Conformational changes and stabilization induced by ligand binding in the DNA-binding domain of the E2 protein from human papillomavirus

Molecular cloning, biophysical and in silico studies of Human papillomavirus 33 E2 DNA binding domain

Human papillomavirus 33, a high-risk HPV strain, is mainly responsible for HPV infection and cervical cancer in Asian countries. The E2 protein of HPV 33 is a DNA-binding protein that plays a crucial role in viral replication and transcription. We have cloned, overexpressed, and purified the DNA binding domain of the E2 protein. Size exclusion chromatography results suggested that the protein exists in a homodimeric state in the native form. Circular dichroism data showed that the protein has a higher content of β-sheet. The melting temperature obtained from differential scanning calorimetry is 52.59 °C, and the protein is stable at pH 8 and is in a dimeric form at basic pH. The protein is monomeric or unfolded at a very low pH. Chemical denaturation studies suggested that the protein denatured and dissociated simultaneously. The DNA binding activity of the protein was also confirmed and it showed binding affinity in the order of 106 M-1. The protein structure was modeled using homology modeling and other bioinformatic tools. The virtual screening and molecular dynamic simulation studies were performed to find compounds that can act as potent inhibitors against E2 DBD. This study expands the understanding of the conserved structural and binding properties of HPV33 E2 DBD and provides the first report on the characterization of the viral protein.Communicated by Ramaswamy H. Sarma.

Using Intrinsic Fluorescence to Measure Protein Stability Upon Thermal and Chemical Denaturation

Understanding how point mutations affect the performance of protein stability has been the focus of several studies all over the years. Intrinsic fluorescence is commonly used to follow protein unfolding since during denaturation, progressive redshifts on tryptophan fluorescence emission are observed. Since the unfolding process (achieved by chemical or physical denaturants) can be considered as two-state N➔D, it is possible to utilize the midpoint unfolding curves (fU = 50%) as a parameter to evaluate if the mutation destabilizes wild-type protein. The idea is to determine the [D]_1/2 or T_m values from both wild type and mutant and calculate the difference between them. Positive values indicate the mutant is less stable than wild type.

DNA activates the Nse2/Mms21 SUMO E3 ligase in the Smc5/6 complex

Modification of chromosomal proteins by conjugation to SUMO is a key step to cope with DNA damage and to maintain the integrity of the genome. The recruitment of SUMO E3 ligases to chromatin may represent one layer of control on protein sumoylation. However, we currently do not understand how cells upregulate the activity of E3 ligases on chromatin. Here we show that the Nse2 SUMO E3 in the Smc5/6 complex, a critical player during recombinational DNA repair, is directly stimulated by binding to DNA Activation of sumoylation requires the electrostatic interaction between DNA and a positively charged patch in the ARM domain of Smc5, which acts as a DNA sensor that subsequently promotes a stimulatory activation of the E3 activity in Nse2. Specific disruption of the interaction between the ARM of Smc5 and DNA sensitizes cells to DNA damage, indicating that this mechanism contributes to DNA repair. These results reveal a mechanism to enhance a SUMO E3 ligase activity by direct DNA binding and to restrict sumoylation in the vicinity of those Smc5/6-Nse2 molecules engaged on DNA.

Thermodynamics of cooperative DNA recognition at a replication origin and transcription regulatory site

Binding cooperativity guides the formation of protein−nucleic acid complexes, in particular those that are highly regulated such as replication origins and transcription sites. Using the DNA binding domain of the origin binding and transcriptional regulator protein E2 from human papillomavirus type 16 as model, and through isothermal titration calorimetry analysis, we determined a positive, entropy-driven cooperativity upon binding of the protein to its cognate tandem double E2 site. This cooperativity is associated with a change in DNA structure, where the overall B conformation is maintained. Two homologous E2 domains, those of HPV18 and HPV11, showed that the enthalpic−entropic components of the reaction and DNA deformation can diverge. Because the DNA binding helix is almost identical in the three domains, the differences must lie dispersed throughout this unique dimeric β-barrel fold. This is in surprising agreement with previous results for this domain, which revealed a strong coupling between global dynamics and DNA recognition.

