Receptor Proteins for Nongenomic Actions of Thyroid Hormone.

Genomic actions of thyroid hormone require the intranuclear binding by nuclear thyroid hormone receptors (TRs) of 3,5,3’-triiodo-L-thyronine (T3). Nongenomic actions of the hormone have been described that are initiated at the plasma membrane, in cytoplasm or in the mitochondrion. These are complex processes associated with maintenance of the cytoskeleton, control of cell respiration, cell proliferation—including tumor cell proliferation and angiogenesis—and nervous system function. We briefly review here the nature of the proteins which are now appreciated to initiate nongenomic actions of the hormone when they bind T3 or L-thyroxine (T4). These receptor proteins for nongenomic effects include truncated isoforms of TRalpha, cytoplasmic intact TRbeta, certain cytoplasmic enzymes and a structural protein of the plasma membrane, integrin alphaVbeta3

Nongenomic regulation by thyroid hormone of plasma membrane ion and small molecule pumps

The sodium/proton (Na/H) exchanger, Na,K-ATPase, and Ca2+-ATPase are membrane ion pumps whose basal activities may be regulated by local nongenomic actions of thyroid hormone and hormone analogues via a hormone receptor on plasma membrane integrin αvβ3. System A amino acid transport and the activity of P-glycoprotein (P-gp; ABCB1), a multidrug efflux pump, are also modulated by thyroid hormone and αvβ3. Where signal transduction has been studied, the presence of the hormone at the receptor is transduced by mitogen-activated protein kinase (MAPK) isoforms (ERK1/2; p38) or phosphatidylinositol 3-kinase into local actions. The existence of the cell surface receptor offers opportunities to pharmacologically modify actions of these important transport functions with nanoparticulate formulations of T4 and T3 that do not enter the cell. Such formulations may reverse complex intracellular accumulations of H+, Na+, and Ca2+ that occur in clinical settings such as ischemia. In addition, nanoparticulate tetraiodothyroacetic acid (tetrac), a thyroid hormone analogue that inhibits binding of T4 and T3 to integrin αvβ3 as well as certain other functions of the integrin, may reverse P-gp-dependent resistance to anti-cancer drugs in tumor cells

L-Thyroxine vs 3,5,3'-Triodo-L-Thyronine and cell proliferation: Activation of mitogen-activated protein kinase and phosphatidylinositol 3-kinase

Triiodo-L-thyronine (T(3)), but not L-thyroxine (T(4)), activated Src kinase and, downstream, phosphatidylinositol 3-kinase (PI3-kinase) by means of an alpha(v)beta(3) integrin receptor on human glioblastoma U-87 MG cells. Although both T(3) and T(4) stimulated extracellular signal-regulated kinase (ERK) 1/2, activated ERK1/2 did not contribute to T(3)-induced Src kinase or PI3-kinase activation, and an inhibitor of PI3-kinase, LY-294002, did not block activation of ERK1/2 by physiological concentrations of T(3) and T(4). Thus the PI3-kinase, Src kinase, and ERK1/2 signaling cascades are parallel pathways in T(3)-treated U-87 MG cells. T(3) and T(4) both caused proliferation of U-87 MG cells; these effects were blocked by the ERK1/2 inhibitor PD-98059 but not by LY-294002. Small-interfering RNA knockdown of PI3-kinase confirmed that PI3-kinase was not involved in the proliferative action of T(3) on U-87 MG cells. PI3-kinase-dependent actions of T(3) in these cells included shuttling of nuclear thyroid hormone receptor-alpha (TR alpha) from cytoplasm to nucleus and accumulation of hypoxia-inducible factor (HIF)-1 alpha mRNA; LY-294002 inhibited these actions. Results of studies involving alpha(v)beta(3) receptor antagonists tetraiodothyroacetic acid (tetrac) and Arg-Gly-Asp (RGD) peptide, together with mathematical modeling of the kinetics of displacement of radiolabeled T(3) from the integrin by unlabeled T(3) and by unlabeled T(4), are consistent with the presence of two iodothyronine receptor domains on the integrin. A model proposes that one site binds T(3) exclusively, activates PI3-kinase via Src kinase, and stimulates TR alpha trafficking and HIF-1 alpha gene expression. Tetrac and RGD peptide both inhibit T(3) action at this site. The second site binds T(4) and T(3), and, via this receptor, the iodothyronines stimulate ERK1/2-dependent tumor cell proliferation. T(3) action here is inhibited by tetrac alone, but the effect of T(4) is blocked by both tetrac and the RGD peptide

