Nanomolar Protein–Protein Interaction Monitoring with a Label-Free Protein-Probe Technique

Protein–protein interactions (PPIs) are an essential part of correct cellular functionality, making them increasingly interesting drug targets. While Förster resonance energy transfer-based methods have traditionally been widely used for PPI studies, label-free techniques have recently drawn significant attention. These methods are ideal for studying PPIs, most importantly as there is no need for labeling of either interaction partner, reducing potential interferences and overall costs. Already, several different label-free methods are available, such as differential scanning calorimetry and surface plasmon resonance, but these biophysical methods suffer from low to medium throughput, which reduces suitability for high-throughput screening (HTS) of PPI inhibitors. Differential scanning fluorimetry, utilizing external fluorescent probes, is an HTS compatible technique, but high protein concentration is needed for experiments. To improve the current concepts, we have developed a method based on time-resolved luminescence, enabling PPI monitoring even at low nanomolar protein concentrations. This method, called the protein probe technique, is based on a peptide conjugated with Eu3+ chelate, and it has already been applied to monitor protein structural changes and small molecule interactions at elevated temperatures. Here, the applicability of the protein probe technique was demonstrated by monitoring single-protein pairing and multiprotein complexes at room and elevated temperatures. The concept functionality was proven by using both artificial and multiple natural protein pairs, such as KRAS and eIF4A together with their binding partners, and C-reactive protein in a complex with its antibody.

[1]  M. Holderfield,et al.  Homogeneous Dual-Parametric-Coupled Assay for Simultaneous Nucleotide Exchange and KRAS/RAF-RBD Interaction Monitoring , 2020, Analytical chemistry.

[2]  H. Härmä,et al.  Sensitive Label-Free Thermal Stability Assay for Protein Denaturation and Protein–Ligand Interaction Studies , 2020, Analytical chemistry.

[3]  K. Cain,et al.  eIF4A2 drives repression of translation at initiation by Ccr4-Not through purine-rich motifs in the 5′UTR , 2019, Genome Biology.

[4]  H. Härmä,et al.  QTR-FRET: Efficient background reduction technology in time-resolved förster resonance energy transfer assays. , 2019, Analytica chimica acta.

[5]  Jason E Gestwicki,et al.  Inhibitors of protein-protein interactions (PPIs): an analysis of scaffold choices and buried surface area. , 2018, Current opinion in chemical biology.

[6]  P. Buchwald,et al.  Toward Small-Molecule Inhibition of Protein-Protein Interactions: General Aspects and Recent Progress in Targeting Costimulatory and Coinhibitory (Immune Checkpoint) Interactions. , 2018, Current topics in medicinal chemistry.

[7]  U. Sauer,et al.  A Map of Protein-Metabolite Interactions Reveals Principles of Chemical Communication , 2018, Cell.

[8]  Y. Sako,et al.  High-resolution cryo-EM: the nuts and bolts. , 2017, Current opinion in structural biology.

[9]  David A. Scott,et al.  Potent and Selective Covalent Quinazoline Inhibitors of KRAS G12C. , 2017, Cell chemical biology.

[10]  Jing Zhang,et al.  Structural and functional characterization of a DARPin which inhibits Ras nucleotide exchange , 2017, Nature Communications.

[11]  K. Cole,et al.  Differential scanning calorimetry and fluorimetry measurements of monoclonal antibodies and reference proteins: Effect of scanning rate and dye selection , 2017, Biotechnology progress.

[12]  K. Wennerberg,et al.  High-Throughput Dual Screening Method for Ras Activities and Inhibitors. , 2017, Analytical chemistry.

[13]  B. Carpick,et al.  Differential Scanning Calorimetry — A Method for Assessing the Thermal Stability and Conformation of Protein Antigen , 2017, Journal of visualized experiments : JoVE.

[14]  R. Cencic,et al.  CRISPR-Mediated Drug-Target Validation Reveals Selective Pharmacological Inhibition of the RNA Helicase, eIF4A , 2016, Cell reports.

[15]  C. Partch,et al.  Analysis of Protein Stability and Ligand Interactions by Thermal Shift Assay , 2015, Current protocols in protein science.

[16]  Andrew P. Turnbull,et al.  Fragment-based drug discovery and protein–protein interactions , 2014 .

[17]  P. Hänninen,et al.  A homogeneous quenching resonance energy transfer assay for the kinetic analysis of the GTPase nucleotide exchange reaction , 2014, Analytical and Bioanalytical Chemistry.

[18]  Christopher M Johnson,et al.  Differential scanning calorimetry as a tool for protein folding and stability. , 2013, Archives of biochemistry and biophysics.

