Influence of the solvent on the conformational-dependent properties of random-coil polypeptides. I. The mean-square of the end-to-end distance and of the dipole moment

Reactions of dipolar bio-molecules in nano-capsules--example of folding-unfolding process

The confinement of chemical reactions in nano-capsules can lead to a dramatic effect on the equilibrium constant of these latter. Indeed, capillary effects due to the curvature and surface energy of nano-capsules can alter in a noticeable way the evolution of reactions occurring within. Nano-encapsulation of bio-materials has attracted lately wide interest from the scientific community because of the great potential of its applications in biomedical areas and targeted therapies. The present paper focuses one's attention on alterations of conformation mechanisms due to extremely confining and interacting solvated dipolar macromolecules at their isoelectric point. As a specific example studied here, the folding-unfolding reaction of proteins (particularly RNase A and creatine kinase CK) is drastically changed when encapsulated in solid inorganic hollow nano-capsules. The effects demonstrated in this work can be extended to a wide variety of nano-encapsulation situations. The design and sizing of nano-capsules can even make use of the effects shown in the present study to achieve better and more effective encapsulation.

Biophysical characterization of the unstructured cytoplasmic domain of the human neuronal adhesion protein neuroligin 3

Cholinesterase-like adhesion molecules (CLAMs) are a family of neuronal cell adhesion molecules with important roles in synaptogenesis, and in maintaining structural and functional integrity of the nervous system. Our earlier study on the cytoplasmic domain of one of these CLAMs, the Drosophila protein, gliotactin, showed that it is intrinsically unstructured in vitro. Bioinformatic analysis suggested that the cytoplasmic domains of other CLAMs are also intrinsically unstructured, even though they bear no sequence homology to each other or to any known protein. In this study, we overexpress and purify the cytoplasmic domain of human neuroligin 3, notwithstanding its high sensitivity to the Escherichia coli endogenous proteases that cause its rapid degradation. Using bioinformatic analysis, sensitivity to proteases, size exclusion chromatography, fluorescence correlation spectroscopy, analytical ultracentrifugation, small angle x-ray scattering, circular dichroism, electron spin resonance, and nuclear magnetic resonance, we show that the cytoplasmic domain of human neuroligin 3 is intrinsically unstructured. However, several of these techniques indicate that it is not fully extended, but becomes significantly more extended under denaturing conditions.

The carboxy-terminal domain of xeroderma pigmentosum complementation group C protein, involved in TFIIH and centrin binding, is highly disordered

Xeroderma pigmentousum group C protein (XPC) is involved in the first step of nucleotide excision repair, with multiple functional roles including DNA damage recognition and recruitment of the repair machinery. This human protein of 940 residues forms a strong heterotrimeric complex with Rad23B and centrin 2. The structure of XPC is actually not known, and lack of significant sequence homology with proteins from structural data bases precludes any relevant prediction. Here, we present the molecular and structural characterization of a C-terminal fragment of XPC (C-XPC: 126 residues, 815-940), which was shown to be involved in centrin 2 and TFIIH binding. C-XPC may be highly expressed in E. coli, but because of its limited solubility it was purified under 6 M urea. Using bioinformatics tools, and a combination of several experimental methods (circular dichroism, fluorescence, nuclear magnetic resonance, and small-angle X-ray scattering), we show that C-XPC has a highly flexible structure under native physiological conditions, with a propensity to form helical secondary structures. Isothermal titration calorimetry experiments show that the C-XPC fragment binds human centrin 2 with high affinity and a 1:1 stoichiometry. NMR analysis indicates that the physical interaction between C-XPC and centrin 2 induces only minor conformational changes into XPC, localized around the 17-mer segment (847-863), showed to be critically involved in the centrin binding.

