Peptide phage display library as source for inhibitors of clostridial neurotoxins

Clostridial neurotoxins are the most powerful toxins known. There are no available antidotes to neutralize neurotoxins after they have been internalized by neuronal cells. Enzymatic domains of clostridial neurotoxins are zinc-endopeptidases specific for protein components of the neuroexocytosis apparatus. Thus, attempts were made to find such antidotes among molecules possessing chelating properties. Subsequently, it was proposed that the process of interaction between clostridial neurotoxins and their substrates might be more complex than viewed previously and may include several separate regions of interaction. Phage display technology is free from bias toward any particular model. This technology in combination with recombinantly produced light chains of botulinum neurotoxins serotypes A, B, and C was used to identify potential inhibitors of clostridial neurotoxins. Identified sequences did not show substantial similarity with substrate proteins of clostridial neurotoxins. Nevertheless, three peptides chosen for further analysis were able to inhibit enzymatic activity of all clostridial neurotoxins tested. This work demonstrates that at least one of these peptides could not be cleaved by clostridial neurotoxin. Attempts to delete amino acid residues from this peptide resulted in dramatic loss of its inhibitory activity. Finally, this work presents a novel approach to searching for inhibitors of clostridial neurotoxins.     

利用噬菌体表面展示技术筛选转铁蛋白黏附肽的研究

为了筛选转铁蛋白黏附肽,应用噬菌体表面展示技术经过三轮生物淘选,成功地从随机七肽库中得到黏附转铁蛋白的重组噬菌体克隆,经过相对亲和力常数测定和DNA测序得到4个转铁蛋白黏附肽的序列。实验中以回收率和选择比为操作参数,对淘选进行了优化,并发展了一种基于噬菌体滴度的相对亲和力常数测定方法。转铁蛋白受体是一种有效的肿瘤标记物,利用转铁蛋白为载体可以实现药物靶向运输,因此转铁蛋白黏附肽将是重组蛋白质药物连接转铁蛋白的有用标签。     

Phage display screening for peptidic chitinase inhibitors

A phage display library with disulfide-cyclized peptides was screened for peptides binding to chitinases from Serratia marcescens. One of those peptides was found to efficiently inhibit chitinase A and two others were inhibitors of chitinase B. Complete substitutional analysis of all three peptides using cellulose-bound peptide spot synthesis revealed key interaction positions and allowed optimization of the chitinase B inhibitory peptides towards higher affinity, with inhibitory constants in the lower nanomolar range. Inhibition by all peptides proved to be competitive and highly specific for the chitinase used to select them, as shown with a series of chitinases from different organisms.     

Phage display: an important tool in the discovery of peptides with anti-HIV activity

Human immunodeficiency virus (HIV) remains a worldwide health problem despite huge investments and research breakthroughs, and no single drug is effective in killing the virus yet. Among new strategies to control HIV infection, the phage display (PD) technology has become a promising tool in the discovery of peptides that can be used as new drugs, or also as possible vaccine candidates. This review discusses basic aspects of PD and its use to advance two main objectives related to combating HIV-1 infection: the identification of peptides that inhibit virus replication and the identification of peptides that induce the production of neutralizing antibodies. We will cover the different approaches used for mapping and selection of mimotopes, and discuss the promising results of these biologicals as antiviral agents.     

A Protocol for Phage Display and Affinity Selection Using Recombinant Protein Baits

Using recombinant phage as a scaffold to present various protein portions encoded by a directionally cloned cDNA library to immobilized bait molecules is an efficient means to discover interactions. The technique has largely been used to discover protein-protein interactions but the bait molecule to be challenged need not be restricted to proteins. The protocol presented here has been optimized to allow a modest number of baits to be screened in replicates to maximize the identification of independent clones presenting the same protein. This permits greater confidence that interacting proteins identified are legitimate interactors of the bait molecule. Monitoring the phage titer after each affinity selection round provides information on how the affinity selection is progressing as well as on the efficacy of negative controls. One means of titering the phage, and how and what to prepare in advance to allow this process to progress as efficiently as possible, is presented. Attributes of amplicons retrieved following isolation of independent plaque are highlighted that can be used to ascertain how well the affinity selection has progressed. Trouble shooting techniques to minimize false positives or to bypass persistently recovered phage are explained. Means of reducing viral contamination flare up are discussed.     

