Your search keyword '"Hemu X"' showing total 28 results

1. Phylotranscriptomics reveals the phylogeny of Asparagales and the evolution of allium flavor biosynthesis.

Author

Wang XX, Huang CH, Morales-Briones DF, Wang XY, Hu Y, Zhang N, Zhao PG, Wei XM, Wei KH, Hemu X, Tan NH, Wang QF, and Chen LY

Subjects

Transcriptome, Gene Expression Regulation, Plant, Plant Proteins genetics, Plant Proteins metabolism, Flavoring Agents metabolism, Mutation, Phylogeny, Allium genetics, Evolution, Molecular

Abstract

Asparagales, the largest monocot order, is renowned for its ecological, economic, and medicinal significance. Here, we leverage transcriptome data from 455 Asparagales species to explore the phylogeny of Asparagales. Moreover, we investigate the evolutionary patterns of the genes involved in allium flavor formation. We not only establish a robust bifurcating phylogeny of Asparagales but also explore their reticulate relationships. Notably, we find that eight genes involved in the biosynthesis of allium flavor compounds underwent expansion in Allium species. Furthermore, we observe Allium-specific mutations in one amino acid within alliinase and three within lachrymatory factor synthase. Overall, our findings highlight the role of gene expansion, increased expression, and amino acid mutations in driving the evolution of Allium-specific compounds. These insights not only deepen our understanding of the phylogeny of Asparagales but also illuminate the genetic mechanisms underpinning specialized compounds., (© 2024. The Author(s).)

Published

2024

2. Repurposing Copper(II)/THPTA as A Bioorthogonal Catalyst for Thiazolidine Bond Cleavage.

Author

Ma C, Liu G, Yin J, Sun J, Luo D, Yang D, Pang S, Hou W, Hemu X, Ye B, and Bi X

Subjects

Catalysis, Triazoles chemistry, Azides chemistry, Copper chemistry, Thiazolidines chemistry, Cycloaddition Reaction methods

Abstract

Metal-mediated chemical transformations are promising approaches to manipulate and regulate proteins in fundamental biological research and therapeutic development. Nevertheless, unlike bond-forming reactions, the exploration of selective bond cleavage reactions catalyzed by metals that are fully compatible with proteins and living systems remains relatively limited. Here, it is reported that Copper(II)/tris(3-hydroxypropyltriazolylmethyl)amine (THPTA), commonly used in copper-catalyzed azide-alkyne cycloaddition (CuAAC) reaction, can be repurposed as a new bioorthogonal catalyst for thiazolidine (Thz) bond cleavage. This process liberates an α-oxo-aldehyde group under physiological conditions, without requiring additional additives. To showcase the utility of this method, this simple catalyst system is coupled with genetic code expansion technology to achieve on-demand activation of genetically encoded Thz-caged α-oxo-aldehydes, enabling further functionalization of proteins. For the first time, this cell-compatible Thz uncaging reaction allows for the site-specific installation of α-oxo-aldehydes at the internal positions of proteins in phage and bacterial surface display systems, expanding the chemical space of proteins. Overall, this study expands the toolkit of bioorthogonal catalysts and paves the way for metal-promoted chemical reactions in living systems, potentially benefiting various applications in the future., (© 2024 The Author(s). Advanced Science published by Wiley‐VCH GmbH.)

Published

2024

3. Recent Toolboxes for Chemoselective Dual Modifications of Proteins.

Author

Zhao Y, Zhang T, Zhu Y, Yin J, Omer R, Hemu X, Li W, and Bi X

Subjects

Humans, Protein Processing, Post-Translational, Proteins chemistry

Abstract

Site-selective chemical modifications of proteins have emerged as a potent technology in chemical biology, materials science, and medicine, facilitating precise manipulation of proteins with tailored functionalities for basic biology research and developing innovative therapeutics. Compared to traditional recombinant expression methods, one of the prominent advantages of chemical protein modification lies in its capacity to decorate proteins with a wide range of functional moieties, including non-genetically encoded ones, enabling the generation of novel protein conjugates with enhanced or previously unexplored properties. Among these, approaches for dual or multiple modifications of proteins are increasingly garnering attention, as it has been found that single modification of proteins is inadequate to meet current demands. Therefore, in light of the rapid developments in this field, this review provides a timely and comprehensive overview of the latest advancements in chemical and biological approaches for dual functionalization of proteins. It further discusses their advantages, limitations, and potential future directions in this relatively nascent area., (© 2024 The Author(s). Chemistry - A European Journal published by Wiley-VCH GmbH.)

Published

2024

4. OSMAC Strategy: A promising way to explore microbial cyclic peptides.

Author

Zhang Y, Feng L, Hemu X, Tan NH, and Wang Z

Subjects

Secondary Metabolism genetics, Peptides, Cyclic pharmacology, Multigene Family

Abstract

Microbial secondary metabolites are pivotal for the development of novel drugs. However, conventional culture techniques, have left a vast array of unexpressed biosynthetic gene clusters (BGCs) in microorganisms, hindering the discovery of metabolites with distinct structural features and diverse biological functions. To address this limitation, several innovative strategies have been emerged. The "One Strain Many Compounds" (OSMAC) strategy, which involves altering microbial culture conditions, has proven to be particularly effective in mining numerous novel secondary metabolites for the past few years. Among these, microbial cyclic peptides stand out. These peptides often comprise rare amino acids, unique chemical structures, and remarkable biological function. With the advancement of the OSMAC strategy, a plethora of new cyclic peptides have been identified from diverse microbial genera. This work reviews the progress in mining novel compounds using the OSMAC strategy and the applications of this strategy in discovering 284 microbial cyclic peptides from 63 endophytic strains, aiming to offer insights for the further explorations into novel active cyclic peptides., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier Masson SAS. All rights reserved.)

