Jason R. Porter

High Specificity in Protein Recognition by Hydrogen-Bond-Surrogate α-Helices: Selective Inhibition of the p53/MDM2 Complex

Stabilized α-helices and nonpeptidic helix mimetics have emerged as powerful molecular scaffolds for the discovery of protein-protein interaction inhibitors.[1–8] Protein-protein interactions often involve large contact areas, which are often difficult for small molecules to target with high specificity.[9–10] The hypothesis behind the design of stabilized helices and helix mimetics is that these medium-sized molecules may pursue their targets with higher specificity because of a larger number of contacts. We recently introduced a new strategy for the preparation of stabilized α-helices, termed hydrogen bond surrogate (HBS) helices, which involves replacement of one of the main chain hydrogen bonds with a covalent linkage (Figure 1A).[11] The salient feature of the HBS approach is its ability to constrain very short peptides into highly stable α-helical conformation without blocking any molecular recognition surfaces. We have extensively analyzed the conformation adopted by HBS α-helices with 2D NMR, X-ray, and circular dichroism spectroscopies.[12–14] In addition, HBS helices have been shown to target their expected protein partners with high affinity in cell-free and cell culture assays.[15–17]

A general and rapid cell-free approach for the interrogation of protein-protein, protein-DNA, and protein-RNA interactions and their antagonists utilizing split-protein reporters

Split-protein reporters have emerged as a powerful methodology for imaging biomolecular interactions which are of much interest as targets for chemical intervention. Herein we describe a systematic evaluation of split-proteins, specifically the green fluorescent protein, beta-lactamase, and several luciferases, for their ability to function as reporters in completely cell-free systems to allow for the extremely rapid and sensitive determination of a wide range of biomolecular interactions without the requirement for laborious transfection, cell culture, or protein purification (12-48 h). We demonstrate that the cell-free split-luciferase system in particular is amenable for directly interrogating protein-protein, protein-DNA, and protein-RNA interactions in homogeneous assays with very high sensitivity (22-1800 fold) starting from the corresponding mRNA or DNA. Importantly, we show that the cell-free system allows for the rapid (2 h) identification of target-site specificity for protein-nucleic acid interactions and in evaluating antagonists of protein-protein and protein-peptide complexes circumventing protein purification bottlenecks. Moreover, we show that the cell-free split-protein system is adaptable for analysis of both protein-protein and protein-nucleic acid interactions in artificial cell systems comprising water-in-oil emulsions. Thus, this study provides a general and enabling methodology for the rapid interrogation of a wide variety of biomolecular interactions and their antagonists without the limitations imposed by current in vitro and in vivo approaches.

An Autoinhibited Coiled-Coil Design Strategy for Split-Protein Protease Sensors

Proteases are widely studied as they are integral players in cell-cycle control and apoptosis. We report a new approach for the design of a family of genetically encoded turn-on protease biosensors. In our design, an autoinhibited coiled-coil switch is turned on upon proteolytic cleavage, which results in the complementation of split-protein reporters. Utilizing this new autoinhibition design paradigm, we present the rational construction and optimization of three generations of protease biosensors, with the final design providing a 1000-fold increase in bioluminescent signal upon addition of the TEV protease. We demonstrate the generality of the approach utilizing two different split-protein reporters, firefly luciferase and beta-lactamase, while also testing our design in the context of a therapeutically relevant protease, caspase-3. Finally, we present a dual protease sensor geometry that allows for the use of these turn-on sensors as potential AND logic gates. Thus, these studies potentially provide a new method for the design and implementation of genetically encoded turn-on protease sensors while also providing a general autoinhibited coiled-coil strategy for controlling the activity of fragmented proteins.

