Michael D. Burkart

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Name: Burkart, Michael

Organization: University of California , USA

Department: Department of Chemistry and Biochemistry

Title: Professor(PhD)

TOPICS

Organic Chemistry

Chemicals
References

Manipulating Protein–Protein Interactions in Nonribosomal Peptide Synthetase Type II Peptidyl Carrier Proteins

Co-reporter:Matt J. Jaremko, D. John Lee, Ashay Patel, Victoria Winslow, Stanley J. Opella, J. Andrew McCammon, and Michael D. Burkart

Biochemistry October 10, 2017 Volume 56(Issue 40) pp:5269-5269

Publication Date(Web):September 18, 2017

DOI:10.1021/acs.biochem.7b00884

In an effort to elucidate and engineer interactions in type II nonribosomal peptide synthetases, we analyzed biomolecular recognition between the essential peptidyl carrier proteins and adenylation domains using nuclear magnetic resonance (NMR) spectroscopy, molecular dynamics, and mutational studies. Three peptidyl carrier proteins, PigG, PltL, and RedO, in addition to their cognate adenylation domains, PigI, PltF, and RedM, were investigated for their cross-species activity. Of the three peptidyl carrier proteins, only PigG showed substantial cross-pathway activity. Characterization of the novel NMR solution structure of holo-PigG and molecular dynamics simulations of holo-PltL and holo-PigG revealed differences in structures and dynamics of these carrier proteins. NMR titration experiments revealed perturbations of the chemical shifts of the loop 1 residues of these peptidyl carrier proteins upon their interaction with the adenylation domain. These experiments revealed a key region for the protein–protein interaction. Mutational studies supported the role of loop 1 in molecular recognition, as mutations to this region of the peptidyl carrier proteins significantly modulated their activities.

Practical 4′-Phosphopantetheine Active Site Discovery from Proteomic Samples

Co-reporter:Sherry Niessen;Michael Meehan;Roland Kersten;Anand D. Patel;Pieter C. Dorrestein;Michael Rothmann;Vineet Bafna;Jordan L. Meier;Benjamin F. Cravatt;Jane Y. Yang

Journal of Proteome Research January 7, 2011 Volume 10(Issue 1) pp:320-329

Publication Date(Web):Publication Date (Web): November 10, 2010

DOI:10.1021/pr100953b

Polyketide and nonribosomal peptides constitute important classes of small molecule natural products. Due to the proven biological activities of these compounds, novel methods for discovery and study of the polyketide synthase (PKS) and nonribosomal peptide synthetase (NRPS) enzymes responsible for their production remains an area of intense interest, and proteomic approaches represent a relatively unexplored avenue. While these enzymes may be distinguished from the proteomic milieu by their use of the 4′-phosphopantetheine (PPant) post-translational modification, proteomic detection of PPant peptides is hindered by their low abundance and labile nature which leaves them unassigned using traditional database searching. Here we address key experimental and computational challenges to facilitate practical discovery of this important post-translational modification during shotgun proteomics analysis using low-resolution ion-trap mass spectrometers. Activity-based enrichment maximizes MS input of PKS/NRPS peptides, while targeted fragmentation detects putative PPant active sites. An improved data analysis pipeline allows experimental identification and validation of these PPant peptides directly from MS2 data. Finally, a machine learning approach is developed to directly detect PPant peptides from only MS2 fragmentation data. By providing new methods for analysis of an often cryptic post-translational modification, these methods represent a first step toward the study of natural product biosynthesis in proteomic settings.Keywords: carrier protein domain, InsPecT; LC−MS/MS; natural products; nonribosomal peptide synthetase; polyketide synthase; post-translational modification; support vector machine;

Polyketide mimetics yield structural and mechanistic insights into product template domain function in nonreducing polyketide synthases

Co-reporter:Jesus F. Barajas;Gaurav Shakya;Gabriel Moreno;David R. Jackson;Caitlyn L. Topper;Heriberto Rivera, Jr.;Shiou-Chuan Tsai;Anna L. Vagstad;James J. La Clair;Craig A. Townsend