Published

2024

5. Substrate-binding glycine residues are major determinants for hydrolase and ligase activity of plant legumains.

Author

Hemu X, Chan NY, Liew HT, Hu S, Zhang X, Serra A, Lescar J, Liu CF, and Tam JP

Subjects

Glycine, Cysteine Endopeptidases metabolism, Plants metabolism, Ligases metabolism, Plant Proteins metabolism, Fabaceae

Abstract

Peptide asparaginyl ligases (PALs) are useful tools for precision modifications of proteins and live-cell surfaces by ligating peptides after Asn/Asp (Asx). They share high sequence and structural similarity to plant legumains that are generally known as asparaginyl endopeptidases (AEPs), thus making it challenging to identify PALs from AEPs. In this study, we investigate 875 plant species from algae to seed plants with available sequence data in public databases to identify new PALs. We conducted evolutionary trace analysis on 1500 plant legumains, including eight known PALs, to identify key residues that could differentiate ligases and proteases, followed by recombinant expression and functional validation of 16 novel legumains. Previously, we showed that the substrate-binding sequences flanking the catalytic site can strongly influence the enzymatic direction of a legumain and which we named as ligase-activity determinants (LADs). Here, we show that two conserved substrate-binding Gly residues of LADs are critical, but negative determinants for ligase activity. Our results suggest that specific glycine residues are molecular determinants to identify PALs and AEPs as two different legumain subfamilies, accounting for c. 1% and 88%, respectively., (© 2023 The Authors. New Phytologist © 2023 New Phytologist Foundation.)

Published

2023

6. Consensus design and engineering of an efficient and high-yield peptide asparaginyl ligase for protein cyclization and ligation.

Author

Hemu X, Zhang X, Chang HY, Poh JE, and Tam JP

Subjects

Amino Acid Sequence, Cyclization, Plants metabolism, Peptide Synthases metabolism, Protein Engineering, Peptides metabolism, Endopeptidases metabolism, Plant Proteins metabolism, Escherichia coli genetics, Escherichia coli metabolism

Abstract

Plant legumains are Asn/Asp-specific endopeptidases that have diverse functions in plants. Peptide asparaginyl ligases (PALs) are a special legumain subtype that primarily catalyze peptide bond formation rather than hydrolysis. PALs are versatile protein engineering tools but are rarely found in nature. To overcome this limitation, here we describe a two-step method to design and engineer a high-yield and efficient recombinant PAL based on commonly found asparaginyl endopeptidases. We first constructed a consensus sequence derived from 1500 plant legumains to design the evolutionarily stable legumain conLEG that could be produced in E. coli with 20-fold higher yield relative to that for natural legumains. We then applied the ligase-activity determinant hypothesis to exploit conserved residues in PAL substrate-binding pockets and convert conLEG into conPAL1-3. Functional studies showed that conLEG is primarily a hydrolase, whereas conPALs are ligases. Importantly, conPAL3 is a superefficient and broadly active PAL for protein cyclization and ligation., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

7. Structural basis for proenzyme maturation, substrate recognition, and ligation by a hyperactive peptide asparaginyl ligase.

Author

Hu S, El Sahili A, Kishore S, Wong YH, Hemu X, Goh BC, Zhipei S, Wang Z, Tam JP, Liu CF, and Lescar J

Subjects

Substrate Specificity, Peptides metabolism, Proteins, Enzyme Precursors metabolism, Ligases genetics, Ligases metabolism

Abstract

Peptide ligases are versatile enzymes that can be utilized for precise protein conjugation for bioengineering applications. Hyperactive peptide asparaginyl ligases (PALs), such as butelase-1, belong to a small class of enzymes from cyclotide-producing plants that can perform site-specific, rapid ligation reactions after a target peptide asparagine/aspartic acid (Asx) residue binds to the active site of the ligase. How PALs specifically recognize their polypeptide substrates has remained elusive, especially at the prime binding side of the enzyme. Here we report crystal structures that capture VyPAL2, a catalytically efficient PAL from Viola yedoensis, in an activated state, with and without a bound substrate. The bound structure shows one ligase with the N-terminal polypeptide tail from another ligase molecule trapped at its active site, revealing how Asx inserts in the enzyme's S1 pocket and why a hydrophobic residue is required at the P2' position. Besides illustrating the anchoring role played by P1 and P2' residues, these results uncover a role for the Gatekeeper residue at the surface of the S2 pocket in shifting the nonprime portion of the substrate and, as a result, the activity toward ligation or hydrolysis. These results suggest a picture for proenzyme maturation in the vacuole and will inform the rational design of peptide ligases with tailored specificities., (© American Society of Plant Biologists 2022. All rights reserved. For permissions, please email: journals.permissions@oup.com.)

