TY - JOUR
T1 - Backbone dynamics of the cytotoxic Ribonuclease α-sarcin by 15N NMR
AU - Pérez-Cañadillas, J.M.
AU - Guenneugues, M.N.L.
AU - Campos-Olivas, R.
AU - Santoro, J.
AU - Martínez del Pozo, A.
AU - Gavilanes, J.G.
AU - Rico, M.
AU - Bruix, M.
PY - 2002
Y1 - 2002
N2 - The cytotoxic ribonuclease α-sarcin is a 150-residue protein that inactivates ribosomes by selectively cleaving a
single phosphodiester bond in a strictly conserved rRNA loop. In order to gain insights on the molecular basis of its
highly specific activity, we have previously determined its solution structure and studied its electrostatics properties.
Here, we complement those studies by analysing the backbone dynamics of α-sarcin through measurement of
longitudinal relaxation rates R1, off resonance rotating frame relaxation rates R1ρ, and the 15N{1H} NOE of the
backbone amide 15N nuclei at two different magnetic field strengths (11.7 and 17.6 T). The two sets of relaxation
parameters have been analysed in terms of the reduced spectral density mapping formalism, as well as by the
model-free approach. α-Sarcin behaves as an axial symmetric rotor of the prolate type (D /D⊥ = 1.16 ± 0.02)
which tumbles with a correlation time τm of 7.54 ± 0.02 ns. The rotational diffusion properties have been also
independently evaluated by hydrodynamic calculations and are in good agreement with the experimental results.
The analysis of the internal dynamics reveals that α-sarcin is composed of a rigid hydrophobic core and some
exposed segments which undergo fast (ps to ns) internal motions. Slower motions in the μs to ms time scale are
less abundant and in some cases can be assigned to specific motional processes. All dynamic data are discussed in
relation to the role of some particular residues of α-sarcin in the process of recognition of its ribosomal target.
AB - The cytotoxic ribonuclease α-sarcin is a 150-residue protein that inactivates ribosomes by selectively cleaving a
single phosphodiester bond in a strictly conserved rRNA loop. In order to gain insights on the molecular basis of its
highly specific activity, we have previously determined its solution structure and studied its electrostatics properties.
Here, we complement those studies by analysing the backbone dynamics of α-sarcin through measurement of
longitudinal relaxation rates R1, off resonance rotating frame relaxation rates R1ρ, and the 15N{1H} NOE of the
backbone amide 15N nuclei at two different magnetic field strengths (11.7 and 17.6 T). The two sets of relaxation
parameters have been analysed in terms of the reduced spectral density mapping formalism, as well as by the
model-free approach. α-Sarcin behaves as an axial symmetric rotor of the prolate type (D /D⊥ = 1.16 ± 0.02)
which tumbles with a correlation time τm of 7.54 ± 0.02 ns. The rotational diffusion properties have been also
independently evaluated by hydrodynamic calculations and are in good agreement with the experimental results.
The analysis of the internal dynamics reveals that α-sarcin is composed of a rigid hydrophobic core and some
exposed segments which undergo fast (ps to ns) internal motions. Slower motions in the μs to ms time scale are
less abundant and in some cases can be assigned to specific motional processes. All dynamic data are discussed in
relation to the role of some particular residues of α-sarcin in the process of recognition of its ribosomal target.
M3 - Article
SN - 0925-2738
VL - 24
SP - 301
EP - 316
JO - Journal of Biomolecular NMR
JF - Journal of Biomolecular NMR
IS - 2
ER -