Walburga Croteau

Expression of the Type II Iodothyronine Deiodinase in Cultured Rat Astrocytes Is Selenium-dependent

The iodothyronine deiodinases are a family of selenoproteins that metabolize thyroxine and other thyroid hormones to active and inactive metabolites in a number of tissues including brain. Using primary cultures of rat astroglial cells as a model system, we demonstrate that the mRNA for the type II iodothyronine deiodinase (DII) selenoenzyme is rapidly and markedly induced by forskolin and 8-bromo-cAMP. The induction of DII activity, however, was significantly impaired by culturing cells in selenium-deficient medium for 7 days. Under such conditions, the addition of selenium resulted in a rapid increase in cAMP-induced DII activity that was dose-dependent, with maximal effects noted within 2 h. Cycloheximide blocked this effect of selenium on restoring cAMP-induced DII activity, whereas actinomycin D did not. These data demonstrate that the DII selenoenzyme is expressed in cultured astrocytes and that the induction of DII activity by cAMP analogues appears to be mediated, at least in part, by pretranslational mechanisms. Furthermore, selenium deprivation impairs the expression of DII activity at the level of translation.

Cloning and Expression of a 5*-Iodothyronine Deiodinase from the Liver of Fundulus heteroclitus*

Recent molecular cloning studies in mammals and amphibians have demonstrated that the types I, II, and III deiodinases constitute a family of selenoproteins of critical importance in metabolizing T4 to active (i.e. T3) and inactive (i.e. rT3) metabolites. In several tissues of teleost fish, various deiodinase processes have been described, but the structural and functional characteristics of these enzymes and their relationship to the deiodinases present in higher vertebrates remains uncertain. Using a complementary DNA library derived from the liver of the teleost Fundulus heteroclitus, we have identified a complementary DNA that codes for a deiodinase with functional characteristics virtually identical to those of the mammalian and amphibian type II deiodinase. Sequence analysis demonstrates a high degree of homology at both the nucleotide and predicted amino acid levels between the Fundulus clone and these previously characterized type II enzymes, including the presence of an in-frame TGA codon that codes for selenocysteine. These findings demonstrate that the deiodinase family of selenoproteins has been highly conserved during vertebrate evolution and underscores their importance in the regulation of thyroid hormone action.

Conserved Cysteines in the Type 1 Deiodinase Selenoprotein Are Not Essential for Catalytic Activity

The iodothyronine deiodinases are a family of oxidoreductases that catalyze the removal of iodide from thyroid hormones. Each of the three isoforms contain selenocysteine at its active site and several cysteine residues that may be important for catalytic activity. Of particular interest in the type I deiodinase (D1) is Cys124, which is vicinal to the selenocysteine at position 126, and Cys194, which has been conserved in all deiodinases identified to date. In the present studies, we have characterized the functional properties of C124A, C194A, and C124A/C194A D1 mutants, which were prepared by site-directed mutagenesis and expressed in COS-7 cells. In broken cell preparations, the sensitivity of the mutants to the selective D1 inhibitors propylthiouracil and aurothioglucose were unaltered. Mutagenesis at the Cys124 position was associated with a 7–11-fold increase in the K m of dithiothreitol, whereasV max values remained largely unchanged. However, both mutations resulted in marked decreases inV max values when glutathione or a reconstituted thioredoxin cofactor system were used in the assay. In contrast to the results of these in vitro studies, no impairment in deiodinating capability was noted in intact cells expressing equivalent levels of the mutant constructs. These studies demonstrate that Cys124 and Cys194 influence the reactivity of the D1 with thiol cofactors in in vitro assay systems but are not determinants of the sensitivity of the enzyme to propylthiouracil and aurothioglucose. Furthermore, the observation that the cysteine mutants are fully active in intact cells demonstrates that the results of commonly used broken cell assays do not accurately predict the activity of the D1 in intact cells and suggests that glutathione and thioredoxin are not the major thiols utilized in vivo to support D1 activity.

Melanoma Induces, and Adenosine Suppresses, CXCR3-Cognate Chemokine Production and T-cell Infiltration of Lungs Bearing Metastatic-like Disease

Clancy-Thompson and colleagues show that lung metastatic-like melanoma induces a transient production of CXCR3-cognate chemokines and IFN required for antigen-specific T-cell infiltration into the tumor site, which in part is temporally limited by adenosine signaling and reversible by the adenosine receptor antagonist aminophylline. Despite immunogenicity, melanoma-specific vaccines have demonstrated minimal clinical efficacy in patients with established disease but enhanced survival when administered in the adjuvant setting. Therefore, we hypothesized that organs bearing metastatic-like melanoma may differentially produce T-cell chemotactic proteins over the course of tumor development. Using an established model of metastatic-like melanoma in lungs, we assessed the production of specific cytokines and chemokines over a time course of tumor growth, and we correlated chemokine production with chemokine receptor–specific T-cell infiltration. We observed that the interferon (IFN)-inducible CXCR3-cognate chemokines (CXCL9 and CXCL10) were significantly increased in lungs bearing minimal metastatic lesions, but chemokine production was at or below basal levels in lungs with substantial disease. Chemokine production was correlated with infiltration of the organ compartment by adoptively transferred CD8+ tumor antigen-specific T cells in a CXCR3- and host IFNγ-dependent manner. Adenosine signaling in the tumor microenvironment (TME) suppressed chemokine production and T-cell infiltration in the advanced metastatic lesions, and this suppression could be partially reversed by administration of the adenosine receptor antagonist aminophylline. Collectively, our data demonstrate that CXCR3-cognate ligand expression is required for efficient T-cell access of tumor-infiltrated lungs, and these ligands are expressed in a temporally restricted pattern that is governed, in part, by adenosine. Therefore, pharmacologic modulation of adenosine activity in the TME could impart therapeutic efficacy to immunogenic but clinically ineffective vaccine platforms. Cancer Immunol Res; 3(8); 956–67. ©2015 AACR.

