Shi S D, Hendrickson C L, Marshall A G
Department of Chemistry, Florida State University, Tallahassee, FL 32306-3006, USA.
Proc Natl Acad Sci U S A. 1998 Sep 29;95(20):11532-7. doi: 10.1073/pnas.95.20.11532.
A typical molecular ion mass spectrum consists of a sum of signals from species of various possible isotopic compositions. Only the monoisotopic peak (e.g., all carbons are 12C; all nitrogens are 14N, etc.) has a unique elemental composition. Every other isotope peak at approximately integer multiples of approximately 1 Da higher in nominal mass represents a sum of contributions from isotope combinations differing by a few mDa (e.g., two 13C vs. two 15N vs. one 13C and one 15N vs. 34S, vs. 18O, etc., at approximately 2 Da higher in mass than the monoisotopic mass). At sufficiently high mass resolving power, each of these nominal-mass peaks resolves into its isotopic fine structure. Here, we report resolution of the isotopic fine structure of proteins up to 15.8 kDa (isotopic 13C,15N doubly depleted tumor suppressor protein, p16), made possible by electrospray ionization followed by ultrahigh-resolution Fourier transform ion cyclotron resonance mass analysis at 9.4 tesla. Further, a resolving power of m/Deltam50% approximately 8,000,000 has been achieved on bovine ubiquitin (8.6 kDa). These results represent a 10-fold increase in the highest mass at which isotopic fine structure previously had been observed. Finally, because isotopic fine structure reveals elemental composition directly, it can be used to confirm or determine molecular formula. For p16, for example, we were able to determine (5.1 +/- 0.3) the correct number (five) of sulfur atoms solely from the abundance ratio of the resolved 34S peak to the monoisotopic peak.
典型的分子离子质谱由来自各种可能同位素组成的物种的信号总和组成。只有单同位素峰(例如,所有碳都是(^{12}C);所有氮都是(^{14}N)等)具有独特的元素组成。其他每个在标称质量上比单同位素峰高约(1Da)的整数倍处的同位素峰,都代表了质量相差几个(mDa)的同位素组合的贡献总和(例如,两个(^{13}C)对两个(^{15}N)对一个(^{13}C)和一个(^{15}N)对(^{34}S)对(^{18}O)等,质量比单同位素质量高约(2Da))。在足够高的质量分辨率下,这些标称质量峰中的每一个都会分解为其同位素精细结构。在此,我们报告了通过电喷雾电离,然后在(9.4)特斯拉下进行超高分辨率傅里叶变换离子回旋共振质量分析,实现了高达(15.8kDa)的蛋白质(同位素(^{13}C)、(^{15}N)双缺失肿瘤抑制蛋白,(p16))的同位素精细结构的解析。此外,在牛泛素((8.6kDa))上实现了(m/\Delta m_{50%})约为(8,000,000)的分辨率。这些结果代表了之前观察到同位素精细结构的最高质量提高了(10)倍。最后,由于同位素精细结构直接揭示了元素组成,它可用于确认或确定分子式。例如,对于(p16),我们仅从解析的(^{34}S)峰与单同位素峰的丰度比就能确定((5.1\pm0.3))硫原子的正确数量(五个)。