PNAS 2017 Volume 114 (Issue 21 ) pp:E4142-E4148

Publication Date(Web):2017-05-23

DOI:10.1073/pnas.1609001114

Product template (PT) domains from fungal nonreducing polyketide synthases (NR-PKSs) are responsible for controlling the aldol cyclizations of poly-β-ketone intermediates assembled during the catalytic cycle. Our ability to understand the high regioselective control that PT domains exert is hindered by the inaccessibility of intrinsically unstable poly-β-ketones for in vitro studies. We describe here the crystallographic application of “atom replacement” mimetics in which isoxazole rings linked by thioethers mimic the alternating sites of carbonyls in the poly-β-ketone intermediates. We report the 1.8-Å cocrystal structure of the PksA PT domain from aflatoxin biosynthesis with a heptaketide mimetic tethered to a stably modified 4′-phosphopantetheine, which provides important empirical evidence for a previously proposed mechanism of PT-catalyzed cyclization. Key observations support the proposed deprotonation at C4 of the nascent polyketide by the catalytic His1345 and the role of a protein-coordinated water network to selectively activate the C9 carbonyl for nucleophilic addition. The importance of the 4′-phosphate at the distal end of the pantetheine arm is demonstrated to both facilitate delivery of the heptaketide mimetic deep into the PT active site and anchor one end of this linear array to precisely meter C4 into close proximity to the catalytic His1345. Additional structural features, docking simulations, and mutational experiments characterize protein–substrate mimic interactions, which likely play roles in orienting and stabilizing interactions during the native multistep catalytic cycle. These findings afford a view of a polyketide “atom-replaced” mimetic in a NR-PKS active site that could prove general for other PKS domains.

A Challenging Pie to Splice: Drugging the Spliceosome

Co-reporter:Dr. Brian León;Dr. Manoj K. Kashyap;Warren C. Chan;Kelsey A. Krug; Januario E. Castro;Dr. James J. La Clair; Michael D. Burkart

Angewandte Chemie International Edition 2017 Volume 56(Issue 40) pp:12052-12063

Publication Date(Web):2017/09/25

DOI:10.1002/anie.201701065

AbstractSince its discovery in 1977, the study of alternative RNA splicing has revealed a plethora of mechanisms that had never before been documented in nature. Understanding these transitions and their outcome at the level of the cell and organism has become one of the great frontiers of modern chemical biology. Until 2007, this field remained in the hands of RNA biologists. However, the recent identification of natural product and synthetic modulators of RNA splicing has opened new access to this field, allowing for the first time a chemical-based interrogation of RNA splicing processes. Simultaneously, we have begun to understand the vital importance of splicing in disease, which offers a new platform for molecular discovery and therapy. As with many natural systems, gaining clear mechanistic detail at the molecular level is key towards understanding the operation of any biological machine. This minireview presents recent lessons learned in this emerging field of RNA splicing chemistry and chemical biology.

Das Spliceosom als Angriffspunkt für Pharmaka

Co-reporter:Dr. Brian León;Dr. Manoj K. Kashyap;Warren C. Chan;Kelsey A. Krug; Januario E. Castro;Dr. James J. La Clair; Michael D. Burkart

Angewandte Chemie 2017 Volume 129(Issue 40) pp:12218-12230

Publication Date(Web):2017/09/25

DOI:10.1002/ange.201701065

AbstractSeit seiner Entdeckung im Jahr 1977 hat die Untersuchung des alternativen RNA-Spleißens eine Vielzahl von Mechanismen zutage gefördert, die zuvor aus der Natur noch unbekannt waren. Die Erklärung dieser Umwandlungen und ihrer Resultate auf Ebene von Zellen und Organismen hat sich zu einer wichtigen Stoßrichtung der modernen chemischen Biologie entwickelt. Bis 2007 arbeiteten ausschließlich RNA-Biologen an diesem Thema. Durch die vor kurzem erfolgte Identifizierung von Naturstoffen und synthetischen Modulatoren des RNA-Spleißens sind aber auch chemische Untersuchungen des RNA-Spleißens möglich geworden. Gleichzeitig wurde die Bedeutung des Spleißens bei Erkrankungen erkannt, was eine neue Therapieplattform erschließt. Wie bei vielen natürlichen Systemen ist die Kenntnis mechanistischer Details auf molekularer Ebene der Schlüssel für das Verständnis der Funktion einer biologischen Maschine. Dieser Kurzaufsatz stellt aktuelle Erkenntnisse und Schlussfolgerungen zur Chemie und Biochemie des RNA-Spleißens vor.

Trapping of the Enoyl-Acyl Carrier Protein Reductase–Acyl Carrier Protein Interaction

Co-reporter:Lorillee Tallorin; Kara Finzel; Quynh G. Nguyen; Joris Beld; James J. La Clair

Journal of the American Chemical Society 2016 Volume 138(Issue 12) pp:3962-3965

Publication Date(Web):March 3, 2016

DOI:10.1021/jacs.5b13456

An ideal target for metabolic engineering, fatty acid biosynthesis remains poorly understood on a molecular level. These carrier protein-dependent pathways require fundamental protein–protein interactions to guide reactivity and processivity, and their control has become one of the major hurdles in successfully adapting these biological machines. Our laboratory has developed methods to prepare acyl carrier proteins (ACPs) loaded with substrate mimetics and cross-linkers to visualize and trap interactions with partner enzymes, and we continue to expand the tools for studying these pathways. We now describe application of the slow-onset, tight-binding inhibitor triclosan to explore the interactions between the type II fatty acid ACP from Escherichia coli, AcpP, and its corresponding enoyl-ACP reductase, FabI. We show that the AcpP–triclosan complex demonstrates nM binding, inhibits in vitro activity, and can be used to isolate FabI in complex proteomes.

