Refolding and characterization of a diabody against Pfs25, a vaccine candidate of Plasmodium falciparum.

Pfs25, a vaccine candidate, expressed on the surface of the malarial parasite, plays an important role in the development of Plasmodium falciparum. 1269, a monoclonal antibody targeting the epidermal growth factor-like domain 1 and epidermal growth factor-like domain 3 of Pfs25, blocks the transmission of parasites in mosquitoes. In this study, we refolded 1269-Db, a dimeric antibody fragment referred as diabody, designed from 1269, with a yield of 3 mg/litre of bacterial culture. Structural integrity of the protein was validated with thermal stability, disulphide bond analysis and glutaraldehyde crosslinking experiments. To evaluate the functionality of 1269-Db, recombinant monomeric MBP-Pfs25 was produced from bacteria. Qualitative binding assays demonstrated that 1269-Db recognized the epitopes on Pfs25 in its native, but not the denatured state. An apparent KD of 2.6 nM was determined for 1269-Db with monomeric MBP-Pfs25, using isothermal titration calorimetry. 1269-Db recognized the periphery of zygotes/ookinetes, demonstrating recognition of Pfs25, expressed on the surface of the parasite. As the established refolding method resulted in a functional diabody, the optimized method pipeline for 1269-Db can potentially facilitate engineering of antibody fragments with desired properties.

Structure of a 14-3-3ε:FOXO3apS253 Phosphopeptide Complex Reveals 14-3-3 Isoform-Specific Binding of Forkhead Box Class O Transcription Factor (FOXO) Phosphoproteins.

The transcriptional activity of Forkhead Box O3 (FOXO3a) is inactivated by AKT-mediated phosphorylation on Serine 253 (S253), which enables FOXO3a binding to 14-3-3. Phosphorylated FOXO3a binding to 14-3-3 facilitates the nuclear exclusion of FOXO3a, causing cancer cell proliferation. The FOXO3a/14-3-3 interaction has, therefore, emerged as an important therapeutic target. Here, we report a comprehensive analysis using fluorescence polarization, isothermal titration calorimetry, small-angle X-ray scattering, X-ray crystallography, and molecular dynamics simulations to gain molecular-level insights into the interaction of FOXO3apS253 phosphopeptide with 14-3-3ε. A high-resolution structure of the fluorophore-labeled FOXO3apS253:14-3-3ε complex revealed a distinct mode of interaction compared to other 14-3-3 phosphopeptide complexes. FOXO3apS253 phosphopeptide showed significant structural difference in the positions of the -3 and -4 Arg residues relative to pSer, compared to that of a similar phosphopeptide, FOXO1pS256 bound to 14-3-3σ. Moreover, molecular dynamics studies show that the significant structural changes and molecular interactions noticed in the crystal structure of FOXO3apS253:14-3-3ε are preserved over the course of the simulation. Thus, this study reveals structural differences between the binding to 14-3-3 isoforms of FOXO1pS256 versus FOXO3apS253, providing a framework for the rational design of isoform-specific FOXO/14-3-3 protein-protein interaction inhibitors for therapy.

Molecular insights into α-synuclein interaction with individual human core histones, linker histone, and dsDNA.

α-Synuclein (αS) plays a key role in Parkinson's disease (PD). The αS nuclear role, its binding affinity and specificity to histones and dsDNA remains unknown. Here, we have measured the binding affinity ( Kd ) between αS wild-type (wt) and PD-specific αS S129-phosphorylation mimicking (S129E) mutant with full-length and flexible tail truncated individual core histones (H2a, H2b, H3, and H4), linker histone (H1), and carried out αS-dsDNA interaction studies. This study revealed that αS(wt) interacts specifically with N-terminal flexible tails of histone H3, H4, and flexible tails of H1. The αS(S129E) mutant recognizes histones similar to αS(wt) but binds with higher affinity. Intriguingly, αS(S129E) showed a binding affinity for control proteins (bovine serum albumin and lysozyme), while no interaction was seen for αS(wt). Based on our above observation, we contemplate that the physio-chemical properties of αS with S129-phosphorylation has changed compared to αS(wt), resulting in interaction for other proteins, which is the basis for Lewy body formation. Besides, this study showed αS binding to dsDNA is weak and nonspecific. Overall, αS specificity for histone binding suggests that its nuclear role is possibly driven through histone interaction.

Target identification for small-molecule discovery in the FOXO3a tumor-suppressor pathway using a biodiverse peptide library.

Genetic screening technologies to identify and validate macromolecular interactions (MMIs) essential for complex pathways remain an important unmet need for systems biology and therapeutics development. Here, we use a library of peptides from diverse prokaryal genomes to screen MMIs promoting the nuclear relocalization of Forkhead Box O3 (FOXO3a), a tumor suppressor more frequently inactivated by post-translational modification than mutation. A hit peptide engages the 14-3-3 family of signal regulators through a phosphorylation-dependent interaction, modulates FOXO3a-mediated transcription, and suppresses cancer cell growth. In a crystal structure, the hit peptide occupies the phosphopeptide-binding groove of 14-3-3ε in a conformation distinct from its natural peptide substrates. A biophysical screen identifies drug-like small molecules that displace the hit peptide from 14-3-3ε, providing starting points for structure-guided development. Our findings exemplify "protein interference," an approach using evolutionarily diverse, natural peptides to rapidly identify, validate, and develop chemical probes against MMIs essential for complex cellular phenotypes.

Targeting Phosphopeptide Recognition by the Human BRCA1 Tandem BRCT Domain to Interrupt BRCA1-Dependent Signaling.

Intracellular signals triggered by DNA breakage flow through proteins containing BRCT (BRCA1 C-terminal) domains. This family, comprising 23 conserved phosphopeptide-binding modules in man, is inaccessible to small-molecule chemical inhibitors. Here, we develop Bractoppin, a drug-like inhibitor of phosphopeptide recognition by the human BRCA1 tandem (t)BRCT domain, which selectively inhibits substrate binding with nanomolar potency in vitro. Structure-activity exploration suggests that Bractoppin engages BRCA1 tBRCT residues recognizing pSer in the consensus motif, pSer-Pro-Thr-Phe, plus an abutting hydrophobic pocket that is distinct in structurally related BRCT domains, conferring selectivity. In cells, Bractoppin inhibits substrate recognition detected by Förster resonance energy transfer, and diminishes BRCA1 recruitment to DNA breaks, in turn suppressing damage-induced G2 arrest and assembly of the recombinase, RAD51. But damage-induced MDC1 recruitment, single-stranded DNA (ssDNA) generation, and TOPBP1 recruitment remain unaffected. Thus, an inhibitor of phosphopeptide recognition selectively interrupts BRCA1 tBRCT-dependent signals evoked by DNA damage.