The Type 3 Deiodinase is a Critical Determinant of Appropriate Thyroid Hormone Action in the Developing Testis

Timely and appropriate levels of thyroid hormone (TH) signaling are necessary to ensure normal developmental outcomes in many tissues. Studies using pharmacological models of altered TH status have revealed an influence of these hormones on testis development and size, but little is known about the role of endogenous determinants of TH action in the developing male gonads. Using a genetic approach, we demonstrate that the type 3 deiodinase (D3), which inactivates TH and protects developing tissues from undue TH action, is a key factor. D3 is highly expressed in the developing testis, and D3-deficient (D3KO) mice exhibit thyrotoxicosis and cell proliferation arrest in the neonatal testis, resulting in an approximately 75% reduction in testis size. This is accompanied by larger seminiferous tubules, impaired spermatogenesis, and a hormonal profile indicative of primary hypogonadism. A deficiency in the TH receptor-α fully normalizes testis size and adult testis gene expression in D3KO mice, indicating that the effects of D3 deficiency are mediated through this type of receptor. Similarly, genetic deficiencies in the D2 or in the monocarboxylate transporter 8 partially rescue the abnormalities in testis size and gonadal axis gene expression featured in the D3KO mice. Our study highlights the testis as an important tissue in which determinants of TH action coordinately converge to ensure normal development and identifies D3 as a critical factor in testis development and in testicular protection from thyrotoxicosis.

Differential Mechanisms of Tumor Progression in Clones From a Single Heterogeneous Human Melanoma

We used vertical growth phase (VGP) human VMM5 melanoma cells to ask whether the tumor microenvironment could induce matrix metalloproteinase‐1 (MMP‐1) in vivo, and whether this induction correlated with metastasis. We isolated two clones from parental VMM5 cells: a low MMP‐1 producing clone (C4) and high producing clone (C9). When these clones were injected orthotopically (intradermally) into nude mice, both were equally tumorigenic and produced equivalent and abundant amounts of MMP‐1. However, the tumors from the C4 clones displayed different growth kinetics and distinct profiles of gene expression from the C9 population. The C4 tumors, which had low MMP‐1 levels in vitro, appeared to rely on growth factors and cytokines in the microenvironment to increase MMP‐1 expression in vivo, while MMP‐1 levels remained constant in the C9 tumors. C9 cells, but not C4 cells, grew as spheres in culture and expressed higher levels of JARID 1B, a marker associated with melanoma initiating cells. We conclude that VMM5 melanoma cells exhibit striking intra‐tumor heterogeneity, and that the tumorigenicity of these clones is driven by different molecular pathways. Our data suggest that there are multiple mechanisms for melanoma progression within a tumor, which may require different therapeutic strategies. J. Cell. Physiol. 228: 773–780, 2013.

The BRAFV600E inhibitor, PLX4032, increases type I collagen synthesis in melanoma cells

Vertical growth phase (VGP) melanoma is frequently metastatic, a process mediated by changes in gene expression, which are directed by signal transduction pathways in the tumor cells. A prominent signaling pathway is the Ras-Raf-Mek-Erk MAPK pathway, which increases expression of genes that promote melanoma progression. Many melanomas harbor a mutation in this pathway, BRAFV600E, which constitutively activates MAPK signaling and expression of downstream target genes that facilitate tumor progression. In BRAFV600E melanoma, the small molecule inhibitor, vemurafenib (PLX4032), has revolutionized therapy for melanoma by inducing rapid tumor regression. This compound down-regulates the expression of many genes. However, in this study, we document that blocking the Ras-Raf-Mek-Erk MAPK pathway, either with an ERK (PLX4032) or a MEK (U1026) signaling inhibitor, in BRAFV600E human and murine melanoma cell lines increases collagen synthesis in vitro and collagen deposition in vivo. Since TGFβ signaling is a major mediator of collagen synthesis, we examined whether blocking TGFβ signaling with a small molecule inhibitor would block this increase in collagen. However, there was minimal reduction in collagen synthesis in response to blocking TGFβ signaling, suggesting additional mechanism(s), which may include activation of the p38 MAPK pathway. Presently, it is unclear whether this increased collagen synthesis and deposition in melanomas represent a therapeutic benefit or an unwanted “off target” effect of inhibiting the Ras-Raf-Erk-Mek pathway.