p-Nitrophenol degradation via 4-nitrocatechol in Burkholderia sp. SJ98 and cloning of some of the lower pathway genes

Microbial degradation studies have pointed toward the occurrence of two distinct PNP catabolic pathways in Gram positive and Gram negative bacteria. The former involves 4-nitrocatechol (4-NC), 1,2,4-benzenetriol (BT), and maleylacetate (MA) as major degradation intermediates, whereas the later proceeds via formation of 1,4-benzoquinone (BQ) and hydroquinone (HQ). In the present study we identified a Gram negative organism viz. Burkholderia sp. strain SJ98 that degrades PNP via 4NC, BT, and MA. A 6.89 Kb genomic DNA fragment of strain SJ98 that encompasses seven putatively identified ORFs (orfA, pnpD, pnpC, orfB, orfC, orfD, and orfE) was cloned. PnpC is benzenetriol dioxygenase belonging to the intradiol dioxygenase superfamily, whereas PnpD is identified as maleylacetate reductase, a member of the Fe-ADH superfamily showing NADH dependent reductase activity. The in vitro activity assays carried out with purified pnpC and pnpD (btd and mar) gene products transformed BT to MA and MA to beta-ketoadipate, respectively. The cloning, sequencing, and characterization of these genes along with the functional PNP degradation studies ascertained the involvement of 4-NC, BT, and MA as degradation intermediates of PNP pathway in this strain. This is one of the first conclusive reports for 4-NC and BT mediated degradation of PNP in a Gram negative organism.

Kinetically driven refolding of the hyperstable EBNA1 origin DNA-binding dimeric beta-barrel domain into amyloid-like spherical oligomers

The Epstein-Barr nuclear antigen 1 (EBNA1) is essential for DNA replication and episome segregation of the viral genome, and participates in other gene regulatory processes of the Epstein-Barr virus in benign and malignant diseases related to this virus. Despite the participation of other regions of the protein in evading immune response, its DNA binding, dimeric beta-barrel domain (residues 452-641) is necessary and sufficient for the main functions. This domain has an unusual topology only shared by another viral origin binding protein (OBP), the E2 DNA binding domain of papillomaviruses. Both the amino acid and DNA target sequences are completely different for these two proteins, indicating a link between fold conservation and function. In this work we investigated the folding and stability of the DNA binding domain of EBNA1 OBP and found it is extremely resistant to chemical, temperature, and pH denaturation. The thiocyanate salt of guanidine is required for obtaining a complete transition to a monomeric unfolded state. The unfolding reaction is extremely slow and shows a marked uncoupling between tertiary and secondary structure, indicating the presence of intermediate species. The Gdm.SCN unfolded protein refolds to fully soluble and spherical oligomeric species of 1.2 MDa molecular weight, with identical fluorescence centre of spectral mass but different intensity and different secondary structure. The refolded spherical oligomers are substantially less stable than the native recombinant dimer. In keeping with the substantial structural rearrangement in the oligomers, the spherical oligomers do not bind DNA, indicating that the DNA binding site is either disrupted or participates in the oligomerization interface. The puzzling extreme stability of a dimeric DNA binding domain from a protein from a human infecting virus in addition to a remarkable kinetically driven folding where all molecules do not return to the most stable original species suggests a co-translational and directional folding of EBNA1 in vivo, possibly assisted by folding accessory proteins. Finally, the oligomers bind Congo red and thioflavin-T, both characteristic of repetitive beta-sheet elements of structure found in amyloids and their soluble precursors. The stable nature of the "kinetically trapped" oligomers suggest their value as models for understanding amyloid intermediates, their toxic nature, and the progress to amyloid fibers in misfolding diseases. The possible role of the EBNA1 spherical oligomers in the virus biology is discussed.

