Taniguchi S, Yoshida A, Shigemasa C, Mitani Y, Ueta Y, Urabe K, Mashiba H
First Department of Internal Medicine, Tottori University School of Medicine, Yonago, Japan.
Endocrinology. 1990 Feb;126(2):796-803. doi: 10.1210/endo-126-2-796.
It has been reported that the addition of antibody (Ab) against human immunoglobulin G (IgG) converts TSH receptor-bound blocking-type IgG to stimulating-type IgG. However, the detail of converting mechanism remains unclear. In this study we examined the mechanism involved in this conversion using FRTL-5 cells. Blocking-type IgG was obtained from a patient with hypothyroidism. FRTL-5 cells were first incubated with IgG solution, then washed with PBS and exposed to antihuman IgG Ab. The effect of antihuman IgG Ab on converting activity was dose dependent. Maximal stimulation of cAMP was achieved with an antiserum dilution of 1:75. It seems likely that antimicrosomal Ab does not interfere with cAMP production, since IgG with a high anti-hemagglutination antibody titer did not show converting activity. Of the several kinds of antibodies tested, Ab against human IgG-Fab fragment was the most effective in converting ability, while the least effective were those against human IgG-Fc fragment. Although the divalent F(ab')2 fragment of antihuman IgG was significantly more effective in its converting ability than the monovalent Fab fragment, the Fab fragment itself also converted blocking IgG to the stimulating type in a dose-dependent manner. Accordingly, receptor cross-linking or aggregation does not play a major role in promoting this converting phenomenon. When cells were first exposed to blocking-type IgG and then to both antihuman IgG Ab and bovine TSH, cAMP production was much greater than the sum of each alone. However, anti-IgG Ab alone did not affect the binding of blocking-type IgG to receptor. These results suggest that the addition of antihuman IgG Ab not only converts blocking-type IgG to the stimulating type but also recovers TSH activity via a postreceptor step. Forskolin, like TSH, showed an additive effect on cAMP stimulatory action with antihuman IgG. In contrast, cholera toxin and antihuman IgG Ab were not additive. The reason for this discrepancy remains unknown. In summary, our observation indicates that 1) the converting phenomenon is induced via IgG-TSH receptor complexes; 2) the mechanism aside from receptor aggregation, i.e. the recognition of a critical domain in TSH receptor molecule, seems necessary for promoting converting phenomenon; and 3) the addition of antihuman IgG Ab affects a postreceptor step via TSH receptor structures that differ from the TSH-binding site.
据报道,添加抗人免疫球蛋白G(IgG)抗体可将与促甲状腺激素(TSH)受体结合的阻断型IgG转变为刺激型IgG。然而,这种转变机制的细节仍不清楚。在本研究中,我们使用FRTL-5细胞研究了参与这种转变的机制。阻断型IgG取自一名甲状腺功能减退患者。首先将FRTL-5细胞与IgG溶液孵育,然后用磷酸盐缓冲液(PBS)洗涤并暴露于抗人IgG抗体。抗人IgG抗体对转变活性的影响呈剂量依赖性。抗血清稀释度为1:75时可实现对环磷酸腺苷(cAMP)的最大刺激。抗微粒体抗体似乎不干扰cAMP的产生,因为具有高抗血凝抗体效价的IgG未显示转变活性。在所测试的几种抗体中,抗人IgG-Fab片段在转变能力方面最有效,而抗人IgG-Fc片段最无效。尽管抗人IgG的二价F(ab')2片段在其转变能力方面比单价Fab片段明显更有效,但Fab片段本身也以剂量依赖性方式将阻断型IgG转变为刺激型。因此,受体交联或聚集在促进这种转变现象中不起主要作用。当细胞首先暴露于阻断型IgG,然后暴露于抗人IgG抗体和牛TSH时,cAMP的产生远大于单独使用每种物质时的总和。然而,单独的抗IgG抗体并不影响阻断型IgG与受体的结合。这些结果表明,添加抗人IgG抗体不仅将阻断型IgG转变为刺激型,而且还通过受体后步骤恢复TSH活性。福斯高林与TSH一样,对cAMP刺激作用与抗人IgG显示出相加效应。相比之下,霍乱毒素和抗人IgG抗体没有相加效应。这种差异的原因尚不清楚。总之,我们的观察结果表明:1)转变现象是通过IgG-TSH受体复合物诱导的;2)除受体聚集之外的机制,即识别TSH受体分子中的关键结构域,似乎是促进转变现象所必需的;3)添加抗人IgG抗体通过与TSH结合位点不同的TSH受体结构影响受体后步骤。
