Non-Covalent Selection Methodologies Utilizing Phage Display

Meyer, Scott C.

January 2007

In nature, non-covalent interactions are as important and dynamic as they are elusive. As such, the study of non-covalent interactions both in vivo and in vitro has proven to be challenging. Given the potential benefits of elucidating protein-protein, ligand-receptor, and other biologically relevant interactions, the development of methodologies for the study of non-covalent interactions is an attractive goal.Biologically encoded protein and peptide libraries that connect the genotypic information with the expressed phenotype have emerged in recent years as powerful methods for studying non-covalent interactions. One of the quintessential platforms for the creation of such libraries is phage display. In phage display, the connection between genetic information and the corresponding protein allows for the iterative isolation and amplification of library members that possess a desired function. Hence, an in vitro selection can be used to isolate epitopes that bind to desired targets or display specific attributes.We have sought to develop novel phage display methodologies that have the potential to expand the scope of this in vitro selection platform. Specifically, we developed a method for the non-covalent attachment of a small molecule ligand to a cyclic peptide library. This system localizes the phage display library to the ligand binding site, thus allowing for the translation of the selected cyclic peptides to a covalently tethered bivalent inhibitor.The first class of biological molecules that we chose to target with our methodology is the biologically and therapeutically important class of enzymes called protein kinases. In the first demonstration of this strategy, we were able to isolate cyclic peptide ligands for the model kinase PKA (cAMP-dependent protein kinase), which were subsequently translated to a bivalent inhibitor. This inhibitor showed both increased affinity and selectivity for PKA in relation to other protein kinases.In a separate project, we sought to develop a method for the isolation of small molecule-responsive mutants of a well-characterized protein scaffold from a phage display library. During these investigations, we discovered interesting homologous single-point mutations of the protein that resulted in large spherical oligomers that may mimic species relevant to the study of protein misfolding diseases such as Alzheimer's.

phage display

kinase

avidin

NeutrAvidin

PKA

cAMP-dependent protein kinase

Development of methods to determine the binding capacities of solid supports and improvement in immunoassay efficiency using dendrimer-modified beads

Tiwari, Umadevi B.

January 2009

No description available.

Biochemistry

ligand binding capacity

biotin binding capacity

dendrimer

solid support

streptavidin

NeutrAvidin

Towards the Development of Synergistic Inhibitors that Exploit the Replication Strategy of HIV-1