Published

2022

8. The legumain McPAL1 from Momordica cochinchinensis is a highly stable Asx-specific splicing enzyme.

Author

Liew HT, To J, Zhang X, Hemu X, Chan NY, Serra A, Sze SK, Liu CF, and Tam JP

Subjects

Amino Acid Sequence, Cyclization, Cyclotides genetics, Cyclotides metabolism, Cysteine Endopeptidases analysis, Cysteine Endopeptidases genetics, Models, Molecular, Momordica chemistry, Momordica genetics, Peptides, Cyclic genetics, Peptides, Cyclic metabolism, Plant Proteins analysis, Plant Proteins genetics, Protein Engineering, Transcriptome, Cysteine Endopeptidases metabolism, Momordica metabolism, Plant Proteins metabolism

Abstract

Legumains, also known as asparaginyl endopeptidases (AEPs), cleave peptide bonds after Asn/Asp (Asx) residues. In plants, certain legumains also have ligase activity that catalyzes biosynthesis of Asx-containing cyclic peptides. An example is the biosynthesis of MCoTI-I/II, a squash family-derived cyclic trypsin inhibitor, which involves splicing to remove the N-terminal prodomain and then N-to-C-terminal cyclization of the mature domain. To identify plant legumains responsible for the maturation of these cyclic peptides, we have isolated and characterized a legumain involved in splicing, McPAL1, from Momordica cochinchinensis (Cucurbitaceae) seeds. Functional studies show that recombinantly expressed McPAL1 displays a pH-dependent, trimodal enzymatic profile. At pH 4 to 6, McPAL1 selectively catalyzed Asp-ligation and Asn-cleavage, but at pH 6.5 to 8, Asn-ligation predominated. With peptide substrates containing N-terminal Asn and C-terminal Asp, such as is found in precursors of MCoTI-I/II, McPAL1 mediates proteolysis at the Asn site and then ligation at the Asp site at pH 5 to 6. Also, McPAL1 is an unusually stable legumain that is tolerant of heat and high pH. Together, our results support that McPAL1 is a splicing legumain at acidic pH that can mediate biosynthesis of MCoTI-I/II. We purport that the high thermal and pH stability of McPAL1 could have applications for protein engineering., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

9. Editorial: Food Proteomes: Beyond Their Nutritional Value.

Author

Gallart-Palau X, Hemu X, Motilva MJ, and Serra A

Abstract

Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Published

2021

10. Characterization and application of natural and recombinant butelase-1 to improve industrial enzymes by end-to-end circularization.

Author

Hemu X, Zhang X, Nguyen GKT, To J, Serra A, Loo S, Sze SK, Liu CF, and Tam JP

Abstract

Butelase-1, an asparaginyl endopeptidase or legumain, is the prototypical and fastest known Asn/Asp-specific peptide ligase. It is highly useful for engineering and macrocyclization of peptides and proteins. However, certain biochemical properties and applications of naturally occurring and recombinant butelase-1 remain unexplored. Here we report methods to increase the yield of natural and bacterial expressed recombinant butelase-1 and how they can be used to improve the stability and activity of two important industrial enzymes, lipase and phytase, by end-to-end circularization. First, the yield of natural butelase-1 was increased 3-fold to 15 mg kg -1 by determining its highest distribution which is found in young tissues, such as shoots. The yield of recombinantly-produced soluble butelase-1 was improved by promoting cytoplasmic disulfide folding, codon changes, and truncation of the N-terminal pro-domain. Natural and recombinant butelase-1 displayed similar ligase activity, physical stability, and salt tolerance. Furthermore, the processing and glycosylation sites of natural and recombinant butelase-1 were determined by proteomic analysis. Storage conditions for both forms of butelase-1, frozen or lyophilized, were also optimized. Cyclization of lipase and phytase mediated by either soluble or immobilized butelase-1 was highly efficient and simple, and resulted in increased thermal stability and enhanced enzymatic activity. Overall, improved production of butelase-1 can be exploited to improve the biocatalytic efficacy of lipase and phytase by end-to-end cyclization. In turn, ligase-improved enzymes could be a general and environmentally friendly strategy for producing more stable and efficient industrial enzymes., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2021

11. Engineering protein theranostics using bio-orthogonal asparaginyl peptide ligases.

Author

Wang Z, Zhang D, Hemu X, Hu S, To J, Zhang X, Lescar J, Tam JP, and Liu CF

Subjects

Cell Line, Tumor, Doxorubicin metabolism, ErbB Receptors metabolism, Humans, MCF-7 Cells, Mitochondria metabolism, Precision Medicine methods, Protein Engineering methods, Protein Processing, Post-Translational physiology, Recombinant Proteins metabolism, Substrate Specificity, Ligases metabolism, Peptides metabolism

