Effect of conserved intersubunit amino acid substitutions on Hfq protein structure and stability.

Hfq is a thermostable RNA-binding bacterial protein that forms a uniquely shaped homohexamer. Based on sequence and structural similarity, Hfq belongs to the like-Sm (LSm) protein family. In spite of a rather high degree of homology between archaeal and eukaryotic LSm proteins, their quaternary structure is different, usually consisting of five to eight monomers. In this work, the importance of conserved intersubunit hydrogen bonds for the Hfq spatial organization was tested. The structures and stabilities for the Gln8Ala, Asn28Ala, Asp40Ala, and Tyr55Ala Hfq mutants were determined. All these proteins have the same hexamer organization, but their stability is different. Elimination of a single intersubunit hydrogen bond due to Gln8Ala, Asp40Ala, and Tyr55Ala substitutions results in decreased stability of the Hfq hexamer. Tyr55Ala Hfq as well as the earlier studied His57Ala Hfq has reduced protein thermostability, which seems to correspond to an opening of the protein hydrophobic core.

[Molecular basis of oncogenesis induced by human papilloma viruses].

Human papilloma viruses (HPV) of high carcinogenesis risk play important role in development of cancer of oropharyngeal and anogenital areas. Possible malignant transformation of cells, infected by HPV, is due to the expression of three proteins, E6, E7 and E5. These proteins mostly influence on mechanisms that regulate cellular cycle, proliferation and apoptosis inducing and maintaining oncogenesis. This review briefly presents data on malignant tumors induced by HPV as well as biology of these viruses and their vital cycle. Special accent is made on description of current trends in molecular basis of oncogenesis, induced by HPV, which understanding is necessary for elaboration of new methods of treatment for HPV-infection such as therapeutic vaccines.

[Chimeric SHA-D domain ("SH3-Bergerac"): 3D-structure and dynamics studies in solution].

Protein SHA-D of "SH3-Bergerac" chimeric proteins family was constructed by substitution of beta-turn N47-D48 in spectrin SH3-domain by KATANDKTYE amino acid sequence. Structural and dynamics properties of SHA-D in solution were studied by with the help of high-resolution NMR. The extension of SHA-D polypeptide chain in comparison with wild type of protein WT-SH3 (~ 17%) practically doesn't affect almost the total molecule topology. 3D-structure of SHA-D is practically identical to the proteins of "SH3-Bergerac" family. However there are some differences in dynamic characteristics in the region of substitution. The G52D substitution in SHA-D protein results in a destabilization of the region insertion where the conditions for conformational exchange appear. Destabilization further affects the entire SHA- D molecule making its structure more labile.

[NMR structure and dynamics of the chimeric protein SH3-F2].

For the further elucidation of structural and dynamic principles of protein self-organization and protein-ligand interactions the design of new chimeric protein SH3-F2 was made and genetically engineered construct was created. The SH3-F2 amino acid sequence consists of polyproline ligand mgAPPLPPYSA, GG linker and the sequence of spectrin SH3 domain circular permutant S19-P20s. Structural and dynamics properties of the protein were studied by high-resolution NMR. According to NMR data the tertiary structure of the chimeric protein SH3-F2 has the topology which is typical of SH3 domains in the complex with the ligand, forming polyproline type II helix, located in the conservative region of binding in the orientation II. The polyproline ligand closely adjoins with the protein globule and is stabilized by hydrophobic interactions. However the interaction of ligand and the part of globule relative to SH3 domain is not too large because the analysis of protein dynamic characteristics points to the low amplitude, high-frequency ligand tumbling in relation to the slow intramolecular motions of the main globule. The constructed chimera permits to carry out further structural and thermodynamic investigations of polyproline helix properties and its interaction with regulatory domains.

[Design and structural and thermodynamic studies of a chimeric protein derived from spectrin SH3-domain].