A Carbohydrate-Derived Splice Modulator

Co-reporter:Sachin Dhar; James J. La Clair; Brian León; Justin C. Hammons; Zhe Yu; Manoj K. Kashyap; Januario E. Castro

Journal of the American Chemical Society 2016 Volume 138(Issue 15) pp:5063-5068

Publication Date(Web):April 8, 2016

DOI:10.1021/jacs.5b13427

Small-molecule splice modulators have recently been recognized for their clinical potential for diverse cancers. This, combined with their use as tools to study the importance of splice-regulated events and their association with disease, continues to fuel the discovery of new splice modulators. One of the key challenges found in the current class of materials arises from their instability, where rapid metabolic degradation can lead to off-target responses. We now describe the preparation of bench-stable splice modulators by adapting carbohydrate motifs as a central scaffold to provide rapid access to potent splice modulators.

Selectivity in Small Molecule Splicing Modulation

Co-reporter:Deepak Kumar, Manoj K. Kashyap, James J. La Clair, Reymundo Villa, Ide Spaanderman, Stephen Chien, Laura Z. Rassenti, Thomas J. Kipps, Michael D. Burkart, and Januario E. Castro

ACS Chemical Biology 2016 Volume 11(Issue 10) pp:2716

Publication Date(Web):August 8, 2016

DOI:10.1021/acschembio.6b00399

The dysregulation of RNA splicing is a molecular hallmark of disease, including different and often complex cancers. While gaining recognition as a target for therapeutic discovery, understanding the complex mechanisms guiding RNA splicing remains a challenge for chemical biology. The discovery of small molecule splicing modulators has recently enabled an evaluation of the mechanisms of aberrant splicing. We now report on three unique features within the selectivity of splicing modulators. First, we provide evidence that structural modifications within a splicing modulator can alter the splicing of introns in specific genes differently. These studies indicate that structure activity relationships not only have an effect on splicing activity but also include specificity for specific introns within different genes. Second, we find that these splicing modulators also target the mRNAs encoding components of the spliceosome itself. Remarkably, this effect includes the genes for the SF3B complex, a target of pladienolide B and related splicing modulators. Finally, we report on the first observation of a temporal phenomenon associated with small molecule splicing modulation. Combined, these three observations provide an important new perspective for the exploration of splicing modulation in terms of both future medicinal chemistry programs as well as understanding the key facets underlying its timing.

Probing fatty acid metabolism in bacteria, cyanobacteria, green microalgae and diatoms with natural and unnatural fatty acids

Co-reporter:Joris Beld, Raffaela Abbriano, Kara Finzel, Mark Hildebrand and Michael D. Burkart

Molecular BioSystems 2016 vol. 12(Issue 4) pp:1299-1312

Publication Date(Web):05 Feb 2016

DOI:10.1039/C5MB00804B

In both eukaryotes and prokaryotes, fatty acid synthases are responsible for the biosynthesis of fatty acids in an iterative process, extending the fatty acid by two carbon units every cycle. Thus, odd numbered fatty acids are rarely found in nature. We tested whether representatives of diverse microbial phyla have the ability to incorporate odd-chain fatty acids as substrates for their fatty acid synthases and their downstream enzymes. We fed various odd and short chain fatty acids to the bacterium Escherichia coli, cyanobacterium Synechocystis sp. PCC 6803, green microalga Chlamydomonas reinhardtii and diatom Thalassiosira pseudonana. Major differences were observed, specifically in the ability among species to incorporate and elongate short chain fatty acids. We demonstrate that E. coli, C. reinhardtii, and T. pseudonana can produce longer fatty acid products from short chain precursors (C3 and C5), while Synechocystis sp. PCC 6803 lacks this ability. However, Synechocystis can incorporate and elongate longer chain fatty acids due to acyl–acyl carrier protein synthetase (AasS) activity, and knockout of this protein eliminates the ability to incorporate these fatty acids. In addition, expression of a characterized AasS from Vibrio harveyii confers a similar capability to E. coli. The ability to desaturate exogenously added fatty acids was only observed in Synechocystis and C. reinhardtii. We further probed fatty acid metabolism of these organisms by feeding desaturase inhibitors to test the specificity of long-chain fatty acid desaturases. In particular, supplementation with thia fatty acids can alter fatty acid profiles based on the location of the sulfur in the chain. We show that coupling sensitive gas chromatography mass spectrometry to supplementation of unnatural fatty acids can reveal major differences between fatty acid metabolism in various organisms. Often unnatural fatty acids have antibacterial or even therapeutic properties. Feeding of short precursors now gives us easy access to these extended molecules.