Phage display combinatorial libraries of short peptides: ligand selection for protein purification

A library of heptapeptides displayed on the surface of filamentous phage M13 was evaluated as a potential source of affinity ligands for the purification of Rhizomucor miehei lipase. Two independent selection (biopanning) protocols were employed: the enzyme was either physically adsorbed on polystyrene or chemically immobilized on small magnetic beads. From screening with the polystyrene-adsorbed lipase it was found that there was a rapid enrichment of the library with “doublet” clones i.e. the phage species which carried two consecutive sequences of heptapeptides, whilst no such clones were observed from the screening using lipase attached to magnetic beads. The binding of the best clones to the enzyme was unambiguously confirmed by ELISA. However the synthetic heptapeptide of identical sequence to the best “monomeric” clone did not act as a satisfactory affinity ligand after immobilization on Sepharose. This indicated that the interaction with lipase was due to both the heptapeptide and the presence of a part of the phage coat protein. This conclusion was further verified by immobilizing the whole phage on the surface of magnetic beads and using the resulting conjugate as an affinity adsorbent. The scope of application of this methodology and the possibility of preparing phage-based affinity materials are briefly discussed.     

Biologic protease inhibitors as novel therapeutic agents

Deregulated proteolytic activities frequently have causative or exacerbative functions in pathological conditions such as cancer and inflammatory disease. Many proteases therefore represent therapeutic targets, but the generation of successful small molecule drugs is often limited by the ability to achieve sufficient specificity of action. Consequently, several proteases have been deemed as unsuitable drug targets due to the inability to target them successfully. In an effort to circumvent these issues, much interest has recently focused on the development and application of biologic inhibitors. In this review, the latest research in the development of biologic protease inhibitors is examined. This includes a review of engineered kunitz and other inhibitory domains as well as the application of antibodies as therapeutically viable inhibitors.     

Corruption of phage display libraries by target-unrelated clones: Diagnosis and countermeasures

Phage display is used to discover peptides or proteins with a desired target property—most often, affinity for a target selector molecule. Libraries of phage clones displaying diverse surface peptides are subject to a selection process designed to enrich for the target behavior and subsequently propagated to restore phage numbers. A recurrent problem is enrichment of clones, called target-unrelated phages or peptides (TUPs), that lack the target behavior. Many TUPs are propagation related; they have mutations conferring a growth advantage and are enriched during the propagations accompanying selection. Unlike other filamentous phage libraries, fd-tet-based libraries are relatively resistant to propagation-related TUP corruption. Their minus-strand origin is disrupted by a large cassette that simultaneously confers resistance to tetracycline and imposes a rate-limiting growth defect that cannot be bypassed with simple mutations. Nonetheless, a new type of propagation-related TUP emerged in the output of in vivo selections from an fd-tet library. The founding clone had a complex rearrangement that restored the minus-strand origin while retaining tetracycline resistance. The rearrangement involved two recombination events, one with a contaminant having a wild-type minus-strand origin. The founder’s infectivity advantage spread by simple recombination to clones displaying different peptides. We propose measures for minimizing TUP corruption.     

Use of in vivo phage display to engineer novel adenoviruses for targeted delivery to the cardiac vasculature

We performed in vivo phage display in the stroke prone spontaneously hypertensive rat, a cardiovascular disease model, and the normotensive Wistar Kyoto rat to identify cardiac targeting peptides, and then assessed each in the context of viral gene delivery. We identified both common and strain-selective peptides, potentially indicating ubiquitous markers and those found selectively in dysfunctional microvasculature of the heart. We show the utility of the peptide, DDTRHWG, for targeted gene delivery in human cells and rats in vivo when cloned into the fiber protein of subgroup D adenovirus 19p. This study therefore identifies cardiac targeting peptides by in vivo phage display and the potential of a candidate peptide for vector targeting strategies.     