Abstract

Background: Protein theranostics integrate both diagnostic and treatment functions on a single disease-targeting protein. However, the preparation of these multimodal agents remains a major challenge. Ideally, conventional recombinant proteins should be used as starting materials for modification with the desired detection and therapeutic functionalities, but simple chemical strategies that allow the introduction of two different modifications into a protein in a site-specific manner are not currently available. We recently discovered two highly efficient peptide ligases, namely butelase-1 and VyPAL2. Although both ligate at asparaginyl peptide bonds, these two enzymes are bio-orthogonal with distinguishable substrate specificities, which can be exploited to introduce distinct modifications onto a protein. Methods: We quantified substrate specificity differences between butelase-1 and VyPAL2, which provide orthogonality for a tandem ligation method for protein dual modifications. Recombinant proteins or synthetic peptides engineered with the preferred recognition motifs of butelase-1 and VyPAL2 at their respective C- and N-terminal ends could be modified consecutively by the action of the two ligases. Results: Using this method, we modified an EGFR-targeting affibody with a fluorescein tag and a mitochondrion-lytic peptide at its respective N- and C-terminal ends. The dual-labeled protein was found to be a selective bioimaging and cytotoxic agent for EGFR-positive A431 cancer cells. In addition, the method was used to prepare a cyclic form of the affibody conjugated with doxorubicin. Both modified affibodies showed increased cytotoxicity to A431 cells by 10- and 100-fold compared to unconjugated doxorubicin and the free peptide, respectively. Conclusion: Bio-orthogonal tandem ligation using two asparaginyl peptide ligases with differential substrate specificities is a straightforward approach for the preparation of multifunctional protein biologics as potential theranostics., Competing Interests: Competing Interests: The authors have declared that no competing interest exists., (© The author(s).)

Published

2021

12. Correction to Immobilized Peptide Asparaginyl Ligases Enhance Stability and Facilitate Macrocyclization and Site-Specific Ligation.

Author

Hemu X, To J, Zhang X, and Tam JP

Published

2020

13. Immobilized Peptide Asparaginyl Ligases Enhance Stability and Facilitate Macrocyclization and Site-Specific Ligation.

Author

Hemu X, To J, Zhang X, and Tam JP

Subjects

Catalysis, Cyclization, Enzymes, Immobilized, Ligases metabolism, Peptides, Proteins

Abstract

The recently discovered peptide asparaginyl ligases (PALs) from cyclotide-producing plants are efficient and versatile tools for protein and peptide engineering. Here, we report immobilization of two glycosylated PALs, butelase-1 and VyPAL2, using three different attachment methods and their applications for peptide engineering. We compared immobilization indirectly via noncovalent affinity capture using NeutrAvidin or concanavalin A agarose beads or directly via covalent coupling of free amines on the enzyme surface with the N -hydroxysuccinimide (NHS) ester attached on agarose beads. The catalytic efficiency of immobilized PALs correlated with the distance between the biocatalysts and the solid supports, and in turn, the mobility of enzymes and the accessibility of substrates. Compared to their soluble counterparts, the site separations of immobilized PALs retain higher activity after prolonged storage and confer reusability for over 100 runs with less than 10% activity loss. We also showed that the cyclization and ligation of peptides and proteins with varying shapes and sizes can be accelerated by providing higher concentration of reusable immobilized PALs. These advantages could be exploited for large-scale industrial applications and nanodevices.

Published

2020

14. Structural determinants for peptide-bond formation by asparaginyl ligases.

Author

Hemu X, El Sahili A, Hu S, Wong K, Chen Y, Wong YH, Zhang X, Serra A, Goh BC, Darwis DA, Chen MW, Sze SK, Liu CF, Lescar J, and Tam JP

Subjects

Mutagenesis physiology, Cysteine Endopeptidases metabolism, Ligases metabolism, Peptides, Cyclic metabolism, Plant Proteins metabolism, Violaceae metabolism

Abstract

Asparaginyl endopeptidases (AEPs) are cysteine proteases which break Asx (Asn/Asp)-Xaa bonds in acidic conditions. Despite sharing a conserved overall structure with AEPs, certain plant enzymes such as butelase 1 act as a peptide asparaginyl ligase (PAL) and catalyze Asx-Xaa bond formation in near-neutral conditions. PALs also serve as macrocyclases in the biosynthesis of cyclic peptides. Here, we address the question of how a PAL can function as a ligase rather than a protease. Based on sequence homology of butelase 1, we identified AEPs and PALs from the cyclic peptide-producing plants Viola yedoensis ( Vy ) and Viola canadensis ( Vc ) of the Violaceae family. Using a crystal structure of a PAL obtained at 2.4-Å resolution coupled to mutagenesis studies, we discovered ligase-activity determinants flanking the S1 site, namely LAD1 and LAD2 located around the S2 and S1' sites, respectively, which modulate ligase activity by controlling the accessibility of water or amine nucleophile to the S -ester intermediate. Recombinantly expressed Vy PAL1-3, predicted to be PALs, were confirmed to be ligases by functional studies. In addition, mutagenesis studies on Vy PAL1-3, Vy AEP1, and Vc AEP supported our prediction that LAD1 and LAD2 are important for ligase activity. In particular, mutagenesis targeting LAD2 selectively enhanced the ligase activity of Vy PAL3 and converted the protease Vc AEP into a ligase. The definition of structural determinants required for ligation activity of the asparaginyl ligases presented here will facilitate genomic identification of PALs and engineering of AEPs into PALs., Competing Interests: The authors declare no conflict of interest.

