Fluorescence emission properties of various derivatives of Octopus vulgaris hemocyanin, namely, oxy, deoxy, met, half-met, half-apo, and apo derivatives, are studied by means of time-resolved and quenching techniques. Fluorescence decay can be satisfactorily fitted by two-exponential analysis in all hemocyanin derivatives. Fluorescence quenching experiments, using acrylamide, iodide, and a combination of the two, are carried out in order to correlate the observed lifetimes with different classes of fluorophores, distinguishable by their accessibility to the external quenchers. Fluorescence lifetimes of 1.2, 2.1, and 5.5 ns are attributed to buried, partially exposed, and fully exposed tryptophans, respectively, in 11s hemocyanin at pH 8.5. For 50s hemocyanin, the lifetime pattern is very similar, but a shortening of all lifetime values is observed. The fluorescence of the class of partially exposed tryptophans, situated in close proximity to the active site, is totally quenched in oxy-, met-, and half-methemocyanin. Our results rule out a Forster-type energy-transfer process from excited tryptophans to the copper-peroxide complex as a major quenching mechanism accounting for the lower quantum yield of oxyhemocyanin as compared to the deoxy and apo forms. “Heavy atom” and “paramagnetic ionn effects, due to the bound copper, fully explain the observed finding. Thus, the application of Forster’s theory to calculate the tryptophan active site average distance in oxyhemocyanin is not justified. Plausible values (r = 1.5 nm) are obtained by applying Forster’s theory to the complexes of hemocyanin with carbon monoxide or 1 -anilino-8-naphthalenesulfonate.

EMISSION QUENCHING MECHANISMS IN OCTOPUS-VULGARIS HEMOCYANIN - STEADY-STATE AND TIME-RESOLVED FLUORESCENCE STUDIES

BELTRAMINI, MARIANO;
1987

Abstract

Fluorescence emission properties of various derivatives of Octopus vulgaris hemocyanin, namely, oxy, deoxy, met, half-met, half-apo, and apo derivatives, are studied by means of time-resolved and quenching techniques. Fluorescence decay can be satisfactorily fitted by two-exponential analysis in all hemocyanin derivatives. Fluorescence quenching experiments, using acrylamide, iodide, and a combination of the two, are carried out in order to correlate the observed lifetimes with different classes of fluorophores, distinguishable by their accessibility to the external quenchers. Fluorescence lifetimes of 1.2, 2.1, and 5.5 ns are attributed to buried, partially exposed, and fully exposed tryptophans, respectively, in 11s hemocyanin at pH 8.5. For 50s hemocyanin, the lifetime pattern is very similar, but a shortening of all lifetime values is observed. The fluorescence of the class of partially exposed tryptophans, situated in close proximity to the active site, is totally quenched in oxy-, met-, and half-methemocyanin. Our results rule out a Forster-type energy-transfer process from excited tryptophans to the copper-peroxide complex as a major quenching mechanism accounting for the lower quantum yield of oxyhemocyanin as compared to the deoxy and apo forms. “Heavy atom” and “paramagnetic ionn effects, due to the bound copper, fully explain the observed finding. Thus, the application of Forster’s theory to calculate the tryptophan active site average distance in oxyhemocyanin is not justified. Plausible values (r = 1.5 nm) are obtained by applying Forster’s theory to the complexes of hemocyanin with carbon monoxide or 1 -anilino-8-naphthalenesulfonate.
1987
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11577/132545
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