Benecky M J, Kolvenbach C G, Wine R W, DiOrio J P, Mosesson M W
Sinai Samaritan Medical Center, University of Wisconsin Medical School, Milwaukee 53233.
Biochemistry. 1990 Mar 27;29(12):3082-91. doi: 10.1021/bi00464a027.
In order to more clearly define the structure of human plasma fibronectin (PFn) under physiologic buffer conditions, we determined the mean harmonic rotational relaxation times (rho H) of PFn and the thrombin-derived 190/170-kDa PFn fragment using steady-state fluorescence polarization. These measurements utilized the long lifetime emission (tau = 1.2 X 10(-7) S) exhibited by 1-pyrenebutyrate, which had been covalently attached to amino groups at random sites on the PFn subunit. Our data analysis assumed that two independent processes depolarize the fluorescence exhibited by the dansylcadaverine and 1-pyrenebutyrate conjugates of PFn: (A) rapid (rho H less than 10(-9) S) "thermally-activated" localized rotational motion of the protein side chains bearing the fluorescent probe [Weber, G. (1952) Biochem. J. 51, 145-154] and (B) slow (rho H approximately 10(-6) S) temperature-independent global rotational motion of the whole PFn molecule. Since only the rho H associated with the latter process is a true hydrodynamic parameter (i.e., sensitive to size and/or shape of the PFn molecule), we utilized isothermal polarization measurements to discriminate against the interfering signal arising from "thermally activated" probe rotation. The rho H (4.4 +/- 0.9 microseconds) derived from an experiment in which pyrene-PFn fluorescence polarization was monitored as a function of sucrose concentration at constant temperature is 7 (+/- 1.4) times longer than that predicted for an equivalent hydrated sphere. We propose that "thermally activated" probe rotation gives rise to the nearly 100-fold shorter PFn rho H values previously reported in the literature. Consequently, our data exclude all previous models which invoke segmental flexibility of the PFn peptide backbone. The simplest hydrodynamic model supported by our fluorescence data is an oblate ellipsoid with an axial ratio of 15:1. All prolate models can be unambiguously excluded by this result. We estimate that the disk-shaped PFn molecule has a diameter and thickness of 30 and 2 nm, respectively. Electron microscopy of negatively stained PFn specimens on carbon also showed PFn to have a compact rounded structure. The much faster rotational relaxation rate of the pyrene-190/170-kDa PFn fragment (rho H = 0.92 +/- 0.11 microseconds) compared to pyrene-PFn indicated that this monomeric PFn fragment, like native PFn, had an oblate shape under physiologic buffer conditions.
为了更清晰地界定生理缓冲条件下人类血浆纤连蛋白(PFn)的结构,我们使用稳态荧光偏振测定了PFn以及凝血酶衍生的190/170-kDa PFn片段的平均谐波旋转弛豫时间(ρH)。这些测量利用了1-芘丁酸表现出的长寿命发射(τ = 1.2×10⁻⁷秒),该物质已共价连接到PFn亚基上随机位点的氨基。我们的数据分析假定有两个独立过程使PFn的丹磺酰尸胺和1-芘丁酸缀合物表现出的荧光去极化:(A)携带荧光探针的蛋白质侧链的快速(ρH小于10⁻⁹秒)“热激活”局部旋转运动[韦伯,G.(1952年)《生物化学杂志》51,145 - 154],以及(B)整个PFn分子的缓慢(ρH约为10⁻⁶秒)与温度无关的整体旋转运动。由于只有与后一过程相关的ρH是一个真正的流体动力学参数(即对PFn分子的大小和/或形状敏感),我们利用等温偏振测量来区分由“热激活”探针旋转产生的干扰信号。在恒温下监测芘-PFn荧光偏振随蔗糖浓度变化的实验得出的ρH(4.4±0.9微秒)比同等水合球体预测的值长7(±1.4)倍。我们提出“热激活”探针旋转导致了文献中先前报道的PFn的ρH值短近100倍。因此,我们的数据排除了所有先前援引PFn肽主链片段灵活性的模型。我们的荧光数据支持的最简单流体动力学模型是一个轴比为15:1的扁椭球体。这一结果可以明确排除所有长椭球体模型。我们估计盘状的PFn分子直径和厚度分别为30和2纳米。对碳上负染的PFn标本进行电子显微镜观察也显示PFn具有紧密的圆形结构。与芘-PFn相比,芘-190/170-kDa PFn片段的旋转弛豫速率要快得多(ρH = 0.92±0.11微秒),这表明该单体PFn片段在生理缓冲条件下与天然PFn一样呈扁状。
