Increasing evidence suggests that thyroid hormones, L-thyroxine (T4) and 3,3′,5-triiodo-L-thyronine (T3), are modulators of the immune response. In monocytes, macrophages, leukocytes, natural killer cells, and lymphocytes, a wide range of immune functions such as chemotaxis, phagocytosis, generation of reactive oxygen species (ROS), and cytokine synthesis and release are altered under hypo- and hyperthyroid conditions.
Summary:
Hyperthyroidism decreases the proinflammatory activities of monocytes and macrophages, whereas enhancement of phagocytosis and increased levels of ROS may occur during hypothyroidism. The expression of proinflammatory molecules such as macrophage inflammatory protein-1α and interleukin-1β increases in hypothyroidism. However, in Kupffer cells, proinflammatory activities such as the respiratory burst, nitric oxide synthase activity, and tumor necrosis factor-α expression may result from increased T3 levels. Thyroid hormones also affect natural killer cell activity and cell-mediated immune responses. Still, for many immune cells no clear correlation has been found so far between abnormally high or low T3 or T4 levels and the effects observed on the immune responses.
Conclusions:
In this review we outline the contributions of thyroid hormones to different aspects of innate and adaptive immune responses. The relationship between thyroid hormones and immune cells is complex and T3 and T4 may modulate immune responses through both genomic and nongenomic mechanisms. Future studies of the molecular signaling mechanisms involved in this cross-talk between thyroid hormones and the immune system may support development of new strategies to improve clinical immune responses.
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References
1.
BesedovskyHO, del ReyA. 1991. Feed-back interactions between immunological cells and the hypothalamus-pituitary-adrenal axis. Neth J Med, 39:274–280.
2.
BlalockJE. 1994. The syntax of immune-neuroendocrine communication. Immunol Today, 15:504–511.
3.
BesedovskyHO, del ReyA. 1996. Immune-neuro-endocrine interactions: facts and hypotheses. Endocr Rev, 17:64–102.
4.
OberbeckR. 2006. Catecholamines: physiological immunomodulators during health and illness. Curr Med Chem, 13:1979–1989.
5.
KamathJ, YarbroughGG, PrangeAJJr., WinokurA. 2009. The thyrotropin-releasing hormone (TRH)-immune system homeostatic hypothesis. Pharmacol Ther, 121:20–28.
6.
KleinJR. 2006. The immune system as a regulator of thyroid hormone activity. Exp Biol Med, 231:229–236.
7.
SchaeferJS, KleinJR. 2011. Immunological regulation of metabolism—a novel quintessential role for the immune system in health and disease. FASEB J, 25:29–34.
8.
WronaD. 2006. Neural-immune interactions: an integrative view of the bidirectional relationship between the brain and immune systems. J Neuroimmunol, 172:38–58.
9.
BrogdenKA, GuthmillerJM, SalzetM, ZasloffM. 2005. The nervous system and innate immunity: the neuropeptide connection. Nat Immunol, 6:558–564.
VollmarAM. 2005. The role of atrial natriuretic peptide in the immune system. Peptides, 26:1086–1094.
12.
DixitVD, TaubDD. 2005. Ghrelin and immunity: a young player in an old field. Exp Gerontol, 40:900–910.
13.
MatareseG, MoschosS, MantzorosCS. 2005. Leptin in immunology. J Immunol, 174:3137–3142.
14.
RontiT, LupattelliG, MannarinoE. 2006. The endocrine function of adipose tissue: an update. Clin Endocrinol, 64:355–365.
15.
HodkinsonCF, SimpsonEE, BeattieJH, O'ConnorJM, CampbellDJ, StrainJJ, WallaceJM. 2009. Preliminary evidence of immune function modulation by thyroid hormones in healthy man and woman aged 55–70 years. J Endocrinol, 202:55–63.
16.
HaddadJJ, SaadéNE, Safieh-GarabedianB. 2002. Cytokines and neuro-immune-endocrine interactions: a role for the hypothalamic-pituitary adrenal revolving axis. J Neuroimmunol, 133:1–19.
17.
PállingerE, CsabaG. 2008. A hormone map of human immune cell showing the presence of adrenocorticotropic hormone, triiodothyronine and endorphin in immunophenotyped white blood cells. Immunology, 123:584–589.
