TY - JOUR
T1 - Multiple probes reveal a native-like intermediate during low-temperature refolding of ubiquitin
AU - Larios, E.
AU - Li, J. S.
AU - Schulten, K.
AU - Kihara, H.
AU - Gruebele, M.
N1 - Funding Information:
H.K. was supported by the Japan-US Cooperative Science program. M.G. was supported by National Science Foundation grant NSF MCB-0316925. Travel of M.G. & E.L. to the Photon Factory was supported by National Science Foundation grant NSF INT-0089286. K.S. was supported by National Institutes of Health P41 RR05969-05, and by NRAC grant MCA 935028. Beam time at the Photon Factory was supported by Proposal no. 2000G330. E.L. was supported by a Beckman Institute Fellowship in addition to the funding sources of M.G. & K.S.
PY - 2004/6/25
Y1 - 2004/6/25
N2 - We investigate the refolding of ubiquitin Phe45Trp/Ile61Ala (Ub *I61A) in a low-temperature, high-viscosity buffer, where folding is slowed so that apparent two-state and three-state mechanisms are readily distinguishable. Ub*I61A forms a compact ensemble rapidly (as judged from stopped-flow, small-angle X-ray scattering) with a secondary structure signature similar to that of the native state (as judged from stopped-flow circular dichroism from 215 nm to 250 nm), but the fluorescence signature still resembles the guanidinium-denatured state. The compact ensemble forms over a range of solvent and temperature conditions. The native fluorescence signature, which requires the tryptophan residue to be packed tightly, is acquired at least 500 times more slowly. Molecular dynamics simulations at 495 K show no contraction of the backbone in ethylene glycol buffer compared to pure aqueous buffer, and no significant effect on the local backbone structure of the unfolded protein. Only at higher simulation temperature does a backbone contraction appear. Thus, it appears unlikely that the aqueous ethylene glycol buffer fundamentally changes the folding mechanism of ubiquitin. We suggest that ubiquitin forms a compact ensemble with native-like secondary structure, but without tight packing, long before the native state.
AB - We investigate the refolding of ubiquitin Phe45Trp/Ile61Ala (Ub *I61A) in a low-temperature, high-viscosity buffer, where folding is slowed so that apparent two-state and three-state mechanisms are readily distinguishable. Ub*I61A forms a compact ensemble rapidly (as judged from stopped-flow, small-angle X-ray scattering) with a secondary structure signature similar to that of the native state (as judged from stopped-flow circular dichroism from 215 nm to 250 nm), but the fluorescence signature still resembles the guanidinium-denatured state. The compact ensemble forms over a range of solvent and temperature conditions. The native fluorescence signature, which requires the tryptophan residue to be packed tightly, is acquired at least 500 times more slowly. Molecular dynamics simulations at 495 K show no contraction of the backbone in ethylene glycol buffer compared to pure aqueous buffer, and no significant effect on the local backbone structure of the unfolded protein. Only at higher simulation temperature does a backbone contraction appear. Thus, it appears unlikely that the aqueous ethylene glycol buffer fundamentally changes the folding mechanism of ubiquitin. We suggest that ubiquitin forms a compact ensemble with native-like secondary structure, but without tight packing, long before the native state.
KW - CD, circular dichroism
KW - kinetic intermediate
KW - MD, molecular dynamics
KW - protein folding
KW - SAXS, small-angle X-ray scattering
KW - side-chain packing barrier
KW - topological barrier
KW - two-state/three-state
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U2 - 10.1016/j.jmb.2004.04.048
DO - 10.1016/j.jmb.2004.04.048
M3 - Article
C2 - 15184026
AN - SCOPUS:2942623941
SN - 0022-2836
VL - 340
SP - 115
EP - 125
JO - Journal of Molecular Biology
JF - Journal of Molecular Biology
IS - 1
ER -