Protein folding denaturation kinetics

Measuring Protein Sta.bihty, Protein stabihty is usually measured quantitatively as the difference in free energy between the folded and unfolded states of the protein. These states are most commonly measured using spectroscopic techniques, such as circular dichroic spectroscopy, fluorescence (generally tryptophan fluorescence) spectroscopy, nmr spectroscopy, and absorbance spectroscopy (10). For most monomeric proteins, the two-state model of protein folding can be invoked. This model states that under equihbrium conditions, the vast majority of the protein molecules in a solution exist in either the folded (native) or unfolded (denatured) state. Any kinetic intermediates that might exist on the pathway between folded and unfolded states do not accumulate to any significant extent under equihbrium conditions (39). In other words, under any set of solution conditions, at equihbrium the entire population of protein molecules can be accounted for by the mole fraction of denatured protein, and the mole fraction of native protein,, ie. 

The steps leading to the formation of the intrinsic chro-mophore have recently been investigated kinetically with S65T-GFP. The process of chromophore formation is an ordered sequence of three distinct steps (1) slow protein folding (kf = 2.44 X 10 s ) that precedes chromophore modification (2) an intermediate step occurs that includes, but may not be necessarily limited to, cycli-zation of the tripeptide chromophore motif (kc = 3.8 X 10 s ) and (3) rate-limiting oxidation of the cyclized chromophore (kox = 1 51 X s ). Reid and Flynn also reasoned that because chromophore forms de novo from purified denatured protein and is a first-order process, GFP chromophore formation is likely to be an autocatalytic process. 

T4 lysozyme 33,497 helix stability of 528, 529 hydrophobic core stability of 533, 544 Tanford j8 value 544, 555, 578, 582-Temperature jump 137, 138, 541 protein folding 593 Terminal transferase 408,410 Ternary complex 120 Tertiary structure 22 Theorell-Chance mechanism 120 Thermodynamic cycles 125-131 acid denaturation 516,517 alchemical steps 129 double mutant cycles 129-131, 594 mutant cycles 129 specificity 381, 383 Thermolysin 22, 30,483-486 Thiamine pyrophosphate 62, 83 - 84 Thionesters 478 Thiol proteases 473,482 TNfn3 domain O-value analysis 594 folding kinetics 552 Torsion angle 16-18 Tbs-L-phenylalanine chloromethyl ketone (TPCK) 278, 475 Transaldolase 79 Tyransducin-o 315-317 Transit time 123-125 Transition state 47-49 definition 55... 

Although copper binds tighter than zinc to aU forms of the enzyme tested, zinc stabilizes the protein fold better as judged by solvent-induced denaturation experiments. In addition the dissociation rate constant for zinc is about 100 times slower than copper suggesting the zinc is kinetically trapped once folding has occurred. This may thus be a physiological means by which metal ion specificity is achieved. ... 

Folding of proteins. The primary structure of a protein dictates the way that it folds into its tertiary structure, which is a stable conformation that is identical to the shape of other molecules of the same protein (that is, its native conformation.) Chaperonins act as templates to overcome the kinetic barrier to reaching a stable conformation. Prion proteins cause neurodegenerative diseases by acting as a template for mi folding. Heat, acid, and other agents cause proteins to denature, that is, to unfold or refold and lose their native three-dimensional conformation. 

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