A quasi-spontaneous amyloid route in a DNA binding gene regulatory domain: The papillomavirus HPV16 E2 protein

The DNA binding domain of papillomavirus E2 proteins is at the center of the regulation of gene transcription and replication of the virus. Its unique fold consists of a beta-barrel domain that combines an eight-stranded dimeric beta-barrel core interface with two symmetrical DNA binding alpha-helices and other two helices, packed against the central barrel. Treatment with low amounts of trifluoroethanol readily leads to a mostly beta-sheet oligomeric species, with a loss of near-UV circular dichroism signal and increase in its ANS binding capacity, indicating that buried hydrophobic surfaces become accessible to the solvent. This species subsequently undergoes a slow transition into amyloid aggregates as determined by light scattering and Congo red and thioflavin T binding. Electron microscopy shows short amyloid fibers with a curly aspect as the end product. The amyloid route is completely prevented by addition of stoichiometrical amounts of specific DNA, strongly suggesting that unfolding of the DNA binding alpha-helix is required for the formation of the intermediate. The slow nature of this expanded beta-oligomeric species and the availability of several different conformational probes make it an excellent model for investigating amyloid mechanisms. The mild perturbation required for entering an amyloid route is indicative of a preexisting equilibrium. Oligomerization processes are required for the assembly of transcription initiation and DNA replication machineries, where proteins from different viruses must come together with host cell proteins. The E2 protein is a virus-encoded multifunctional master regulator that may exert one of its multiple functions through its ability to oligomerize.

How does dextran sulfate prevent heat induced aggregation of protein?: The mechanism and its limitation as aggregation inhibitor

The effect of dextran sulfate on protein aggregation was investigated to provide the clues of its biochemical mechanism. The interaction between dextran sulfate and BSA varied with the pH values of the solution, which led to the different extent of aggregation prevention by dextran sulfate. Light scattering data with thermal scan showed that dextran sulfate suppressed BSA aggregation at pH 5.1 and pH 6.2, while it had no effect at pH 7.5. Isothermal titration calorimetric analysis suggested that the pH dependency of the role of dextran sulfate on BSA aggregation would be related to the difference in the mode of BSA-dextran sulfate complex formation. Isothermal titration calorimetric analysis at pH 6.2 indicated that dextran sulfate did not bind to native BSA at this pH, but interacted with partially unfolded BSA. While stabilizing native form of protein by the complex formation has been suggested as the suitable mechanism of preventing aggregation, our observation of conformational changes by circular dichroism spectroscopy showed that strong electrostatic interaction between dextran sulfate and BSA rather facilitated the denaturation of BSA. Combining the data from isothermal titration calorimetry, circular dichroism, and dynamic light scattering, we found that the complex formation of the intermediate state of denatured BSA with dextran sulfate is a prerequisite to suppress the aggregation by preventing further oligomerization/aggregation process of denatured protein.

Specificity in DNA recognition by a peptide from papillomavirus E2 protein

The E2 proteins of papillomavirus specifically bind to double-stranded DNA containing the consensus sequence ACCG-N4-CGGT, where N is any nucleotide. Here, we show the binding and recognition of dissimilar DNA sequences by an 18 amino-acid peptide (alpha1E2), which corresponds to the DNA-recognition helix, alpha-helix-1. Isothermal DNA binding assays performed with the DNA consensus sequence show saturable curves with alpha1E2 peptide, and the alpha1E2 peptide is converted to an ordered conformation upon complexation. Measurements performed with non-specific DNA sequence fail to saturate, a behavior characteristic of non-specific binding. Binding of the alpha1E2 peptide to these DNA sequences display a different counter-ion dependence, indicating a dissimilar, sequence-dependent mechanism of interaction. Quantitative stoichiometric measurements revealed the specificity in alpha1E2 peptide recognition of the ACCG half-site, demonstrating capacity for discrimination of nucleic acid bases sequences without the need of a whole protein architecture.

