Long-range distance measurements in proteins at physiological temperatures using saturation recovery EPR spectroscopy

  1. Yang, Z. 2
  2. Jiménez-Osés, G. 2
  3. López, Carlos .J. 2
  4. Bridges, M.D. 1
  5. Houk, K.N. 2
  6. Hubbell, W.L. 2
  1. 1 California State University, Fullerton
    info

    California State University, Fullerton

    Fullerton, Estados Unidos

    ROR https://ror.org/02avqqw26

  2. 2 University of California Los Angeles
    info

    University of California Los Angeles

    Los Ángeles, Estados Unidos

    ROR https://ror.org/046rm7j60

Revista:
Journal of the American Chemical Society

ISSN: 0002-7863

Ano de publicación: 2014

Volume: 136

Número: 43

Páxinas: 15356-15365

Tipo: Artigo

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DOI: 10.1021/JA5083206 SCOPUS: 2-s2.0-84908636987 WoS: WOS:000344042900036 GOOGLE SCHOLAR

Outras publicacións en: Journal of the American Chemical Society

Repositorio institucional: lock_openAcceso aberto Editor

Resumo

Site-directed spin labeling in combination with EPR is a powerful method for providing distances on the nm scale in biological systems. The most popular strategy, double electron-electron resonance (DEER), is carried out at cryogenic temperatures (50-80 K) to increase the short spin-spin relaxation time (T2) upon which the technique relies. A challenge is to measure long-range distances (20-60 Å) in proteins near physiological temperatures. Toward this goal we are investigating an alternative approach based on the distance-dependent enhancement of spin-lattice relaxation rate (T1 -1) of a nitroxide spin label by a paramagnetic metal. With a commonly used nitroxide side chain (R1) and Cu2+, it has been found that interspin distances 25 Å can be determined in this way (Jun et al. Biochemistry 2006, 45, 11666). Here, the upper limit of the accessible distance is extended to ≈40 Å using spin labels with long T1, a high-affinity 5-residue Cu2+ binding loop inserted into the protein sequence, and pulsed saturation recovery to measure relaxation enhancement. Time-domain Cu2+ electron paramagnetic resonance, quantum mechanical calculations, and molecular dynamics simulations provide information on the structure and geometry of the Cu2+ loop and indicate that the metal ion is well-localized in the protein. An important aspect of these studies is that both Cu2+/nitroxide DEER at cryogenic temperatures and T1 relaxation measurements at room temperature can be carried out on the same sample, allowing both validation of the relaxation method and assessment of the effect of freezing on protein structure. © 2014 American Chemical Society.