoglin expression in human and rat mesangial cells and its upregulation by TGF-beta1

Endoglin is a component of the TGF-beta receptor complex present in the kidney at the human glomerular mesangium. Since the cellular origin of the glomerular endoglin is unknown, in the present study we investigated the expression of endoglin in mesangial cells in culture, as well as their response to TGF-beta1. Western and Northern blot analysis identified the expression of endoglin protein and mRNA transcript in both human and rat mesangial cells. Flow cytometry and immunocytochemistry analyses revealed that endoglin is present on the cell membrane. Exogenous TGF-beta1 stimulated not only the expression of collagen alpha1 (I) I and TGF-beta1, but also that of endoglin. These data provide the first evidence for the expression of endoglin in mesangial cells, as well as its upregulation by TGF-beta1, thus suggesting that endoglin may have a role in modulating the effects of TGF-beta1 on the glomerular mesangium.

Evidence of tissue-specific, post-transcriptional regulation of NRF-2 expression

Mitochondrial respiratory function requires the expression of genes both from the mitochondrial and nuclear genomes. Nuclear respiratory factor 2 (NRF-2) is a transcription factor required for the expression of several nuclear-encoded mitochondrial proteins, including the specific mitochondrial transcription factor Tfam. This makes NRF-2 a likely candidate to coordinate expression of mitochondrial components. NRF-2 is a multisubunit complex of which the alpha subunit binds DNA and the beta subunit enhances this binding, respectively. We have analysed in vivo the expression patterns of NRF-2 subunits both at the mRNA and protein level, in three rat tissues, liver, testis and brain. In contrast with Tfam or the 'housekeeping' beta-actin expressions in which a parallel gradient was observed, no correlation was found between NRF-2 mRNAs and proteins levels, thus suggesting post-transcriptional regulation.

Expression of mitochondrial genes and of the transcription factors involved in the biogenesis of mitochondria Tfam, NRF-1 and NRF-2, in rat liver, testis and brain

Mitochondrial function requires genes encoded in both mitochondrial and nuclear genomes. Tfam, the activator of mammalian mitochondrial transcription, is encoded in the nucleus and its expression has been shown in in vitro studies to be controlled by nuclear respiratory factors NRF-1 and NRF-2. In order to understand the physiological dependence of mitochondrial gene expression, we have analyzed in rat liver, testis and brain the expression level of mitochondrial genes in parallel with those of the three transcription factors. We found that: a) Tfam expression is down-regulated in rat testis, both at the protein and transcript level. The three-fold reduction in the abundance of Tfam protein in rat testis does not result in low steady-state levels of mitochondrial gene transcripts, suggesting that Tfam is in excess and does not limit transcription in vivo; and b) NRF-1 and NRF-2 (alpha, beta and gamma subunits) mRNAs were analyzed by Northern blotting; for each mRNA, several transcripts were observed as well as tissue-specific patterns of expression. The mRNA steady-state levels of NRF-1 and NRF-2 were higher in testis than in liver or brain. These data suggest that the low expression level of Tfam found in testis is not due to decreased NRF-1 and/or NRF-2 expression and further suggest the existence of tissue-specific post-transcriptional regulatory mechanisms for the expression of NRF-1/NRF-2 genes.

Oligodendrocyte development and thyroid hormone

Thyroid hormone plays an important role in brain development and is essential to ensure a normal myelination. The effects of thyroid hormone are mediated by nuclear thyroid hormone receptors, which act as ligand-regulated transcription factors. There are several isoforms encoded by two genes, alpha and beta. Developmental studies have shown that alpha isoforms are widely expressed in the fetal brain, while beta isoforms expression is more restricted with a dramatic increase that begins at birth in the rat. Remarkably, receptor number reaches maximal levels by postnatal day 10, when serum thyroid hormone levels also peak and myelination is the most prominent event in the developing rat brain. Likewise, oligodendrocyte precursor cells express alpha isoforms and expression of the beta isoforms is confined to the differentiated oligodendrocytes, suggesting that these isoforms might mediate different thyroid hormone effects in the oligodendrocyte lineage. Thyroid hormone acts at multiple steps in the development of oligodendrocytes: (a) Early in development, it can function as an instructive signal for the generation of oligodendrocytes and enhance the proliferation of the committed preprecursor oligodendrocyte cells. (b) Thyroid hormone regulates the number of oligodendrocyte generated by directly promoting their differentiation. Since oligodendrocytes are produced in vitro after the same period in culture regardless of whether thyroid hormone was added to the cultures, it has been suggested that thyroid hormone is required for neither the timing nor the generation of oligodendrocytes, but is necessary to achieve adequate oligodendrocyte numbers. (c) Finally, thyroid hormone increases morphological and functional maturation of postmitoitic oligodendrocytes by stimulation of the expression of various myelin genes.