A number of chimerical constructions based on the spectrin SH3 domain were designed for structural and thermodynamic studies of protein folding and protein-ligand interactions. SH3 domains were found in many regulatory proteins and operate through weak interactions with proline-rich fragments of the partners. The recombinant protein studied in this work (WT-CIIA) was constructed by linking the peptide PPPVPPYSAG to the domain C-terminal trough a long 12-residue linker with the aim to achieve stable ligand binding in orientation II, which until now has not been considered as typical for spectrin domain. A comparison of fluorescence spectra of the chimerical protein and the parent domain suggests that the ligand sticks to the conservative binding site. The analysis of the urea-induced unfolding curves revealed, however, that the protein-ligand contact is not stable enough and as a result the chimerical protein structure unfolds in two steps. In order to clarify the structural aspects of the protein-ligand interaction, WT-CIIA was crystallized and a set of the X-ray diffraction data at 1.75 angstroms resolution was acquired. Preliminary analysis of the diffraction data indicated that the crystals belong to the space group P32, with unit-cell parameters a = b = 3639, c = = 112.17 angstroms, alpha = beta = 90.0, gamma = 120.0.

[Study of the structure and dynamics of a chimeric variant of the SH3 domain (SHA-Bergerac) by NMR spectroscopy].

A structural-dynamic study of one of the chimeric proteins (SHA) belonging to the SH3-Bergerac family and containing the KATANGKTYE sequence instead of the N47D48 beta-turn in the spectrin SH3 domain was carried out by high resolution NMR spectroscopy. The spatial structure of the protein was determined and its dynamics in solution was investigated on the basis of the NMR data. The elongation of the SHA polypeptide chain in comparison with the WT-SH3 original protein (by ~17%) exerts practically no effect on the general topology of the molecule. The presence of a stable beta-hairpin in the region of insertion was confirmed. This hairpin was shown to have a higher mobility in comparison with other regions of the protein.

A binding event converted into a folding event.

We have designed a chimeric protein by connecting a circular permutant of the alpha-spectrin SH3 domain to the proline-rich decapeptide APSYSPPPPP with a three-residue link. Our aim was to obtain a single-chain protein with a tertiary fold that would mimic the binding between SH3 domains and proline-rich peptides. A comparison of the circular-dichroism and fluorescence spectra of the purified chimera and the SH3 circular permutant showed that the proline-rich sequence occupies the putative SH3 binding site in a similar conformation and with comparable interactions to those found in complexes between SH3 and proline-rich peptides. Differential scanning calorimetry indicated that the interactions in the binding motif interface are highly cooperative with the rest of the structure and thus the protein unfolds in a two-state process. The chimera is more stable than the circular permutant SH3 by 6-8 kJ mol(-1) at 25 degrees C and the difference in their unfolding enthalpy is approximately 32 kJ mol(-1), which coincides with the values found for the binding of proline-rich peptides to SH3 domains. This type of chimeric protein may be useful in designing SH3 peptide ligands with improved affinity and specificity.

AS-48: a circular protein with an extremely stable globular structure.

The unfolding thermodynamics of the circular enterocin protein AS-48, produced by Enterococcus faecalis, has been characterized by differential scanning calorimetry. The native structure of the 70-residue protein is extremely thermally stable. Thus, at pH 2.5 and low ionic strength thermal denaturation occurs under equilibrium at 102 degrees C, while the unfolded state irreversibly aggregates at neutral and alkaline pH. Calorimetric data analysis shows that the specific enthalpy change upon unfolding is unusually small and the heat capacity change is quite normal for a protein of this size, whereas the Gibbs energy change at 25 degrees C is relatively high. At least part of this high stability might be put down to entropic constraints induced by the circular organization of the polypeptide chain.

Modeling, mutagenesis, and structural studies on the fully conserved phosphate-binding loop (loop 8) of triosephosphate isomerase: toward a new substrate specificity.

