pH-induced conformational changes in spinach ferredoxin: steady-state and time-resolved fluorescence studies

Adsorption-Induced Conformational Changes in the Serine Proteinase Savinase: A Tryptophan Fluorescence and Circular Dichroism Study

In this paper spectroscopic data of a proteolytic enzyme adsorbed on solid-liquid interfaces are discussed. The experiments consisted of time-resolved and steady-state fluorescence of tryptophan residues and of circular dichroism (CD) which give information on the tertiary and secondary state of the protein, respectively. The spectroscopic properties are measured for the inhibited form of subtilisin 309 in situ on a hydrophilic silica surface and on a hydrophobic Teflon surface. The results are compared with those obtained for the protein in solution. In the case of fluorescence it is reasoned that the average excited-state lifetime and short internal rotation correlation times are indicative parameters for structural changes in the protein. The internal rotation is superimposed on the rotation of the adsorbed protein which is immobile on the fluorescence time scale. Fluorescence and CD both prove that the protein alters its conformation when it adsorbs at low surface coverage on hydrophobic Teflon particles. In that case the tryptophan fluorescence lifetime is shortened which is accompanied by an increase in the alpha-helix content. At monolayer coverage the protein maintains its original structure, although minor changes in fluorophore dynamics occur. On hydrophilic silica particles the results from both techniques do not point in the same direction. The fluorescence was not affected, irrespective of the surface occupation, while the CD experiments show a decrease in alpha-helix content at low surface coverage. Copyright 1997 Academic Press.

Properties of the soluble polypeptide of the proton-translocating transhydrogenase from Rhodospirillum rubrum obtained by expression in Escherichia coli

Transhydrogenase, which catalyses the reduction of NADP+ by NADH coupled to proton translocation across a membrane, may be unique in the photosynthetic bacterium Rhodospirillum rubrum. Unlike the homologous enzyme from animal mitochondria and other bacterial sources, it has a water-soluble polypeptide, which exists as a dimer (Ths), that can be reversibly dissociated from the membrane component [Williams, R., Cotton, N. P. J., Thomas, C. M. & Jackson, J. B. (1994) Microbiology, 140, 1595-1604]. We have expressed the gene for Ths in cells of Escherichia coli under control of the tac promoter and a strong ribosome binding site. The protein, purified by column chromatography, fully reconstituted transhydrogenation activity to everted membrane vesicles of Rhs. rubrum that had been washed to remove Ths. The purified expressed protein was prepared in quantities over 100-fold greater than were obtained from wild-type Rhs. rubrum. The fluorescence spectrum of purified expressed Ths had an intense and unusually short wavelength emission maximum at 310 nm with shoulders at 298 and 322 nm. Time-resolved measurements indicated that the fluorescence decay was almost monoexponential with a lifetime of 5.2 ns. On denaturation with 4 M guanidine hydrochloride, the emission band shifted to 352 nm and decreased in intensity. In the native protein, the fluorophore was relatively inaccessible to quenching solutes, such as iodide ions and acrylamide. It is concluded that the fluorescence emission arises mainly from the single tryptophan residue of Ths (Trp72), which is locked into a rigid conformation and is located in highly non-polar environment. The 310-nm fluorescence of Ths was quenched by NADH, maximally to 46%. The apparent binding constant was 18 microM. The fluorescence of Ths-bound NADH was enhanced relative to the nucleotide in free solution and its emission maximum was shifted to a shorter wavelength (440 nm). These data support previous indications that the NADH binding site is located in domain I of proton-translocating transhydrogenase. Excitation of Ths at 280 nm did not lead to sensitized emission at 440 nm from bound NADH. This indicates that the quenching of fluorescence of Ths by NADH does not result from resonance energy transfer from Trp72 to the bound nucleotide. NAD+, NADP+ and NADPH had little effect on the protein fluorescence. The kinetics of quenching of Ths fluorescence by NADH were examined after mixing in a stopped-flow device. The 'on' rate constant for nucleotide binding was approximately 8 x 10(6) M-1 s-1 and the 'off' constant approximately 150 s-1.

A comparative picosecond-resolved fluorescence study of tryptophan residues in iron-sulfur proteins

The fluorescence intensity and anisotropy decays of the intrinsic tryptophan emission from six Fe/S proteins (ranging from the very simplest ones to enzyme complexes containing one, two or more Trp residues) were measured. All proteins were examined in the reduced and the oxidized state. In either redox state each protein exhibits ultrarapid tryptophan fluorescence decay on the picosecond timescale contributing up to 93% of the total decay. Correlation times in the range of 1 ns or less were found for all six iron-sulfur proteins reflecting internal Trp motion. In addition, some proteins exhibit longer correlation times reflecting segmental motion and overall protein tumbling. The ultrarapid fluorescence decay in iron-sulfur proteins indicates efficient radiationless energy transfer between distant tryptophan residues and iron-sulfur clusters. Such an energy transfer mechanism can be accounted for by referring to the three-dimensional structures of rubredoxin and ferredoxin in calculating the transfer efficiency of the single tryptophan-iron-sulfur couple.