Triiodothyronine receptor from rat liver nuclei Interaction, after partial purification, with DNA and chromatin

Alain Anselmet, Janine Bismuth, Maria-Margarida Menezes Ferreira, Janine Torresani
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引用次数: 6

Abstract

Nuclear triiodothyronine-binding proteins (NTBP) which are at present considered as a nuclear receptor for triiodothyronine (T3) have been partially purified (about 100-fold) from rat liver nuclei by Sephadex G-100 gel filtration and DEAE-Sephadex chromatography and incubated with [125I]-T3([125I]T3-NTBP complexes). Their ability to bind to DNA and chromatin was analyzed by using in the first case rat liver or calf thymus DNA either soluble or coupled to Sepharose 4B and in the second case expanded chromatin preparations from residual chromatin after NTBP extraction (extracted chromatin) or from whole nuclei (total chromatin). [125I]T3-NTBP complexes could be rapidly and totally bound to DNA; chromatin binding was slower and less efficient on a DNA weight basis, particularly with total chromatin. In both cases, binding presented similar characteristics: it was highly sensitive to concentration of KCl and divalent cations; it depended upon the presence of reducing agents and probably the maintenance of a proper conformation of the receptor molecule; it did not need the presence of bound hormone; it was inhibited by ethidium bromide, actinomycin D and heparin. DNA binding of [125I]T3-NTBP complexes was similar with eukaryotic DNAs (rat, calf), reduced with Escherichia coli DNA, synthetic poly[d(A-T)] and heat-denatured DNA, and almost non-existent with poly(dA) or yeast RNA. No saturation of rat liver DNA could be detected, suggesting a capacity higher than 130 pmol NTBP/mg DNA. Saturation curves were observed in only three experiments out of six using total chromatin preparations and suggested capacities about 50-fold higher than the physiological concentrations of NTBP in nuclei (0.5 pmol/mg DNA). Furthermore, NTBP binding was significantly lower with spleen chromatin preparations as compared to liver ones. Thus, the T3 receptor appears as a DNA binding protein; it is suggested from our in vitro chromatin binding studies that DNA could be the major locus of NTBP binding in chromatin. The extent of DNA binding in chromatin is limited by other chromatin components in a more pronounced manner with the least modified chromatin preparations and with chromatin preparations from spleen, a tissue poorly responsive to thyroid hormones. Nevertheless, another chromatin localization of the T3 receptor cannot be excluded.

大鼠肝核三碘甲状腺原氨酸受体部分纯化后与DNA和染色质的相互作用
核三碘甲状腺原氨酸结合蛋白(NTBP)目前被认为是三碘甲状腺原氨酸(T3)的核受体,通过Sephadex G-100凝胶过滤和DEAE-Sephadex层析从大鼠肝核中部分纯化(约100倍),并与[125I]-T3([125I]T3-NTBP复合物)孵育。它们与DNA和染色质结合的能力被分析,在第一种情况下,使用大鼠肝脏或小牛胸腺DNA可溶性或偶联到Sepharose 4B,在第二种情况下,从NTBP提取后的残余染色质(提取的染色质)或从整个细胞核(总染色质)中扩增染色质制备。[125I]T3-NTBP复合物可以快速和完全结合DNA;在DNA重量的基础上,染色质结合速度较慢,效率较低,特别是总染色质。在这两种情况下,结合具有相似的特点:对KCl和二价阳离子的浓度高度敏感;它取决于还原剂的存在和受体分子适当构象的维持;它不需要结合激素的存在;溴化乙锭、放线菌素D和肝素对其有抑制作用。[125I]T3-NTBP复合物的DNA结合与真核DNA(大鼠、小牛)相似,与大肠杆菌DNA、合成聚[d(A-T)]和热变性DNA结合减少,与聚(dA)或酵母RNA结合几乎不存在。大鼠肝脏DNA未见饱和,容量高于130 pmol NTBP/mg DNA。在使用总染色质制剂的6个实验中,只有3个实验观察到饱和曲线,并且表明容量比细胞核中NTBP的生理浓度(0.5 pmol/mg DNA)高约50倍。此外,与肝染色质制剂相比,脾染色质制剂与NTBP的结合显著降低。因此,T3受体作为DNA结合蛋白出现;我们的体外染色质结合研究表明,DNA可能是NTBP在染色质中结合的主要位点。DNA在染色质中的结合程度受到其他染色质成分的限制,以一种更明显的方式,使用修饰最少的染色质制剂和来自脾脏的染色质制剂,这是一个对甲状腺激素反应较差的组织。然而,不能排除T3受体的另一个染色质定位。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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