Institute for Organic Chemistry and Chemical Biology, Center for Biomolecular Magnetic Resonance, Johann Wolfgang Goethe-University of Frankfurt, Max-von-Laue-Strasse 7, 60438 Frankfurt, Germany.
J Am Chem Soc. 2011 Feb 2;133(4):808-19. doi: 10.1021/ja104983t.
Lanthanide-binding tags (LBTs) are valuable tools for investigation of protein structure, function, and dynamics by NMR spectroscopy, X-ray crystallography, and luminescence studies. We have inserted LBTs into three different loop positions (denoted L, R, and S) of the model protein interleukin-1β (IL1β) and varied the length of the spacer between the LBT and the protein (denoted 1−3). Luminescence studies demonstrate that all nine constructs bind Tb3+ tightly in the low nanomolar range. No significant change in the fusion protein occurs from insertion of the LBT, as shown by two X-ray crystallographic structures of the IL1β-S1 and IL1β-L3 constructs and for the remaining constructs by comparing the 1H−15N heteronuclear single-quantum coherence NMR spectra with that of the wild-type IL1β. Additionally, binding of LBT-loop IL1β proteins to their native binding partner in vitro remains unaltered. X-ray crystallographic phasing was successful using only the signal from the bound lanthanide. Large residual dipolar couplings (RDCs) could be determined by NMR spectroscopy for all LBT-loop constructs and revealed that the LBT-2 series were rigidly incorporated into the interleukin-1β structure. The paramagnetic NMR spectra of loop-LBT mutant IL1β-R2 were assigned and the Δχ tensor components were calculated on the basis of RDCs and pseudocontact shifts. A structural model of the IL1β-R2 construct was calculated using the paramagnetic restraints. The current data provide support that encodable LBTs serve as versatile biophysical tags when inserted into loop regions of proteins of known structure or predicted via homology modeling.
镧系元素结合标签 (LBTs) 是通过 NMR 光谱、X 射线晶体学和发光研究来研究蛋白质结构、功能和动力学的有价值的工具。我们已经将 LBT 插入模型蛋白白细胞介素-1β(IL1β)的三个不同环位置(分别表示为 L、R 和 S),并改变了 LBT 与蛋白之间的间隔长度(表示为 1-3)。发光研究表明,所有九个构建体都能在低纳摩尔范围内紧密结合 Tb3+。插入 LBT 不会导致融合蛋白发生明显变化,这可以通过 IL1β-S1 和 IL1β-L3 构建体的两个 X 射线晶体结构以及剩余构建体通过比较 1H-15N 异核单量子相干 NMR 谱与野生型 IL1β 的 1H-15N 异核单量子相干 NMR 谱来证明。此外,LBT 环 IL1β 蛋白与它们天然结合伴侣的结合在体外仍然不变。仅使用结合的镧系元素的信号即可成功进行 X 射线晶体学相位确定。通过 NMR 光谱可以为所有 LBT 环构建体确定大的残余偶极耦合 (RDC),并表明 LBT-2 系列被刚性地纳入白细胞介素-1β结构中。可以对环-LBT 突变体 IL1β-R2 的顺磁 NMR 谱进行分配,并根据 RDC 和赝接触位移计算 Δχ 张量分量。使用顺磁约束计算了 IL1β-R2 构建体的结构模型。目前的数据提供了支持,即当插入已知结构的蛋白质的环区或通过同源建模预测的蛋白质的环区时,可编码的 LBT 可用作多功能生物物理标记。