An unusual intramolecular trans-amidation

Co-reporter:Heriberto Rivera Jr., Sachin Dhar, James J. La Clair, Shiou-Chuan Tsai, Michael D. Burkart

Tetrahedron 2016 Volume 72(Issue 25) pp:3605-3608

Publication Date(Web):23 June 2016

DOI:10.1016/j.tet.2016.01.062

Polyketide biosynthesis engages a series of well-timed biosynthetic operations to generate elaborate natural products from simple building blocks. Mimicry of these processes has offered practical means for total synthesis and provided a foundation for reaction discovery. We now report an unusual intramolecular trans-amidation reaction discovered while preparing stabilized probes for the study of actinorhodin biosynthesis. This rapid cyclization event offers insight into the natural cyclization process inherent to the biosynthesis of type II polyketide antibiotics.

Phosphopantetheinylation in the green microalgae Chlamydomonas reinhardtii

Co-reporter:Eva C. Sonnenschein;Yuan Pu;Joris Beld

Journal of Applied Phycology 2016 Volume 28( Issue 6) pp:3259-3267

Publication Date(Web):2016 December

DOI:10.1007/s10811-016-0875-7

Microalgal biofuel is a promising solution to the decline of fossil fuels. However, algal fatty acid metabolism, the machinery producing the raw material for biofuels, remains poorly understood. The central unit of the fatty acid synthase (FAS) is the acyl carrier protein (ACP), which is responsible for holding the product. Fatty acid biosynthesis is initiated through posttranslational modification of the ACP by the phosphopantetheinyl transferase (PPTase). We identified two PPTases, PptC1 and PptC2, in the model alga Chlamydomonas reinhardtii by genome analysis and phylogenetic and structural comparison. Both PPTases are of Sfp-type, the archetypical PPTase type for non-ribosomal peptide and polyketide biosynthetic pathways in bacteria and cyanobacteria. In vitro analysis revealed that PptC2 has a broader substrate range than PptC1. Both PPTases were able to activate the cognate ACP of the type II FAS, while PptC2 also recognized ACP of Escherichia coli type II FAS and actinorhodin type II polyketide synthase. Besides FAS as PPTase target, the C. reinhardtii genome encodes a single type I PKS, and we hypothesize that PptC2 is responsible for its activation. Screening of the currently available microalgal genome data revealed that most green microalgae appear to carry two PPTases forming clusters with each C. reinhardtii PPTase, while microalgae of other divisions carry one or two PPTases and do not cluster in the pattern of the green algal data. This new understanding on the PPTases in microalgae shows that microalgae are already primed for biotechnological applications in contrast to other organisms. Thus, microalgae have great potential for metabolic engineering efforts in the realm of biofuel and high-value products including direct engineering of the fatty acid or secondary metabolism using the natural genomic reservoir and as biotechnological platform for heterologous expression.

Probing the Substrate Specificity and Protein-Protein Interactions of the E. coli Fatty Acid Dehydratase, FabA

Co-reporter:Kara Finzel, Chi Nguyen, David R. Jackson, Aarushi Gupta, Shiou-Chuan Tsai, Michael D. Burkart

Chemistry & Biology 2015 Volume 22(Issue 11) pp:1453-1460

Publication Date(Web):19 November 2015

DOI:10.1016/j.chembiol.2015.09.009

•The application of mechanistic crosslinking to evaluate FabA specificity•Mutagenesis utilized to identify important residues for FabA substrate preference•First gain-of-function FabA mutant for shorter chain length fatty acidsMicrobial fatty acid biosynthetic enzymes are important targets for areas as diverse as antibiotic development to biofuel production. Elucidating the molecular basis of chain length control during fatty acid biosynthesis is crucial for the understanding of regulatory processes of this fundamental metabolic pathway. In Escherichia coli, the acyl carrier protein (AcpP) plays a central role by sequestering and shuttling the growing acyl chain between fatty acid biosynthetic enzymes. FabA, a β-hydroxyacyl-AcpP dehydratase, is an important enzyme in controlling fatty acid chain length and saturation levels. FabA-AcpP interactions are transient in nature and thus difficult to visualize. In this study, four mechanistic crosslinking probes mimicking varying acyl chain lengths were synthesized to systematically probe for modified chain length specificity of 14 FabA mutants. These studies provide evidence for the AcpP-interacting “positive patch,” FabA mutations that alter substrate specificity, and the roles that the FabA “gating residues” play in chain length control.Figure optionsDownload full-size imageDownload high-quality image (171 K)Download as PowerPoint slide

