Phage display to identify Nedd8-mimicking peptides as inhibitors of the Nedd8 transfer cascade.

The Nedd8 activating enzyme (NAE) launches the transfer of the ubiquitin-like protein Nedd8 through an enzymatic cascade to covalently modify a diverse array of proteins, thus regulating their biological functions in the cell. The C-terminal peptide of Nedd8 extends deeply into the active site of NAE and plays an important role in the specific recognition of Nedd8 by NAE. We used phage display to profile C-terminal mutant sequences of Nedd8 that could be recognized by NAE for the activation reaction. We found that NAE can accommodate diverse changes in the Nedd8 C-terminal sequence (7¹ LALRGG76), including Arg and Ile replacing Leu71, Leu, Ser, and Gln replacing Ala72, and substitutions by bulky aromatic residues at positions 73 and 74. We also observed that short peptides corresponding to the C-terminal sequences of the Nedd8 variants can be activated by NAE to form peptide~NAE thioester conjugates. Once NAE is covalently loaded with these Nedd8-mimicking peptides, it can no longer activate full-length Nedd8 for transfer to the neddylation targets, such as the cullin subunits of cullin-RING E3 ubiquitin ligases (CRLs). We have thus developed a new method to inhibit protein neddylation by Nedd8-mimicking peptides.

Engineering new protein-protein interactions on the ß-propeller fold by yeast cell surface display.

REINVENTING THE WHEEL: The ß-propeller domain folds like a wheel to provide key protein-protein interactions in the cell. Here we used high-throughput yeast sorting to "invent" ß-propellers of new binding specificities with cellular targets.

Coupling Binding to Catalysis: Using Yeast Cell Surface Display to Select Enzymatic Activities.

We find yeast cell surface display can be used to engineer enzymes by selecting the enzyme library for high affinity binding to reaction intermediates. Here we cover key steps of enzyme engineering on the yeast cell surface including library design, construction, and selection based on magnetic and fluorescence-activated cell sorting.

Phage selection assisted by Sfp phosphopantetheinyl transferase-catalyzed site-specific protein labeling.

Phosphopantetheinyl transferases (PPTase) Sfp and AcpS catalyze a highly efficient reaction that conjugates chemical probes of diverse structures to proteins. PPTases have been widely used for site-specific protein labeling and live cell imaging of the target proteins. Here we describe the use of PPTase-catalyzed protein labeling in protein engineering by facilitating high-throughput phage selection.

Identification and Characterization of a New Alkaline Thermolysin-Like Protease, BtsTLP1, from Bacillus thuringiensis Serovar Sichuansis Strain MC28.

Thermolysin and its homologs are a group of metalloproteases that have been widely used in both therapeutic and biotechnological applications. We here report the identification and characterization of a novel thermolysin-like protease, BtsTLP1, from insect pathogen Bacillus thuringiensis serovar Sichuansis strain MC28. BtsTLP1 is extracellularly produced in Bacillus subtilis, and the active protein was purified via successive chromatographic steps. The mature form of BtsTLP1 has a molecule mass of 35.6 kDa as determined by mass spectrometry analyses. The biochemical characterization indicates that BtsTLP1 has an apparent Km value of 1.57 mg/ml for azocasein and is active between 20°C and 80°C. Unlike other reported neutral gram-positive thermolysin homologs with optimal pH around 7, BtsTLP1 exhibits an alkaline pH optimum around 10. The activity of BtsTLP1 is strongly inhibited by EDTA and a group of specific divalent ions, with Zn(2+) and Cu(2+) showing particular effects in promoting the enzyme autolysis. Furthermore, our data also indicate that BtsTLP1 has potential in cleaning applications.

Profiling the cross reactivity of ubiquitin with the Nedd8 activating enzyme by phage display.

