Mingzhang Wang scite author profile

The recent breakthroughs in NMR probe technologies resulted in the development of MAS NMR probes with rotation frequencies exceeding 100 kHz. Herein, we explore dramatic increases in sensitivity and resolution observed at MAS frequencies of 110–111 kHz in a novel 0.7 mm HCND probe that enable structural analysis of fully protonated biological systems. Proton-detected 2D and 3D correlation spectroscopy under such conditions requires only 0.1 – 0.5 mg of sample and a fraction of time compared to conventional 13C-detected experiments. We discuss the performance of several proton- and heteronuclear- (13C-,15N-) based correlation experiments in terms of sensitivity and resolution, using a model microcrystalline fMLF tripeptide. We demonstrate the applications of ultrafast MAS to a large, fully protonated protein assembly of the 231-residue HIV-1 CA capsid protein. Resonance assignments of protons and heteronuclei, as well as 1H-15N dipolar and 1HN CSA tensors are readily obtained from the high sensitivity and resolution proton-detected 3D experiments. The approach demonstrated here is expected to enable the determination of atomic-resolution structures of large protein assemblies, inaccessible by current methodologies.

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Fast Magic‐Angle Spinning ¹⁹F NMR Spectroscopy of HIV‐1 Capsid Protein Assemblies

Wang

Fritz

et al. 2018

Angew Chem Int Ed

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F NMR spectroscopy is an attractive and growing area of research with broad applications in biochemistry, chemical biology, medicinal chemistry, and materials science. We have explored fast magic angle spinning (MAS) F solid-state NMR spectroscopy in assemblies of HIV-1 capsid protein. Tryptophan residues with fluorine substitution at the 5-position of the indole ring were used as the reporters. The F chemical shifts for the five tryptophan residues are distinct, reflecting differences in their local environment. Spin-diffusion and radio-frequency-driven-recoupling experiments were performed at MAS frequencies of 35 kHz and 40-60 kHz, respectively. Fast MAS frequencies of 40-60 kHz are essential for consistently establishing F- F correlations, yielding interatomic distances of the order of 20 Å. Our results demonstrate the potential of fast MAS F NMR spectroscopy for structural analysis in large biological assemblies.

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Quenching protein dynamics interferes with HIV capsid maturation

et al. 2017

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Maturation of HIV-1 particles encompasses a complex morphological transformation of Gag via an orchestrated series of proteolytic cleavage events. A longstanding question concerns the structure of the C-terminal region of CA and the peptide SP1 (CA–SP1), which represents an intermediate during maturation of the HIV-1 virus. By integrating NMR, cryo-EM, and molecular dynamics simulations, we show that in CA–SP1 tubes assembled in vitro, which represent the features of an intermediate assembly state during maturation, the SP1 peptide exists in a dynamic helix–coil equilibrium, and that the addition of the maturation inhibitors Bevirimat and DFH-055 causes stabilization of a helical form of SP1. Moreover, the maturation-arresting SP1 mutation T8I also induces helical structure in SP1 and further global dynamical and conformational changes in CA. Overall, our results show that dynamics of CA and SP1 are critical for orderly HIV-1 maturation and that small molecules can inhibit maturation by perturbing molecular motions.

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Mingzhang Wang

Expanding the horizons for structural analysis of fully protonated protein assemblies by NMR spectroscopy at MAS frequencies above 100 kHz

Fast Magic‐Angle Spinning ¹⁹F NMR Spectroscopy of HIV‐1 Capsid Protein Assemblies

Quenching protein dynamics interferes with HIV capsid maturation

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Mingzhang Wang

Expanding the horizons for structural analysis of fully protonated protein assemblies by NMR spectroscopy at MAS frequencies above 100 kHz

Fast Magic‐Angle Spinning 19F NMR Spectroscopy of HIV‐1 Capsid Protein Assemblies

Quenching protein dynamics interferes with HIV capsid maturation

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Fast Magic‐Angle Spinning ¹⁹F NMR Spectroscopy of HIV‐1 Capsid Protein Assemblies