Fatty acid biosynthesis revisited: structure elucidation and metabolic engineering

Co-reporter:Joris Beld, D. John Lee and Michael D. Burkart

Molecular BioSystems 2015 vol. 11(Issue 1) pp:38-59

Publication Date(Web):20 Oct 2014

DOI:10.1039/C4MB00443D

Fatty acids are primary metabolites synthesized by complex, elegant, and essential biosynthetic machinery. Fatty acid synthases resemble an iterative assembly line, with an acyl carrier protein conveying the growing fatty acid to necessary enzymatic domains for modification. Each catalytic domain is a unique enzyme spanning a wide range of folds and structures. Although they harbor the same enzymatic activities, two different types of fatty acid synthase architectures are observed in nature. During recent years, strained petroleum supplies have driven interest in engineering organisms to either produce more fatty acids or specific high value products. Such efforts require a fundamental understanding of the enzymatic activities and regulation of fatty acid synthases. Despite more than one hundred years of research, we continue to learn new lessons about fatty acid synthases' many intricate structural and regulatory elements. In this review, we summarize each enzymatic domain and discuss efforts to engineer fatty acid synthases, providing some clues to important challenges and opportunities in the field.

Bulk solvent extraction of biomass slurries using a lipid trap

Co-reporter:Nathan G. Schoepp, Wilson Wong, Stephen P. Mayfield and Michael D. Burkart

RSC Advances 2015 vol. 5(Issue 70) pp:57038-57044

Publication Date(Web):23 Jun 2015

DOI:10.1039/C5RA11444F

Extraction of lipids and hydrophobic metabolites from microbial sources remains an obstacle in the production of these compounds at the laboratory and industrial scale. Analytical techniques for the total extraction of non-polar metabolites from biological material are well established, but rely on expensive and time consuming processes. This makes these techniques unsuitable for direct translation to continuous or large volume systems, unable to move beyond proof-of-concept studies, and leaves a major gap in the translation of new bio-products requiring a purified extract. Here we attempt to bridge that gap by demonstrating the use of a semi-continuous liquid–liquid extraction system capable of bulk lipid extraction from wet, untreated biomass, and simultaneous concentration of the unmodified extract in a lipid trap. A 1.8 L model was used to evaluate system dynamics with bacterial, fungal, algal, and plant feedstock, prior to scaling the system by an order of magnitude to demonstrate large-scale viability. Extraction efficiency was above 90% for each feedstock compared to standard Bligh and Dyer extraction. Following scale-up, extraction was performed on upwards of 4 kg of slurry (660 g dry weight), yielding an average efficiency of 96%, and allowing generation of a crude extract at a scale not previously possible in a laboratory setting. The resulting system allows for direct and high-throughput extraction of biomass sources without pretreatment, specialized instrumentation, or intensive user input.

Using Modern Tools To Probe the StructureFunction Relationship of Fatty Acid Synthases

Co-reporter:Kara Finzel;D. John Lee; Michael D. Burkart

ChemBioChem 2015 Volume 16( Issue 4) pp:528-547

Publication Date(Web):

DOI:10.1002/cbic.201402578

Abstract

Fatty acid biosynthesis is essential to life and represents one of the most conserved pathways in nature, preserving the same handful of chemical reactions across all species. Recent interest in the molecular details of the de novo fatty acid synthase (FAS) has been heightened by demand for renewable fuels and the emergence of multidrug-resistant bacterial strains. Central to FAS is the acyl carrier protein (ACP), a protein chaperone that shuttles the growing acyl chain between catalytic enzymes within the FAS. Human efforts to alter fatty acid biosynthesis for oil production, chemical feedstock, or antimicrobial purposes has been met with limited success, due in part to a lack of detailed molecular information behind the ACP–partner protein interactions inherent to the pathway. This review will focus on recently developed tools for the modification of ACP and analysis of protein–protein interactions, such as mechanism-based crosslinking, and the studies exploiting them. Discussion specific to each enzymatic domain will focus first on mechanism and known inhibitors, followed by available structures and known interactions with ACP. Although significant unknowns remain, new understandings of the intricacies of FAS point to future advances in manipulating this complex molecular factory.