Activity-based selection of a proteolytic species using ribosome display

We have examined the potential of displaying a protease species in vitro using ribosome display and demonstrate specific capture on the basis of its catalytic activity. Using a model bacterial cysteine protease, sortase A (SrtA), we show that this enzyme can be functionally expressed in vitro. By overlap PCR we constructed ribosome display templates with the SrtA open reading frame fused to a C terminal glycine-serine rich flexible linker and a tether derived from eGFP. Using the broad range cysteine protease irreversible inhibitor E-64 linked to acrylic beads, we show that we can isolate SrtA ribosome display ternary complexes, and recover their encoding mRNA by RT-PCR. This recovery was lost when applied to a SrtA catalytically inactive mutant, or could be alleviated by competition with free inhibitor. This sensitive technique could be further developed to allow the screening of proteases against putative inhibitors and/or the identification of novel proteolytic species.     

The making of the minibody: An engineered β-protein for the display of conformationally constrained peptides

Conformationally constraining selectable peptides onto a suitable scaffold that enables their conformation to be predicted or readily determined by experimental techniques would considerably boost drug discovery process by reducing the gap between the discovery of a peptide lead and the design of a peptidomimetic with a more desirable pharmacological profile. With this in mind, we designed the minibody, a 61-residue β-protein aimed at retaining some desirable features of immunogloblin variable domains, such as tolerance to sequence variability in selected regions of the protein and predictability of main chain conformation of the same regions, based on the ‘canonical structures’ model. To test the ability of the minibody scaffold to support functional sites we also designed a metal binding version of the protein by suitably choosing the sequences of its loops. The minibody was produced both by chemical syntyhesis and expression in E. coli and charactgerized by size exclusion chromatography, UV CD (circular dichroism) spectroscopy and metal binding activity. All our data supported the model, but a more detailed structural characterization of the molecule was impaired by its low soubility. We were able to overcome this problem both by further; mutagenesis of the framework and by addition of a solublizing motif. The minibody is being used to select constrained human IL-6 peptidic ligands from a library displayed on the surface of the f1 bacteriophage.     

Identification of acridinyl hydrazides as potent aspartic protease inhibitors

We have identified acridinyl derivatives as potent aspartic protease inhibitors by virtual screening of in-house library of synthetic compounds. Enzyme inhibition experiments showed that both compounds inhibit human cathepsin D and Plasmodium falciparum plasmepsin-II in nanomolar ranges. The IC₅₀ values against cathepsin D and plasmepsin-II of compound-Nar103 were found to be 9.0 ± 2.0 and 4.0 ± 1.0 nM and of compound-Nar110 were 0.5 ± 0.05 and 0.13 ± 0.03 nM, respectively. Ligand docking predicted the binding of acridinyl derivatives at the substrate-binding cleft, where hydrazide part of the inhibitors interact with the S1–S1′ subsite residues including catalytic aspartates. The phenyl ring and acridinyl moiety of the inhibitors were predicted to interact with S2/S3 and S2′/S3′ subsite residues.     

Phage antibody display libraries: a powerful antibody discovery platform for immunotherapy

Phage display technology (PDT), a combinatorial screening approach, provides a molecular diversity tool for creating libraries of peptides/proteins and discovery of new recombinant therapeutics. Expression of proteins such as monoclonal antibodies (mAbs) on the surface of filamentous phage can permit the selection of high affinity and specificity therapeutic mAbs against virtually any target antigen. Using a number of diverse selection platforms (e.g. solid phase, solution phase, whole cell and in vivo biopannings), phage antibody libraries (PALs) from the start point provides great potential for the isolation of functional mAb fragments with diagnostic and/or therapeutic purposes. Given the pivotal role of PDT in the discovery of novel therapeutic/diagnostic mAbs, in the current review, we provide an overview on PALs and discuss their impact in the advancement of engineered mAbs.     