The Folding Mechanism of a Dimeric β-Barrel Domain

The dimeric beta-barrel domain is an unusual topology, shared only by two viral origin binding proteins, where secondary, tertiary and quaternary structure are coupled, and where the dimerization interface is composed of two four-stranded half-beta-barrels. The folding of the DNA binding domain of the E2 transcriptional regulator from human papillomavirus, strain-16, takes place through a stable and compact monomeric intermediate, with 31% the stability of the folded dimeric domain. Double jump multiple wavelength experiments allowed the reconstruction of the fluorescence spectrum of the monomeric intermediate at 100 milliseconds, indicating that tryptophan residues, otherwise buried in the folded state, are accessible to the solvent. Burial of surface area as well as differential behavior to ionic strength and pH with respect to the native ground state, plus the impossibility of having over 2500 A2 of surface area of the half-barrel exposed to the solvent, indicates that the formation of a non-native compact tertiary structure precedes the assembly of native quaternary structure. The monomeric intermediate can dimerize, albeit with a weaker affinity (approximately 1 microM), to yield a non-native dimeric intermediate, which rearranges to the native dimer through a parallel folding channel, with a unimolecular rate-limiting step. Folding pathways from either acid or urea unfolded states are identical, making the folding model robust. Unfolding takes place through a major phase accounting for apparently all the secondary structure change, with identical rate constant to that of the fluorescence unfolding experiment. In contrast to the folding direction, no unfolding intermediate was found.

Free energy contributions to direct readout of a DNA sequence

The energetic contributions of individual DNA-contacting side chains to specific DNA recognition in the human papillomavirus 16 E2C-DNA complex is small (less than 1.0 kcal mol(-1)), independent of the physical and chemical nature of the interaction, and is strictly additive. The sum of the individual contributions differs 1.0 kcal mol(-1) from the binding energy of the wild-type protein. This difference corresponds to the contribution from the deformability of the DNA, known as "indirect readout." Thus, we can dissect the energetic contribution to DNA binding into 90% direct and 10% indirect readout components. The lack of high energy interactions indicates the absence of "hot spots," such as those found in protein-protein interfaces. These results are compatible with a highly dynamic and "wet" protein-DNA interface, yet highly specific and tight, where individual interactions are constantly being formed and broken.

New insights into conformational and functional stability of human alpha-thrombin probed by high hydrostatic pressure

The effects of high hydrostatic pressure (HHP) and urea on conformational transitions of human alpha-thrombin structure were studied by fluorescence spectroscopy and by measuring the catalytic activity of the enzyme. Treatment of thrombin with urea produced a progressive red shift in the center of mass of the intrinsic fluorescence emission spectrum, with a maximum displacement of 650 cm(-1). HHP (270 MPa) shifted the centre of mass by only 370 cm(-1). HHP combined with a subdenaturing urea concentration (1.5 m) displaced the centre of mass by approximately 750 cm(-1). The binding of the fluorescent probe bis(8-anilinonaphthalene-1-sulfonate) to thrombin was increased by 1.8-, 4.0-, and 2.7-fold after treatment with high urea concentration, HHP or HHP combined with urea, respectively, thus suggesting that all treatments convert the enzyme to partially folded intermediates with exposed hydrophobic regions. On the other hand, treatment of thrombin with urea (but not HHP) combined with dithiothreitol progressively displaced the fluorescent probe, thus suggesting that this condition converts the enzyme to a completely unfolded state. Urea and HHP also led to different conformations when changes in the thrombin catalytic site environment were assessed using the fluorescence emission of fluorescein-d-Phe-Pro-Arg-cloromethylketone-alpha-thrombin: addition of urea up to 2 m gradually decreased the fluorescence emission of the probe to 65% of the initial intensity, whereas HHP caused a progressive increase in fluorescence. Hydrolysis of the synthetic substrate S-2238 was enhanced (35%) in 2 m urea and gradually abolished at higher concentrations, while HHP (270 MPa) inhibited the enzyme's catalytic activity by 45% and abolished it when 1.5 m urea was also present. Altogether, analysis of urea and HHP effects on thrombin structure and activity indicates the formation of dissimilar intermediate states during denaturation by these agents.