18.
CsabaG, KovácsP, PállingerE. 2005. Effect of the inhibition of triiodothyronine (T3) production by thiamazole on the T3 and serotonin content of immune cells. Life Sci, 76:2043–2052.
19.
KamathJ, YarbroughGG, PrangeAJJr., WinokurA. 2009. The thyrotropin-releasing hormone (TRH)-immune system homeostatic hypothesis. Pharmacol Therapeut, 121:20–28.
20.
CsabaG, PállingerE. 2009. Thyrotropic hormone (TSH) regulation of triiodothyronine (T3) concentration in immune cells. Inflamm Res, 58:151–154.
DebaveyeY, EllgerB, MebisL, DarrasVM, Van den BergheG. 2008. Regulation of tissue iodothyronine deiodinase activity in a model of prolonged critical illness. Thyroid, 18:551–560.
23.
DiezD, Grijota-MartinezC, AgrettiP, De MarcoG, TonaccheraM, PincheraA, de EscobarGM, BernalJ, MorteB. 2008. Thyroid hormone action in the adult brain: gene expression profiling of the effects of single and multiple doses of triiodo-L-thyronine in the rat striatum. Endocrinology, 149:3989–4000.
BassettJH, HarveyCB, WilliamsGR. 2003. Mechanism of thyroid hormone receptor-specific nuclear and extra nuclear actions. Mol Cell Endocrinol, 213:1–11.
26.
DavisPJ, DavisFB. 1996. Nongenomic actions of thyroid hormone. Thyroid, 6:497–504.
27.
DavisPJ, DavisFB. 2002. Nongenomic actions of thyroid hormone on the heart. Thyroid, 12:459–466.
28.
DavisPJ, ShihA, LinHY, MartinoLJ, DavisFB. 2000. Thyroxine promotes association of mitogen-activated protein kinase and nuclear thyroid hormone receptors (TR) and causes serine phosphorylation of TR. J Biol Chem, 275:38032–38039.
29.
IncerpiS, LulyP, De VitoP, FariasRN. 1999. Short-term effects of thyroid hormones on the Na/H antiport in L-6 myoblasts: high molecular specificity for 3,3′,5-triiodo-L-thyronine. Endocrinology, 140:683–689.
30.
D'ArezzoS, IncerpiS, DavisFB, AcconciaF, MarinoM, FariasRN, DavisPJ. 2004. Rapid nongenomic effects of 3,5,3′-triiodo-L-thyronine on the intracellular pH of L-6 myoblasts are mediated by intracellular calcium mobilization and kinase pathways. Endocrinology, 145:5694–5703.
31.
IncerpiS, DavisPJ, De VitoP, FariasRN, LinH-Y, DavisFB. 2008. Nongenomic actions of thyroid hormones and intracellular calcium mobilization. Clin Rev Bone Miner Metab, 6:53–61.
32.
KavokNS, KrasilnkovaOA, BabenkoNA. 2001. Thyroxine signal transduction in liver cells involves phospholipase C and phospholipase D activation. Genomic independent action of thyroid hormone. BMC Cell Biol, 2:5.
33.
BerghJJ, LinHY, LansingL, MohamedSN, DavisFB, MousaS, DavisPJ. 2005. Integrin αVβ3 contains a cell surface receptor site for thyroid hormones that is linked to activation of mitogen-activated protein kinase and induction of angiogenesis. Endocrinology, 146:2864–2871.
CodyV, DavisPJ, DavisFB. 2007. Molecular modelling of the thyroid hormone interactions with αVβ3 integrin. Steroids, 72:165–170.
36.
LinHY, SunM, TangHY, LuidensMK, MousaMA, IncerpiS, DrusanoGL, DavisFB, DavisPJ. 2009. L-Thyroxine vs. 3,5,3′-triiodo-L-thyronine and cell proliferation: activation of mitogen-activated protein kinase and phosphatidylinositol 3-kinase. Am J Physiol Cell Physiol, 296:C980–C991.
37.
DavisPJ, DavisFB, LinH-Y, MousaSA, ZhouM, LuidensMK. 2009. Solomon Berson Award Lecture: Translational implications of nongenomic actions of thyroid hormone initiated at its integrin receptor. Am J Physiol Endocrinol Metab, 297:E1238–E1246.