Pattenden, Leonard Keith

January 2005

HIV-1 has evolved with a great deal of functional complexity contained within a very small genome by encoding small, but critical viral proteins within larger viral genes and dividing the replication cycle into early and late phases to differentially produce all proteins leading to efficient replication and virion release. Early replication is restricted by the host spliceosome that processes HIV-1 vRNA transcripts so only the small intragenomic proteins are produced, one of which is Rev (Regulator of Virion Expression). Rev in turn governs the transition from early to late replication by interacting with a highly structured region of vRNA termed the Rev Response Element (RRE). The binding of Rev to the RRE is believed to cause a change in the vRNA tertiary structure and inhibition of splicing of the vRNA. Once, a Rev:RRE complex is formed, a nuclear export signal within Rev facilitates the export of partially spliced and unspliced vRNA to the cytoplasm. During late replication the partially spliced and unspliced vRNA is translated to polyproteins and is packaged into a budding virion where the viral aspartyl protease (HIV-1 PR) autocatalytically excises itself from the larger polyprotein and processes the remaining polyproteins to release all viral structural and functional proteins to form a mature and infectious virion. Since the vRNA salvaged by Rev is translated to the polyproteins containing HIV-1 PR, the inhibition of Rev function will reduce the amount of HIV-1 PR available and thereby reduce the amount of HIV-1 PR therapeutics required to elicit a clinical effect. Therfore a combination approach to HIV-1 treatment using suitably developed therapeutics that inhibit Rev and HIV-1 PR function represents an attractive synergistic approach to treating HIV-1 infection in vivo. The work of this thesis was divided into two parts, the first part was concerned with HIV-1 PR structural biology and addressing problems encountered with inhibitor design. A bicyclic peptide (based on inhibitors of analogous structure) was co-crystallised with active HIV-1 PR to develop an enzyme-product (E-P) complex and with a catalytically inactive mutant HIV-1 PR to provide an analogy to the enzyme-substrate (E-S) complex. Both structures of the E-P and E-S complexes were solved to 1.6Å resolution and were compared to a hydroxyethylamine isostere enzyme-inhibitor complex (E-I), highlighting the similarity of binding mode for all ligands. The inhibitor in the E-I complex was translated towards the S1 - S3 pockets of the substrate binding cleft relative to the substrate in the E-S complex due to the increased length of the hydroxylethylamine isostere compared to the peptide backbone, although the inhibitor "puckered" the isostere linkage and maintains a binding mode similar to the substrate with very little overall differences in the position of the ligands and surrounding protein. The similarity of the E-S, E-I and E-P complexes was attributed to the macrocyclic ligands ordering the surrounding protein environment, especially the protein -strand "flap" structures that form a roof over the ligands in the active site but were not found to close more tightly in any of the trapped catalytic states. The new structures allowed refinement of details of the mechanism of peptide hydrolysis. The mechanism relies on the optimal nucleophilic attack of a water molecule on the scissile amide bond with concerted acid-base catalysis of the active site aspartyl residues intitiated by D125. The alignment and intrinsic position of the N-terminus of the bicyclic substrate was interpreted as being critical to facilitate efficient electron transfer with the bicyclic substrate. An N-terminal cyclic inhibitor, similar to the N-terminal portion of the bicyclic substrate, was used to address a major problem in HIV-1 PR drug design termed "cooperativity," where the sequential optimisation of an inhibitor (or substrate) to individual pockets of the substrate binding cleft, can negatively impact on adjacent and downfield subsites and thereby alter the binding mode of the "optimised" inhibitor. The technique referred to here as "templating" uses the N-terminal cycle to lock the binding mode into a known conformation, probing the S1' and S2' pockets. The structure activity relationship suggested that by viewing the S1' - S3' pockets as a single trough, bulky aromatic groups attached to an N-alkyl sulfonamide could be directed along the line of the trough without adverse interactions with the tops of the S1' and S3' pockets, providing very potent inhibitors. It was also found that specificity and potency of an inhibitor can be maintained with smaller functionalities that carry their bulk low and close to the inhibitor backbone in the S2' pocket, making the P2 functionalities more substrate-like. The second part of the thesis was concerned with establishing suitable surface plasmon resonance assays for testing potential inhibitors of Rev function. Recombinant Rev and its minimal RNA aptamer target (stem loop II of the RRE termed RBE3), were expressed, purified, and used to develop BIAcore-based assays and test potential inhibitors of their interaction. The system was applied to screening of aminoglycoside antibiotics and other small molecules in a competitive assay, and also to quantitative assay of Neomycin and moderate sized analytes: Rev and three peptidic analogues of the high-affinity binding site of Rev - the native peptide, succinylated form of the peptide and a form incorporating a novel helix-inducing cap. The peptide and protein assay was undertaken to test the proposition that helix induction of the high-affinity binding site of Rev can increase affinity for the biologically important RNA target and thereby form the basis of a new class of inhibitors. The screen of small molecule antagonists found that Neomycin was the best inhibitor of the Rev:RBE3 interaction and that efficacy of other aminoglycosides was due to the neamine-base structure presenting charge to bind to the RNA and blocking interaction with Rev. The quantitative assay was optimised to reduce non-specific interactions of Rev protein to allow reliable studies of the analytes with RBE3 by the sytematic testing of buffers and modifiers. It was found that mutliple analytes bound to the RBE3 aptamer and a comparison of the KD values found that the native and capped peptides had similar affinity for RBE3 RNA (native slightly greater at 21 ± 7nM cf capped 41 ± 10nM) that was greater than the Rev protein (101 ± 19nM), however the succinylated peptide exhibited stronger binding with a KD ≤8nM and Neomycin had the lowest affinity (KD 13 ± 3M). The similarity of the native and capped peptides may be due to the high concentration of salt in the assay buffers and was necessary for the stability of the Rev protein, but is sufficient to influence secondary structure of the peptides. Therefore, it could not be stated that the helix-inducing cap increased the affinity of the native peptide for the biologically important therapeutic target. The work conducted in this thesis firmly establishes foundations for the continued development of inhibitors against both Rev and HIV-1 PR that play key roles in the HIV-1 replication strategy. It is envisaged this work could lead to a novel synergistic therapeutic approach to treating HIV-1 infection.

Aspartyl Protease

HIV-1 Protease

Substrate Complex

Product Complex

X-ray Crystallography

Cyclic Peptide

-strand Mimetic

Catalysis

Cooperativity

HIV-1 Rev

RRE

RBE3

RNA

BIAcore

Surface Plasmon Resonance

in vitro transcription

Aminoglycoside

Helix-inducing Cap

Neomycin

Streptavidin

Neutravidin

Helix Mimetic