The mouse neurotrophin receptor trkB gene is transcribed from two different promoters

We have analysed a 7-kb region upstream of the mouse trkB coding sequence. The region showed promoter activity in transient transfection experiments and conferred tissue-specific expression to a reporter gene. Deletion analysis of this region demonstrated the presence of two alternative promoters named P1 and P2 that have been mapped by RNase protection. P1 has been located to 1.8 kb and P2 to 0.5 kb upstream of the trkB translation start site. From the P1 promoter, alternative splicing generates various transcripts. Interestingly, P2 is located in an intron of the transcripts produced from the P1 promoter. This peculiar arrangement results in different mRNA species that encode the same protein(s) but differ in their 5'-untranslated regions. In addition, transcription of the trkB locus results in two different trkB isoforms (kinase and truncated receptors) originated by alternative splicing of the mRNA, that possess differential spatial and temporal expression patterns. Using RT-PCR, we demonstrated that there was no linkage between promoter usage and alternative splicing, since transcripts initiated from each promoter encoded both kinase and truncated receptor proteins.

Stimulation of the myelin basic protein gene expression by 9-cis-retinoic acid and thyroid hormone: activation in the context of its native promoter

Thyroid hormone plays an important role in brain development, in part by regulating myelination. Previous studies have shown that the myelin basic protein (MBP) promoter is activated by thyroid hormone (T3) via a T3-response element (T3RE) at position -186. Surprisingly, although MBP levels are initially decreased in hypothyroid neonates, they approach later control levels, in most brain regions, despite persistent hypothyroidism. We have studied the T3-independent transcriptional regulation of this gene, using transient transfection assays. We found that, in the absence of T3, the RXR ligand, 9-cis-retinoic acid (9cRA) was able to stimulate transcription of the MBP promoter in a dose-dependent manner. This activation was unaffected by the mutation or deletion of the T3RE and required DNA sequences located between positions -162/+60. Accordingly, this MBP promoter fragment bound RXR in vitro. The 9cRA-dependent activation of the MBP promoter required the presence of both, the DNA binding and the ligand-dependent transactivation domain (AF-2) in RXR. Furthermore, as T3, 9cRA was able to stimulate MBP expression in the CG-4 cell line after differentiation to oligodendrocytes and increased the number of cells expressing the MBP protein in primary rat optic nerve glial cell cultures.

Thyroid hormone receptor isoforms are sequentially expressed in oligodendrocyte lineage cells during rat cerebral development

In the mammalian brain, thyroid hormones regulate myelination. Their actions are mediated by interactions with nuclear receptors that function as ligand-regulated transcription factors. Two genes, alpha and beta, encode different isoforms, of which only the beta and alpha1 isoforms are authentic nuclear triiodothyronine (T3)-receptors (NT3R). In agreement with the important role of T3 on myelination and oligodendrocyte generation, the presence of NT3Rs has been reported in oligodendrocytes and their precursors. We and others have shown that both progenitors and oligodendrocytes in vitro express the alpha1 and alpha2 isoforms, but the expression of the beta1 isoform is confined to differentiated oligodendrocytes, suggesting that they have different functions. To establish if this is the case during development in vivo, we have studied NT3R isoform expression in glial cells isolated by density gradient centrifugation from rat brains of various ages. We report the presence of the alpha1 NT3R and its variant alpha2, but not that of the beta1 isoform, in newborn rat glial progenitors. The pattern of expression of beta1, both at the level of mRNA and protein, parallels the increase in the number of oligodendrocytes. We found a significant change in the kinetic parameters of [125I]-T3 binding to NT3Rs in these cells during the first month of life, consisting of an increase in the binding capacity that peaks with myelination, and a significative decrease in Kd that coincides with the switch from the alpha to the beta1 isoform. Thus, the expression of NT3R isoforms in the rat oligodendrocyte lineage changes radically from the alpha to the beta1 isoform during the period when oligodendrocytes differentiate from progenitors.