The C-terminal peptides of ubiquitin (UB) and UB-like proteins (UBLs) play a key role in their recognition by the specific activating enzymes (E1s) to launch their transfer through the respective enzymatic cascades thus modifying cellular proteins. UB and Nedd8, a UBL regulating the activity of cullin-RING UB ligases, only differ by one residue at their C-termini; yet each has its specific E1 for the activation reaction. It has been reported recently that UAE can cross react with Nedd8 to enable its passage through the UB transfer cascade for protein neddylation. To elucidate differences in UB recognition by UAE and NAE, we carried out phage selection of a UB library with randomized C-terminal sequences based on the catalytic formation of UB∼NAE thioester conjugates. Our results confirmed the previous finding that residue 72 of UB plays a "gate-keeping" role in E1 selectivity. We also found that diverse sequences flanking residue 72 at the UB C-terminus can be accommodated by NAE for activation. Furthermore heptameric peptides derived from the C-terminal sequences of UB variants selected for NAE activation can function as mimics of Nedd8 to form thioester conjugates with NAE and the downstream E2 enzyme Ubc12 in the Nedd8 transfer cascade. Once the peptides are charged onto the cascade enzymes, the full-length Nedd8 protein is effectively blocked from passing through the cascade for the critical modification of cullin. We have thus identified a new class of inhibitors of protein neddylation based on the profiles of the UB C-terminal sequences recognized by NAE.

Engineering the substrate specificity of the DhbE adenylation domain by yeast cell surface display.

The adenylation (A) domains of nonribosomal peptide synthetases (NRPSs) activate aryl acids or amino acids to launch their transfer through the NRPS assembly line for the biosynthesis of many medicinally important natural products. In order to expand the substrate pool of NRPSs, we developed a method based on yeast cell surface display to engineer the substrate specificities of the A-domains. We acquired A-domain mutants of DhbE that have 11- and 6-fold increases in k(cat)/K(m) with nonnative substrates 3-hydroxybenzoic acid and 2-aminobenzoic acid, respectively and corresponding 3- and 33-fold decreases in k(cat)/K(m) values with the native substrate 2,3-dihydroxybenzoic acid, resulting in a dramatic switch in substrate specificity of up to 200-fold. Our study demonstrates that yeast display can be used as a high throughput selection platform to reprogram the "nonribosomal code" of A-domains.

Specificity of the E1-E2-E3 enzymatic cascade for ubiquitin C-terminal sequences identified by phage display.

Ubiquitin (UB) is a protein modifier that regulates many essential cellular processes. To initiate protein modification by UB, the E1 enzyme activates the C-terminal carboxylate of UB to launch its transfer through the E1-E2-E3 cascade onto target proteins. In this study, we used phage display to profile the specificity of the two human E1 enzymes, Ube1 and Uba6, toward the C-terminal sequence of UB ending with (71)LRLRGG(76). Phage selection revealed that while Arg72 of UB is absolutely required for E1 recognition, UB residues at positions 71, 73, and 74 can be replaced with bulky aromatic side chains, and Gly75 of UB can be changed to Ser, Asp, and Asn for efficient E1 activation. We have thus found that the E1 enzymes have substantial promiscuity regarding the UB C-terminal sequence. The UB variants from phage selection can also be transferred from E1 to E2 enzymes; however, they are blocked from further transfer to the E3 enzymes. This suggests that the C-terminal sequence of UB is important for its discharge from E2 and subsequent transfer to E3. In addition, we observed that the Leu73Phe and Leu73Tyr single mutants of UB are resistant to cleavage by deubiquitinating enzymes (DUBs), although they can be assembled by the E1-E2-E3 cascade into poly-UB chains, thus indicating differences in UB C-terminal specificities between the E1 and DUBs. Consequently these UB mutants may provide stability to UB polymers attached to cellular proteins and facilitate the elucidation of the biological signals encoded in the UB chains.

Orthogonal ubiquitin transfer through engineered E1-E2 cascades for protein ubiquitination.

