The MDM2-binding region in the transactivation domain of p53 also acts as a Bcl-X(L)-binding motif.

While the transcription-dependent mechanism of p53 has been extensively studied, recently the transcription-independent apoptotic activity of p53 has also been described. Bcl-2 and Bcl-X(L) interact with p53 and induce apoptosis. Initially, the p53 DNA-binding domain (p53DBD) was found to bind to Bcl-2 and Bcl-X(L). Later, the p53 N-terminal domain (p53NTD) was reported to be sufficient for inducing the transcription-independent apoptotic activity of p53 and also shown to interact with Bcl-X(L). Here, we further document that the transactivation domain of p53 (p53TAD) in p53NTD alone binds to Bcl-X(L). We demonstrated that the MDM2-binding region (residues S15 to N29, herein referred to as SN15) in p53TAD is the binding site for Bcl-X(L). The binding interface on Bcl-X(L) was identified at the hydrophobic pocket formed by the BH1, BH2, and BH3 domains, which also binds to the Bak/Bad BH3 peptides, suggesting Bcl-X(L) and MDM2 share a common binding motif in p53TAD. Our NMR structural studies have shown that the SN15 peptide undergoes a conformational change upon binding to Bcl-X(L). A Bcl-X(L)/SN15 complex structural model suggests that the SN15 peptide adopts an extended alpha-helical structure to bind to the hydrophobic pocket on the Bcl-X(L), which is similar to the mode of binding between BH3 peptides and Bcl-X(L).

Quaternary protein mimetics of gp41 elicit neutralizing antibodies against HIV fusion-active intermediate state.

During viral entry, the fusogenic state of human immunodeficiency virus Type 1 (HIV-1) envelope protein gp41 is a quaternary structure consisting of three gp41 glycoproteins, each with two conserved helical domains (N-HR and C-HR). Thus far, the examination of monomeric gp41 peptides as an immunologically focused approach to vaccine design has not been successful. Here we report an approach using quaternary protein mimetics (called 3alpha mimetics) that are based on the gp41 N-HR and C-HR domains to closely mimic the fusogenic state and overcome the deficiencies of the monomeric peptide approach for synthetic vaccine design. The 3alpha mimetics are conveniently prepared by chemoselective ligation of unprotected monomeric peptides to an interstrand linker, and display enhanced conformational stability compared to the corresponding monomers. The 3alpha mimetics with or without a covalently attached T-helper epitope were immunogenic and elicited antisera that bound both recombinant gp160, which contains gp41, and HIV-1 virions and immunoprecipitated recombinant gp41. Anti-3alpha mimetic antisera neutralized viral infectivity against R5- and X4-tropic strains of HIV-1 at 31.5 degrees C. The results suggest that a quaternary protein approach to mimic conserved and functional domains of viral envelope proteins is desirable for HIV vaccine development as such antigens are more likely to produce immunologically-focused and broadly neutralizing antibody responses.

Selection of active ScFv to G-protein-coupled receptor CCR5 using surface antigen-mimicking peptides.

This study describes the use of cyclic peptides for use in the selection of single-chain (ScFv) antibodies specific for the HIV-1 coreceptor CCR5, a representative G-protein-coupled receptor (GPCR). A tandem ligation strategy was developed for preparing biotinylated cyclic peptides, first through an orthogonal end-to-end ligation and then a chemoselective ligation with functionalized biotin. Cyclic peptides mimicking the extracellular loops of CCR5 and their unconstrained counterparts were then used for solution-phase selection of ScFv antibodies from a phage display antibody library. Antibodies reactive with CCR5 on cells were detected using a homogeneous high throughput assay. Of 19 isolated ScFv antibodies that bound to CCR5+ cells, three inhibited CCR5-mediated but not CXCR4-mediated HIV infection. Only ScFvs selected by binding to cyclic constrained peptides exhibited inhibitory activity. Our results demonstrate that surface-antigen mimetics of a GPCR are effective tools for selecting active, site-specific ScFv antibodies that hold promise as immunological reagents and therapeutics.

Translocating proline-rich peptides from the antimicrobial peptide bactenecin 7.

The intracellular delivery of most peptides, proteins, and nucleotides to the cytoplasm and nucleus is impeded by the cell membrane. To allow simplified, noninvasive delivery of attached cargo, cell-permeant peptides that are either highly cationic or hydrophobic have been utilized. Because cell-permeable peptides share half of the structural features of antimicrobial peptides containing clusters of charge and hydrophobic residues, we have explored antimicrobial peptides as templates for designing cell-permeant peptides. We prepared synthetic fragments of Bac 7, an antimicrobial peptide with four 14-residue repeats from the bactenecin family. The dual functions of cell permeability and antimicrobial activity of Bac 7 were colocalized at the N-terminal 24 residues of Bac 7. In general, long fragments of Bac(1-24) containing both regions were bactericidal and cell-permeable, whereas short fragments with only a cationic or hydrophobic region were cell-permeant without the attendant microbicidal activity when measured in a fluorescence quantitation assay and by confocal microscopy. In addition, the highly cationic fragments were capable of traversing the cell membrane and residing within the nucleus. A common characteristic shared by the cell-permeant Bac(1-24) fragments, irrespective of their number of charged cationic amino acids, is their high proline content. A 10-residue proline-rich peptide with two arginine residues was capable of delivering a noncovalently linked protein into cells. Thus, the proline-rich peptides represent a potentially new class of cell-permeant peptides for intracellular delivery of protein cargo. Furthermore, our results suggest that antimicrobial peptides may represent a rich source of templates for designing cell-permeant peptides.

Peptide dendrimers: applications and synthesis.

Peptide dendrimers are radial or wedge-like branched macromolecules consisting of a peptidyl branching core and/or covalently attached surface functional units. The multimeric nature of these constructs, the unambiguous composition and ease of production make this type of dendrimer well suited to various biotechnological and biochemical applications. Applications include use as biomedical diagnostic reagents, protein mimetics, anticancer and antiviral agents, vaccines and drug and gene delivery vehicles. This review focuses on the different types of peptide dendrimers currently in use and the synthetic methods commonly employed to generate peptide dendrimers ranging from stepwise solid-phase synthesis to chemoselective and orthogonal ligation.