Rapid optimization of a peptide inhibitor of malaria parasite invasion by comprehensive N-methyl scanning.

Apical membrane antigen 1 (AMA1) of the malaria parasite Plasmodium falciparum has been implicated in the invasion of host erythrocytes and is an important vaccine candidate. We have previously described a 20-residue peptide, R1, that binds to AMA1 and subsequently blocks parasite invasion. Because this peptide appears to target a site critical for AMA1 function, it represents an important lead compound for anti-malarial drug development. However, the effectiveness of this peptide inhibitor was limited to a subset of parasite isolates, indicating a requirement for broader strain specificity. Furthermore, a barrier to the utility of any peptide as a potential therapeutic is its susceptibility to rapid proteolytic degradation. In this study, we sought to improve the proteolytic stability and AMA1 binding properties of the R1 peptide by systematic methylation of backbone amides (N-methylation). The inclusion of a single N-methyl group in the R1 peptide backbone dramatically increased AMA1 affinity, bioactivity, and proteolytic stability without introducing global structural alterations. In addition, N-methylation of multiple R1 residues further improved these properties. Therefore, we have shown that modifications to a biologically active peptide can dramatically enhance activity. This approach could be applied to many lead peptides or peptide therapeutics to simultaneously optimize a number of parameters.

Phage display of peptides in ligand selection for use in affinity chromatography.

Large repertoires of peptides displayed on bacteriophage have been extensively used to select for ligand-binding molecules. This is a relatively straightforward process involving several cycles of selection against target molecules, and the resulting ligands can be tailored to various applications. In this chapter we describe detailed methods to select peptide ligands for affinity chromatography, with particular focus on selection of peptides that mimic antigen epitopes. The selection process involves screening a phage peptide library against a monoclonal antibody, proving the peptide is an authentic epitope mimic and coupling the peptide mimotope to an affinity resin for purifying antibodies from human serum. There are several other applications of phage peptides that could be used for affinity chromatography; the approaches are outlined, but detailed methods have not been included.

Shark IgNAR antibody mimotopes target a murine immunoglobulin through extended CDR3 loop structures.

Mimotopes mimic the three-dimensional topology of an antigen epitope, and are frequently recognized by antibodies with affinities comparable to those obtained for the original antibody-antigen interaction. Peptides and anti-idiotypic antibodies are two classes of protein mimotopes that mimic the topology (but not necessarily the sequence) of the parental antigen. In this study, we combine these two classes by selecting mimotopes based on single domain IgNAR antibodies, which display exceptionally long CDR3 loop regions (analogous to a constrained peptide library) presented in the context of an immunoglobulin framework with adjacent and supporting CDR1 loops. By screening an in vitro phage-display library of IgNAR variable domains (V(NAR)s) against the target antigen monoclonal antibody MAb5G8, we obtained four potential mimotopes. MAb5G8 targets a linear tripeptide epitope (AYP) in the flexible signal sequence of the Plasmodium falciparum Apical Membrane Antigen-1 (AMA1), and this or similar motifs were detected in the CDR loops of all four V(NAR)s. The V(NAR)s, 1-A-2, -7, -11, and -14, were demonstrated to bind specifically to this paratope by competition studies with an artificial peptide and all showed enhanced affinities (3-46 nM) compared to the parental antigen (175 nM). Crystallographic studies of recombinant proteins 1-A-7 and 1-A-11 showed that the SYP motifs on these V(NAR)s presented at the tip of the exposed CDR3 loops, ideally positioned within bulge-like structures to make contact with the MAb5G8 antibody. These loops, in particular in 1-A-11, were further stabilized by inter- and intra- loop disulphide bridges, hydrogen bonds, electrostatic interactions, and aromatic residue packing. We rationalize the higher affinity of the V(NAR)s compared to the parental antigen by suggesting that adjacent CDR1 and framework residues contribute to binding affinity, through interactions with other CDR regions on the antibody, though of course definitive support of this hypothesis will rely on co-crystallographic studies. Alternatively, the selection of mimotopes from a large (<4 x 10(8)) constrained library may have allowed selection of variants with even more favorable epitope topologies than present in the original antigenic structure, illustrating the power of in vivo selection of mimotopes from phage-displayed molecular libraries.

Structure of an IgNAR-AMA1 complex: targeting a conserved hydrophobic cleft broadens malarial strain recognition.