Published

2019

15. Ligase-Controlled Cyclo-oligomerization of Peptides.

Author

Hemu X, Zhang X, and Tam JP

Subjects

Amino Acids metabolism, Catalysis, Depsipeptides metabolism, Ligases metabolism, Molecular Structure, Peptides, Cyclic metabolism, Amino Acids chemistry, Depsipeptides chemistry, Ligases chemistry, Peptides, Cyclic chemistry

Abstract

A biomimetic one-step ligase-catalyzed cyclo-oligomerization mediated by butelase 1, an Asn/Asp-specific ligase, is introduced that is time-, concentration-, length-, and sequence-dependent. This reaction yields cyclic mono-, di-, tri-, and tetramers from peptide precursors containing 3-15 amino acids ended with Asn and a His-Val tail. The cyclomonomers were favored when the peptide lengths were >9 amino acids. A turn-forming Pro residue at the P2 position favored the formation of higher-order cyclo-oligomers.

Published

2019

16. Butelase 1-Mediated Ligation of Peptides and Proteins.

Author

Hemu X, Zhang X, Bi X, Liu CF, and Tam JP

Subjects

Amino Acids chemistry, Catalysis, Cyclization, Peptides, Cyclic chemistry, Plant Proteins chemistry, Protein Engineering, Protein Processing, Post-Translational, Staining and Labeling, Ligases chemistry, Peptides chemistry, Proteins chemistry

Abstract

Structurally, butelase 1 is a cysteine protease of the asparaginyl endoprotease (AEP) family, but functionally, it displays intense Asn/Asp-specific (Asx) ligase activity and is virtually devoid of protease activity. Butelase 1 recognizes specifically a C-terminal Asx-containing tripeptide motif, Asx-His-Val, to form an Asx-Xaa peptide bond (Xaa = any amino acid), either intramolecularly or intermolecularly, resulting in cyclic peptides or site-specific modified peptides/proteins, respectively. Our work in the past 4 years has validated that butelase 1 is a potent and versatile tool for peptide and protein modification. Here we describe our protocols using butelase 1 for efficient and site-specific peptide and protein ligation, N-terminal labeling, preparation of thioesters, and bioconjugation of dendrimers. Additionally, we provide an example using butelase 1 for protein cyclization in combination with genetic code expansion in order to incorporate unnatural building blocks.

Published

2019

17. Immobilization and Intracellular Delivery of Circular Proteins by Modifying a Genetically Incorporated Unnatural Amino Acid.

Author

Bi X, Yin J, Hemu X, Rao C, Tam JP, and Liu CF

Subjects

Amino Acids metabolism, Biotin, Cyclization, Genetic Code, Peptides, Cyclic genetics, Cell Membrane Permeability, Cell-Penetrating Peptides genetics, Peptides, Cyclic metabolism, Protein Engineering methods

Abstract

Backbone-cyclic proteins are of great scientific and therapeutic interest owing to their higher stability over their linear counterparts. Modification of such cyclic proteins at a selected site would further enhance their versatility. Here we report a chemoenzymatic strategy to engineer site-selectively modified cyclic proteins by combining butelase-mediated macrocyclization with the genetic code expansion methodology. Using this strategy, we prepared a cyclic protein which was modified with biotin or a cell-penetrating peptide at a genetically incorporated noncanonical amino acid, making the cyclization-stabilized protein further amenable for site-specific immobilization and intracellular delivery. Our results point to a new avenue to engineering novel cyclic proteins with improved physicochemical and pharmacological properties for potential applications in biotechnology and medicine.

Published

2018

18. Peptidomic Identification of Cysteine-Rich Peptides from Plants.

Author

Hemu X, Serra A, Darwis DA, Cornvik T, Sze SK, and Tam JP

Subjects

Peptide Fragments genetics, Plant Proteins genetics, Transcriptome, Clitoria metabolism, Cysteine chemistry, Mass Spectrometry methods, Peptide Fragments analysis, Peptide Fragments metabolism, Plant Proteins metabolism, Proteomics methods

Abstract

Plant cysteine-rich peptides (CRPs) constitute a majority of plant-derived peptides with high molecular diversity. This protocol describes a rapid and efficient peptidomic approach to identify a whole spectrum of CRPs in a plant extract and decipher their molecular diversity and bioprocessing mechanism. Cyclotides from C. ternatea are used as the model CRPs to demonstrate our methodology. Cyclotides exist naturally in both cyclic and linear forms, although the linear forms (acyclotide) are generally present at much lower concentrations. Both cyclotides and acyclotides require linearization of their backbone prior to fragmentation and sequencing. A novel and practical three-step chemoenzymatic treatment was developed to linearize and distinguish both forms: (1) N-terminal acetylation that pre-labels the acyclotides; (2) conversion of Cys into pseudo-Lys through aziridine-mediated S-alkylation to reduce disulfide bonds and to increase the net charge of peptides; and (3) opening of cyclic backbones by the novel asparaginyl endopeptidase butelase 2 that cleaves at the native bioprocessing site. The treated peptides are subsequently analyzed by liquid chromatography coupled to mass spectrometry using electron transfer dissociation fragmentation and sequences are identified by matching the MS/MS spectra directly with the transcriptomic database.