Protein modification by ubiquitin (UB) controls diverse cellular processes. UB is conjugated to cellular proteins by sequential transfer through an E1-E2-E3 enzymatic cascade. The cross-activities of 2 E1s, 50 E2s and thousands of E3s encoded by the human genome make it difficult to identify the substrate proteins of a specific E3 enzyme in the cell. One way to solve this problem is to engineer an orthogonal UB transfer (OUT) cascade in which the engineered UB (xUB) is relayed by engineered E1, E2 and E3 enzymes (xE1, xE2, xE3) to modify the substrate proteins of a specific E3. Here, we use phage display and mutagenesis to construct xUB-xE1 and xE1-xE2 pairs that are orthogonal to the native E1 and E2 enzymes. Our work on engineering the UB transfer cascades will enable us to use OUT to map the signal transduction networks mediated by protein ubiquitination.

Inhibiting the protein ubiquitination cascade by ubiquitin-mimicking short peptides.

Short heptapeptides were identified to function as ubiquitin (UB) mimics that are activated by E1 and form thioester conjugates with E1, E2, and HECT type E3 enzymes. The activities (k(cat)/K(1/2)) of E1 with the UB-mimicking peptides are 130-1,400-fold higher than the equally long peptide with the native C-terminal sequence of UB. By forming covalent conjugates with E1, E2, and E3 enzymes, the UB-mimicking peptides can block the transfer of native UB through the cascade.

Chapter 10 using phosphopantetheinyl transferases for enzyme posttranslational activation, site specific protein labeling and identification of natural product biosynthetic gene clusters from bacterial genomes.

Phosphopantetheinyl transferases (PPTases) covalently attach the phosphopantetheinyl group derived from coenzyme A (CoA) to acyl carrier proteins or peptidyl carrier proteins as part of the enzymatic assembly lines of fatty acid synthases (FAS), polyketide synthases (PKS), and nonribosomal peptide synthetases (NRPS). PPTases have demonstrated broad substrate specificities for cross-species modification of carrier proteins embedded in PKS or NRPS modules. PPTase Sfp from Bacillus subtilis and AcpS from Escherichia coli also transfer small molecules of diverse structures from their CoA conjugates to the carrier proteins. Short peptide tags have thus been developed as efficient substrates of Sfp and AcpS for site-specific labeling of the peptide-tagged fusion proteins with biotin or organic fluorophores. This chapter discusses the use of PPTases for in vivo and in vitro modification of PKS and NRPS enzymes and for site-specific protein labeling. We also describe a phage selection method based on PPTase-catalyzed carrier protein modification for the identification of PKS or NRPS genes from bacterial genomes.

Catalytic turnover-based phage selection for engineering the substrate specificity of Sfp phosphopantetheinyl transferase.

We report a high-throughput phage selection method to identify mutants of Sfp phosphopantetheinyl transferase with altered substrate specificities from a large library of the Sfp enzyme. In this method, Sfp and its peptide substrates are co-displayed on the M13 phage surface as fusions to the phage capsid protein pIII. Phage-displayed Sfp mutants that are active with biotin-conjugated coenzyme A (CoA) analogues would covalently transfer biotin to the peptide substrates anchored on the same phage particle. Affinity selection for biotin-labeled phages would enrich Sfp mutants that recognize CoA analogues for carrier protein modification. We used this method to successfully change the substrate specificity of Sfp and identified mutant enzymes with more than 300-fold increase in catalytic efficiency with 3'-dephospho CoA as the substrate. The method we developed in this study provides a useful platform to display enzymes and their peptide substrates on the phage surface and directly couples phage selection with enzyme catalysis. We envision this method to be applied to engineering the catalytic activities of other protein posttranslational modification enzymes.

Multiple deprotonations and deaminations of phenethylamines to synthesize pyrroles.

A unique method was discovered to construct polysubstituted pyrroles via an unprecedented multiple deprotonations/deaminations process from commercially available phenethylamines. During this transformation, twelve bonds were broken and five new bonds were constructed.

Highly selective C-H functionalization/halogenation of acetanilide.

Highly regioselective C-H functionalization/halogenation of acetanilides to produce ortho-haloacetanilides was catalyzed by Pd(OAc)2 and Cu(OAc) 2 with CuX2 as the halogen source.