38.
ScapinS, LeoniS, SpagnuoloS, GnocchiD, De VitoP, LulyP, PedersenJZ, IncerpiS. 2010. Short-term effects of thyroid hormones during development: focus on signal transduction. Steroids, 75:576–584.
39.
CalzáL, FernandezM, GiardinoL. 2010. Cellular approaches to central nervous system remyelination stimulation: thyroid hormone to promote myelin repair via endogenous stem and precursor cells. J Mol Endocrinol, 44:13–23.
LadensonPW. 2003. Problems in the management of hypothyroidism. BravermanLE. Diseases of the Thyroid, second. Humana Press: Totawa, NJ, 161–176.
43.
LaniaA, PersaniL, Beck-PeccozP. 2008. Central hypothyroidism. Pituitary, 11:181–186.
44.
KaiO, NagaseH, SuzukiM, KakegawaT, SatoK. 1993. Effects of hypothyroidism with treatment of an anti-thyroid drug, propylthiouracil on immune response in chicken. Vet Immunol Immunopathol, 36:123–135.
45.
WeetmanAP. 1992. How antithyroid drugs work in Graves' disease. Clin Endocrinol, 37:317–318.
46.
DuarteCG, AzzoliniAE, Assis-PandochiAI. 2003. Effect of the period of treatment with a single dose of propylthiouracil on the antibody response in rats. Int Immunopharmacol, 3:1419–1427.
47.
PaciniF, NakamuraH, DeGrootLJ. 1983. Effect of hypo- and hyperthyroidism on the balance between helper and suppressor T cells in rats. Acta Endocrinol, 103:528–534.
48.
LiuWK, TsuiKW, WongCC. 1993. Repressed activity of peritoneal macrophages in methimazole-induced hypothyroid mice. Virchows Arch B Cell Pathol Incl Mol Pathol, 63:131–136.
49.
KlechaAJ, GenaroAM, GorelikG, Barreiro ArcosML, SilbermanDM, SchumanM, GarciaSI, PirolaC, CremaschiGA. 2006. Integrative study of hypothalamus-pituitary-thyroid-immune system interaction: thyroid hormone-mediated modulation of lymphocyte activity through the protein kinase C signaling pathway. J Endocrinol, 189:45–55.
50.
KlechaAJ, GenaroAM, LysionekAE, CaroRA, ColucciaAG, CremaschiGA. 2000. Experimental evidence pointing to the bidirectional interaction between the immune system and the thyroid axis. Int J Immunopharmacol, 22:491–500.
51.
SchoenfeldPS, MyersJW, MyersL, LaRocqueJC. 1995. Suppression of cell-mediated immunity in hypothyroidism. South Med J, 88:347–349.
52.
FrickLR, RapanelliM, BussmannUA, KlechaAJ, Barreiro ArcosML, GenaroAM, CremaschiGA. 2009. Involvement of thyroid hormones in the alterations of T-cell immunity and tumor progression induced by chronic stress. Biol Psychiatry, 65:935–942.
53.
Barreiro ArcosML, GorelikG, KlechaA, GenaroAM, CremaschiGA. 2006. Thyroid hormones increase inducible nitric oxide synthase gene expression from PKC-zeta in murine tumor lymphocytes. Am J Physiol Cell Physiol, 291:C327–C336.
54.
VolpéR. 2001. The immunomodulatory effects of anti-thyroid drugs are mediated via actions on thyroid cells, affecting thyrocyte-immunocyte signalling: a review. Curr Pharm Des, 7:451–460.
55.
HrycekA. 1993. Functional characterization of peripheral blood neutrophils in patients with primary hypothyroidism. Folia Biol, 39:304–310.
56.
WolachB, LebanonB, JedeikinA, ShapiroMS, ShenkmanL. 1989. Neutrophil chemotaxis, random migration, and adherence in patients with hyperthyroidism. Acta Endocrinol (Copenh), 121:817–820.
57.
HrycekA, KalinaZ. 1992. Cytochemical properties of peripheral blood neutrophils in patients with hyperthyroidism. Acta Haematol Pol, 23:101–109.
58.