Published

2018

19. Enzymatic Engineering of Live Bacterial Cell Surfaces Using Butelase 1.

Author

Bi X, Yin J, Nguyen GKT, Rao C, Halim NBA, Hemu X, Tam JP, and Liu CF

Subjects

Amino Acid Sequence, Animals, Animals, Genetically Modified, Clitoria enzymology, Escherichia coli chemistry, Glycopeptides chemistry, HeLa Cells, Host-Pathogen Interactions, Humans, Lysosomes chemistry, Lysosomes metabolism, Macrophages cytology, Macrophages metabolism, Microscopy, Confocal, Zebrafish, Escherichia coli metabolism, Glycopeptides metabolism, Ligases metabolism, Plant Proteins metabolism

Abstract

Butelase-mediated ligation (BML) can be used to modify live bacterial cell surfaces with diverse cargo molecules. Surface-displayed butelase recognition motif NHV was first introduced at the C-terminal end of the anchoring protein OmpA on E. coli cells. This then served as a handle of BML for the functionalization of E. coli cell surfaces with fluorescein and biotin tags, a tumor-associated monoglycosylated peptide, and mCherry protein. The cell-surface ligation reaction was achieved at low concentrations of butelase and the labeling substrates. Furthermore, the fluorescein-labeled bacterial cells were used to show the interactions with cultured HeLa cells and with macrophages in live transgenic zebrafish, capturing the latter's powerful phagocytic effect in action. Together these results highlight the usefulness of butelase 1 in live bacterial cell surface engineering for novel applications., (© 2017 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2017

20. Macrocyclic Antimicrobial Peptides Engineered from ω-Conotoxin.

Author

Hemu X and Tam JP

Subjects

Antimicrobial Cationic Peptides chemical synthesis, Antimicrobial Cationic Peptides chemistry, Calcium Channel Blockers chemical synthesis, Calcium Channel Blockers chemistry, Conotoxins chemical synthesis, Conotoxins chemistry, Dose-Response Relationship, Drug, Erythrocytes drug effects, Erythrocytes microbiology, Healthy Volunteers, Humans, Macrocyclic Compounds chemical synthesis, Macrocyclic Compounds chemistry, Microbial Sensitivity Tests, Molecular Structure, Protein Engineering, Structure-Activity Relationship, Antimicrobial Cationic Peptides pharmacology, Calcium Channel Blockers pharmacology, Conotoxins pharmacology, Gram-Negative Bacteria drug effects, Gram-Positive Bacteria drug effects, Macrocyclic Compounds pharmacology

Abstract

The potent calcium channel blocker ω-conotoxin MVIIA is a linear cystine-knot peptide with multiple basic amino acids at both termini. This work shows that macrocyclization of MVIIA linking two positive-charge terminal clusters as a contiguous segment converts a conotoxin into an antimicrobial peptide. In addition, conversion of disulfide bonds to amino butyric acids improved the antimicrobial activity of the cyclic analogs. Ten macrocyclic analogs, with or without disulfide bonds, were prepared by both Boc and Fmoc chemistry using native chemical ligation. All cyclic analogs were active against selected Gram-positive and Gram-negative bacteria with minimal inhibitory concentrations in a low μM range. In contrast, MVIIA and its linear analog were inactive at concentrations up to 0.5 mM. The cyclic analogs also showed 2 to 3-fold improved chemotactic activity against human monocytes THP-1 compared with MVIIA. Reduction of molecular stability against thermal and acid treatment due to the reduced number of disulfide crosslinks can be partly restored by backbone cyclization. Together, these results show that macrocyclization and side chain modification of a linear conopeptide lead to a gain-of-function, which brings a new perspective in designing and engineering of peptidyl therapeutics., (Copyright© Bentham Science Publishers; For any queries, please email at epub@benthamscience.org.)

Published

2017

21. Butelase-Mediated Macrocyclization of d-Amino-Acid-Containing Peptides.

Author

Nguyen GK, Hemu X, Quek JP, and Tam JP

Subjects

Amino Acids pharmacology, Anti-Bacterial Agents pharmacology, Escherichia coli drug effects, Macrocyclic Compounds chemistry, Macrocyclic Compounds pharmacology, Microbial Sensitivity Tests, Peptides pharmacology, Staphylococcus aureus drug effects, Amino Acids chemistry, Anti-Bacterial Agents chemistry, Macrocyclic Compounds chemical synthesis, Peptides chemistry

Abstract

Macrocyclic compounds have received increasing attention in recent years. With their large surface area, they hold promise for inhibiting protein-protein interactions, a chemical space that was thought to be undruggable. Although many chemical methods have been developed for peptide macrocyclization, enzymatic methods have emerged as a promising new economical approach. Thus far, most enzymes have been shown to act on l-peptides; their ability to cyclize d-amino-acid-containing peptides has rarely been documented. Herein we show that macrocycles consisting of d-amino acids, except for the Asn residue at the ligating site, were efficiently synthesized by butelase 1, an Asn/Asp-specific ligase. Furthermore, by using a peptide-library approach, we show that butelase 1 tolerates most of the d-amino acid residues at the P1'' and P2'' positions., (© 2016 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2016