Loop 8 (residues 232-242) in triosephosphate isomerase (TIM) is a highly conserved loop that forms a tight binding pocket for the phosphate moiety of the substrate. Its sequence includes the fully conserved, solvent-exposed Leu238. The tight phosphate-binding pocket explains the high substrate specificity of TIM being limited to the in vivo substrates dihydroxyacetone-phosphate and D-glyceraldehyde-3-phosphate. Here we use the monomeric variant of trypanosomal TIM for exploring the structural consequences of shortening this loop. The mutagenesis, guided by extensive modeling calculations and followed up by crystallographic characterization, is aimed at widening the phosphate-binding pocket and, consequently, changing the substrate specificity. Two new variants were characterized. The crystal structures of these variants indicate that in monomeric forms of TIM, the Leu238 side-chain is nicely buried in a hydrophobic cluster. Monomeric forms of wild-type dimeric TIM are known to exist transiently as folding intermediates; our structural analysis suggests that in this monomeric form, Leu238 of loop 8 also adopts this completely buried conformation, which explains its full conservation across the evolution. The much wider phosphate-binding pocket of the new variant allows for the development of a new TIM variant with a different substrate specificity.

Protein engineering as a strategy to avoid formation of amyloid fibrils.

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.

Thermodynamic analysis of helix-engineered forms of the activation domain of human procarboxypeptidase A2.

Thermodynamic characterization of the activation domain of human procarboxypeptidase A2, ADA2h, and its helix-engineered mutants was carried out by differential scanning calorimetry. The mutants were engineered by changing residues in the exposed face of the two alpha helices in order to increase their stability. At neutral and alkaline pH the three mutants, alpha-helix 1 (M1), alpha-helix 2 (M2) and alpha-helix 1 and alpha-helix 2 (DM), were more stable than the wild-type domain, in the order DM, M2, M1 and wild-type. Under these conditions the CD and NMR spectra of all the variants are very similar, indicating that this increase in stability is not the result of gross structural changes. Calorimetric analysis shows that the stabilizing effect of mutating the water-exposed surfaces of the helices seems to be mainly entropic, because the mutations do not change the enthalpy or the increase in heat capacity of denaturation. The unfolding behavior of all variants changes under acidic conditions: whereas wild-type and M1 have a strong tendency to aggregate, giving rise to a beta conformation upon unfolding, M2 and DM unfold reversibly, M2 being more stable than DM. CD and NMR experiments at pH 3.0 suggest that a region involving residues of the second and third beta strands as well as part of alpha-helix 1 changes its conformation. It seems that the enhanced stability of the altered conformation of M2 and DM reduces the aggregation tendency of ADA2h at acidic pH.

Thermodynamic analysis of the structural stability of phage 434 Cro protein.

Thermodynamic parameters describing the phage 434 Cro protein have been determined by calorimetry and, independently, by far-UV circular dichroism (CD) measurements of isothermal urea denaturations and thermal denaturations at fixed urea concentrations. These equilibrium unfolding transitions are adequately described by the two-state model. The far-UV CD denaturation data yield average temperature-independent values of 0.99 +/- 0.10 kcal mol(-)(1) M(-)(1) for m and 0.98 +/- 0.05 kcal mol(-)(1) K(-)(1) for DeltaC(p)()(,U), the heat capacity change accompanying unfolding. Calorimetric data yield a temperature-independent DeltaC(p)()(,U) of 0.95 +/- 0.30 kcal mol(-)(1) K(-)(1) or a temperature-dependent value of 1.00 +/- 0.10 kcal mol(-)(1) K(-)(1) at 25 degrees C. DeltaC(p)()(,U) and m determined for 434 Cro are in accord with values predicted using known empirical correlations with structure. The free energy of unfolding is pH-dependent, and the protein is completely unfolded at pH 2.0 and 25 degrees C as judged by calorimetry or CD. The stability of 434 Cro is lower than those observed for the structurally similar N-terminal domain of the repressor of phage 434 (R1-69) or of phage lambda (lambda(6)(-)(85)), but is close to the value reported for the putative monomeric lambda Cro. Since a protein's structural stability is important in determining its intracellular stability and turnover, the stability of Cro relative to the repressor could be a key component of the regulatory circuit controlling the levels and, consequently, the functions of the two proteins in vivo.