HrycekA. 1995. Functional characterization of peripheral blood neutrophils in patients with hyperthyroidism. Folia Biol, 41:79–87.
59.
SzaboJ, ForisG, MezosiE, NagyEV, ParaghGY, SztojkaI, LeoveyA. 1996. Parameters of respiratory burst and arachidonic acid metabolism in polymorphonuclear granulocytes from patients with various thyroid diseases. Exp Clin Endocrinol Diabetes, 104:172–176.
60.
FaridNR, WoodfordG, AuB, ChandraRK. 1976. Polymorphonuclear leukocyte function in hypothyroidism. Horm Res, 7:247–253.
61.
NandakumarDN, KonerBC, VinayagamoorthiR, NandaN, NegiVS, GoswamiK, BobbyZ, HamideA. 2008. Activation of NF-kB in lymphocytes and increase in serum immunoglobulin in hyperthyroidism: possible role of oxidative stress. Immunobiology, 213:409–415.
62.
MarinoF, GuastiL, CosentinoM, De PiazzaD, SimoniC, PiantanidaE, CimpanelliM, KlersyC, BartalenaL, VencoA, LecchiniS. 2006. Thyroid hormone regulation of cell migration and oxidative metabolism in polymorphonuclear leukocytes: clinical evidence in thyroidectomized subjects on thyroxine replacement therapy. Life Sci, 78:1071–1077.
63.
FabrisN, MocchegianiE, ProvincialiM. 1995. Pituitary-thyroid axis and immune system: a reciprocal neuroendocrine-immune interaction. Horm Res, 43:29–38.
64.
FosterMP, JensenER, Montecino-RodriguezE, LeathersH, HorsemanN, DorshkindK. 2000. Humoral and cell-mediated immunity in mice with genetic deficiencies of prolactin, growth hormone, insulin-like growth factor-1, and thyroid hormone. Clin Immunol, 96:140–149.
65.
JafarzadehA, PoorgholamiM, IzadiN, NematiM, RezayatiM. 2010. Immunological and haematological changes in patients with hyperthyroidism or hypothyroidism. Clin Invest Med, 33:E271–E279.
66.
BittencourtCS, AzzoliniAE, FerreiraDA, Assis-PandochiAI. 2007. Antibody responses in hyperthyroid rats. Int Immunopharmacol, 7:989–993.
67.
VinayagamoorthiR, KonerBC, KavithaS, NandakumarDN, Padma PriyaP, GoswamiK. 2005. Potentiation of humoral immune response and activation of NF-κB pathway in lymphocytes in experimentally induced hyperthyroid rats. Cell Immunol, 238:56–60.
68.
DorshkindK, HorsemanND. 2000. The roles of prolactin, growth hormone, insulin-like growth factor-I, and thyroid hormones in lymphocytes development and function: insights from genetic models of hormone and hormone receptor deficiency. Endocr Rev, 21:292–312.
69.
HumeDA. 2006. The mononuclear phagocyte system. Curr Opin Immunol, 18:49–53.
RosaLF, SafiDA, CuriR. 1995. Effect of hypo- and hyperthyroidism on the function and metabolism of macrophages in rats. Cell Biochem Funct, 13:141–147.
72.
Kwan TatS, PadrinesM, ThéoleyreS, HeymannD, FortunY. 2004. IL-6, RANKL, TNF-alpha/IL-1: interrelations in bone resorption pathophysiology. Cytokine Growth Factor Rev, 15:49–60.
ImhofBA, Aurrand-LionsM. 2004. Adhesion mechanism regulating the migration of monocytes. Nat Rev Immunol, 4:432–444.
75.
OrtegaE, FornerMA, GarciaJJ, RodriguezAB, BarrigaC. 1999. Enhanced chemotaxis of macrophages by strenuous exercise in trained mice: thyroid hormones as possible mediators. Mol Cell Biochem, 201:41–47.
76.
da CostaVM, MoreiraDG, RosenthalD. 2001. Thyroid function and aging: gender-related differences. J Endocrinol, 171:193–198.
77.
El-ShaikhKA, GabryMS, OthmanGA. 2006. Recovery of age-dependent immunological deterioration in old mice by thyroxine treatment. J Anim Physiol Anim Nutr, 90:244–254.
78.