Modeling Linear and Cyclic PKS Intermediates through Atom Replacement

Co-reporter:Gaurav Shakya ; Heriberto Rivera ; Jr.; D. John Lee ; Matt J. Jaremko ; James J. La Clair ; Daniel T. Fox ; Robert W. Haushalter ; Andrew J. Schaub ; Joel Bruegger ; Jesus F. Barajas ; Alexander R. White ; Parminder Kaur ; Emily R. Gwozdziowski ; Fiona Wong ; Shiou-Chuan Tsai

Journal of the American Chemical Society 2014 Volume 136(Issue 48) pp:16792-16799

Publication Date(Web):November 19, 2014

DOI:10.1021/ja5064857

The mechanistic details of many polyketide synthases (PKSs) remain elusive due to the instability of transient intermediates that are not accessible via conventional methods. Here we report an atom replacement strategy that enables the rapid preparation of polyketone surrogates by selective atom replacement, thereby providing key substrate mimetics for detailed mechanistic evaluations. Polyketone mimetics are positioned on the actinorhodin acyl carrier protein (actACP) to probe the underpinnings of substrate association upon nascent chain elongation and processivity. Protein NMR is used to visualize substrate interaction with the actACP, where a tetraketide substrate is shown not to bind within the protein, while heptaketide and octaketide substrates show strong association between helix II and IV. To examine the later cyclization stages, we extended this strategy to prepare stabilized cyclic intermediates and evaluate their binding by the actACP. Elongated monocyclic mimics show much longer residence time within actACP than shortened analogs. Taken together, these observations suggest ACP-substrate association occurs both before and after ketoreductase action upon the fully elongated polyketone, indicating a key role played by the ACP within PKS timing and processivity. These atom replacement mimetics offer new tools to study protein and substrate interactions and are applicable to a wide variety of PKSs.

The phosphopantetheinyl transferases: catalysis of a post-translational modification crucial for life

Co-reporter:Joris Beld, Eva C. Sonnenschein, Christopher R. Vickery, Joseph P. Noel and Michael D. Burkart

Natural Product Reports 2014 vol. 31(Issue 1) pp:61-108

Publication Date(Web):29 Nov 2013

DOI:10.1039/C3NP70054B

Covering: up to 2013 Although holo-acyl carrier protein synthase, AcpS, a phosphopantetheinyl transferase (PPTase), was characterized in the 1960s, it was not until the publication of the landmark paper by Lambalot et al. in 1996 that PPTases garnered wide-spread attention being classified as a distinct enzyme superfamily. In the past two decades an increasing number of papers have been published on PPTases ranging from identification, characterization, structure determination, mutagenesis, inhibition, and engineering in synthetic biology. In this review, we comprehensively discuss all current knowledge on this class of enzymes that post-translationally install a 4′-phosphopantetheine arm on various carrier proteins.

Chemoenzymatic exchange of phosphopantetheine on protein and peptide

Co-reporter:Nicolas M. Kosa, Kevin M. Pham and Michael D. Burkart

Chemical Science 2014 vol. 5(Issue 3) pp:1179-1186

Publication Date(Web):02 Jan 2014

DOI:10.1039/C3SC53154F

Evaluation of new acyl carrier protein hydrolase (AcpH, EC 3.1.4.14) homologs from proteobacteria and cyanobacteria reveals significant variation in substrate selectivity and kinetic parameters for phosphopantetheine hydrolysis from carrier proteins. Evaluation with carrier proteins from both primary and secondary metabolic pathways reveals an overall preference for acyl carrier protein (ACP) substrates from type II fatty acid synthases, as well as variable activity for polyketide synthase ACPs and peptidyl carrier proteins (PCP) from non-ribosomal peptide synthases. We also demonstrate the kinetic parameters of these homologs for AcpP and the 11-mer peptide substrate YbbR. These findings enable the fully reversible labeling of all three classes of natural product synthase carrier proteins as well as full and minimal fusion protein constructs.

Versatility of Acyl-Acyl Carrier Protein Synthetases

Co-reporter:Joris Beld, Kara Finzel, Michael D. Burkart

Chemistry & Biology 2014 Volume 21(Issue 10) pp:1293-1299

Publication Date(Web):23 October 2014

DOI:10.1016/j.chembiol.2014.08.015

•Efficient loading of various acids on acyl carrier protein (ACP) using AasS•Acylation of ACPs with AasS from different pathways and organisms•Uptake, acylation, and extension of unnatural acids in vivo, catalyzed by AasSThe acyl carrier protein (ACP) requires posttranslational modification with a 4′-phosphopantetheine arm for activity, and this thiol-terminated modification carries cargo between enzymes in ACP-dependent metabolic pathways. We show that acyl-ACP synthetases (AasSs) from different organisms are able to load even, odd, and unnatural fatty acids onto E. coli ACP in vitro. Vibrio harveyi AasS not only shows promiscuity for the acid substrate, but also is active upon various alternate carrier proteins. AasS activity also extends to functional activation in living organisms. We show that exogenously supplied carboxylic acids are loaded onto ACP and extended by the E. coli fatty acid synthase, including unnatural fatty acid analogs. These analogs are further integrated into cellular lipids. In vitro characterization of four different adenylate-forming enzymes allowed us to disambiguate CoA-ligases and AasSs, and further in vivo studies show the potential for functional application in other organisms.Figure optionsDownload full-size imageDownload high-quality image (430 K)Download as PowerPoint slide