A Coiled-Coil Enabled Split-Luciferase Three-Hybrid System: Applied Toward Profiling Inhibitors of Protein Kinases

The 518 protein kinases encoded in the human genome are exquisitely regulated and their aberrant function(s) are often associated with human disease. Thus, in order to advance therapeutics and to probe signal transduction cascades, there is considerable interest in the development of inhibitors that can selectively target protein kinases. However, identifying specific compounds against such a large array of protein kinases is difficult to routinely achieve utilizing traditional activity assays, where purified protein kinases are necessary. Toward a simple, rapid, and practical method for identifying specific inhibitors, we describe the development and application of a split-protein methodology utilizing a coiled-coil-assisted three-hybrid system. In this approach, a protein kinase of interest is attached to the C-terminal fragment of split-firefly luciferase and the coiled-coil Fos, which is specific for the coiled-coil Jun, is attached to the N-terminal fragment. Upon addition of Jun conjugated to a pan-kinase inhibitor such as staurosporine, a three-hybrid complex is established with concomitant reassembly of the split-luciferase enzyme. An inhibitor can be potentially identified by the commensurate loss in split-luciferase activity by displacement of the modified staurosporine. We demonstrate that this new three-hybrid approach is potentially general by testing protein kinases from the different kinase families. To interrogate whether this method allows for screening inhibitors, we tested six different protein kinases against a library of 80 known protein kinase inhibitors. Finally, we demonstrate that this three-hybrid system can potentially provide a rapid method for structure/function analysis as well as aid in the identification of allosteric inhibitors.

A General Approach for Receptor and Antibody-Targeted Detection of Native Proteins Utilizing Split-Luciferase Reassembly

The direct detection of native proteins in heterogeneous solutions remains a challenging problem. Standard methodologies rely on a separation step to circumvent nonspecific signal generation. We hypothesized that a simple and general method for the detection of native proteins in solution could be achieved through ternary complexation, where the conditional signal generation afforded by split-protein reporters could be married to the specificity afforded by either native receptors or specific antibodies. Toward this goal, we describe a solution phase split-luciferase assay for native protein detection, where we fused fragmented halves of firefly luciferase to separate receptor fragments or single-chain antibodies, allowing for conditional luciferase complementation in the presence of several biologically significant protein targets. To demonstrate the utility of this strategy, we have developed and validated assay platforms for the vascular endothelial growth factor, the gp120 coat protein from HIV-1, and the human epidermal growth factor receptor 2 (HER2), a marker for breast cancer. The specificities of the recognition elements, CD4 and the 17b single-chain antibody, employed in the gp120 sensor allowed us to parse gp120s from different clades. Our rationally designed HER2 sensing platform was capable of discriminating between HER2 expression levels in several tumor cell lines. In addition, luminescence from reassembled luciferase was linear across a panel of cell lines with increasing HER2 expression. We envision that the proof of principle studies presented herein may allow for the potential detection of a broad range of biological analytes utilizing ternary split-protein systems.

Profiling small molecule inhibitors against helix-receptor interactions: The Bcl-2 family inhibitor BH3I-1 potently inhibits p53/hDM2

We validate a practical methodology for the rapid profiling of small molecule inhibitors of protein-protein interactions. We find that a well known BH3 family inhibitor can potently inhibit the p53/hDM2 interaction.

Seeing Genetic and Epigenetic Information Without DNA Denaturation Using Sequence-Enabled Reassembly (SEER)

Virtually all methods for reading the sequence of bases in DNA rely on the ability to denature double-stranded DNA into single strands and then use Watson-Crick base-pairing rules to hybridize the strands with high specificity to another DNA primer or probe. However, nature frequently uses an alternative method, reading the sequence information directly from double-stranded DNA using sequence-specific DNA-binding proteins. Here we describe methods for the construction and testing of sequence probes based on engineered zinc finger DNA-binding proteins. Background is reduced using split-reporter molecules, and signal is amplified using enzymatic reporters. The resulting sequence-enabled reassembly (SEER) probes can be configured to detect DNA sequence (genetic) or DNA methylation (epigenetic) information.