Magusin P C, Hemminga M A
Department of Molecular Physics, Agricultural University, Wageningen, The Netherlands.
Biophys J. 1993 Jun;64(6):1861-8. doi: 10.1016/S0006-3495(93)81557-1.
The experimentally observed 31P lineshapes and transversal relaxation of 15% (wt/wt) M13, 30% M13, and 30% tobacco mosaic virus (TMV) are compared with lineshapes and relaxation curves that are simulated for various types of rotational diffusion using the models discussed previously (Magusin, P. C. M. M., and M. A. Hemminga. 1993. Biophys. J. 64:1851-1860). It is found that isotropic diffusion cannot explain the observed lineshape effects. A rigid rod diffusion model is only successful in describing the experimental data obtained for 15% M13. For 30% M13 the experimental lineshape and relaxation curve cannot be interpreted consistently and the TMV lineshape cannot even be simulated alone, indicating that the rigid rod diffusion model does not generally apply. A combined diffusion model with fast isolated motions of the encapsulated nucleic acid dominating the lineshape and a slow overall rotation of the virion as a whole, which mainly is reflected in the transversal relaxation, is able to provide a consistent picture for the 15 and 30% M13 samples, but not for TMV. Strongly improved lineshape fits for TMV are obtained assuming that there are three binding sites with different mobilities. The presence of three binding sites is consistent with previous models of TMV. The best lineshapes are simulated for a combination of one mobile and two static sites. Although less markedly, the assumption that two fractions of DNA with different mobilities exist within M13 also improves the simulated lineshapes. The possible existence of two 31P fractions in M13 sheds new light on the nonintegral ratio 2.4:1 between the number of nucleotides and protein coat subunits in the phage: 83% of the viral DNA is less mobile, suggesting that the binding of the DNA molecule to the protein coat actually occurs at the integral ratio of two nucleotides per protein subunit.
将实验观察到的15%(重量/重量)M13、30% M13和30%烟草花叶病毒(TMV)的31P线形和横向弛豫与使用先前讨论的模型(Magusin,P.C.M.M.和M.A.Hemminga.1993.Biophys.J.64:1851 - 1860)针对各种类型的旋转扩散模拟的线形和弛豫曲线进行了比较。发现各向同性扩散无法解释观察到的线形效应。刚性棒扩散模型仅成功描述了15% M13的实验数据。对于30% M13,实验线形和弛豫曲线无法得到一致的解释,而TMV线形甚至无法单独模拟,这表明刚性棒扩散模型并不普遍适用。一种组合扩散模型,其中被包裹的核酸的快速孤立运动主导线形,而病毒体整体的缓慢整体旋转主要反映在横向弛豫中,能够为15%和30% M13样品提供一致的图像,但不适用于TMV。假设存在三个具有不同迁移率的结合位点,可获得TMV显著改善的线形拟合。三个结合位点的存在与TMV的先前模型一致。对于一个可移动位点和两个静态位点的组合,模拟出了最佳线形。尽管不太明显,但假设M13内存在两个具有不同迁移率的DNA部分也改善了模拟线形。M13中可能存在两个31P部分,这为噬菌体中核苷酸与蛋白质外壳亚基数量之间2.4:1的非整数比例提供了新的线索:83%的病毒DNA迁移率较低,这表明DNA分子与蛋白质外壳的结合实际上是以每个蛋白质亚基两个核苷酸的整数比例发生的。