Antibody recognition of a flexible epitope at the DNA binding site of the human papillomavirus transcriptional regulator E2

The influence of proline isomerization on potency and stability of anti-HIV antibody 10E8

Monoclonal antibody (mAb) 10E8 recognizes a highly conserved epitope on HIV and is capable of neutralizing > 95% of circulating viral isolates making it one of the most promising Abs against HIV. Solution instability and biochemical heterogeneity of 10E8 has hampered its development for clinical use. We identify the source of 10E8 heterogeneity being linked to cis/trans isomerization at two prolines within the YPP motif in the CRD3 loop that exists as two predominant conformers that interconvert on a slow timescale. The Y_transP conformation conformer can bind the HIV gp41 epitope, while the Y_cisP is not binding competent and shows a higher aggregation propensity. The high barrier of isomerization and propensity to adopt non-binding competent proline conformers provides novel insight into the slow binding kinetics, low potency, and poor solubility of 10E8. This study highlights how proline isomerization should be considered a critical quality attribute for biotherapeutics with paratopes containing potential cis proline amide bonds.

Epitope location for two monoclonal antibodies against human cystatin C, representing opposite aggregation inhibitory properties

Human cystatin C (hCC), like many other amyloidogenic proteins, dimerizes and possibly makes aggregates by subdomain swapping. Inhibition of the process should suppress the fibrillogenesis leading to a specific amyloidosis (hereditary cystatin C amyloid angiopathy, HCCAA). It has been reported that exogenous agents like monoclonal antibodies against cystatin C are able to suppress formation of cystatin C dimers and presumably control the neurodegenerative disease. We have studied in detail two monoclonal antibodies (mAbs) representing very different aggregation inhibitory potency, Cyst10 and Cyst28, to find binding sites in hCC sequence responsible for the immunocomplex formation and pave the way for possible immunotherapy of HCCAA. We used the epitope extraction/excision mass spectrometry approach with the use of different enzymes complemented by affinity studies with synthetic hCC fragments as a basic technique for epitope identification. The results were analyzed in the context of hCC structure allowing us to discuss the binding sites for both antibodies. Epitopic sequences for clone Cyst28 which is a highly potent dimerization inhibitor were found in N-terminus, loop 1 and 2 (L1, L2) and fragments of β2 and β3 strands. The crucial difference between conformational epitope sequences found for both mAbs seems to be the lack of interactions with hCC via N-terminus and the loop 1 in the case of mAb Cyst10. Presumably the interactions of mAbs with hCC via L1 and β sheet fragments make the hCC structure rigid and unable to undergo the swapping process.

Minute time scale prolyl isomerization governs antibody recognition of an intrinsically disordered immunodominant epitope

Conformational rearrangements in antibody·antigen recognition are essential events where kinetic discrimination of isomers expands the universe of combinations. We investigated the interaction mechanism of a monoclonal antibody, M1, raised against E7 from human papillomavirus, a prototypic viral oncoprotein and a model intrinsically disordered protein. The mapped 12-amino acid immunodominant epitope lies within a "hinge" region between the N-terminal intrinsically disordered and the C-terminal globular domains. Kinetic experiments show that despite being within an intrinsically disordered region, the hinge E7 epitope has at least two populations separated by a high energy barrier. Nuclear magnetic resonance traced the origin of this barrier to a very slow (t(1/2)∼4 min) trans-cis prolyl isomerization event involving changes in secondary structure. The less populated (10%) cis isomer is the binding-competent species, thus requiring the 90% of molecules in the trans configuration to isomerize before binding. The association rate for the cis isomer approaches 6 × 10(7) M(-1) s(-1), a ceiling for antigen-antibody interactions. Mutagenesis experiments showed that Pro-41 in E7Ep was required for both binding and isomerization. After a slow postbinding unimolecular rearrangement, a consolidated complex with K(D) = 1.2 × 10(-7) M is reached. Our results suggest that presentation of this viral epitope by the antigen-presenting cells would have to be "locked" in the cis conformation, in opposition to the most populated trans isomer, in order to select the specific antibody clone that goes through affinity and kinetic maturation.

A strained DNA binding helix is conserved for site recognition, folding nucleation, and conformational modulation

Nucleic acid recognition is often mediated by alpha-helices or disordered regions that fold into alpha-helix on binding. A peptide bearing the DNA recognition helix of HPV16 E2 displays type II polyproline (PII) structure as judged by pH, temperature, and solvent effects on the CD spectra. NMR experiments indicate that the canonical alpha-helix is stabilized at the N-terminus, while the PII forms at the C-terminus half of the peptide. Re-examination of the dihedral angles of the DNA binding helix in the crystal structure and analysis of the NMR chemical shift indexes confirm that the N-terminus half is a canonical alpha-helix, while the C-terminal half adopts a 3(10) helix structure. These regions precisely match two locally driven folding nucleii, which partake in the native hydrophobic core and modulate a conformational switch in the DNA binding helix. The peptide shows only weak and unspecific residual DNA binding, 10(4)-fold lower affinity, and 500-fold lower discrimination capacity compared with the domain. Thus, the precise side chain conformation required for modulated and tight physiological binding by HPV E2 is largely determined by the noncanonical strained alpha-helix conformation, "presented" by this unique architecture. (c) 2009 Wiley Periodicals, Inc. Biopolymers 91: 432-443, 2009.

Epitope mapping by proteolysis of antigen-antibody complexes

The ability to accurately characterize an epitope on an antigen is essential to understand the pathogenesis of an infectious material, and for the design and development of drugs and vaccines. Emergence of a new contagious microbial or viral variant necessitates the need for robust identification and characterization of the antigenic determinant. Recent advances have made mass spectrometry (MS) a robust and sensitive analytical tool with high mass accuracy. The use of MS to characterize peptides and proteins has gained popularity in the research arena involving protein-protein interactions. Combining the modern mass spectrometric principles of protein-protein interaction studies with the classical use of limited proteolysis, a linear epitope on a peptide or a protein antigen can be accurately mapped in a short time, compared with other traditional techniques available for epitope mapping. Additionally, complete MS analyses can be achieved with very little sample consumption. Here we discuss the overall approach to characterize the detailed interaction between a linear antigen (either a peptide or a protein antigen) and its corresponding monoclonal antibody by using MS. The steps involved in epitope excision, epitope extraction, and indirect immunosorption are outlined thoroughly. Conditions required for MS analysis using either matrix assisted laser desorption ionization (MALDI) or electrospray ionization (ESI) sources are summarized, with special emphasis on the experimental protocols.

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.