Project description:Engineered Peptide Barcodes for In-Depth Analyses of Binding Protein Ensembles

Project description:Binding protein generation relies on laborious screening cascades that process candidate molecules individually. To break with this paradigm, we developed NestLink, a binder selection and identification technology able to biophysically characterize thousands of library members at once without handling individual clones at any stage of the process. NestLink builds on genetically fused barcoding peptides, termed flycodes, which are designed for maximal detectability by mass spectrometry and serve as unique molecular identifiers for accurate deep sequencing. We applied NestLink to overcome current limitations of binder generation. Rare binders against an integral membrane protein were identified directly in the cellular environment of a human pathogen. Hundreds of binder candidates were simultaneously ranked according to kinetic parameters. Adverse effects of target immobilization were overcome by selecting nanobodies against an ABC transporter entirely in solution. NestLink may provide a basis for the selection of tailored binder characteristics directly in tissues or in living organisms

Project description:MOTS-c peptide binding protein

Project description:To elucidate the molecular mechanism of MOTS-c against NASH progression, we screened for potential MOTS-c binding proteins using biotin-labeled MOTS-c and HuProt human proteome microarray.

Project description:Phosphopeptide binding domains mediate the directed and localized assembly of protein complexes essential to intracellular kinase signaling. To identify phosphopeptide binding proteins, we developed a proteomic screening method using immobilized partially degenerate phosphopeptide mixtures combined with SILAC and microcapillary LC-MS/MS. The method was used to identify proteins that specifically bound to phosphorylated peptide library affinity matrices, including pTyr, and the motifs pSer/pThr-Pro, pSer/pThr-X-X-X-pSer/pThr, pSer/pThr-Glu/Asp, or pSer/pThr-pSer/pThr in degenerate sequence contexts. Heavy and light SILAC lysates were applied to columns containing these phosphorylated and nonphosphorylated (control) peptide libraries respectively, and bound proteins were eluted, combined, digested, and analyzed by LC-MS/MS using a hybrid quadrupole-TOF mass spectrometer. Heavy/light peptide ion ratios were calculated, and peptides that yielded ratios greater than ?3:1 were considered as being from potential phosphopeptide binding proteins since this ratio represents the lowest ratio from a known positive control. Many of those identified were known phosphopeptide-binding proteins, including the SH2 domain containing p85 subunit of PI3K bound to pTyr, 14-3-3 bound to pSer/pThr-Asp/Glu, polo-box domain containing PLK1 and Pin1 bound to pSer/pThr-Pro, and pyruvate kinase M2 binding to pTyr. Approximately half of the hits identified by the peptide library screens were novel. Protein domain enrichment analysis revealed that most pTyr hits contain SH2 domains, as expected, and to a lesser extent SH3, C1, STAT, Tyr phosphatase, Pkinase, C2, and PH domains; however, pSer/pThr motifs did not reveal enriched domains across hits.

Project description:Proteases comprise the class of enzymes that catalyzes the hydrolysis of peptide bonds, thereby playing a pivotal role in many aspects of life. The amino acids surrounding the scissile bond determine the susceptibility toward protease-mediated hydrolysis. A detailed understanding of the cleavage specificity of a protease can lead to the identification of its endogenous substrates, while it is also essential for the design of inhibitors. Although many methods for protease activity and specificity profiling exist, none of these combine the advantages of combinatorial synthetic libraries, i.e., high diversity, equimolar concentration, custom design regarding peptide length, and randomization, with the sensitivity and detection power of mass spectrometry. Here, we developed such a method and applied it to study a group of bacterial metalloproteases that have the unique specificity to cleave between two prolines, i.e., Pro-Pro endopeptidases (PPEPs). We not only confirmed the prime-side specificity of PPEP-1 and PPEP-2, but also revealed some new unexpected peptide substrates. Moreover, we have characterized a new PPEP (PPEP-3) that has a prime-side specificity that is very different from that of the other two PPEPs. Importantly, the approach that we present in this study is generic and can be extended to investigate the specificity of other proteases.

Project description:There is considerable interest in the discovery of peptide ligands that bind to protein targets. Discovery of such ligands is usually approached by screening large peptide libraries. However, the individual peptides must be tethered to a tag that preserves their individual identities (e.g., phage display or one-bead one-compound). To overcome this limitation, we have developed a method for screening libraries of label-free peptides for binding to a protein target in solution as a single batch. The screening is based on decreased amide hydrogen exchange by peptides that bind to the target. Hydrogen exchange is measured by mass spectrometry. We demonstrate the approach using a peptide library derived from the Escherichia coli proteome that contained 6664 identifiable features. The library was spiked separately with a peptide spanning the calmodulin binding domain of endothelial nitric oxide synthase (eNOS, 494-513) and a peptide spanning the N-terminal 20 residues of bovine ribonuclease A (S peptide). Human calmodulin and bovine ribonuclease S (RNase S) were screened against the library. Using a novel data analysis workflow, we identified the eNOS peptide as the only calmodulin binding peptide and S peptide as the only ribonuclease S binding peptide in the library.

Project description:The transpeptidase sortase A of Staphylococcus aureus (Sa-SrtA) is a valuable tool in protein chemistry. The native enzyme anchors surface proteins containing a highly conserved LPxTG sorting motif to a terminal glycine residue of the peptidoglycan layer in Gram-positive bacteria. This reaction is exploited for sortase-mediated ligation (SML), allowing the site-specific linkage of synthetic peptides and recombinant proteins by a native peptide bond. However, the moderate catalytic efficiency and specificity of Sa-SrtA fueled the development of new biocatalysts for SML, including the screening of sortase A variants form microorganisms other than S. aureus and the directed protein evolution of the Sa-SrtA enzyme itself. Novel display platforms and screening formats were developed to isolate sortases with altered properties from mutant libraries. This yielded sortases with strongly enhanced catalytic activity and enzymes recognizing new sorting motifs as substrates. This minireview focuses on recent advances in the field of directed sortase evolution and applications of these tailor-made enzymes in biochemistry.

Project description:Farnesylation, catalyzed by protein farnesyltransferase (FTase), is an important post-translational modification guiding cellular localization. Recently predictive models for identifying FTase substrates have been reported. Here we evaluate these models through screening of dansylated-GCaaS peptides, which also provides new insights into the protein substrate selectivity of FTase.

Project description:Nature has three biopolymers: oligonucleotides, polypeptides, and oligosaccharides. Each biopolymer has independent functions, but when needed, they form mixed assemblies for higher-order purposes, as in the case of ribosomal protein synthesis. Rather than forming large complexes to coordinate the role of different biopolymers, we dovetail protein amino acids and nucleobases into a single low molecular weight precision polyamide polymer. We established efficient chemical synthesis and de novo sequencing procedures and prepared combinatorial libraries with up to 100 million biohybrid molecules. This biohybrid material has a higher bulk affinity to oligonucleotides than peptides composed exclusively of canonical amino acids. Using affinity selection mass spectrometry, we discovered variants with a high affinity for pre-microRNA hairpins. Our platform points toward the development of high throughput discovery of sequence defined polymers with designer properties, such as oligonucleotide binding.