Apical membrane antigen 1 (AMA1) is essential for invasion of erythrocytes and hepatocytes by Plasmodium parasites and is a leading malarial vaccine candidate. Although conventional antibodies to AMA1 can prevent such invasion, extensive polymorphisms within surface-exposed loops may limit the ability of these AMA1-induced antibodies to protect against all parasite genotypes. Using an AMA1-specific IgNAR single-variable-domain antibody, we performed targeted mutagenesis and selection against AMA1 from three P. falciparum strains. We present cocrystal structures of two antibody-AMA1 complexes which reveal extended IgNAR CDR3 loops penetrating deep into a hydrophobic cleft on the antigen surface and contacting residues conserved across parasite species. Comparison of a series of affinity-enhancing mutations allowed dissection of their relative contributions to binding kinetics and correlation with inhibition of erythrocyte invasion. These findings provide insights into mechanisms of single-domain antibody binding, and may enable design of reagents targeting otherwise cryptic epitopes in pathogen antigens.

Structure of the malaria antigen AMA1 in complex with a growth-inhibitory antibody.

Identifying functionally critical regions of the malaria antigen AMA1 (apical membrane antigen 1) is necessary to understand the significance of the polymorphisms within this antigen for vaccine development. The crystal structure of AMA1 in complex with the Fab fragment of inhibitory monoclonal antibody 1F9 reveals that 1F9 binds to the AMA1 solvent-exposed hydrophobic trough, confirming its importance. 1F9 uses the heavy and light chain complementarity-determining regions (CDRs) to wrap around the polymorphic loops adjacent to the trough, but uses a ridge of framework residues to bind to the hydrophobic trough. The resulting 1F9-AMA1-combined buried surface of 2,470 A(2) is considerably larger than previously reported Fab-antigen interfaces. Mutations of polymorphic AMA1 residues within the 1F9 epitope disrupt 1F9 binding and dramatically reduce the binding of affinity-purified human antibodies. Moreover, 1F9 binding to AMA1 is competed by naturally acquired human antibodies, confirming that the 1F9 epitope is a frequent target of immunological attack.

Mimotopes of apical membrane antigen 1: Structures of phage-derived peptides recognized by the inhibitory monoclonal antibody 4G2dc1 and design of a more active analogue.

Apical membrane antigen 1 (AMA1) of the malaria parasite Plasmodium falciparum is an integral membrane protein that plays a key role in merozoite invasion of host erythrocytes. A monoclonal antibody, 4G2dc1, recognizes correctly folded AMA1 and blocks merozoite invasion. Phage display was used to identify peptides that bind to 4G2dc1 and mimic an important epitope of AMA1. Three of the highest-affinity binders--J1, J3, and J7--were chosen for antigenicity and immunogenicity studies. J1 and J7 were found to be true antigen mimics since both peptides generated inhibitory antibodies in rabbits (J. L. Casey et al., Infect. Immun. 72:1126-1134, 2004). In the present study, the solution structures of all three mimotopes were investigated by nuclear magnetic resonance spectroscopy. J1 adopted a well-defined region of structure, which can be attributed in part to the interactions of Trp11 with surrounding residues. In contrast, J3 and J7 did not adopt an ordered conformation over the majority of residues, although they share a region of local structure across their consensus sequence. Since J1 was the most structured of the peptides, it provided a template for the design of a constrained analogue, J1cc, which shares a structure similar to that of J1 and has a disulfide-stabilized conformation around the Trp11 region. J1cc binds with greater affinity to 4G2dc1 than does J1. These peptide structures provide the foundation for a better understanding of the complex conformational nature of inhibitory epitopes on AMA1. With its greater conformational stability and higher affinity for AMA1, J1cc may be a better in vitro correlate of immunity than the peptides identified by phage display.

Peptide mimotopes selected from a random peptide library for diagnosis of Epstein-Barr virus infection.