Nanotetrac targets integrin αvβ3 on tumor cells to disorder cell defense pathways and block angiogenesis.

The extracellular domain of integrin αvβ3 contains a receptor for thyroid hormone and hormone analogs. The integrin is amply expressed by tumor cells and dividing blood vessel cells. The proangiogenic properties of thyroid hormone and the capacity of the hormone to promote cancer cell proliferation are functions regulated nongenomically by the hormone receptor on αvβ3. An L-thyroxine (T4) analog, tetraiodothyroacetic acid (tetrac), blocks binding of T4 and 3,5,3'-triiodo-L-thyronine (T3) by αvβ3 and inhibits angiogenic activity of thyroid hormone. Covalently bound to a 200 nm nanoparticle that limits its activity to the cell exterior, tetrac reformulated as Nanotetrac has additional effects mediated by αvβ3 beyond the inhibition of binding of T4 and T3 to the integrin. These actions of Nanotetrac include disruption of transcription of cell survival pathway genes, promotion of apoptosis by multiple mechanisms, and interruption of repair of double-strand deoxyribonucleic acid breaks caused by irradiation of cells. Among the genes whose expression is suppressed by Nanotetrac are EGFR, VEGFA, multiple cyclins, catenins, and multiple cytokines. Nanotetrac has been effective as a chemotherapeutic agent in preclinical studies of human cancer xenografts. The low concentrations of αvβ3 on the surface of quiescent nonmalignant cells have minimized toxicity of the agent in animal studies

Response of Human Pancreatic Cancer Cell Xenografts to Tetraiodothyroacetic Acid Nanoparticles

Tetraiodothyroacetic acid (tetrac) and its nanoparticle formulation (Tetrac NP) act at an integrin cell surface receptor to inhibit tumor cell proliferation and tumor-related angiogenesis. Human pancreatic cancer cell (PANC-1 and MPanc96) xenografts were established in nude mice, and the effects of tetrac versus Tetrac NP on tumor growth and tumor angiogenesis were determined. The in vitro effects of tetrac and Tetrac NP were also determined by reverse transcription polymerase chain reaction or immunoblot on gene expression or gene products relevant to cell cycle arrest, apoptosis, or angiogenesis. Tetrac and Tetrac NP reduced both PANC-1 tumor mass by 45-55 % and PANC-1 tumor hemoglobin content, a marker of angiogenesis, by 50-60 % (*P < 0.05) in treated groups vs. controls by treatment day 15. Comparable results were obtained with tetrac and Tetrac NP in suppressing tumor growth and tumor angiogenesis in MPanc96 xenografts. In vitro studies showed that tetrac and Tetrac NP caused accumulation of pro-apoptotic protein BcLx-s. Tetrac NP was more effective than tetrac in increasing cellular abundance of mRNAs of pro-apoptotic p53 and p21 and anti-angiogenesis thrombospondin 1 protein in PANC-1 and MPanc96 cancer cell lines. Tetrac NP noticeably decreased expression of EGFR and of anti-apoptosis gene XIAP; tetrac did not affect EGFR and increased XIAP mRNA in both MPanc96 and PANC-1. In conclusion, tetrac or Tetrac NP effectively inhibited human pancreatic xenograft growth and tumor angiogenesis via a plasma membrane receptor that downstream modulated cellular abundance of proteins or mRNAs relevant to apoptosis and angiogenesis.Pharmaceutical Research Institute at ACPH