Affinity selection to papain yields potent peptide inhibitors of cathepsins L, B, H, and K

Endogenous cysteine proteases were given much attention lately, as their role in a variety of pathophysiological disorders became evident. Amongst them cathepsins, which are thought to be implicated in mediation of osteoporosis, cancer progression, atherosclerosis, and many other conditions, are of considerable interest as drug targets. In the presented work, papain was chosen as a model cysteine protease and panning protocol was optimized for selection of papain-binding phage-displayed peptides from a commercially available combinatorial peptide library. Different selection strategies were applied in order to select high-affinity binders. Ultimately, five cyclic peptides (CNWAAGYNCGGGS-NH2, CWSMMGFQCGGGS-NH2, CWEWGGWHCGGSS-OH, CNWTLGGYKCGGGS-NH2 (all cyclized through formation of intramolecular disulphide bond), and GNWTLGGYKGG (cyclized head-to-tail)) were synthesized and tested for inhibitory activity towards papain and human cathepsins L, B, H, and K. The peptides possess inhibitory constants in the low micromolar to mid-nanomolar range and exhibit certain selectivity for different lysosomal cysteine proteases included in this study.     

An optimized procedure for efficient phage display of antibody fragments with a low folding efficiency

We recently developed an efficient bacterial expression system for phagemid-coded antigen-binding fragments of antibody (Fabs) without the use of a helper bacteriophage. This system is characterized by an unusually long cultivation at a low temperature and gentle induction of Fab expression without the addition of the inducer isopropyl-β-D-thiogalactopyranoside (IPTG). This method allows for a high yield production of Fabs fused with phage gene III coat protein, even when the protein is defective in its folding ability. With this cultivation procedure, we aimed here at improving the production and selection efficiency of filamentous bacteriophages displaying functional Fabs on their surface (Fab-phages) that have high affinity but low folding ability. The Fab components of the Fab-phages used were clonally related but differed in their affinity and folding ability. The production of the functional Fab-phages was quantitatively evaluated under various culture conditions. With conventional phage particle preparation, the production of functional Fab-phages was significantly biased according to the folding ability of the displayed Fabs, and affinity-based biopanning was therefore unsuccessful. In contrast, with the present procedure employing cultivation at 25 °C for 16 h without IPTG induction, functional Fab-phages were produced without any such dependence on folding ability. With this optimized library, affinity-based biopanning was successful. Especially noteworthy, bead-based biopanning accurately discriminated between high affinity Fab-phages and Fab-phages with low or middling affinity. In obtaining Fab-phages with high affinity but low folding ability, these optimized procedures for both cultivation and selection were essential.     

Detection of protease inhibitors by a reverse zymography method, performed in a tris(hydroxymethyl)aminomethane-Tricine buffer system

A new detecting method for protease inhibitors, especially for low-molecular-weight inhibitors, is reported. Inhibitor samples were separated on a protein substrate-SDS-polyacrylamide gel in a Tris-Tricine buffer system that improves the separation and identification of peptides and low-molecular-weight proteins. After electrophoresis, the gel was incubated with the target proteases to hydrolyze the background protein substrate. The inhibitor bands, which were protected from proteolysis by the target proteases, were stained. Standard low-molecular-weight inhibitors, such as pepstatin A for pepsin or matrix metalloproteases inhibitor I for collagenase, as well as larger inhibitors, such as soybean trypsin inhibitor or aprotinin for tryspin and cystatin C for papain, were demonstrated by this method and showed clear blue inhibitor bands in the white background when the gels were treated with the target proteases. Some significant applications of this method are introduced. This method is an ideal system for discovering new protease inhibitors in small natural samples.     

Engineering the E. coli beta-galactosidase for the screening of antiviral protease inhibitors

Site-specific proteolysis is essential in many fundamental cellular and viral processes. It has been previously shown that the Escherichia coli beta-galactosidase can be useful for the high-throughput screening of human immunodeficiency virus type 1 protease inhibitors. Here, by using crystallographic and functional data of the bacterial enzyme, we have identified a new accommodation site between amino acids 581 and 582, in a solvent-exposed and flexible beta-turn of domain III. The placement of the model peptide reproducing the matrix-capsid (p17/p24) gag cleavage sequence renders a highly active and efficiently digested chimeric construct. The use of this insertion site, that increases the cleavage potential of this reporter enzyme, can improve the sensitivity and dynamic range of the antiviral drug assay. This simple and highly specific analytical test may also be extended to the screening of other specific protease inhibitors by a convenient colorimetric assay.     