A thermodynamic study of the 434-repressor N-terminal domain and of its covalently linked dimers.

The isolated N-terminal 1-69 domain of the 434-phage repressor, R69, and its covalently linked (head-to-tail and tail-to-tail) dimers have been studied by differential scanning microcalorimetry (DSC) and CD. At neutral solvent conditions the R69 domain maintains its native structure, both in isolated form and within the dimers. The stability of the domain depends highly upon pH within the acidic range, thus at pH 2 and low ionic strength R69 is already partially unfolded at room temperature. The thermodynamic parameters of unfolding calculated from the DSC data are typical for small globular proteins. At neutral pH and moderate ionic strength, the domains of the dimers behave as two independent units with unfolding parameters similar to those of the isolated domain, which means that linking two R69 domains, either by a long peptide linker or by a designed C-terminal disulfide bridge, does not induce any cooperation between them.

A thermodynamic analysis of a family of small globular proteins: SH3 domains.

The stability and folding thermodynamics of two SH3-domains, belonging to Fyn and Abl proteins, have been studied by scanning calorimetry and urea-induced unfolding. They undergo an essentially two-state unfolding with parameters similar to those of the previously studied alpha-spectrin SH3 domain. The correlations between the thermodynamic parameters (heat capacity increment, delta Cp,U, the proportionality factor, m, and the Gibbs energy, delta Gw298) of unfolding and some integral structural parameters, such as polar and non-polar areas exposed upon domain denaturation, have been analyzed. The experimental data on delta Cp,U and the m-factor of the linear extrapolation model (LEM) obey the simple empirical correlations deduced elsewhere. The Gibbs energies calculated from the DSC data were compared with those found by fitting urea-unfolding curves to the LEM and the denaturant-binding model (DBM). The delta Gw298 values found with DBM correlate better with the DSC data, while those obtained with LEM are systematically smaller. The systematic difference between the parameters calculated with LEM and DBM are explained by an inherent imperfection of the LEM.

Secondary structure and oligomerization behavior of equilibrium unfolding intermediates of the lambda cro repressor.

The thermal unfolding of the wild-type Cro repressor, its disulfide-bridged mutant Cro-V55C (with the Val-55 --> Cys single amino acid substitution), and a CNBr-fragment (13-66)2 of Cro-V55C was studied by Fourier transform infrared spectroscopy and dynamic light scattering. The combined approach reveals that thermal denaturation of Cro-WT and Cro-V55C proceeds in two steps through equilibrium unfolding intermediates. The first thermal transition of the Cro-V55C dimer involves the melting of the alpha-helices and the short beta-strand localized in the N-terminal part of the molecule. This event is accompanied by the formation of tetramers, and also impacts on the hydrogen-bonding interactions of the C-terminal beta-strands. The beta-sheet formed by the C-terminal parts of each polypeptide chain is the major structural feature of the intermediate state of Cro-V55C and unfolds during a second thermal transition, which is accompanied by the dissociation of the tetramers. Cutting of 12 amino acids in the N-terminal region is sufficient to prevent the formation of alpha-helical structure in the CNBr-fragment of Cro-V55C, and to induce tetramerization already at room temperature. The tetramers may persist over a broad temperature range, and start to dissociate only upon thermal unfolding of the beta-sheet structure formed by the C-terminal regions. The wild-type protein is a dimer at room temperature and at protein concentrations of 1.8-5.8 mg/mL. At lower concentrations, the dimers are stable until the onset of thermal unfolding, which is accompanied by the dissociation of the dimers into monomers. At higher protein concentrations, the unfolding is more complex and involves the formation of tetramers at intermediate temperatures. At these intermediate temperatures, the Cro-WT has lost all of its alpha-helical structure and also most of its native beta-sheet structure. Upon further temperature increase, a tendency for an intermolecular association of the beta-strands is observed, which may result in irreversible beta-aggregation at high protein concentrations.

