纤维细胞
促炎细胞因子
Graves眼病
甲状腺
格雷夫斯病
医学
受体
促甲状腺激素受体
癌症研究
免疫学
生物
病理
炎症
细胞生物学
内分泌学
内科学
标识
DOI:10.1038/nrendo.2014.226
摘要
Thyroid-associated ophthalmopathy (TAO) is an orbital manifestation of Graves disease. The pathogenesis of TAO is still not well understood and effective therapies for TAO are lacking. Here, Terry Smith reviews the processes that underlie autoimmunity and inflammation in the orbit of patients with TAO, with a focus on the role of infiltrating fibrocytes expressing the TSH receptor. Therapeutic implications are also discussed. Thyroid-associated ophthalmopathy (TAO) is a vexing and undertreated ocular component of Graves disease in which orbital tissues undergo extensive remodelling. My colleagues and I have introduced the concept that fibrocytes expressing the haematopoietic cell antigen CD34 (CD34+ fibrocytes), which are precursor cells of bone-marrow-derived monocyte lineage, express the TSH receptor (TSHR). These cells also produce several other proteins whose expression was traditionally thought to be restricted to the thyroid gland. TSHR-expressing fibrocytes in which the receptor is activated by its ligand generate extremely high levels of several inflammatory cytokines. Acting in concert with TSHR, the insulin-like growth factor 1 receptor (IGF-1R) expressed by orbital fibroblasts and fibrocytes seems to be necessary for TSHR-dependent cytokine production, as anti-IGF-1R blocking antibodies attenuate these proinflammatory actions of TSH. Furthermore, circulating fibrocytes are highly abundant in patients with TAO and seem to infiltrate orbital connective tissues, where they might transition to CD34+ fibroblasts. My research group has postulated that the infiltration of fibrocytes into the orbit, their unique biosynthetic repertoire and their proinflammatory and profibrotic phenotype account for the characteristic properties exhibited by orbital connective tissues that underlie susceptibility to TAO. These insights, which have emerged in the past few years, might be of use in therapeutically targeting pathogenic orbit-infiltrating fibrocytes selectively by utilizing novel biologic agents that interfere with TSHR and IGF-1R signalling.
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