Thyroid hormone regulates the expression of the MAL proteolipid, a component of glycolipid-enriched membranes, in neonatal rat brain

Detergent-insoluble glycosphingolipid-enriched membranes (DIGs) have been involved in the sorting and transport of specific proteins during oligodendrocyte maturation. The MAL (MAL, MVP17, VIP17) proteolipid, an integral membrane protein present in DIGs in mature oligodendrocytes, has been proposed as a component of the machinery for DIG-mediated transport in a restricted pattern of cell types including myelinating cells. We have previously shown that thyroid hormone regulates the expression of the myelin protein genes coordinately, and have suggested a major role for thyroid hormone in the control of oligodendrocytes generation. Here we show that the expression of the MAL gene is down-regulated by hypothyroidism and up-regulated by hyperthyroidism in myelinated regions of the brain. In contrast, adult-onset hypothyroidism has no effect on the steady-state levels of MAL mRNA. Taken together, our results show that MAL expression during oligodendrocyte maturation is modulated by thyroid hormone, suggesting that this hormone could play an important role in the myelin biogenesis during neonatal development.

Hypothyroidism coordinately and transiently affects myelin protein gene expression in most rat brain regions during postnatal development

To assess the role of thyroid hormone on myelin gene expression, we have studied the effect of hypothyroidism on the mRNA steady state levels for the major myelin protein genes: myelin basic protein (MBP), proteolipid protein (PLP), myelin-associated glycoprotein (MAG) and 2':3'-cyclic nucleotide 3'-phosphodiesterase (CNP) in different rat brain regions, during the first postnatal month. We found that hypothyroidism reduces the levels of every myelin protein transcript, with striking differences between the different brain regions. Thus, in the more caudal regions, the effect of hypothyroidism was extremely modest, being only evident at the earlier stages of myelination. In contrast, in the striatum and the cerebral cortex the important decrease in the myelin protein transcripts is maintained beyond the first postnatal month. Therefore, thyroid hormone modulates in a synchronous fashion the expression of the myelin genes and the length of its effect depends on the brain region. On the other hand, hyperthyroidism leads to an increase of the major myelin protein transcripts above control values. Finally, lack of thyroid hormone does not change the expression of the oligodendrocyte progenitor-specific gene, the platelet derived growth factor receptor alpha.

Expression of neurotrophins and their receptors in sciatic nerve of experimentally diabetic rats

The levels of neurotrophins and their receptor mRNAs were measured in rat sciatic nerve, after 6 or 12 weeks of streptozotocin-induced diabetes. Expression of neurotrophin-3 (NT-3) and neurotrophin-4 (NT-4) was decreased by 50 and 29%, respectively, compared with age-matched controls after 12 weeks of diabetes. Expression of brain-derived neurotrophic factor (BDNF) was not detected. In addition, diabetes induced a reduction in the expression levels of the neurotrophin receptors: trkB mRNA decreased by 50% after 6 weeks of diabetes, but returned to control levels after 12 weeks; meanwhile the trkC and p75LNGFR transcripts were reduced by 20% of control at both times studied. trkA expression was below detection limits. Thus, these data suggest that a reduction in neurotrophin and neurotrophin receptors could contribute to the development and maintenance of diabetic neuropathy.

Induction of platelet-derived growth factor B/c-sis by the v-erbA oncogene in glial cells

The v-erbA oncogene codes for a mutated form of the thyroid hormone receptor TR/c-erbA-alpha. Thyroid hormone (triiodothyronine, T3) regulates glial functions such as myelination and both astrocytes and oligodendrocytes have been shown to express thyroid hormone receptors (TRs). To study putative effects of v-erbA on glial precursors, we have expressed it in a glial clonal cell line established from early embryonal mouse brain. We have found that v-erbA increases cell survival in serum-free conditions. Moreover, v-erbA-expressing cells show a substantial growth in the presence of insulin or IGF-I, whereas normal and TR/c-erbA-over-expressing cells progressively degenerate. By Northern blotting, immunofluorescence, immunoprecipitation, and neutralization experiments, we show that v-erbA actions are mediated by an increase in the levels of PDGF B/c-sis mRNA and protein. We used anti-PDGF receptor and anti-phosphotyrosine antibodies to show the constitutive activation of PDGF receptors in B3.1 + v-erbA cells, and neutralizing anti-PDGF antibodies to demonstrate that v-erbA enhances the secretion of active PDGF into the culture medium. Our data indicate that v-erbA induces PDGF B/c-sis, a factor involved in the generation of gliomas, the most common central nervous system tumor in humans.