FabrisN. 1990. A neuroendocrine-immune theory of ageing. Int J Neurosci, 51:373–375.
79.
KoliosG, ValatasV, KouroumalisE. 2006. Role of Kupffer cells in the pathogenesis of liver disease. World J Gastroenterol, 12:7413–7420.
80.
KhoslaS, Eghbali-FatourechiGZ. 2006. Circulating cells with osteogenic potential. Ann N Y Acad Sci, 1068:489–497.
FernándezV, TapiaG, VarelaP, VidelaLA. 2005. Redox regulation of thyroid hormone-induced Kupffer cell-dependent IκB-α phosphorylation in relation to inducible nitric oxide synthase expression. Free Radic Res, 39:411–418.
83.
ValenciaC, CornejoP, RomanqueP, TapiaG, VaralaP, VidelaLA, FernándezV. 2004. Effects of acute lindane intoxication and thyroid hormone administration in relation to nuclear factor-κB activation, tumor necrosis factor-α expression, and Kupffer cell function in the rat. Toxicol Lett, 148:21–28.
84.
TapiaG, FernandezV, VarelaP, CornejoP, GuerreroJ, VidelaLA. 2003. Thyroid hormone-induced oxidative stress triggers nuclear factor-κB activation and cytokine gene expression in rat liver. Free Radic Biol Med, 35:257–265.
85.
AllainTJ, ChambersTJ, FlanaganAM, McGregorAM. 1992. Tri-iodothyronine stimulates rat osteoclastic bone resorption by an indirect effect. J Endocrinol, 133:327–331.
86.
KimCH, KimHK, ShongYK, LeeKU, KimGS. 1999. Thyroid hormone stimulates basal and interleukin (IL)-1-induced IL-6 production in human bone marrow stromal cells: a possible mediator of thyroid hormone-induced bone loss. J Endocrinol, 160:97–102.
87.
SiddiqiA, BurrinJM, WoodDF, MonsonJP. 1998. Tri-iodothyronine regulates the production of interleukin-6 and interleukin-8 in human bone marrow stromal and osteoblast-like cells. J Endocrinol, 157:453–461.
88.
HoffmanSJ, Vasko-MoserJ, MillerWH, LarkMW, GowenM, StroupG. 2002. Rapid inhibition of thyroxine-induced bone resorption in the rat by an orally active vitronectin receptor antagonist. J Pharmacol Exp Ther, 302:205–211.
89.
Hoffman-GoetzL, PedersenBK. 1994. Exercise and the immune system: a model of the stress response?Immunol Today, 15:382–387.
90.
MastorakosG, PavlatouM. 2005. Excercise as a stress model and the interplay between the hypothalamus-pituitary-adrenal and the hypothalamus-pituitary-thyroid axes. Horm Metab Res, 37:577–584.
91.
OrtegaE, FornerMA, BarrigaC. 1997. Excercise-induced stimulation of murine macrophage chemotaxis: role of corticosterone and prolactin as mediators. J Physiol, 498:729–734.
92.
FornerMA, CollazosME, BarrigaC, De la FuenteM, RodriguezAB, OrtegaE. 1994. Effect of age on adherence and chemotaxis capacities of peritoneal macrophages. Influence of physical activity stress. Mech Ageing Dev, 75:179–189.
93.
ChrousosGP. 2009. Stress and disorders of the stress system. Nat Rev Endocrinol, 5:374–381.
94.
DohmsJE, MetzA. 1991. Stress-mechanisms of immunosuppression. Vet Immunol Immunopathol, 30:89–109.
95.
FornerMA, BarrigaC, OrtegaE. 1996. Exercise-induced stimulation of murine macrophage phagocytosis may be mediated by thyroxine. J Appl Physiol, 80:899–903.
96.
KhansariDN, MurgoAJ, FaithRE. 1990. Effects of stress on the immune system. Immunol Today, 11:170–175.
97.
KimJ, RemickDG. 2007. Tumor necrosis factors inhibitors for the treatment of asthma. Curr Allergy Asthma Rep, 7:151–156.
98.
NiuN, Le GoffMK, LiF, RahmanM, HomerRJ, CohnL. 2007. A novel pathway that regulates inflammatory disease in the respiratory tract. J Immunol, 178:3846–3855.