22. Butelase-mediated cyclization and ligation of peptides and proteins.

Author

Nguyen GK, Qiu Y, Cao Y, Hemu X, Liu CF, and Tam JP

Abstract

Enzymes that catalyze efficient macrocyclization or site-specific ligation of peptides and proteins can enable tools for drug design and protein engineering. Here we describe a protocol to use butelase 1, a recently discovered peptide ligase, for high-efficiency cyclization and ligation of peptides and proteins ranging in size from 10 to >200 residues. Butelase 1 is the fastest known ligase and is found in pods of the common medicinal plant Clitoria ternatea (also known as butterfly pea). It has a very simple C-terminal-specific recognition motif that requires Asn/Asp (Asx) at the P1 position and a dipeptide His-Val at the P1' and P2' positions. Substrates for butelase-mediated ligation can be prepared by standard Fmoc (9-fluorenylmethyloxycarbonyl) chemistry or recombinant expression with the minimal addition of this tripeptide Asn-His-Val motif at the C terminus. Butelase 1 achieves cyclizations that are 20,000 times faster than those of sortase A, a commonly used enzyme for backbone cyclization. Unlike sortase A, butelase is traceless, and it can be used for the total synthesis of naturally occurring peptides and proteins. Furthermore, butelase 1 is also useful for intermolecular ligations and synthesis of peptide or protein thioesters, which are versatile activated intermediates necessary for and compatible with many chemical ligation methods. The protocol describes steps for isolation and purification of butelase 1 from plant extract using a four-step chromatography procedure, which takes ∼3 d. We then describe steps for intramolecular cyclization, intermolecular ligation and butelase-mediated synthesis of protein thioesters. Butelase reactions are generally completed within minutes and often achieve excellent yields.

Published

2016

23. Total Synthesis of Circular Bacteriocins by Butelase 1.

Author

Hemu X, Qiu Y, Nguyen GK, and Tam JP

Subjects

Amino Acid Sequence, Anti-Bacterial Agents chemistry, Anti-Bacterial Agents pharmacology, Bacteriocins chemistry, Bacteriocins pharmacology, Catalysis, Cyclization, Peptides, Cyclic chemistry, Peptides, Cyclic pharmacology, Anti-Bacterial Agents chemical synthesis, Bacteriocins chemical synthesis, Chemistry Techniques, Synthetic methods, Clitoria enzymology, Ligases chemistry, Peptides, Cyclic chemical synthesis

Abstract

Circular bacteriocins, ranging from 35 to 70 amino acids, are the largest cyclic peptides produced by lactic acid bacteria to suppress growth of other bacteria. Their end-to-end cyclized backbone that enhances molecular stability is an advantage to survive in pasteurization and cooking processes in food preservation, but becomes a disadvantage and challenge in chemical synthesis. They also contain unusually long and highly hydrophobic segments which pose an additional synthetic challenge. Here we report the total synthesis of the three largest circular bacteriocins, AS-48, uberolysin, and garvicin ML, by an efficient chemoenzymatic strategy. A key feature of our synthetic scheme is the use of an Asn-specific butelase-mediated cyclization of their linear precursors, prepared by microwave stepwise synthesis. Antimicrobial assays showed that the AS-48 linear precursor is inactive at concentrations up to 100 μM, whereas the macrocyclic AS-48 is potently active against pathogenic and drug-resistant bacteria, with minimal inhibitory concentrations in a sub-micromolar range.

Published

2016

24. Commercial processed soy-based food product contains glycated and glycoxidated lunasin proteoforms.

Author

Serra A, Gallart-Palau X, See-Toh RS, Hemu X, Tam JP, and Sze SK

Subjects

Glycoproteins chemistry, Glycosylation, Humans, Ion Exchange, Mass Spectrometry, Soybean Proteins chemistry, Dietary Supplements analysis, Food Analysis, Food Handling methods, Glycoproteins analysis, Soybean Proteins isolation & purification, Glycine max chemistry

Abstract

Nutraceuticals have been proposed to exert positive effects on human health and confer protection against many chronic diseases. A major bioactive component of soy-based foods is lunasin peptide, which has potential to exert a major impact on the health of human consumers worldwide, but the biochemical features of dietary lunasin still remain poorly characterized. In this study, lunasin was purified from a soy-based food product via strong anion exchange solid phase extraction and then subjected to top-down mass spectrometry analysis that revealed in detail the molecular diversity of lunasin in processed soybean foods. We detected multiple glycated proteoforms together with potentially toxic advanced glycation end products (AGEs) derived from lunasin. In both cases, modification sites were Lys24 and Lys29 located at the helical region that shows structural homology with a conserved region of chromatin-binding proteins. The identified post-translational modifications may have an important repercussion on lunasin epigenetic regulatory capacity. Taking together, our results demonstrate the importance of proper chemical characterization of commercial processed food products to assess their impact on consumer's health and risk of chronic diseases.

Published

2016

25. A high-throughput peptidomic strategy to decipher the molecular diversity of cyclic cysteine-rich peptides.

Author

Serra A, Hemu X, Nguyen GK, Nguyen NT, Sze SK, and Tam JP

Subjects

Amino Acid Sequence, Clitoria genetics, Cyclotides genetics, Cysteine genetics, Gene Expression Profiling, Protein Domains, Protein Processing, Post-Translational, Clitoria chemistry, Cyclotides chemistry, Cysteine chemistry, Plant Proteins chemistry

Abstract

Cyclotides are plant cyclic cysteine-rich peptides (CRPs). The cyclic nature is reported to be gene-determined with a precursor containing a cyclization-competent domain which contains an essential C-terminal Asn/Asp (Asx) processing signal recognized by a cyclase. Linear forms of cyclotides are rare and are likely uncyclizable because they lack this essential C-terminal Asx signal (uncyclotide). Here we show that in the cyclotide-producing plant Clitoria ternatea, both cyclic and acyclic products, collectively named cliotides, can be bioprocessed from the same cyclization-competent precursor. Using an improved peptidomic strategy coupled with the novel Asx-specific endopeptidase butelase 2 to linearize cliotides at a biosynthetic ligation site for transcriptomic analysis, we characterized 272 cliotides derived from 38 genes. Several types of post-translational modifications of the processed cyclotides were observed, including deamidation, oxidation, hydroxylation, dehydration, glycosylation, methylation, and truncation. Taken together, our results suggest that cyclotide biosynthesis involves 'fuzzy' processing of precursors into both cyclic and linear forms as well as post-translational modifications to achieve molecular diversity, which is a commonly found trait of natural product biosynthesis.