Positive contribution of hydration on DNA binding by E2c protein from papillomavirus

Protein-nucleic acid interactions are responsible for the regulation of key biological events such as genomic transcription and recombination and viral replication. However, the recognition mechanisms involved in these processes are not completely understood. Here, we investigate the dominant forces involved in protein-protein and protein-DNA interactions for the 80-amino-acid C-terminal domain of the E2 protein (E2c) from human papillomavirus (HPV-16). The E2c protein is a homodimer that specifically binds to double-stranded DNA containing the consensus sequence ACCG-N(4)-CGGT, where N is any nucleotide. DNA binding affinity is reduced by lowering water chemical potential, accompanied by an increase in cooperativity. Wyman linkage relations between affinity and water chemical potential indicate that 11 additional water molecules are bound in the formation of the complex between E2c and DNA. Salt dissociation isotherms showed that 10 counterions are released upon association, even at low water activity, indicating that this latter variable does not change the electrostatic component of the interaction. Further analysis demonstrates a strong dependence of cooperativity of binding on the protein concentration. Altogether, these results reveal a novel binding pathway in which the consolidated complex may achieve its final form via a monomer-DNA intermediate, which favors the binding of a second monomer. This molecular mechanism reveals the contributions of multiple conformers in a tight virus genome modulation that seems to be important in the cell infection scenario.

A protein-DNA binding mechanism proceeds through multi-state or two-state parallel pathways

The DNA-binding mechanism of the dimeric C-terminal domain of the papillomavirus E2 protein with its specific DNA target was investigated and shown to proceed through two parallel pathways. A sequential multi-step reaction is initiated by the diffusion-controlled formation of an encounter complex, with no evidence of base sequence discrimination capacity. Following a substantial conformational rearrangement of the protein, a solvent exclusion step leading to the formation of a final protein-DNA complex was identified. This last step involves the largest burial of surface area from the interface and involves the consolidation of the direct readout of the DNA bases. Double-jump stopped-flow experiments allowed us to characterize the sequence of events and demonstrated that a fast-formed consolidated complex can take place through a parallel route. We present the simplest model for the overall mechanism with a description of all the intermediate species in energetic terms.

Structural changes in RepA, a plasmid replication initiator, upon binding to origin DNA

RepA protein is the DNA replication initiator of the Pseudomonas plasmid pPS10. RepA dimers bind to an inversely repeated operator sequence in repA promoter, thus repressing its own synthesis, whereas monomers bind to four directly repeated sequences (iterons) to initiate DNA replication. We had proposed previously that RepA is composed of two winged-helix (WH) domains, a structural unit also present in eukaryotic and archaeal initiators. To bind to the whole iteron sequence through both domains, RepA should couple monomerization to a conformational change in the N-terminal WH, which includes a leucine zipper-like sequence motif. We show for the first time that, by itself, binding to iteron DNA in vitro dissociates RepA dimers into monomers and alters RepA conformation, suggesting an allosteric effect. Furthermore, we also show that similar changes in RepA are promoted by mutations that substitute two Leu residues of the putative leucine zipper by Ala, destabilizing the hydrophobic core of the first WH. We propose that this mutant (RepA-2L2A) resembles a transient folding intermediate in the pathway leading to active monomers. These findings, together with the known activation of other Rep-type proteins by chaperones, are relevant to understand the molecular basis of plasmid DNA replication initiation.