Expression of neurotrophins and the trk family of neurotrophin receptors in normal and hypothyroid rat brain

Thyroid hormone deficiency has dramatic effects on rat brain maturation. The expression of genes encoding neurotrophins and the trk family of neurotrophin receptors has been evaluated in several brain regions of normal and of neonatal or adult hypothyroid rats to analyze whether they are subject to thyroid hormone action. We found that hypothyroidism decreased trk mRNA levels in its major site of expression, the striatum, on postnatal days 5 (P5; 45%) and 15 (P15; 25%) and also in adults (35%). In contrast, no differences in trkB or trkC mRNAs levels were observed in any brain region at studied ages. According to previous reports, p75LNGFR mRNA was elevated in hypothyroid cerebellum as compared to age-matched controls on P5 and P15. We have also observed a distinct pattern for neurotrophin genes. The level of NGF mRNA was 20-50% lower in the cortex, hippocampus, and cerebellum of hypothyroid rats on neonatal hypothyroid rats on P15 and also after adult-onset hypothyroidism. Treatment of neonatally-induced hypothyroid rats with a single injection of triiodothyronine led to the recovery of hippocampal but not cortex NGF mRNA levels to that of control animals. On the contrary, no differences in the relatively high expression of the two mRNAs encoding BDNF were observed in any brain area. In contrast to a recent report, we did not find a reduction in brain NT-3 mRNA levels in hypothyroid animals. If any, the effect of thyroid deficiency in the hippocampus and cortex seems to be an early upregulation of NT-3 expression.(ABSTRACT TRUNCATED AT 250 WORDS)

c-erbA and v-erbA modulate growth and gene expression of a mouse glial precursor cell line

The c-erbA alpha protooncogene coding for the thyroid hormone (T3) receptor (TR alpha 1) and the viral, mutated v-erbA oncogene were expressed in an immortal mouse glial cell line (B3.1) using retroviral vectors. c-erbA alpha expression led to a decrease in cell proliferation in high and low serum conditions, both in the presence and in the absence of T3. In serum-free medium, c-erbA-expressing cells (B3.1 + TR alpha 1) were completely arrested, whereas cells expressing v-erbA (B3.1 + v-erbA) showed a higher DNA synthesis rate than normal B3.1 cells. Although proliferation of all three cell types was stimulated by platelet-derived growth factor and basic fibroblast growth factor, differences were also observed in the response to these agents. B3.1 + TR alpha 1 cells were more sensitive to platelet-derived growth factor than B3.1 and B3.1 + v-erbA cells. In contrast, B3.1 cells responded to basic fibroblast growth factor better than B3.1 + TR alpha 1 or B3.1 + v-erbA cells. Insulin-like growth factor I potentiated the action of platelet-derived growth factor and basic fibroblast growth factor. Again, different responses to treatment with insulin-like growth factor I alone were observed; B3.1 + TR alpha 1 cells did not respond to it, whereas B3.1 + v-erbA cells showed a dramatic stimulation by this agent. Interestingly, in the presence of T3, the blockade in B3.1 + TR alpha 1 cell proliferation was accompanied by the down-regulation of the typical astrocytic genes, glial fibrillary acidic protein and vimentin. These hormone effects were not found in v-erbA-expressing cells. In addition, v-erbA inhibited the basal expression of the cyclic nucleotide phosphodiesterase gene, an oligodendrocytic marker.(ABSTRACT TRUNCATED AT 250 WORDS)

Unliganded c-erbA/thyroid hormone receptor induces trkB expression in neuroblastoma cells

Neurotrophins are responsible for the differentiation and survival of neurons in the developing and in the adult nervous system. They bind to specific membrane receptors with tyrosine kinase activity whose prototype is the product of the trkA proto-oncogene. TrkB, a member of this family, is the receptor for the neurotrophins brain derived growth factor (BDNF) and neurotrophins-3, -4/5. In this study, we show that stable expression of the c-erbA proto-oncogene, which encodes the alpha 1-isoform of the nuclear receptor for thyroid hormone (Tr alpha 1) induces the expression of trkB mRNA with a concomitant decrease to undetectable levels of trkA and trkC mRNAs in the mouse neuroblastoma N2a cell line. trkB induction by c-erbA is ligand independent, since addition of T3 had no effect. The induced trkB transcript encodes a functional gp145trkB protein, which is phosphorylated on tyrosine in response to BDNF. Furthermore, induction of trkB mRNA is also caused by transient expression of either TR alpha 1 or beta 1 isoforms. Our results are compatible with the idea that there are certain pathways which are under control of unliganded thyroid hormone receptor, and that one of these pathways results in regulation of trk expression.

