Ohashi Tomoo, Galiacy Stephane D, Briscoe Gina, Erickson Harold P
Department of Cell Biology, Duke University Medical Center, Durham, NC 27710, USA.
Protein Sci. 2007 Jul;16(7):1429-38. doi: 10.1110/ps.072845607.
We have experimentally studied the fluorescence resonance energy transfer (FRET) between green fluorescent protein (GFP) molecules by inserting folded or intrinsically unstructured proteins between CyPet and Ypet. We discovered that most of the enhanced FRET signal previously reported for this pair was due to enhanced dimerization, so we engineered a monomerizing mutation into each. An insert containing a single fibronectin type III domain (3.7 nm end-to-end) gave a moderate FRET signal while a two-domain insert (7.0 nm) gave no FRET. We then tested unstructured proteins of various lengths, including the charged-plus-PQ domain of ZipA, the tail domain of alpha-adducin, and the C-terminal tail domain of FtsZ. The structures of these FRET constructs were also studied by electron microscopy and sedimentation. A 12 amino acid linker and the N-terminal 33 amino acids of the charged domain of the ZipA gave strong FRET signals. The C-terminal 33 amino acids of the PQ domain of the ZipA and several unstructured proteins with 66-68 amino acids gave moderate FRET signals. The 150 amino acid charged-plus-PQ construct gave a barely detectable FRET signal. FRET efficiency was calculated from the decreased donor emission to estimate the distance between donor and acceptor. The donor-acceptor distance varied for unstructured inserts of the same length, suggesting that they had variable stiffness (persistence length). We conclude that GFP-based FRET can be useful for studying intrinsically unstructured proteins, and we present a range of calibrated protein inserts to experimentally determine the distances that can be studied.
我们通过在CyPet和Ypet之间插入折叠的或内在无序的蛋白质,对绿色荧光蛋白(GFP)分子之间的荧光共振能量转移(FRET)进行了实验研究。我们发现,此前报道的该对蛋白增强的FRET信号大多归因于二聚化增强,因此我们在每个蛋白中设计了一个单体化突变。包含单个III型纤连蛋白结构域(端到端长度为3.7 nm)的插入片段产生了适度的FRET信号,而包含两个结构域的插入片段(7.0 nm)则未产生FRET信号。然后,我们测试了各种长度的无序蛋白,包括ZipA的带电加PQ结构域、α - 内收蛋白的尾部结构域以及FtsZ的C末端尾部结构域。还通过电子显微镜和沉降法研究了这些FRET构建体的结构。12个氨基酸的接头和ZipA带电结构域的N末端33个氨基酸产生了强烈的FRET信号。ZipA的PQ结构域的C末端33个氨基酸和几种含有66 - 68个氨基酸的无序蛋白产生了适度的FRET信号。包含150个氨基酸的带电加PQ构建体产生的FRET信号几乎无法检测到。通过供体发射的降低来计算FRET效率,以估计供体和受体之间的距离。对于相同长度的无序插入片段,供体 - 受体距离有所不同,这表明它们具有可变的刚性(持久长度)。我们得出结论,基于GFP的FRET可用于研究内在无序蛋白,并且我们展示了一系列经过校准的蛋白插入片段,以通过实验确定可研究的距离。