NishizawaY, FushikiS, AmakataY, NishizawaY. 1998. Thyroxine-induced production of superoxide anion by human alveolar neutrophils and macrophages: a possible mechanism for the exacerbation of bronchial asthma with the development of hyperthyroidism. In Vivo, 12:253–257.
101.
CockcroftDW, SilverbergJD, DosmanJA. 1978. Decrease in nonspecific bronchial reactivity in an asthmatic following treatment of hyperthyroidism. Ann Allergy, 41:160–163.
102.
SlemmerJE, ShackaJJ, SweeneyMI, WeberJT. 2008. Antioxidant and free radical scavengers for the treatment of stroke, traumatic brain injury and aging. Curr Med Chem, 15:404–414.
103.
SaicićZS, MijalkovićDN, NikolićAL, BlagojevićDP, SpasićMB. 2006. Effect of thyroxine on antioxidant defense system in the liver of different aged rats. Physiol Res, 55:561–568.
104.
RahamanSO, GhoshS, MohanakumarKP, DasS, SarkarPK. 2001. Hypothyroidism in the developing rat brain is associated with marked oxidative stress and aberrant intraneuronal accumulation of neurofilaments. Neurosci Res, 40:273–279.
VendittiP, Di MeoS. 2006. Thyroid hormones-induced oxidative stress. Cell Mol Life Sci, 63:414–434.
107.
ZamonerA, BarretoKP, FilhoDW, SellF, WoehlVM, GumaFC, SilvaFR, Pessoa-PureurR. 2007. Hyperthyroidism in the developing rat testis is associated with oxidative stress and hyperphosphorylated vimentin accumulation. Mol Cell Endocrinol, 267:116–126.
108.
SarkarM, VarshneyR, ChopraM, SekhriT, AdhikariJS, DwarakanathBS. 2005. Flow-cytometric analysis of reactive oxygen species in peripheral blood mononuclear cells of patients with thyroid dysfunction. Cytometry B Clin Cytom, 70:20–23.
109.
MagsinoCHJr., HamoudaW, GhaninH, BrowneR, AljadaA, DandonaP. 2000. Effect of triiodothyronine on reactive oxygen species generation by leukocytes, indices of oxidative damage, and antioxidant reserve. Metabolism, 49:799–803.
110.
BlountBC, DuncanMW. 1997. Trace quantification of the oxidative damage products, meta- and ortho-tyrosine, in biological samples by gas chromatography-electron capture negative ionization mass spectrometry. Anal Biochem, 244:270–276.
111.
FernándezV, VidelaLA. 1995. On the mechanism of thyroid hormone-induced respiratory burst activity in rat polymorphonuclear leukocytes. Free Radic Biol Med, 19:359–363.
112.
BalázsC, LeöveyA, SzabóM, BakóG. 1980. Stimulating effect of triiodothyronine on cell-mediated immunity. Eur J Clin Pharmacol, 17:19–23.
113.
VidelaLA, CorreaL, RiveraM, SirT. 1993. Zymosan-induced luminol-amplified chemiluminescence of whole blood phagocytes in experimental and human hyperthyroidism. Free Radic Biol Med, 14:669–675.
114.
VidelaLA, FernándezV, TapiaG, VarelaP. 2007. Thyroid hormone calorigenesis and mitochondrial redox signaling: upregulation of gene expression. Front Biosci, 12:1220–1228.
115.
KanazawaH, KuriharaN, HirataK, TerakawaK, FujiwaraH, MatsushitaH, OtaK, TakedaT. 1992. The effect of thyroid hormones on the generation of free radicals by neutrophils and alveolar macrophages. Arerugi, 41:135–139.
116.
MezosiE, SzaboJ, NagyEV, BorbelyA, VargaE, ParaghG, VargaZ. 2005. Nongenomic effect of thyroid hormone on free-radical production in human polymorphonuclear leukocytes. J Endocrinol, 185:121–129.
117.
LinHY, ThacoreHR, DavisFB, DavisPJ. 1996. Potentiation by thyroxine of interferon-γ-induced antiviral state requires PKA and PKC activities. Am J Physiol Cell Physiol, 271:C1256–C1261.
118.