Epstein-Barr virus (EBV) is a ubiquitous, worldwide infectious agent that causes infectious mononucleosis, affecting >90% of the world's population. Currently, enzyme-linked immunosorbent assay, mostly with purified preparations of EBV cell extracts to capture immunoglobulin M (IgM) antibodies in patients' serum, is used for primary diagnosis. Our objective was to determine whether a small set of peptides could contain sufficient immunogenic information to replace solid-phase antigens in EBV diagnostics. Using monoclonal antibodies, we selected four peptides that mimic different epitopes of EBV from a phage-displayed random peptide library. To assess their diagnostic value, we screened a panel of 62 individual EBV IgM sera for their reactivities with the peptides alone. For all peptides, there was a clear distinction between the EBV-positive and the EBV-negative samples, resulting in 100% specificity. The sensitivities were 88%, 85%, 71%, and 54% for peptides F1, A3, gp125, and A2, respectively. Any combination of peptides increased the sensitivity, indicating that individual peptides react with different subsets of antibodies. Furthermore, when the F1 and the gp125 peptides were coupled to bovine serum albumin and screened against 216 serum samples, there were dramatic improvements in sensitivities (95% and 92%, respectively) and little cross-reactivity with the other peptides encountered during acute viral infections, including rheumatoid factor. This study shows the potential for the use of peptide mimotopes as alternatives to the complex antigens used in current serodiagnostics for EBV infection.

Binding hot spot for invasion inhibitory molecules on Plasmodium falciparum apical membrane antigen 1.

Apical membrane antigen 1 (AMA1) is expressed in schizont-stage malaria parasites and sporozoites and is thought to be involved in the invasion of host red blood cells. AMA1 is an important vaccine candidate, as immunization with this antigen induces a protective immune response in rodent and monkey models of human malaria. Additionally, anti-AMA1 polyclonal and monoclonal antibodies inhibit parasite invasion in vitro. We have isolated a 20-residue peptide (R1) from a random peptide library that binds to native AMA1 as expressed by Plasmodium falciparum parasites. Binding of R1 peptide is dependent on AMA1 having the proper conformation, is strain specific, and results in the inhibition of merozoite invasion of host erythrocytes. The solution structure of R1, as determined by nuclear magnetic resonance spectroscopy, contains two structured regions, both involving turns, but the first region, encompassing residues 5 to 10, is hydrophobic and the second, at residues 13 to 17, is more polar. Several lines of evidence reveal that R1 targets a "hot spot" on the AMA1 surface that is also recognized by other peptides and monoclonal antibodies that have previously been shown to inhibit merozoite invasion. The functional consequence of binding to this region by a variety of molecules is the inhibition of merozoite invasion into host erythrocytes. The interaction between these peptides and AMA1 may further our understanding of the molecular mechanisms of invasion by identifying critical functional regions of AMA1 and aid in the development of novel antimalarial strategies.

Selection and affinity maturation of IgNAR variable domains targeting Plasmodium falciparum AMA1.

The new antigen receptor (IgNAR) is an antibody unique to sharks and consists of a disulphide-bonded dimer of two protein chains, each containing a single variable and five constant domains. The individual variable (V(NAR)) domains bind antigen independently, and are candidates for the smallest antibody-based immune recognition units. We have previously produced a library of V(NAR) domains with extensive variability in the CDR1 and CDR3 loops displayed on the surface of bacteriophage. Now, to test the efficacy of this library, and further explore the dynamics of V(NAR) antigen binding we have performed selection experiments against an infectious disease target, the malarial Apical Membrane Antigen-1 (AMA1) from Plasmodium falciparum. Two related V(NAR) clones were selected, characterized by long (16- and 18-residue) CDR3 loops. These recombinant V(NAR)s could be harvested at yields approaching 5mg/L of monomeric protein from the E. coli periplasm, and bound AMA1 with nanomolar affinities (K(D)= approximately 2 x 10(-7) M). One clone, designated 12Y-2, was affinity-matured by error prone PCR, resulting in several variants with mutations mapping to the CDR1 and CDR3 loops. The best of these variants showed approximately 10-fold enhanced affinity over 12Y-2 and was Plasmodium falciparum strain-specific. Importantly, we demonstrated that this monovalent V(NAR) co-localized with rabbit anti-AMA1 antisera on the surface of malarial parasites and thus may have utility in diagnostic applications.

Antibodies to malaria peptide mimics inhibit Plasmodium falciparum invasion of erythrocytes.

