TY - JOUR
T1 - Ultrafast electron transfer in the complex between fluorescein and a cognate engineered lipocalin protein, a so-called anticalin
AU - Götz, M.
AU - Hess, S.
AU - Beste, G.
AU - Skerra, A.
AU - Michel-Beyerle, M. E.
PY - 2002/3/26
Y1 - 2002/3/26
N2 - Anticalins are a novel class of engineered ligand-binding proteins with tailored specificities derived from the lipocalin scaffold. The anticalin FluA complexes fluorescein as ligand with high affinity, and it effects almost complete quenching of its steady-state fluorescence. To study the underlying mechanism, we have applied femtosecond absorption spectroscopy, which revealed excited-state electron transfer within the FluA·Fl complex to be responsible for the strong fluorescence quenching. On the basis of a comparison of redox potentials, either tryptophan or tyrosine may serve as electron donor to the bound fluorescein group in its excited singlet state, thus forming the fluorescein trianion radical within 400 fs. The almost monoexponential rate points to a single, well-defined binding site, and its temperature independence suggests an (almost) activationless process. Applying conventional electron transfer theory to the ultrafast forward and slower back-rates, the resulting electronic interaction is rather large, with ∼140 cm-1 for tyrosine, which would be consistent with a coplanar arrangement of both aromatic moieties within van der Waals distance. The weak residual steady-state fluorescence originates from a small (∼10%) component with a time constant in the 40-60 ps range. These results demonstrate the power of timeresolved absorption spectroscopy as a diagnostic tool for the elucidation of a fluorescence quenching mechanism and the temporal profiles of the processes involved. The high structural and dynamic definition of the complexation site suggests the anticalin FluA to be a promising model in order to tailor and probe electronic interactions and energetics in proteins.
AB - Anticalins are a novel class of engineered ligand-binding proteins with tailored specificities derived from the lipocalin scaffold. The anticalin FluA complexes fluorescein as ligand with high affinity, and it effects almost complete quenching of its steady-state fluorescence. To study the underlying mechanism, we have applied femtosecond absorption spectroscopy, which revealed excited-state electron transfer within the FluA·Fl complex to be responsible for the strong fluorescence quenching. On the basis of a comparison of redox potentials, either tryptophan or tyrosine may serve as electron donor to the bound fluorescein group in its excited singlet state, thus forming the fluorescein trianion radical within 400 fs. The almost monoexponential rate points to a single, well-defined binding site, and its temperature independence suggests an (almost) activationless process. Applying conventional electron transfer theory to the ultrafast forward and slower back-rates, the resulting electronic interaction is rather large, with ∼140 cm-1 for tyrosine, which would be consistent with a coplanar arrangement of both aromatic moieties within van der Waals distance. The weak residual steady-state fluorescence originates from a small (∼10%) component with a time constant in the 40-60 ps range. These results demonstrate the power of timeresolved absorption spectroscopy as a diagnostic tool for the elucidation of a fluorescence quenching mechanism and the temporal profiles of the processes involved. The high structural and dynamic definition of the complexation site suggests the anticalin FluA to be a promising model in order to tailor and probe electronic interactions and energetics in proteins.
UR - http://www.scopus.com/inward/record.url?scp=0037177210&partnerID=8YFLogxK
U2 - 10.1021/bi015888y
DO - 10.1021/bi015888y
M3 - Article
C2 - 11900559
AN - SCOPUS:0037177210
SN - 0006-2960
VL - 41
SP - 4156
EP - 4164
JO - Biochemistry
JF - Biochemistry
IS - 12
ER -