[19]  T. Blundell,et al.  Using a Fragment-Based Approach To Target Protein–Protein Interactions , 2013, Chembiochem : a European journal of chemical biology.

[20]  Jon R Lorsch,et al.  The mechanism of eukaryotic translation initiation: new insights and challenges. , 2012, Cold Spring Harbor perspectives in biology.

[21]  Pascal Braun,et al.  History of protein–protein interactions: From egg‐white to complex networks , 2012, Proteomics.

[22]  C. Fraser,et al.  Duplex unwinding and ATPase activities of the DEAD-box helicase eIF4A are coupled by eIF4G and eIF4B. , 2011, Journal of molecular biology.

[23]  R. Jackson,et al.  The mechanism of eukaryotic translation initiation and principles of its regulation , 2010, Nature Reviews Molecular Cell Biology.

[24]  R. Göke,et al.  The tumour suppressor Pdcd4: recent advances in the elucidation of function and regulation , 2009, Biology of the cell.

[25]  Sanjay B. Hari,et al.  High-throughput thermal scanning: a general, rapid dye-binding thermal shift screen for protein engineering. , 2009, Journal of the American Chemical Society.

[26]  N. Sonenberg,et al.  Topology and Regulation of the Human eIF4A/4G/4H Helicase Complex in Translation Initiation , 2009, Cell.

[27]  Haiwei Song,et al.  Structural basis for translational inhibition by the tumour suppressor Pdcd4 , 2009, The EMBO journal.

[28]  Wim Jiskoot,et al.  Extrinsic Fluorescent Dyes as Tools for Protein Characterization , 2008, Pharmaceutical Research.

[29]  Christopher L. McClendon,et al.  Reaching for high-hanging fruit in drug discovery at protein–protein interfaces , 2007, Nature.

[30]  H. Weller,et al.  Luminescent energy transfer between cadmium telluride nanoparticle and lanthanide(III) chelate in competitive bioaffinity assays of biotin and estradiol. , 2007, Analytica chimica acta.

[31]  F. Niesen,et al.  The use of differential scanning fluorimetry to detect ligand interactions that promote protein stability , 2007, Nature Protocols.

[32]  Sara Linse,et al.  Methods for the detection and analysis of protein–protein interactions , 2007, Proteomics.

[33]  B. Glasgow,et al.  ANS fluorescence: potential to augment the identification of the external binding sites of proteins. , 2007, Biochimica et biophysica acta.

[34]  Jonathan Bard,et al.  Evaluation of fluorescence-based thermal shift assays for hit identification in drug discovery. , 2004, Analytical biochemistry.

[35]  A. Plückthun,et al.  High-affinity binders selected from designed ankyrin repeat protein libraries , 2004, Nature Biotechnology.

[36]  O. Jensen Modification-specific proteomics: characterization of post-translational modifications by mass spectrometry. , 2004, Current opinion in chemical biology.

[37]  M. Cooper Label-free screening of bio-molecular interactions , 2003, Analytical and bioanalytical chemistry.

[38]  N. Sonenberg,et al.  The Transformation Suppressor Pdcd4 Is a Novel Eukaryotic Translation Initiation Factor 4A Binding Protein That Inhibits Translation , 2003, Molecular and Cellular Biology.

[39]  Victor S. Lobanov,et al.  High-Density Miniaturized Thermal Shift Assays as a General Strategy for Drug Discovery , 2001 .

[40]  T. Weber,et al.  Rapid determination of C-reactive protein by enzyme immunoassay using two monoclonal antibodies. , 1989, Scandinavian journal of clinical and laboratory investigation.

[41]  J. Wendoloski,et al.  Structural origins of high-affinity biotin binding to streptavidin. , 1989, Science.

[42]  D L Sackett,et al.  Nile red as a polarity-sensitive fluorescent probe of hydrophobic protein surfaces. , 1987, Analytical biochemistry.

[43]  Taosheng Chen,et al.  Using TR-FRET to Investigate Protein-Protein Interactions: A Case Study of PXR-Coregulator Interaction. , 2018, Advances in protein chemistry and structural biology.

[44]  M. Drescher,et al.  Analysis of Protein Interactions by Surface Plasmon Resonance. , 2018, Advances in protein chemistry and structural biology.

[45]  E. Prenner,et al.  Differential scanning calorimetry: An invaluable tool for a detailed thermodynamic characterization of macromolecules and their interactions , 2011, Journal of pharmacy & bioallied sciences.

[46]  M. Willander,et al.  Analysis of biomolecules using surface plasmons. , 2009, Methods in molecular biology.