Vladimir V. Filimonov scite author profile

The folding and unfolding reactions of the SH3 domain of spectrin can be described by a two-state model. This domain is a beta-sheet barrel containing 62 amino acids. Equilibrium unfolding by urea, guanidine hydrochloride, and heat is completely reversible at pH values below 4.0. At higher pH values the unfolding is reversible as long as the protein concentration is below 1 mg/mL. The Gibbs energy of unfolding in the absence of denaturant, delta GH2O, at pH 3.5 and 298 K is calculated to be 12 kJ mol-1 for urea, chemical, and temperature denaturation. The stability of the protein does not change noticeably between pH 5.0 and 7.0 and is around 15.5 kJ mol-1. Since heat effects of unfolding are relatively small and, as a result, heat-induced melting occurs in a wide temperature range, the analysis of scanning calorimetry data was performed taking into account the temperature dependence of unfolding delta Cp. The free energy of unfolding obtained for this domain (delta GH2O = 14 +/- 2 kJ mol-1) was, within experimental error, similar to those obtained in this work by other techniques and with those reported in the literature for small globular proteins. Kinetics of unfolding and refolding at pH 3.5, followed both by fluorescence and by circular dichroism, provide evidence of the simplest folding mechanism consistent with the two-state approximation. A value for delta GH2O = 13 +/- 0.7 kJ mol-1 can be extrapolated from the kinetic data.(ABSTRACT TRUNCATED AT 250 WORDS)

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Protein engineering as a strategy to avoid formation of amyloid fibrils

Villegas

Zurdo²,

et al. 2000

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The activation domain of human procarboxypeptidase A2~ADA2h! aggregates following thermal or chemical denaturation at acidic pH. The aggregated material contains well-defined ordered structures with all the characteristics of the fibrils associated with amyloidotic diseases. Variants of ADA2h containing a series of mutations designed to increase the local stability of each of the two helical regions of the protein have been found to have a substantially reduced propensity to form fibrils. This arises from a reduced tendency of the denatured species to aggregate rather than from a change in the overall stability of the native state. The reduction in aggregation propensity may result from an increase in the stability of local relative to longer range interactions within the polypeptide chain. These findings show that the intrinsic ability of a protein to form amyloid can be altered substantially by protein engineering methods without perturbing significantly its overall stability or activity. This suggests new strategies for combating diseases associated with the formation of aggregated proteins and for the design of novel protein or peptide therapeutics.

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Thermodynamic analysis of the chemotactic protein from Escherichia coli, CheY

Filimonov

Prieto²,

Martínez³

et al. 1993

Biochemistry

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CheY, the 129 amino acid chemotactic protein from Escherichia coli, is a good model for studies of folding of parallel alpha/beta proteins. We report here the thermodynamic characterization of the wild-type CheY at different pH values and in different buffers and denaturation conditions. The denaturation of CheY by urea monitored by circular dichroism and fluorescence fits the two-state unfolding model. The stability of the protein is ionic strength dependent, probably due to the presence of three Asp residues in very close proximity in its active site. The presence of a Mg2+ ion, which seems to interact with Asp 13 in the active site, stabilizes the native structure by up to 6.9 kJ mol-1. The CheY maximum stability (31.7 +/- 2.1 kJ mol-1), without magnesium, is reached at pH 5.1. Analysis of scanning calorimetry data has shown that temperature-induced unfolding of CheY is not a two-state process and proceeds through a highly populated intermediate state, corresponding to protein dimers, as was subsequently confirmed by direct cross-linking experiments. According to circular dichroism, fluorescence, nuclear magnetic resonance, and ANS binding experiments, this "intermediate dimer" at pH 2.5 exhibits all known characteristics of the "molten globule" state. The reversible dimerization of "molten globules" might explain such peculiarities as the increased stability or the cooperative unfolding found for the molten globule state of some proteins.

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A Calorimetric Study of the Thermal Stability of Barnase and Its Interaction with 3'GMP

Martínez¹,

Harrous²,

Filimonov³

et al. 1994

Biochemistry

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We have used high-sensitivity differential scanning calorimetry to characterize the thermal stability of barnase from Bacillus amyloliquefaciens in the pH range 2.0-5.0. The energetics of the interaction between barnase and its inhibitor 3'GMP have been studied by isothermal titration calorimetry in the temperature range 15-30 degrees C. Scanning calorimetry experiments were also made with the protein in the presence of various concentrations of 3'GMP at pH 4.5. A novel, simple procedure is proposed to obtain binding parameters from scanning calorimetry data. This method is based on the calculation of the partition functions of the free and the ligand-bound protein. Isothermal calorimetry shows that at 25 degrees C 3'GMP binds to a single site in barnase with a delta Cp of -250 +/- 50 J/(K.mol). Both free barnase and ligand-bound barnase undergo a highly reversible, two-state thermal unfolding process under our experimental conditions. delta G and delta Cp unfolding values are similar to others found for globular proteins, whereas delta H and delta S unfolding values are unusually high at the denaturation temperature of barnase. We have also found unexpectedly that the thermodynamic unfolding parameters of barnase fit neither the trend of values described in the literature for the correlation between delta Cp and delta H nor the limiting specific enthalpy value in the correlation between delta H and Tm for globular proteins. These discrepancies might be related to particular features of the folded and/or unfolded states of the protein.

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Thermodynamic analysis of transfer RNA unfolding

Privalov¹,

Filimonov²

1978

Journal of Molecular Biology

113

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