LinHY, ThacoreHR, DavisPJ, DavisFB. 1994. Thyroid hormone potentiates the antiviral action of interferon-γ in cultured human cells. J Clin Endocrinol Metab, 79:62–65.
119.
LinHY, ThacoreHR, DavisFB, DavisPJ. 1996. Thyroid hormone analogues potentiate the antiviral action of interferon-γ by two mechanisms. J Cell Physiol, 167:269–276.
120.
LinHY, DavisFB, GordinierJK, MartinoLJ, DavisPJ. 1999. Thyroid hormone induces activation of mitogen-activated protein kinase in cultured cells. Am J Physiol, 45:C1014–C1024.
GriffithsGM. 2003. Endocytosing the death sentence. J Cell Biol, 160:155–156.
123.
TrapaniJA. 1998. Dual mechanisms of apoptosis induction by cytotoxic lymphocytes. Int Rev Cytol, 182:111–192.
124.
KrugerTE. 1996. Immunomodulation of peripheral lymphocytes by hormones of the hypothalamus-pituitary-thyroid axis. Adv Neuroimmunol, 6:387–395.
125.
ProvincialiM, MuzzioliM, Di StefanoG, FabrisN. 1991. Recovery of spleen cell natural killer activity by thyroid hormone treatment in old mice. Nat Immun Cell Growth Regul, 10:226–236.
126.
MocchegianiE, MalavoltaM. 2004. NK and NKT cell function in immunosenescence. Aging Cell, 3:177–184.
127.
KmiecZ, MyśliwskaJ, RachónD, KotlarzG, SworczakK, MyśliwskiA. 2001. Natural Killer activity and thyroid hormone levels in young and elderly persons. Gerontology, 47:282–288.
128.
IngramKG, CrouchDA, DouezDL, CroyBA, WoodwardB. 1995. Effects of triiodothyronine supplements on splenic natural killer cells in malnourished weanling mice. Int J Immunopharmacol, 17:21–32.
129.
HaddadEE, MashalyMM. 1991. Chicken growth hormone, triiodothyronine and thyrotropin releasing hormone modulation of the level of chicken natural cell-mediated cytotoxicity. Dev Comp Immunol, 15:65–71.
130.
SharmaSD, TsaiV, ProffittMR. 1982. Enhancement of mouse natural killer cell activity by thyroxine. Cell Immunol, 73:83–97.
131.
ProvincialiM, FabrisN. 1990. Modulation of lymphoid cell sensitivity to interferon by thyroid hormones. J Endocrinol Invest, 13:187–191.
132.
FaragSS, VanDeusenJB, FehnigerTA, CaligiuriMA. 2003. Biology and clinical impact of human natural killer cells. Int J Hematol, 78:7–17.
133.
ChandratillekeD, HalaK, MarshJA. 1994. Effect of dietary triiodothyronine supplementation on the expression of IL-2R and CD3 molecules on avian splenocytes. Poultry Sci, 73:107–112.
134.
ChandratillekeD, HalaK, MarshJA. 1996. Effect of in vivo thyroid hormone treatment on the expression of interleukin-2 receptors on avian splenocytes. Int J Immunopharmacol, 18:203–210.
135.
MarshJA, MerlinoPG, StaeheliP. 2001. The effects of triodothyronine and thymulin on avian NK cytolytic activity. Int Immunopharmacol, 1:1823–1830.
136.
ChatterjeeS, ChandelAS. 1983. Immunomodulatory role of thyroid hormones: in vivo effect of thyroid hormones on the blastogenic response of lymphoid tissues. Acta Endocrinol (Copenh), 103:95–100.
137.
OhashiH, ItohM. 1994. Effects of thyroid hormones on lymphocyte phenotypes in rats: changes in lymphocyte subsets related to thyroid function. Endocr Regul, 28:117–123.
138.
FabrisN. 1973. Immunodepression in thyroid-deprived animals. Clin Exp Immunol, 15:601–611.
139.
YamD, HellerD, SnapirN. 1981. The effect of thyroidal state on the immunological state of the chicken. Dev Comp Immunol, 5:483–490.
140.
KeastD, TaylorK. 1982. The effect of tri-iodothyronine on the phytohaemagglutinin response of T lymphocytes. Clin Exp Immunol, 47:217–220.
141.
