Methods for Engineering Binders to Multi-Pass Membrane Proteins.

Numerous potential drug targets, including G-protein-coupled receptors and ion channel proteins, reside on the cell surface as multi-pass membrane proteins. Unfortunately, despite advances in engineering technologies, engineering biologics against multi-pass membrane proteins remains a formidable task. In this review, we focus on the different methods used to prepare/present multi-pass transmembrane proteins for engineering target-specific biologics such as antibodies, nanobodies and synthetic scaffold proteins.

Click display: a rapid and efficient in vitro protein display method for directed evolution.

We describe a novel method for in vitro protein display-click display-that does not depend on maintaining RNA integrity during biopanning and yields covalently linked protein-cDNA complexes from double-stranded input DNA within 2 h. The display is achieved in a one-pot format encompassing transcription, translation and reverse transcription reactions in series. Stable linkage between proteins and the encoding cDNA is mediated by a modified DNA linker-ML-generated via a click chemistry reaction between a puromycin-containing oligo and a cDNA synthesis primer.

Chicken-derived CD20 antibodies with potent B-cell depletion activity.

We report four novel anti-human CD20 (hCD20) monoclonal antibodies (mAbs) discovered from a phylogenetically distant species-chickens. The chicken-human chimaeric antibodies exhibit at least 10-fold enhanced antibody-dependent cellular cytotoxicity (ADCC) and 4-8-fold stronger complement-dependent cytotoxicity (CDC) relative to the clinically used mouse-human chimaeric anti-hCD20 antibody rituximab (RTX). Thus, to our knowledge these mAbs are the first to significantly outperform RTX in both Fc-mediated mechanisms of action.

Golden Gate assembly with a bi-directional promoter (GBid): A simple, scalable method for phage display Fab library creation.

Fabs offer an attractive platform for monoclonal antibody discovery/engineering, but library construction can be cumbersome. We report a simple method - Golden Gate assembly with a bi-directional promoter (GBid) - for constructing phage display Fab libraries. In GBid, the constant domains of the Fabs are located in the backbone of the phagemid vector and the library insert comprises only the variable regions of the antibodies and a central bi-directional promoter.

PD 404,182 is a virocidal small molecule that disrupts hepatitis C virus and human immunodeficiency virus.

We describe a virucidal small molecule, PD 404,182, that is effective against hepatitis C virus (HCV) and human immunodeficiency virus (HIV). The median 50% inhibitory concentrations (IC(50)s) for the antiviral effect of PD 404,182 against HCV and HIV in cell culture are 11 and 1 μM, respectively. The antiviral activity of PD 404,182 is due to the physical disruption of virions that is accompanied to various degrees (depending on the virus and exposure temperature/time) by the release of viral nucleic acids into the surrounding medium.

Creation and characterization of a cell-death reporter cell line for hepatitis C virus infection.

The present study describes the creation and characterization of a hepatoma cell line, n4mBid, that supports all stages of the hepatitis C virus (HCV) life cycle and strongly reports HCV infection by a cell-death phenotype. The n4mBid cell line is derived from the highly HCV-permissive Huh-7.5 hepatoma cell line and contains a modified Bid protein (mBid) that is cleaved and activated by the HCV serine protease NS3-4A.

A cell protection screen reveals potent inhibitors of multiple stages of the hepatitis C virus life cycle.

The hepatitis C virus (HCV) life cycle involves multiple steps, but most current drug candidates target only viral replication. The inability to systematically discover inhibitors targeting multiple steps of the HCV life cycle has hampered antiviral development. We present a simple screen for HCV antivirals based on the alleviation of HCV-mediated cytopathic effect in an engineered cell line-n4mBid.

Development of a bacteriophage-based system for the selection of structured peptides.

Short structured peptides can provide scaffolds for protease-resistant peptide therapeutics, serve as useful building blocks in biomedical and biotechnological applications, and shed light on the role of secondary structure elements in protein folding. It is well known that directed evolution is a powerful method for creating proteins and peptides with novel properties, and a system for the selection of short peptides based on structure from a randomized library would be an important advancement. In this study, phage particles monovalently displaying a short peptide and an N-terminal 6xHis tag on their P3 coat protein were bound to nickel agarose resin and were subsequently challenged with a protease that specifically cleaves at a site within the peptide.

Design and application of stimulus-responsive peptide systems.

The ability of peptides and proteins to change conformations in response to external stimuli such as temperature, pH and the presence of specific small molecules is ubiquitous in nature. Exploiting this phenomenon, numerous natural and designed peptides have been used to engineer stimulus-responsive systems with potential applications in important research areas such as biomaterials, nanodevices, biosensors, bioseparations, tissue engineering and drug delivery. This review describes prominent examples of both natural and designed synthetic stimulus-responsive peptide systems.

Engineering and characterization of human manganese superoxide dismutase mutants with high activity and low product inhibition.

Human manganese superoxide dismutase is a mitochondrial metalloenzyme that is involved in protecting aerobic organisms against superoxide toxicity, and has been implicated in slowing tumor growth. Unfortunately, this enzyme exhibits strong product inhibition, which limits its potential biomedical applications. Previous efforts to alleviate human manganese superoxide dismutase product inhibition utilized rational protein design and site-directed mutagenesis.

Creating new specific ligand-receptor pairs for transgene regulation.

The creation of specifically matched ligand-receptor pairs that are orthogonal to naturally present interacting pairs is essential for the development of small molecule-regulated gene expression systems for biotechnological applications. However, for many years this task has represented a significant challenge for synthetic chemists and protein engineers. Recently, Doyle and colleagues demonstrated that highly specific ligand-receptor pairs can be engineered in a rapid fashion by creating large libraries of protein variants and applying a selection scheme to identify variants with improved activation by the target synthetic ligand.

Directed evolution of specific receptor-ligand pairs for use in the creation of gene switches.

Despite their versatility and power in controlling gene regulation in nature, nuclear hormone receptors (NHRs) have largely eluded utility in heterologous gene regulation applications such as gene therapy and metabolic engineering. The main reason for this void is the pleiotropic interference of the receptor-ligand combination with regulatory networks in the host organism. In recent years, numerous strategies have been developed to engineer ligand-receptor pairs that do not cross-interact with host regulatory pathways.

Directed evolution of enzymes and pathways for industrial biocatalysis.

Directed evolution has become a powerful tool for developing enzyme and whole cell based biocatalysts. Significant recent advances include the creation of novel enzyme functions and the development of several new efficient directed evolution methods. The combination of directed evolution and rational design promises to accelerate the development of biocatalysts for applications in the pharmaceutical, chemical and food industries.