Apical membrane antigen 1 (AMA1) is expressed on the surfaces of Plasmodium falciparum merozoites and is thought to play an important role in the invasion of erythrocytes by malaria parasites. To select for peptides that mimic conformational B-cell epitopes on AMA1, we screened a phage display library of >10(8) individual peptides for peptides bound by a monoclonal anti-AMA1 antibody, 4G2dc1, known to inhibit P. falciparum invasion of erythrocytes. The most reactive peptides, J1, J3, and J7, elicited antibody responses in rabbits that recognized the peptide immunogen and both recombinant and parasite AMA1. Human antibodies in plasma samples from individuals exposed to chronic malaria reacted with J1 and J7 peptides and were isolated using immobilized peptide immunoadsorbents. Both rabbit and human antibodies specific for J1 and J7 peptides were able to inhibit the invasion of erythrocytes by P. falciparum merozoites. This is the first example of phage-derived peptides that mimic an important epitope of a blood-stage malaria vaccine candidate, inducing and isolating functional protective antibodies. Our data support the use of J1 and J7 peptide mimics as in vitro correlates of protective immunity in future AMA1 vaccine trials.

Structures of phage-display peptides that bind to the malarial surface protein, apical membrane antigen 1, and block erythrocyte invasion.

Apical membrane antigen 1 (AMA1) of the human malaria parasite Plasmodium falciparum is synthesized by schizont stage parasites and has been implicated in merozoite invasion of host erythrocytes. Phage-display techniques have recently been used to identify two 15-residue peptides, F1 and F2, which bind specifically to P. falciparum AMA1 and inhibit parasite invasion of erythrocytes [Li, F., et al. (2002) J. Biol. Chem. 277, 50303-50310]. We have synthesized F1, F2, and three peptides with high levels of sequence identity, determined their relative binding affinities for P. falciparum AMA1 with a competition ELISA, and investigated their solution structures by NMR spectroscopy. The strongest binding peptide, F1, contains a beta-turn that includes residues identified via an alanine scan as being critical for binding to AMA1 and inhibition of merozoite invasion of erythrocytes. The three F1 analogues include a 10-residue analogue of F1 truncated at the C-terminus (tF1), a partially scrambled 15-mer (sF1), and a disulfide-constrained 14-mer (F1tbp) which is related to F1 but has a sequence identical to that of a disulfide-constrained loop in the first epidermal growth factor module of the latent transforming growth factor-beta binding protein. tF1 and F1tbp bound competitively with F1 to AMA1, and all three contain a type I beta-turn encompassing key residues involved in F1 binding. In contrast, sF1 lacked this structural motif, and did not compete for binding to AMA1 with F1; rather, sF1 contained a type III beta-turn involving a different part of the sequence. Although F2 was able to bind to AMA1, it was unstructured in solution, consistent with its weak invasion inhibitory effects. Thus, the secondary structure elements observed for these peptides in solution correlate well with their potency in binding to AMA1 and inhibiting merozoite invasion. The structures provide a valuable starting point for the development of peptidomimetics as antimalarial antagonists directed at AMA1.

Cambridge Healthtech Institute's 5th Annual 'Molecular Display: The Chemistry Set for Proteins and Small Molecules' Conference.

This meeting covered recent advances in the molecular display of peptides, proteins and nucleotides, including selection and mutational technologies. The scientific organisers assembled an impressive array of 'molecular display' heavyweights. It promised to be a stimulating meeting and the events of the following 2 days did not disappoint. The majority of the presentations were concerned with the development of novel display technologies and processes. Antibodies currently represent > 30% of the biopharmaceutical market, but are likely to be superseded by more efficient display frameworks which avoid their inherent drawbacks. In order to generate such novel therapeutics and diagnostics, high affinity reagents must be selected and/or generated from hitherto unexplored nucleic acid sequences and displayed on suitable frameworks. This meeting was concerned with the identification, generation and validation of novel sequences and framework molecules. The keynote addresses were followed by four themed sessions entitled New technologies and target selection, The discovery of small molecules using phage display, Applications in proteomics, and Novel therapeutics and diagnostics. There was a panel discussion after each session.

Cambridge Healthtech Institute's 4th Annual Recombinant Antibodies Conference.

The 4th Annual Recombinant Antibodies Conference was immediately following the 5th Annual 'Molecular Display: The Chemistry Set for Proteins and Small Molecules' conference, both held in Cambridge, MA and organised by Cambridge Healthtech Institute. The former conference focused on development of new approaches for recombinant antibody development, with particular emphasis on improved methods for selection and optimisation allowing rapid validation and development of human antibodies for the clinic. There were many impressive presentations describing emerging technologies such as new antibody-like scaffolds, covalent P2 antibody display, de-immunisation of antibodies and measuring affinities of as many as 400 clones simultaneously using proteomic microarray platforms. The conference also highlighted the latest applications of library technologies for proteomics and target discovery, and the generation of therapeutic molecules as antibodies alone or as drug, toxin or radionuclide conjugates.