Small-angle X-ray scattering reveals an extended organization for the autoinhibitory resting state of the p47(phox) modular protein

In response to microbial infection, neutrophiles promote the assembly of the NADPH oxidase complex in order to produce superoxide anions. This reaction is activated by the association of cytosolic factors, p47(phox), p67(phox), p40(phox), and a small G protein Rac with the membranous heterodimeric flavocytochrome b(558), composed of gp91(phox) and p22(phox). In the activation process, p47(phox) plays a central role as the target of phosphorylations and as a scaffolding protein conducting the translocation and assembly of cytosolic factors onto the membranous components. The PX and tandem SH3s of p47(phox) have been highlighted as being key determinants for the interaction with membrane lipids and the p22(phox) component, respectively. In the resting state, the two corresponding interfaces are thought to be masked allowing its cytoplasmic localization. However, the resting state modular organization of p47(phox) and its autoinhibition mode are still not fully understood despite available structural information on separate modules. More precisely, it raises the question of the mutual arrangement of the PX domain and the tandem SH3 domains in the resting state. To address this question, we have engaged a study of the entire p47(phox) molecule in solution using small-angle X-ray scattering. Despite internal autoinhibitory interactions, p47(phox) adopts an extended conformation. First insights about the domain arrangement in whole p47(phox) can be derived. Our data allow to discard the usual representation of a globular and compact autoinhibited resting state.

SAXS study of the PIR domain from the Grb14 molecular adaptor: a natively unfolded protein with a transient structure primer?

Grb14 belongs to the Grb7 family of adapters and was identified as a negative regulator of insulin signal transduction. Between the PH (pleckstrin homology) and SH2 (Src homology 2) domains is a new binding domain implicated in the interaction with receptor tyrosine kinases called PIR (phosphorylated insulin receptor interaction region). Both PIR and SH2 domains interact with the insulin receptor, but their relative role varies considering the member of the Grb7 family and the tyrosine kinase receptor. In the case of Grb14, PIR is the main binding domain and is sufficient to inhibit the insulin receptor kinase activity. We have proposed, on the basis of NMR measurements, that PIR lacks ordered structure and presents a high flexibility, although remaining fully active. To complement this first study, we have used small-angle x-ray scattering in solution together with a modeling approach representing the PIR domain as a chain of pseudo residues. Circular dichroism experiments were also performed in the presence of variable amounts of trifluoroethanol. These observations, together with an ensemble of sequence analyses and previous NMR results, all support the view of PIR as essentially unstructured but with a potentially structured short stretch encompassing residues 399-407. This stretch, which may be only structured transiently in the isolated molecule, could play a major role in Grb14 PIR binding to a biological partner by undergoing a structural transition.

Heat-induced unfolding of neocarzinostatin, a small all-β protein investigated by small-angle X-ray scattering 1 1Edited by M. F. Moody

Neocarzinostatin is an all-beta protein, 113 amino acid residues long, with an immunoglobulin-like fold. Its thermal unfolding has been studied by small-angle X-ray scattering. Preliminary differential scanning calorimetry and fluorescence measurements suggest that the transition is not a simple, two-state transition. The apparent radius of gyration is determined using three different approaches, the validity of which is critically assessed using our experimental data as well as a simple, two-state model. Similarly, each step of data analysis is evaluated and the underlying assumptions plainly stated. The existence of at least one intermediate state is formally demonstrated by a singular value decomposition of the set of scattering patterns. We assume that the pattern of the solution before the onset of the transition is that of the native protein, and that of the solution at the highest temperature is that of the completely unfolded protein. Given these, actually not very restrictive, boundary constraints, a least-squares procedure yields a scattering pattern of the intermediate state. However, this solution is not unique: a whole class of possible solutions is derived by adding to the previous linear combination of the native and completely unfolded states. Varying the initial conditions of the least-squares calculation leads to very similar solutions. Whatever member of the class is considered, the conformation of this intermediate state appears to be weakly structured, probably less than the transition state should be according to some proposals. Finally, we tried and used the classical model of three thermodynamically well-defined states to account for our data. The failure of the simple thermodynamic model suggests that there is more than the single intermediate structure required by singular value decomposition analysis. Formally, there could be several discrete intermediate species at equilibrium, or an ensemble of conformations differently populated according to the temperature. In the latter case, a third state would be a weighted average of all non native and not completely unfolded states of the protein but, since the weights change with temperature, no meaningful curve is likely to be derived by a global analysis using the simple model of three thermodynamically well-defined states.