Published

2016

26. Butelase 1 is an Asx-specific ligase enabling peptide macrocyclization and synthesis.

Author

Nguyen GK, Wang S, Qiu Y, Hemu X, Lian Y, and Tam JP

Subjects

Amino Acid Sequence, Animals, Aspartic Acid Endopeptidases metabolism, Cyclization, Disulfides metabolism, Humans, Hydrolysis, Kinetics, Macrocyclic Compounds metabolism, Models, Molecular, Molecular Sequence Data, Peptide Synthases isolation & purification, Peptides chemistry, Peptides metabolism, Plant Proteins isolation & purification, Recombinant Proteins chemistry, Substrate Specificity, Asparagine metabolism, Aspartic Acid metabolism, Clitoria enzymology, Ligases metabolism, Macrocyclic Compounds chemical synthesis, Peptide Synthases chemistry, Plant Proteins chemistry

Abstract

Proteases are ubiquitous in nature, whereas naturally occurring peptide ligases, enzymes catalyzing the reverse reactions of proteases, are rare occurrences. Here we describe the discovery of butelase 1, to our knowledge the first asparagine/aspartate (Asx) peptide ligase to be reported. This highly efficient enzyme was isolated from Clitoria ternatea, a cyclic peptide-producing medicinal plant. Butelase 1 shares 71% sequence identity and the same catalytic triad with legumain proteases but does not hydrolyze the protease substrate of legumain. Instead, butelase 1 cyclizes various peptides of plant and animal origin with yields greater than 95%. With Kcat values of up to 17 s(-1) and catalytic efficiencies as high as 542,000 M(-1) s(-1), butelase 1 is the fastest peptide ligase known. Notably, butelase 1 also displays broad specificity for the N-terminal amino acids of the peptide substrate, thus providing a new tool for C terminus-specific intermolecular peptide ligations.

Published

2014

27. Biomimetic synthesis of cyclic peptides using novel thioester surrogates.

Author

Hemu X, Taichi M, Qiu Y, Liu DX, and Tam JP

Subjects

Peptides chemistry, Solid-Phase Synthesis Techniques, Sulfhydryl Compounds chemistry, Biomimetics, Peptides, Cyclic chemistry

Abstract

Acyl shifts involving N-S and S-S rearrangements are reactions central to the breaking of a peptide bond and forming of thioester intermediates in an intein-catalyzed protein splicing that ultimately leads to the formation of a new peptide bond by an uncatalyzed S-N acyl shift reaction. To mimic these three acyl shift reactions in forming thioesters and the subsequent peptide ligation, here we describe the development of two 9-fluorenylmethoxycarbonyl (Fmoc)-compatible thioester surrogates that can undergo uncatalyzed N-S, S-S, and S-N acyl shifts for preparing thioesters and cyclic peptides. These surrogates were incorporated as a C-terminal amido moiety of a target peptide using Fmoc chemistry by solid-phase synthesis, and then transformed into a thioester or thiolactones via two acyl shift reactions with or without the presence of an external thiol under acidic conditions. The proposed intein-mimetic thioester surrogates were prepared using readily available starting materials including N-methyl cysteine or 2-thioethylbutylamide. A key functional moiety shared in their design is the thioethylamido (TEA) moiety, which is essential to effect a proximity-driven N-S acyl shift under a favorable five-member ring transition in the breaking of a peptide bond. Thus, the tandem series of acyl shifts effected by a TEA moiety in a thioester surrogate together with a thioethylamino moiety of an N-terminal Cys residue in a linear peptide precursor are chemical mimics of an intein, as they mediate both excision and ligation reactions in forming cyclic peptides including cyclic conotoxin and sunflower trypsin inhibitor described herein., (Copyright © 2013 Wiley Periodicals, Inc.)

Published

2013

28. A thioethylalkylamido (TEA) thioester surrogate in the synthesis of a cyclic peptide via a tandem acyl shift.

Author

Taichi M, Hemu X, Qiu Y, and Tam JP

Subjects

Amides chemistry, Cyclotides chemistry, Peptides chemistry, Peptides, Cyclic chemistry, Sulfhydryl Compounds chemistry, Amides chemical synthesis, Cyclotides chemical synthesis, Peptides, Cyclic chemical synthesis, Sulfhydryl Compounds chemical synthesis

Abstract

The cyclic cystine-knot peptide, kalata B1, was synthesized by employing a novel Fmoc-compatible thioethylalkylamido (TEA) thioester surrogate via an N-S acyl shift followed by a thiol-thioester exchange reaction. TEA thioester surrogate is cost-effective, conveniently prepared in one-step with starting materials, readily available from commercial sources, and highly efficient in preparing peptide thioesters.

Published

2013