Thermodynamic analysis of alpha-spectrin SH3 and two of its circular permutants with different loop lengths: discerning the reasons for rapid folding in proteins.

The temperature dependences of the unfolding-refolding reaction of a shorter version of the alpha-spectrin SH3 domain (PWT) used as a reference and of two circular permutants (with different poly-Gly loop lengths at the newly created fused loop) have been measured by differential scanning microcalorimetry and stopped-flow kinetics, to characterize the thermodynamic nature of the transition and native states. Differential scanning calorimetry results show that all these species do not belong to the same temperature dependency of heat effect. The family of the N47-D48s circular permutant (with 0-6 Gly inserted at the fused-loop) shows a higher enthalpy as happens with the PWT domain. The wild type (WT) and the S19-P20s permutant family have a more similar behavior although the second is far less stable. The crystallographic structure of the PWT shows a hairpin formation in the region corresponding to the unstructured N-terminus tail of the WT, explaining the enthalpic difference. There is a very good correlation between the calorimetric changes and the structural differences between the WT, PWT, and two circular permutants that suggests that their unfolded state cannot be too different. Elongation of the fused loop in the two permutants, taking as a reference the protein with one inserted Gly, results in a small Gibbs energy change of entropic origin as theoretically expected. Eyring plots of the unfolding and refolding semireactions show different behaviors for PWT, S19-P20s, and N47-D48s in agreement with previous studies indicating that they have different transition states. The SH3 transition state is relatively close to the native state with regard to changes in heat capacity and entropy, indicating a high degree of compactness and order. Regarding the differences in thermodynamic parameters, it seems that rapid folding could be achieved in proteins by decreasing the entropic barrier.

Reversible association of the equilibrium unfolding intermediate of lambda Cro repressor.

An extended differentiated scanning calorimetry study of the wild-type Cro repressor and of its V55C mutant has revealed a significant concentration dependence of the melting profiles, even though the two polypeptide chains forming the active repressor molecule are covalently bound within the mutant. An analysis of the temperature dependencies of the partial molar heat capacity suggests that in both cases equilibrium unfolding occurs via a highly-populated intermediate state corresponding to polypeptide tetramers. The results of thermodynamic analysis are confirmed by direct glutaraldehyde cross-linking experiments. Judging by heat effects and circular dichroism data, this intermediate state regains about 50% of the ordered structure and melts co-operatively.

A calorimetric study of the thermal stability of barstar and its interaction with barnase.

The temperature-induced unfolding of single, double, and triple mutants of barstar, the specific intracellular protein inhibitor of barnase from Bacillus amyloliquefaciens, has been studied by high-sensitivity differential scanning calorimetry. The thermal unfolding of barstar mutants, where at least one of the two cysteine residues in the molecule had been replaced by alanine, follows a two-state mechanism at neutral and alkaline pH. The unfolding enthalpy and heat capacity changes are slightly lower than those accepted for highly compact, small, globular proteins. We have found that at pH 2.5, where barstar seems to be in a molten globule state, the protein has a heat capacity between that of the native and the unfolded states and shows some tendency for association. Scanning calorimetry experiments were also extended to the barstar--barnase complex in the neutral and alkaline pH range. The binding constants obtained from DSC studies are similar to those already obtained from other (kinetic) studies. The interaction of barstar and barnase was also investigated by isothermal calorimetry in various buffers within the pH range 6.0-10.0 and a temperature range of 15-35 degrees C. The favorable enthalpy contribution to the binding is about 4 times higher than the entropic one at 25 degrees C. The overall data analysis of the combined calorimetric results has led to the thermodynamic characterization of barstar unfolding and the interaction of barstar and barnase over a wide range of temperatures.

A calorimetric study of the thermal stability of barnase and its interaction with 3'GMP.

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.

Thermodynamic and kinetic analysis of the SH3 domain of spectrin shows a two-state folding transition.

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)