A generic approach to engineer antibody pH-switches using combinatorial histidine scanning libraries and yeast display

There is growing interest in the fast and robust engineering of protein pH-sensitivity that aims to reduce binding at acidic pH, compared to neutral pH. Here, we describe a novel strategy for the incorporation of pH-sensitive antigen binding functions into antibody variable domains using combinatorial histidine scanning libraries and yeast surface display. The strategy allows simultaneous screening for both, high affinity binding at pH 7.4 and pH-sensitivity, and excludes conventional negative selection steps. As proof of concept, we applied this strategy to incorporate pH-dependent antigen binding into the complementary-determining regions of adalimumab. After 3 consecutive rounds of separate heavy and light chain library screening, pH-sensitive variants could be isolated. Heavy and light chain mutations were combined, resulting in 3 full-length antibody variants that revealed sharp, reversible pH-dependent binding profiles. Dissociation rate constants at pH 6.0 increased 230- to 780-fold, while high affinity binding at pH 7.4 in the sub-nanomolar range was retained. Furthermore, binding to huFcRn and thermal stability were not affected by histidine substitutions. Overall, this study emphasizes a generalizable strategy for engineering pH-switch functions potentially applicable to a variety of antibodies and further proteins-based therapeutics.     

A generic approach to engineer antibody pH-switches using combinatorial histidine scanning libraries and yeast display

There is growing interest in the fast and robust engineering of protein pH-sensitivity that aims to reduce binding at acidic pH, compared to neutral pH. Here, we describe a novel strategy for the incorporation of pH-sensitive antigen binding functions into antibody variable domains using combinatorial histidine scanning libraries and yeast surface display. The strategy allows simultaneous screening for both, high affinity binding at pH 7.4 and pH-sensitivity, and excludes conventional negative selection steps. As proof of concept, we applied this strategy to incorporate pH-dependent antigen binding into the complementary-determining regions of adalimumab. After 3 consecutive rounds of separate heavy and light chain library screening, pH-sensitive variants could be isolated. Heavy and light chain mutations were combined, resulting in 3 full-length antibody variants that revealed sharp, reversible pH-dependent binding profiles. Dissociation rate constants at pH 6.0 increased 230- to 780-fold, while high affinity binding at pH 7.4 in the sub-nanomolar range was retained. Furthermore, binding to huFcRn and thermal stability were not affected by histidine substitutions. Overall, this study emphasizes a generalizable strategy for engineering pH-switch functions potentially applicable to a variety of antibodies and further proteins-based therapeutics.     

Structural switching of Staphylococcus aureus Clp protease: a key to understanding protease dynamics

ATP-dependent Clp protease (ClpP) is an attractive new target for the development of anti-infective agents. The ClpP protease consists of two heptameric rings that enclose a large chamber containing 14 proteolytic active sites. Recent studies indicate that ClpP likely undergoes conformational switching between an extended and degraded active state required for substrate proteolysis and a compacted and catalytically inactive state allowing product release. Here, we present the wild-type ClpP structures in two distinct states from Staphylococcus aureus. One structure is very similar to those solved ClpP structures in the extended states. The other is strikingly different from both the extended and the compacted state as observed in ClpP from other species; the handle domain of this structure kinks to take on a compressed conformation. Structural analysis and molecular dynamic simulations show that the handle domain predominantly controls the way in which degradation products exit the chamber through dynamic conformational switching from the extended state to the compressed state. Given the highly conserved sequences among ClpP from different species, this compressed conformation is unexpected and novel, which is potentially valuable for understanding the enzymatic dynamics and the acting mechanisms of ClpP.