Antibody response to a viral transcriptional regulator

The E2 transcriptional activator of the human papillomavirus regulates the expression of most viral transcripts. Its binding to specific target DNA sequences involves large conformational changes in the interacting macromolecules. The high stability of the E2:DNA complex prompted us to analyze the role of macromolecular interactions and adjuvant emulsions in the appearance of conformation-specific antibodies. We demonstrate that immunization with free or DNA-complexed E2 emulsified in an oil-in-water adjuvant elicits a humoral response shifted to the recognition of discontinuous epitopes. Epitope mapping and functional analysis of the generated anti-E2 mAbs reveals that two separate antibodies populations can be obtained: those able to form a stable ternary complex with protein and DNA, and those which recognize the DNA-binding surface of the transcription factor, interfering with E2 binding to DNA.

Amino acid substitution analyses of the DNA contact region, two amphipathic alpha-helices and a recognition-helix-like helix outside the dimeric beta-barrel of Epstein-Barr virus nuclear antigen 1

OBJECTIVES AND METHODS

Epstein-Barr virus (EBV) nuclear antigen 1 (EBNA-1), which is essential for EBV latency, homodimerizes and binds to the EBV replication origin, oriP. We analyzed the dimerization/DNA-binding domain of EBNA-1 by random and site-directed amino acid substitution.

RESULTS

Random point mutations that resulted in reduced DNA binding clustered in the DNA contact region (a.a. 461-473) and at or near the termini of alpha-helix II (514-527). Three substitutions of Gly in the DNA contact region each greatly reduced binding to a single binding site oligonucleotide. Substitutions at and near the termini of alpha-helix II diminished DNA binding. A helix-deforming substitution in alpha-helix I (477-489) blocked DNA binding. A helix-deforming substitution in alpha-helix III (568-582) abolished dimerization and DNA binding. Similarities in surface electrostatic properties and conserved amino acids were found between alpha-helix II and recognition helices of papillomavirus E2 proteins.

CONCLUSIONS

The basic DNA contact region is crucial for the specific interaction of EBNA-1 with a single binding site. Alpha-helix I477 is indispensable for oriP binding, and alpha-helix III568 contributes to the homodimeric structure of EBNA-1. Alpha-helix II514 contributes to oriP binding, perhaps changing its alignment with DNA.

Binding of bovine serum albumin to heparin determined by turbidimetric titration and frontal analysis continuous capillary electrophoresis

The association of proteins with glycosaminoglycans is a subject of growing interest, but few techniques exist for elucidating this interaction quantitatively. Here we demonstrate the application of capillary electrophoresis to the system of serum albumin (SA) and heparin (Hp). These two species form soluble complexes, the interaction increasing with reduction in pH and/or ionic strength (I). The acid-base property of Hp was characterized by potentiometric titration of ion-exchanged Hp. Conditions for complex formation with SA were qualitatively determined by turbidimetry, which revealed points of incipient binding (pH(c)) and phase separation (pH(phi)), both of which depend on I. At pH > pH(phi), i.e., prior to phase separation, frontal analysis continuous capillary electrophoresis was used to measure the concentration of free protein and to determine the protein-HP binding isotherm. The binding isotherms were well fit by the McGhee-von Hippel model to yield quantitative binding information in the form of intrinsic binding constants (K(obs)) and binding site size (n). The strong increase in K(obs) with decrease of pH or I could be explained on the basis of electrostatic interactions, considering the effects of protein charge heterogeneity. The value of n, independent of pH, was rationalized on the basis of size considerations. The implications of these findings for clinical applications of Hp and for its physiological behavior are discussed.