Retinoic acid posttranscriptionally up-regulates proteolipid protein gene expression in C6 glioma cells

The proteolipid protein (PLP) gene codes for the major central nervous system myelin protein. We have studied the effects of different agents on the expression of the PLP gene in C6 glioma cells. Retinoic acid (RA), but not dexamethasone, estradiol, insulin, growth hormone, or vitamin D3, had a drastic effect, increasing 10-20-fold the level of PLP mRNA. Concomitantly, RA also induced the appearance of the corresponding immunoreactive protein. The increase in PLP RNA level showed a slow kinetics and was blocked by cycloheximide, suggesting a posttranscriptional regulation by RA. Nuclear run-on assays confirmed that the rate of PLP gene transcription was unchanged by RA. In contrast, we found that retinoic acid augmented PLP mRNA stability, causing a substantial increase in its half-life. RA action was independent of cell density, serum, or PDGF but was partially inhibited by bFGF. On the other hand, thyroid hormone caused a moderate increase in PLP mRNA levels in C6 cells but only when the low numbers of thyroid receptors in these cells were increased by retrovirally mediated expression of an exogenous c-erbA/TR alpha-1 gene. Our results indicate that RA specifically up-regulates PLP expression in glioma C6 cells at a posttranscriptional level by increasing PLP RNA half-life.

Brain-specific prostaglandin D2 synthetase mRNA is dependent on thyroid hormone during rat brain development

We have previously described several cDNA clones whose expression is affected by thyroid hormone during rat brain development. We now report the identification of one of these, the E2 clone, as the brain-specific prostaglandin D2 (PGD2) synthetase gene. Sequence comparison shows a nearly complete identity between the 356 nucleotides of the E2 clone and nucleotides 403 to 759 of PGD2 synthetase cDNA. The pattern of E2 expression corresponds to that expected for brain specific PGD2 synthetase gene, i.e. the corresponding mRNA is not detected in any other tissue analyzed apart of the brain, and it was present at different levels in all brain regions. Hypothyroidism decreased E2 mRNA concentrations in cerebral cortex and cerebellum. Control of the level of expression of PGD2 synthetase gene may contribute the complex effects of thyroid hormone on brain development and function.

Cerebral hypothyroidism in rats with adult-onset iodine deficiency

Rats fed chronically a low iodine diet may have low serum T4 and high circulating TSH, despite normal serum T3. As the brain depends to a great extent on intracellular generation of T3 from T4 for its total and nuclear T3, we have carried out two experiments to determine whether the brain of iodine-deficient rats may become hypothyroid, despite normal serum T3 levels. In both experiments we confirmed previous data, showing that the pituitary and liver of iodine-deficient rats with very low plasma T4 levels are hypothyroid as compared to those of animals receiving the same diet supplemented with KI, though not as markedly as animals which had undetectable circulating levels of both T4 and T3 as a consequence of chronic ingestion of KC1O-4, or of surgical thyroidectomy. We have further found that the nuclear T3 content was decreased in the brain of iodine-deficient rats, as compared with the animals on the iodine-supplemented diet. The nuclear to plasma ratios of labeled T3 showed that the uptake of this hormone into liver and brain nuclei is not decreased in the iodine-deficient rats as compared with those on the iodine-supplemented diet. This finding indicates that the decreased liver and brain nuclear T3 contents of iodine-deficient rats are likely to be a consequence of the marked reduction of their T4 pool, leading to decreased amounts of intracellularly generated T3. The number of spines on shafts of pyramidal neurons from the visual cortex of iodine-deficient rats was lower than that of rats fed the same diet supplemented with KI. Their distributions along the shaft were also not the same. Such changes might well be an index of cerebral hypothyroidism, as they are similar to those found after thyroidectomy of adult rats. It is concluded from the present findings that normal circulating T3 levels may not be sufficient to maintain brain euthyroidism in rats fed a diet iodine deficient enough to result in very low circulating T4 levels.