Characterization of in vitro oxidized barstar

AbstractThe polypeptide inhibitor of the ribonuclease barnase, barstar, has two cysteine residues in positions 40 and 82. These have been proposed to form a disulfide bridge leading to an increase in stability without changing the inhibitory activity of the protein. Barstar and a mutant (E80A) were oxidized in vitro and the biochemical and physico-chemical properties of the oxidized monomers were analysed. The oxidized proteins show no inhibition of barnase using a plate assay and are significantly destabilized. CD spectra indicate a loss of secondary structure. The amino acid substitution E80 → A stabilizes the oxidized barstar to about the same extent as it does the reduced protein, indicating, however, that the helical region which it is in is intact

Chaperone activity and structure of monomeric polypeptide binding domains of GroEL

The chaperonin GroEL is a large complex composed of 14 identical 57-kDa subunits that requires ATP and GroES for some of its activities. We find that a monomeric polypeptide corresponding to residues 191 to 345 has the activity of the tetradecamer both in facilitating the refolding of rhodanese and cyclophilin A in the absence of ATP and in catalyzing the unfolding of native barnase. Its crystal structure, solved at 2.5 A resolution, shows a well-ordered domain with the same fold as in intact GroEL. We have thus isolated the active site of the complex allosteric molecular chaperone, which functions as a "minichaperone." This has mechanistic implications: the presence of a central cavity in the GroEL complex is not essential for those representative activities in vitro, and neither are the allosteric properties. The function of the allosteric behavior on the binding of GroES and ATP must be to regulate the affinity of the protein for its various substrates in vivo, where the cavity may also be required for special functions

Unfolding Rates for the Diffusion-Collision Model

In the diffusion-collision model, the unfolding rates are given by the likelihood of secondary structural cluster dissociation. In this work, we introduce an unfolding rate calculation for proteins whose secondary structural elements are $\alpha$-helices, modeled from thermal escape over a barrier which arises from the free energy in buried hydrophobic residues. Our results are in good agreement with currently accepted values for the attempt rate.Comment: Shorter version of cond-mat/0011024 accepted for publication in PR

Structural basis for inhibition of the histone chaperone activity of SET/TAF-Iß by cytochrome c

Chromatin is pivotal for regulation of the DNA damage process insofar as it influences access to DNA and serves as a DNA repair docking site. Recent works identify histone chaperones as key re- gulators of damaged chromatin’s transcriptional activity. However, understanding how chaperones are modulated during DNA damage response is still challenging. This study reveals that the histone chap- erone SET/TAF-Iß interacts with cytochrome c following DNA damage. Specifically, cytochrome c is shown to be translocated into cell nuclei upon induction of DNA damage, but not upon stimulation of the death receptor or stress-induced pathways. Cytochrome c was found to competitively hinder binding of SET/TAF-Iß to core histones, thereby locking its histone-binding domains and inhibiting its nucle- osome assembly activity. In addition, we have used NMR spectros- copy, calorimetry, mutagenesis, and molecular docking to provide an insight into the structural features of the formation of the complex between cytochrome c and SET/TAF-Iß. Overall, these findings estab- lish a framework for understanding the molecular basis of cyto- chrome c-mediated blocking of SET/TAF-Iß, which subsequently may facilitate the development of new drugs to silence the oncogenic effect of SET/TAF-Iß’s histone chaperone activity

Rate of isomerisation of peptidyl-proline bonds as a probe for interactions in the physiological denatured state of chymotrypsin inhibitor 2

10.1006/jmbi.1997.1043Journal of Molecular Biology2694611-622JMOB

Formation of short-lived protein aggregates directly from the coil in two-state folding

10.1021/bi9909997Biochemistry384013006-13012BICH

Correlation of Levels of Folded Recombinant p53 in Escherichia coli with Thermodynamic Stability in Vitro

The amount of folded functional protein in a cell is controlled by a number of factors, including the relative rates of its biosynthetic and specific degradation processes, and its intrinsic thermodynamic stability. Mutationinduced loss of stability is a common cause of disease. Many oncogenic mutants of the tumour suppressor p53, for example, reduce the intrinsic thermodynamic stability of the protein in vitro. We have analysed the level of recombinant folded human p53 core domain (p53C) and its mutants in Escherichia coli spanning a stability range of 6 kcal/mol to assess the effects of intrinsic thermodynamic stability in vivo in the absence of specific ubiquitin-mediated pathways in human cells. The levels of folded protein were measured fluorimetrically in living cells by fusing the gene of p53C upstream to that of green fluorescent protein and measuring the fluorescence relative to a control at various temperatures. At a fixed temperature, the amount of fluorescence is correlated with the thermodynamic stability of the mutant. The level of each protein varied with temperature according to a sigmoid curve that paralleled the melting in vitro, but the apparent Tm was lower in vivo, because steady-state levels are observed rather than true thermodynamic equilibria. Our results show clearly that changes in the intrinsic thermodynamic stability of p53 reduce the level of folded and hence functional p53 substantially in E. coli, and provide insights into the correlation between protein instability and disease at the cellular level

Workshop on protein folding

Centro de Informacion y Documentacion Cientifica (CINDOC). C/Joaquin Costa, 22. 28002 Madrid. SPAIN / CINDOC - Centro de Informaciòn y Documentaciòn CientìficaSIGLEESSpai