Structure, Biochemistry, and Inhibition of Essential 4′-Phosphopantetheinyl Transferases from Two Species of Mycobacteria

Co-reporter:Christopher R. Vickery, Nicolas M. Kosa, Ellen P. Casavant, Shiteng Duan, Joseph P. Noel, and Michael D. Burkart

ACS Chemical Biology 2014 Volume 9(Issue 9) pp:1939

Publication Date(Web):June 25, 2014

DOI:10.1021/cb500263p

4′-Phosphopantetheinyl transferases (PPTase) post-translationally modify carrier proteins with a phosphopantetheine moiety, an essential reaction in all three domains of life. In the bacterial genus Mycobacteria, the Sfp-type PPTase activates pathways necessary for the biosynthesis of cell wall components and small molecule virulence factors. We solved the X-ray crystal structures and biochemically characterized the Sfp-type PPTases from two of the most prevalent Mycobacterial pathogens, PptT of M. tuberculosis and MuPPT of M. ulcerans. Structural analyses reveal significant differences in cofactor binding and active site composition when compared to previously characterized Sfp-type PPTases. Functional analyses including the efficacy of Sfp-type PPTase-specific inhibitors also suggest that the Mycobacterial Sfp-type PPTases can serve as therapeutic targets against Mycobacterial infections.

Resin supported acyl carrier protein labeling strategies

Co-reporter:Michael Rothmann, Nicolas M. Kosa and Michael D. Burkart

RSC Advances 2014 vol. 4(Issue 18) pp:9092-9097

Publication Date(Web):17 Jan 2014

DOI:10.1039/C3RA47847E

The post-translational modifying enzymes phophopantetheinyl transferase and acyl carrier protein hydrolase show utility in the functional modification of acyl carrier proteins. Here we develop these tools as immobilized biocatalysts on agarose supports. New utility is imparted through these methods, enabling rapid and label-independent protein purification. Immobilization of acyl carrier protein is also demonstrated for rapid activity assays of these 4′-phosophopantetheine modifying enzymes, displaying a particular advantage in the case of phosphopantetheine removal, where few orthogonal techniques have been demonstrated. These tools further enrich the suite of functional utility of 4′-phosophopantetheine chemistry, with applications to protein functionalization, materials, and natural product biosynthetic studies.

Evolution of acyl-ACP thioesterases and β-ketoacyl-ACP synthases revealed by protein–protein interactions

Co-reporter:Joris Beld;Jillian L. Blatti;Craig Behnke;Michael Mendez

Journal of Applied Phycology 2014 Volume 26( Issue 4) pp:1619-1629

Publication Date(Web):2014 August

DOI:10.1007/s10811-013-0203-4

The fatty acid synthase (FAS) is a conserved primary metabolic enzyme complex capable of tolerating cross-species engineering of domains for the development of modified and overproduced fatty acids. In eukaryotes, acyl-acyl carrier protein thioesterases (TEs) off-load mature cargo from the acyl carrier protein (ACP), and plants have developed TEs for short/medium-chain fatty acids. We showed that engineering plant TEs into the green microalga Chlamydomonas reinhardtii does not result in the predicted shift in fatty acid profile. Since fatty acid biosynthesis relies on substrate recognition and protein–protein interactions between the ACP and its partner enzymes, we hypothesized that plant TEs and algal ACP do not functionally interact. Phylogenetic analysis revealed major evolutionary differences between FAS enzymes, including TEs and ketoacyl synthases (KSs), in which the former is present only in some species, whereas the latter is present in all, and has a common ancestor. In line with these results, TEs appeared to be selective towards their ACP partners, whereas KSs showed promiscuous behavior across bacterial, plant, and algal species. Based on phylogenetic analyses, in silico docking, in vitro mechanistic cross-linking, and in vivo algal engineering, we propose that phylogeny can predict effective interactions between ACPs and partner enzymes.