Chain-like conformation of heat-denatured ribonuclease A and cytochrome c as evidenced by solution X-ray scattering

BACKGROUND

Although the characterization of heat-denatured proteins is essential for understanding the thermodynamic mechanism of protein folding, their structural features are still unclear and controversial. In order to address this problem, we studied the size and shape of the heat-denatured states of bovine ribonuclease A (RNase A) and horse ferricytochrome c (cytochrome c) by solution X-ray scattering.

RESULTS

RNase A has four disulfide bonds, whereas cytochrome c, with a covalently bound heme group, has no disulfide bond. Guinier plots show that the heat-denatured RNase A is relatively compact, but the heat-denatured cytochrome c is expanded. On the other hand, the Kratky plots of the two proteins are similar, indicating that the heat-denatured proteins assume a chain-like disordered conformation. The X-ray scattering of RNase A and cytochrome c at various temperatures confirmed that their thermal transitions from a globular native state to a chain-like extended conformation can be approximated well by a two-state transition.

CONCLUSIONS

These results indicate that the heat-denatured RNase A and cytochrome c are substantially unfolded according to the criteria of solution X-ray scattering, although the heat-denatured RNase A remains compact because of the presence of the disulfide bonds. The results also confirm that the thermal denaturation occurs cooperatively with the breakdown of secondary and tertiary structure.

Trifluoroethanol-induced conformational transition of hen egg-white lysozyme studied by small-angle X-ray scattering

The trifluoroethanol (TFE)-induced conformational transition of hen lysozyme was studied with the combined use of far-UV circular dichroism (CD) and small-angle X-ray scattering. At pH 2.0 and 20 degrees C, the addition of TFE to the native lysozyme induced a cooperative transition to an intermediate state with an increased helical content (TFE state). Small-angle X-ray scattering measurements indicated that the TFE state has a radius of gyration which is 20% larger than that of the native state and assumes a chain-like conformation with some remaining globularity. The TFE-induced transition curves obtained by CD and the small-angle X-ray scattering measurements agreed well, consistent with a two-state transition mechanism. A singular value decomposition analysis of Kratky plots of the small-angle X-ray scattering profiles indicated that two basic scattering functions reproduce the observed spectra, further confirming the validity of a two-state approximation.

Conformation of thermally denatured RNase T1 with intact disulfide bonds: a study by small-angle X-ray scattering

Small-angle X-ray scattering of RNase T1 with intact disulfide bonds was measured at 20 degrees and 60 degrees C in order to get insight into the structural changes of the protein caused by thermal denaturation. The radius of gyration increases from R(G)= 1.43 nm to R(G) = 2.21 nm. The conformations of the molecules at 60 degrees C are similar to those of ring-shaped random walk chains. However, the molecules are more compact than one would expect under theta conditions due to attractive interactions between the chain segments. The volume needed for free rotation of the thermally unfolded protein molecules about any axis in solution is five times greater than in the native state whereas the hydrodynamic effective volume is increasing only two times.

The concept of a random coil. Residual structure in peptides and denatured proteins

Non-native states of proteins are of increasing interest because of their relevance to issues such as protein folding, translocation and stability. A framework for interpreting the wealth of experimental data for non-native states emerging from rapid advances in experimental techniques involves comparison with a "random coll' state, which possesses no structure except that inherent in the local interactions. We review here the concept of a random coil, from its global to its local properties. In particular, we focus on the description of a random coil in terms of statistical distributions in psi, phi space. We show that such a model, in combination with experimental data, provides insight into the structural properties of polypeptide chains and has significance for understanding protein folding and for molecular design.

Influence of the solvent on the conformational-dependent properties of random coil polypeptides

Mean square optical anisotropies and molar Kerr constants were calculated for homopolypeptides of the 20 natural amino acids and of several enzymes and proteins in the random-coil state. The effect of hydration was taken into account in constructing the molecular potential that gives the conformational energies as a function of the rotational angles phi and psi of the backbone and chi(1) of the side chain. The Rotational Isomeric State model was used in calculated energies, the Valence Optical Scheme and the matrix calculus technique of Flory being employed in the evaluation of the optical properties. The results are compared with calculations for the same substances that were performed without taking into account the solvent, as well as with other similar studies. The Kerr constant is confirmed as being one of the most sensitive properties of a given polypeptide to the residue class and to the sequence of those residues.