Discovery of novel targets of quinoline drugs in the human purine binding proteome.

The quinolines have been used in the treatment of malaria, arthritis, and lupus for many years, yet the precise mechanism of their action remains unclear. In this study, we used a functional proteomics approach that exploited the structural similarities between the quinoline compounds and the purine ring of ATP to identify quinoline-binding proteins. Several quinoline drugs were screened by displacement affinity chromatography against the purine binding proteome captured with gamma-phosphate-linked ATP-Sepharose. Screening of the human red blood cell purine binding proteome identified two human proteins, aldehyde dehydrogenase 1 (ALDH1) and quinone reductase 2 (QR2). In contrast, no proteins were detected upon screening of the Plasmodium falciparum purine binding proteome with the quinolines. In a complementary approach, we passed cell lysates from mice, red blood cells, or P. falciparum over hydroxychloroquine- or primaquine-Sepharose. Consistent with the displacement affinity chromatography screen, ALDH and QR2 were the only proteins recovered from mice and human red blood cell lysate and no proteins were recovered from P. falciparum. Furthermore, the activity of QR2 was potently inhibited by several of the quinolines in vitro. Our results show that ALDH1 and QR2 are selective targets of the quinolines and may provide new insights into the mechanism of action of these drugs.

Phage-displayed peptides bind to the malarial protein apical membrane antigen-1 and inhibit the merozoite invasion of host erythrocytes.

Apical membrane antigen-1 (AMA1) is a transmembrane protein present on the surface of merozoites that is thought to be involved in the process of parasite invasion of host erythrocytes. Although it is the target of a natural immune response that can inhibit invasion, little is known about the molecular mechanisms by which AMA1 facilitates the invasion process. In an attempt to identify peptides that specifically interact with and block the function of AMA1, a random peptide library displayed on the surface of filamentous phage was panned on recombinant AMA1 from Plasmodium falciparum. Three peptides with affinity for AMA1 were isolated, and characterization of their fine binding specificities indicated that they bind to a similar region on the surface of AMA1. One of these peptides was found to be a potent inhibitor of the invasion of P. falciparum merozoites into human erythrocytes. We propose that this peptide blocks interaction between AMA1 and a ligand on the erythrocyte surface that is involved in a critical step in malarial invasion. The identification and characterization of these peptide inhibitors now permit an evaluation of the essential requirements that are necessary for efficient neutralization of merozoite invasion by blocking AMA1 function.

Structure of domain III of the blood-stage malaria vaccine candidate, Plasmodium falciparum apical membrane antigen 1 (AMA1).

Apical membrane antigen 1 of the malarial parasite Plasmodium falciparum (Pf AMA1) is a merozoite antigen that is considered a strong candidate for inclusion in a malaria vaccine. Antibodies reacting with disulphide bond-dependent epitopes in AMA1 block invasion of host erythrocytes by P.falciparum merozoites, and we show here that epitopes involving sites of mutations in domain III are targets of inhibitory human antibodies. The solution structure of AMA1 domain III, a 14kDa protein, has been determined using NMR spectroscopy on uniformly 15N and 13C/15N-labelled samples. The structure has a well-defined disulphide-stabilised core region separated by a disordered loop, and both the N and C-terminal regions of the molecule are unstructured. Within the disulphide-stabilised core, residues 443-447 form a turn of helix and residues 495-498 and 503-506 an anti-parallel beta-sheet with a distorted type I beta-turn centred on residues 500-501, producing a beta-hairpin-type structure. The structured region of the molecule includes all three disulphide bonds. The previously unassigned connectivities for two of these bonds could not be established with certainty from the NMR data and structure calculations, but were determined to be C490-C507 and C492-C509 from an antigenic analysis of mutated forms of this domain expressed using phage display. Naturally occurring mutations in domain III that are located far apart in the primary sequence tend to cluster in the region of the disulphide core in the three-dimensional structure of the molecule. The structure shows that nearly all the polymorphic sites have a high level of solvent accessibility, consistent with their location in epitopes recognised by protective antibodies. Even though domain III in solution contains significant regions of disorder in the structure, the disulphide-stabilised core that is structured is clearly an important element of the antigenic surface of AMA1 recognised by protective antibodies.