Generation of sequence-specific, high affinity anti-DNA antibodies

By taking advantage of the extreme stability of a protein-DNA complex, we have obtained two highly specific monoclonal antibodies against a predetermined palindromic DNA sequence corresponding to the binding site of the E2 transcriptional regulator of the human papillomavirus (HPV-16). The purified univalent antibody fragments bind to a double-stranded DNA oligonucleotide corresponding to the E2 binding site in solution with dissociation constants in the low and subnanomolar range. This affinity matches that of the natural DNA binding domain and is severalfold higher than the affinity of a homologous bovine E2 C-terminal domain (BPV-1) for the same DNA. These antibodies discriminate effectively among a number of double- and single-stranded synthetic DNAs with factors ranging from 125- to 20,000-fold the dissociation constant of the specific DNA sequence used in the immunogenic protein-DNA complex. Moreover, they are capable of fine specificity tuning, since they both bind less tightly to another HPV-16 E2 binding site, differing in only 1 base pair in a noncontact flexible region. Beyond the relevance of obtaining a specific anti-DNA response, these results provide a first glance at how DNA as an antigen is recognized specifically by an antibody. The accuracy of the spectroscopic method used for the binding analysis suggests that a detailed mechanistic analysis is attainable.

DNA tightens the dimeric DNA-binding domain of human papillomavirus E2 protein without changes in volume

The recognition of palindromic specific DNA sequences by the human papillomavirus (HPV) E2 proteins is responsible for regulation of virus transcription. The dimeric E2 DNA-binding domain of HPV-16 (E2c) dissociates into a partially folded state under high hydrostatic pressure. We show here that pressure-induced monomers of E2c are highly structured, as evidenced by NMR hydrogen-deuterium exchange measurements. On binding to both specific and nonspecific DNA, E2c becomes stable against pressure. Competitive binding studies using fluorescence polarization of fluorescein-labeled DNA demonstrate the reversibility of the specific binding. To assess the thermodynamic parameters for the linkage between protein dissociation and DNA binding, urea denaturation curves were obtained at different pressures in the presence of specific and nonspecific DNA sequences. The change in free energy on denaturation fell linearly with increase in pressure for both protein-DNA complexes, and the measured volume change was similar to that obtained for E2c alone. The data show that the free energy of dissociation increases when E2c binds to a nonspecific DNA sequence but increases even more when the protein binds to the specific DNA sequence. Thus, specific complexes are tighter but do not entail variation in the volume change. The thermodynamic data indicate that DNA-bound E2c dissociates into monomers bound to DNA. The existence of monomeric units of E2c bound to DNA may have implications for the formation of DNA loops, as an additional target for viral and host factors binding to the loosely associated dimer of the N-terminal module of the E2 protein.

Folding of a dimeric beta-barrel: residual structure in the urea denatured state of the human papillomavirus E2 DNA binding domain

The dimeric beta-barrel is a characteristic topology initially found in the transcriptional regulatory domain of the E2 DNA binding domain from papillomaviruses. We have previously described the kinetic folding mechanism of the human HPV-16 domain, and, as part of these studies, we present a structural characterization of the urea-denatured state of the protein. We have obtained a set of chemical shift assignments for the C-terminal domain in urea using heteronuclear NMR methods and found regions with persistent residual structure. Based on chemical shift deviations from random coil values, 3'J(NHN alpha) coupling constants, heteronuclear single quantum coherence peak intensities, and nuclear Overhauser effect data, we have determined clusters of residual structure in regions corresponding to the DNA binding helix and the second beta-strand in the folded conformation. Most of the structures found are of nonnative nature, including turn-like conformations. Urea denaturation at equilibrium displayed a loss in protein concentration dependence, in absolute parallel to a similar deviation observed in the folding rate constant from kinetic experiments. These results strongly suggest an alternative folding pathway in which a dimeric intermediate is formed and the rate-limiting step becomes first order at high protein concentrations. The structural elements found in the denatured state would collide to yield productive interactions, establishing an intermolecular folding nucleus at high protein concentrations. We discuss our results in terms of the folding mechanism of this particular topology in an attempt to contribute to a better understanding of the folding of dimers in general and intertwined dimeric proteins such as transcription factors in particular.

