Unfolding of acrylodan-labeled human serum albumin probed by steady-state and time-resolved fluorescence methods.

Steady-state and time-resolved fluorescence spectroscopy was used to follow the local and global changes in structure and dynamics during chemical and thermal denaturation of unlabeled human serum albumin (HSA) and HSA with an acrylodan moiety bound to Cys34. Acrylodan fluorescence was monitored to obtain information about unfolding processes in domain I, and the emission of the Trp residue at position 214 was used to examine domain II. In addition, Trp-to-acrylodan resonance energy transfer was examined to probe interdomain spatial relationships during unfolding. Increasing the temperature to less than 50 degrees C or adding less than 1.0 M GdHCl resulted in an initial, reversible separation of domains I and II. Denaturation by heating to 70 degrees C or by adding 2.0 M GdHCl resulted in irreversible unfolding of domain II. Further denaturation of HSA by either method resulted in irreversible unfolding of domain I. These results clearly demonstrate that HSA unfolds by a pathway involving at least three distinct steps. The low detection limits and high information content of dual probe fluorescence should allow this technique to be used to study the unfolding behavior of entrapped or immobilized HSA.

[1]  G. Sudlow,et al.  Further characterization of specific drug binding sites on human serum albumin. , 1976, Molecular pharmacology.

[2]  D. Epps,et al.  Site-specific chemical modification of interleukin-1 beta by acrylodan at cysteine 8 and lysine 103. , 1992, The Journal of biological chemistry.

[3]  M. J. Crooks,et al.  Displacement of tolbutamide, glibencalmide and chlorpropamide from serum albumin by anionic drugs. , 1976, Biochemical pharmacology.

[4]  G. Picó Thermodynamic features of the thermal unfolding of human serum albumin. , 1997, International journal of biological macromolecules.

[5]  L. Burtnick,et al.  Fluorescence of equine platelet tropomyosin labeled with acrylodan. , 1988, Archives of biochemistry and biophysics.

[6]  J. Zaroslinski,et al.  Protein binding methodology: comparison of equilibrium dialysis and frontal analysis chromatography in the study of salicylate binding. , 1972, Analytical biochemistry.

[7]  J. Behlke,et al.  Temperature behaviour of human serum albumin. , 1980, European journal of biochemistry.

[8]  M. Siddiqui,et al.  Experimental determination of the free energy of unfolding of proteins , 1995 .

[9]  D C Carter,et al.  Structure of serum albumin. , 1994, Advances in protein chemistry.

[10]  M. Rothschild,et al.  Albumin: Structure, Function and Uses , 1977 .

[11]  James R. Brown SERUM ALBUMIN: AMINO ACID SEQUENCE , 1977 .

[12]  R. Wang,et al.  Dynamics surrounding Cys-34 in native, chemically denatured, and silica-adsorbed bovine serum albumin. , 1995, Analytical chemistry.

[13]  C A Ghiron,et al.  Exposure of tryptophanyl residues in proteins. Quantitative determination by fluorescence quenching studies. , 1976, Biochemistry.

[14]  J. Chmelík,et al.  4.50—Polarographic investigation of conformational changes of human serum albumin: Part I. Unfolding of human serum albumin by urea☆ , 1982 .

[15]  J. Lakowicz,et al.  Quenching of fluorescence by oxygen. A probe for structural fluctuations in macromolecules. , 1973, Biochemistry.

[16]  M. Otagiri,et al.  Probing the cysteine 34 residue in human serum albumin using fluorescence techniques. , 1997, Biochimica et biophysica acta.

[17]  J. Potter,et al.  Synthesis, spectral properties, and use of 6-acryloyl-2-dimethylaminonaphthalene (Acrylodan). A thiol-selective, polarity-sensitive fluorescent probe. , 1983, The Journal of biological chemistry.

[18]  D. W. Bolen,et al.  Unfolding free energy changes determined by the linear extrapolation method. 1. Unfolding of phenylmethanesulfonyl alpha-chymotrypsin using different denaturants. , 1988, Biochemistry.

[19]  B. Farruggia,et al.  Destabilization of human serum albumin by polyethylene glycols studied by thermodynamical equilibrium and kinetic approaches. , 1997, International journal of biological macromolecules.

[20]  D. Jameson,et al.  Time‐resolved fluorescence studies on site‐directed mutants of human serum albumin , 1997, FEBS letters.

[21]  F V Bright,et al.  Accessibility of the fluorescent reporter group in native, silica-adsorbed, and covalently attached acrylodan-labeled serum albumins. , 1996, Analytical chemistry.

[22]  K. Wallevik Reversible denaturation of human serum albumin by pH, temperature, and guanidine hydrochloride followed by optical rotation. , 1973, The Journal of biological chemistry.

[23]  E. R. Birnbaum,et al.  Resonance energy transfer between cysteine-34 and tryptophan-214 in human serum albumin. Distance measurements as a function of pH. , 1983, Biochemistry.

[24]  M. Eftink The use of fluorescence methods to monitor unfolding transitions in proteins. , 1994, Biophysical journal.

[25]  M. Hirose,et al.  Partially folded state of the disulfide-reduced form of human serum albumin as an intermediate for reversible denaturation. , 1992, The Journal of biological chemistry.

[26]  G. Picó Thermodynamic aspects of the thermal stability of human serum albumin. , 1995, Biochemistry and molecular biology international.

[27]  F. G. Prendergast,et al.  Singlet adiabatic states of solvated PRODAN: a semiempirical molecular orbital study , 1989 .

[28]  E. R. Birnbaum,et al.  Resonance energy transfer between cysteine-34, tryptophan-214, and tyrosine-411 of human serum albumin. , 1983, Biochemistry.

[29]  F. Bright,et al.  Dynamics of acrylodan-labeled bovine and human serum albumin sequestered within aerosol-OT reverse micelles. , 1995, Analytical chemistry.

[30]  S. Saavedra,et al.  Spectroscopic characterization of albumin and myoglobin entrapped in bulk sol-gel glasses , 1994 .

[31]  F. Bright,et al.  Dynamics of acrylodan-labeled bovine and human serum albumin entrapped in a sol-gel-derived biogel. , 1995, Analytical chemistry.

[32]  J. Brennan,et al.  Measurement of Fluorescence from Tryptophan To Probe the Environment and Reaction Kinetics within Protein-Doped Sol-Gel-Derived Glass Monoliths. , 1997, Analytical chemistry.

[33]  D. O'connor,et al.  Time-Correlated Single Photon Counting , 1984 .