OngML, MalkinDG, MalkinA. 1986. Alteration of lymphocyte reactivities by thyroid hormones. Int J Immunopharmacol, 8:755–762.
142.
KrugerK, MoorenFC. 2007. T cell homing and exercise. Exerc Immunol Rev, 13:37–54.
IwataM, MukaiM, NakaiY, IsekiR. 1992. Retinoic acids inhibit activation-induced apoptosis in T cell hybridomas and thymocytes. J Immunol, 149:3302–3308.
145.
HuangL, LiZY, XuSY, ChenMZ. 1990. Effect of thyroxine on IgM production and beta-adrenergic receptor on lymphocyte in mice. Sheng Li Xue Bao, 42:469–475.
146.
ChandelAS, ChatterjeeS. 1989. Immunomodulatory role of thyroid hormones: effect on humoral immune response to Salmonella typhi O antigen. Indian J Exp Biol, 27:1013–1016.
147.
WallJR, TwohigP, ChartierB. 1981. Effect of experimental hyper- and hypothyroidism on numbers of blood mononuclear cells and immune function in rats and guinea-pigs. J Endocrinol, 91:61–67.
148.
HassmanR, WeetmanAP, GunnC, StringerBM, Wynford-ThomasD, HallR, McGregorAM. 1985. The effect of hyperthyroidism on experimental autoimmune thyroiditis in the rat. Endocrinology, 116:1253–1258.
149.
WilliamsonRA, DavisonTF, PayneLN. 1990. Effects of thyroid hormones on humoral and cell-mediated immune responses in the domestic fowl (Gallus domesticus)Dev Comp Immunol, 14:305–318.
150.
Barreiro ArcosML, SterleH, PaulazoMA, ValliE, KlechaAJ, IsseB, PellizasCG, FaríasRN, CremaschiGA. 2011. Cooperative nongenomic and genomic actions on thyroid hormone mediated-modulation of T cell proliferation involve up-regulation of thyroid hormone receptor and inducible nitric oxide synthase expression. J Cell Physiol, Feb2210.1002/jcp.22681[Epub ahead of print].
151.
MiharaS, SuzukiN, WakisakaS, SuzukiS, SekitaN, YamamotoS, SaitoN, HoshinoT, SakaneT. 1999. Effects of thyroid hormones on apoptotic cell death of human lymphocytes. J Clin Endocrinol Metab, 84:1378–1385.
ChenYF, KobayashiS, ChenJ, RedetzkeRA, SaidS, LiangQ, GerdesAM. 2008. Short term triiodo-L-thyronine treatment inhibits cardiac myocyte apoptosis in border area after myocardial infarction in rats. J Mol Cell Cardiol, 44:180–187.
155.
GuermonprezP, ValladeauJ, ZitvogelL, ThéryC, AmigorenaS. 2002. Antigen presentation and T cell stimulation by dendritic cells. Annu Rev Immunol, 20:621–667.
156.
MascanfroniI, Montesinos MdelM, SusperreguyS, CerviL, IlarreguiJM, RamseyerVD, Masini-RepisoAM, TargovnikHM, RabinovichGA, PellizasCG. 2008. Control of dendritic cell maturation and function by triiodothyronine. FASEB J, 22:1032–1042.
ShihCH, ChenSL, YenCC, HuangYH, ChenCD, LeeYS, LinKH. 2004. Thyroid hormone receptor-dependent transcriptional regulation of fibrinogen and coagulation proteins. Endocrinology, 145:2804–2814.
159.
MoellerLC, CaoX, DumitrescuAM, SeoH, RefetoffS. 2006. Thyroid hormone mediated changes in gene expression can be initiated by cytosolic action of the thyroid hormone receptor β through the phosphatidylinositol 3-kinase pathway. Nucl Recept Signal, 4:e020.
160.
WeiL, LuJ, FengL, LongD, ShanJ, LiS, LiY. 2010. HIF-1alpha accumulation upregulates MICA and MICB expression on human cardiomyocytes and enhances NK cell cytoxicity during hypoxia-reoxygenation. Life Sci, 87:111–129.
161.
JansenJ, FriesemaEC, MiliciC, VisserTJ. 2005. Thyroid hormone transporters in health and disease. Thyroid, 15:757–768.