Crystal structure of the E2 DNA-binding domain from human papillomavirus type 16: implications for its DNA binding-site selection mechanism

The crystal structure of the E2 DNA-binding domain from the high-risk cervical cancer-associated strain human papillomavirus type 16 (HPV-16) is described here. The papillomavirus E2 proteins regulate transcription from all viral promoters and are required for the initiation of replication in vivo. They belong to a family of viral proteins that form dimeric beta-barrels and use surface alpha-helices for DNA interaction. Although all E2 proteins recognize the same consensus, palindromic DNA sequence, proteins from different viral strains differ in their abilities to discriminate among their specific DNA-binding sites. The structure reported here reveals that while the overall fold of the HPV-16 E2 DNA-binding domain resembles that of its counterpart from the related viral strain bovine papillomavirus type 1, the precise placement of the recognition helices is significantly different. Additionally, the charge distribution on the DNA-binding surfaces of the two proteins varies; HPV-16 E2 has a much less electropositive surface. HPV-16 E2 is thus less able to utilize charge neutralization of the phosphate groups on DNA to induce bending. These results correlate well with previous solution studies that showed decreased affinity between HPV-16 E2 and flexible DNA target sequences, and enhanced affinity towards A-tract-containing, pre-bent sequences. In summary, the crystal structure of the HPV-16 E2 DNA-binding domain shows that the protein presents a stereo-chemically and electrostatically unique surface to DNA, characteristics that can contribute to its mechanism of DNA target discrimination.

Characterization of a partially folded monomer of the DNA-binding domain of human papillomavirus E2 protein obtained at high pressure

The pressure-induced dissociation of the dimeric DNA binding domain of the E2 protein of human papillomavirus (E2-DBD) is a reversible process with a Kd of 5.6 x 10(-8) M at pH 5.5. The complete exposure of the intersubunit tryptophans to water, together with the concentration dependence of the pressure effect, is indicative of dissociation. Dissociation is accompanied by a decrease in volume of 76 ml/mol, which corresponds to an estimated increase in solvent-exposed area of 2775 A2. There is a decrease in fluorescence polarization of tryptophan overlapping the red shift of fluorescence emission, supporting the idea that dissociation of E2-DBD occurs in parallel with major changes in the tertiary structure. The dimer binds bis(8-anilinonaphthalene-1-sulfonate), and pressure reduces the binding by about 30%, in contrast with the almost complete loss of dye binding in the urea-unfolded state. These results strongly suggest the persistence of substantial residual structure in the high pressure state. Further unfolding of the high pressure state was produced by low concentrations of urea, as evidenced by the complete loss of bis(8-anilinonaphthalene-1-sulfonate) binding with less than 1 M urea. Following pressure dissociation, a partially folded state is also apparent from the distribution of excited state lifetimes of tryptophan. The combined data show that the tryptophans of the protein in the pressure-dissociated state are exposed long enough to undergo solvent relaxation, but the persistence of structure is evident from the observed internal quenching, which is absent in the completely unfolded state. The average rotational relaxation time (derived from polarization and lifetime data) of the pressure-induced monomer is shorter than the urea-denatured state, suggesting that the species obtained under pressure are more compact than that unfolded by urea.

Subunit rearrangement accompanies sequence-specific DNA binding by the bovine papillomavirus-1 E2 protein

The 2.5 A crystal structures of the DNA-binding domain of the E2 protein from bovine papillomavirus strain 1 and its complex with DNA are presented. E2 is a transcriptional regulatory protein that is also involved in viral DNA replication. It is the structural prototype for a novel class of DNA-binding proteins: dimeric beta-barrels with surface alpha-helices that serve as recognition helices. These helices contain the amino-acid residues involved in sequence-specifying interactions. The E2 proteins from different papillomavirus strains recognize and bind to the same consensus 12 base-pair DNA sequence. However, recent evidence from solution studies points to differences in the mechanisms by which E2 from the related viral strains bovine papillomavirus-1 and human papillomavirus-16 discriminate between DNA targets based on non-contacted nucleotide sequences. This report provides evidence that sequence-specific DNA-binding is accompanied by a rearrangement of protein subunits and deformation of the DNA. These results suggest that, along with DNA sequence-dependent conformational properties, protein subunit orientation plays a significant role in the mechanisms of target selection utilized by E2.