NMR Fingerprinting: Leveraging optimal control pulse design, tailored isotope labeling, and machine learning to study intractable proteins

NMR 指纹图谱：利用最佳控制脉冲设计、定制同位素标记和机器学习来研究棘手的蛋白质

基本信息

批准号：
10387787
负责人：
Haribabu Arthanari
金额：
$ 7.5万
依托单位：
DANA-FARBER CANCER INST
依托单位国家：
美国
项目类别：
财政年份：
2020
资助国家：
美国
起止时间：
2020-06-01 至 2025-03-31
项目状态：
未结题

项目摘要

Project summary Nuclear magnetic resonance (NMR) spectroscopy is essential for the study structure, dynamics and function of proteins in near-native conditions. NMR studies have vital implications for therapeutic development. However, as the number of amino acids in the protein increases, NMR signals decay (relax) faster, yielding lower sensitivity and resolution, while the spectrum becomes more crowded. In these cases it is challenging to match observed signals to specific nuclei in the protein (called `resonance assignment') in order to meaningfully interpret NMR data. The overarching goal of our research is to push the boundaries of NMR enabling valuable insight about the dynamics and functions of currently intractable proteins. The objective of this project is to design an NMR platform consisting of coordinated, next-generation biochemical, biophysical, mathematical, and computational techniques. Our platform is built around an original approach to NMR spectroscopy in which new information about the local environment of each nucleus is encoded in the shape and pattern of its NMR signal. The rationale is that these patterns are a `fingerprint' – an intricate and unique signature that encodes key information about which atom is responsible for each resonance peak in the NMR spectrum. We will design and realize fingerprint patterns using two innovative approaches: 1) biochemically, by selectively introducing NMR-active isotopes into carefully chosen positions in the protein samples, and biophysically, and 2) by using specialized radiofrequency pulses to accurately control the quantum interactions that determine the NMR spectrum. The resulting fingerprints will be decoded using established algorithmic structures from machine learning, notably artificial neural networks. This will facilitate automated analyses that are accessible to non-NMR specialists. Our approach to spectroscopy holds promise in the study of therapeutically important proteins expressed in eukaryotic expression systems (e.g. G-protein coupled receptors and glycosylated proteins). Current NMR data from such proteins shows clear dynamics and interactions with other proteins, but cannot yet be properly interpreted because of the difficulty of relating each NMR peak to an amino acid in the protein sequence. Our platform will deliver two significant outcomes: 1) NMR resonance assignment for meaningful analyses of previously intractable systems. 2) Enable non-NMR specialists, to easily proceed from expressing their protein sample to using NMR to study dynamics and interactions via assigned spectra. This will have a positive impact on protein science and medical research. To support our mission we have assembled a team of leading experts to test our platform with their own protein systems.

项目概要核磁共振 (NMR) 光谱对于研究结构、动力学和功能至关重要近天然条件下的蛋白质研究对于治疗开发具有重要意义。随着蛋白质中氨基酸数量的增加，NMR 信号衰减（松弛）得更快，产量更低灵敏度和分辨率，而光谱变得更加拥挤，在这些情况下很难匹配。观察到蛋白质中特定核的信号（称为“共振分配”），以便有意义地我们研究的首要目标是突破 NMR 的界限，实现有价值的数据。深入了解当前棘手的蛋白质的动力学和功能。设计一个由协调的下一代生物化学、生物物理、数学、我们的平台是围绕核磁共振波谱的原始方法构建的，其中有关每个原子核局部环境的新信息被编码在其 NMR 的形状和模式中其基本原理是这些模式是“指纹”——一种复杂而独特的编码签名。我们将了解有关 NMR 谱中每个共振峰的原子的关键信息。使用两种创新方法设计和实现指纹图案：1）生物化学，选择性地将 NMR 活性同位素引入蛋白质样品中精心选择的位置，并通过生物物理方法， 2）通过使用专门的射频脉冲来精确控制决定量子相互作用的量子相互作用核磁共振谱将使用已建立的算法结构对所得指纹进行解码。机器学习，尤其是人工神经网络，这将有助于实现自动化分析。对于非 NMR 专家来说，我们的光谱学方法在具有重要治疗意义的研究中具有广阔的前景。在真核表达系统中表达的蛋白质（例如 G 蛋白偶联受体和糖基化目前此类蛋白质的 NMR 数据显示出清晰的动力学以及与其他蛋白质的相互作用，但是由于很难将每个 NMR 峰与氨基酸中的氨基酸相关联，因此尚无法正确解释我们的平台将提供两个重要成果：1) NMR 共振分配。 2) 使非 NMR 专家能够轻松地从使用 NMR 表达蛋白质样品，通过指定的光谱研究动力学和相互作用。将对蛋白质科学和医学研究产生积极影响为了支持我们的使命。组建了一支领先的专家团队，用他们自己的蛋白质系统测试我们的平台。