Fluorescent techniques for discovery and characterization of phosphopantetheinyl transferase inhibitors

Co-reporter:Nicolas M Kosa, Timothy L Foley and Michael D Burkart

The Journal of Antibiotics 2014 67(1) pp:113-120

Publication Date(Web):November 6, 2013

DOI:10.1038/ja.2013.106

Phosphopantetheinyl transferase (PPTase; E.C. 2.7.8.-) activates biosynthetic pathways that synthesize both primary and secondary metabolites in bacteria. Inhibitors of these enzymes have the potential to serve as antibiotic compounds that function through a unique mode of action and possess clinical utility. Here we report a direct and continuous assay for this enzyme class based upon monitoring polarization of a fluorescent phosphopantetheine analog as it is transferred from a low-molecular weight CoA substrate to higher-molecular weight protein acceptor. We demonstrate the utility of this method for the biochemical characterization of PPTase Sfp, a canonical representative from this class. We also establish the portability of this technique to other homologs by adapting the assay to function with the human PPTase, a target for which a microplate detection method does not currently exist. Comparison of these targets provides a basis to predict the therapeutic index of inhibitor candidates and offers a valuable characterization of enzyme activity.

Visualizing the Chain-Flipping Mechanism in Fatty-Acid Biosynthesis

Co-reporter:Dr. Joris Beld;Dr. Hu Cang;Dr. Michael D. Burkart

Angewandte Chemie International Edition 2014 Volume 53( Issue 52) pp:14456-14461

Publication Date(Web):

DOI:10.1002/anie.201408576

Abstract

The acyl carrier protein (ACP) from fatty acid synthases sequesters elongating products within its hydrophobic core, but this dynamic mechanism remains poorly understood. We exploited solvatochromic pantetheine probes attached to ACP that fluoresce when sequestered. The addition of a catalytic partner lures the cargo out of the ACP and into the active site of the enzyme, thus enhancing fluorescence to reveal the elusive chain-flipping mechanism. This activity was confirmed by the use of a dual solvatochromic cross-linking probe and solution-phase NMR spectroscopy. The chain-flipping mechanism was visualized by single-molecule fluorescence techniques, thus demonstrating specificity between the Escherichia coli ACP and its ketoacyl synthase catalytic partner KASII.

Visualizing the Chain-Flipping Mechanism in Fatty-Acid Biosynthesis

Co-reporter:Dr. Joris Beld;Dr. Hu Cang;Dr. Michael D. Burkart

Angewandte Chemie 2014 Volume 126( Issue 52) pp:14684-14689

Publication Date(Web):

DOI:10.1002/ange.201408576

Abstract

Sulfonyl 3-Alkynyl Pantetheinamides as Mechanism-Based Cross-Linkers of Acyl Carrier Protein Dehydratase

Co-reporter:Fumihiro Ishikawa ; Robert W. Haushalter ; D. John Lee ; Kara Finzel

Journal of the American Chemical Society 2013 Volume 135(Issue 24) pp:8846-8849

Publication Date(Web):May 29, 2013

DOI:10.1021/ja4042059

Acyl carrier proteins (ACPs) play a central role in acetate biosynthetic pathways, serving as tethers for substrates and growing intermediates. Activity and structural studies have highlighted the complexities of this role, and the protein–protein interactions of ACPs have recently come under scrutiny as a regulator of catalysis. As existing methods to interrogate these interactions have fallen short, we have sought to develop new tools to aid their study. Here we describe the design, synthesis, and application of pantetheinamides that can cross-link ACPs with catalytic β-hydroxy-ACP dehydratase (DH) domains by means of a 3-alkynyl sulfone warhead. We demonstrate this process by application to the Escherichia coli fatty acid synthase and apply it to probe protein–protein interactions with noncognate carrier proteins. Finally, we use solution-phase protein NMR spectroscopy to demonstrate that sulfonyl 3-alkynyl pantetheinamide is fully sequestered by the ACP, indicating that the crypto-ACP closely mimics the natural DH substrate. This cross-linking technology offers immediate potential to lock these biosynthetic enzymes in their native binding states by providing access to mechanistically cross-linked enzyme complexes, presenting a solution to ongoing structural challenges.

Metabolic Perturbation of an Essential Pathway: Evaluation of a Glycine Precursor of Coenzyme A

Co-reporter:Michael Rothmann ; MinJin Kang ; Reymundo Villa ; Ioanna Ntai ; James J. La Clair ; Neil L. Kelleher ; Eli Chapman

Journal of the American Chemical Society 2013 Volume 135(Issue 16) pp:5962-5965

Publication Date(Web):April 3, 2013

DOI:10.1021/ja400795m

Pantetheine and its corresponding disulfide pantethine play a key role in metabolism as building blocks of coenzyme A (CoA), an essential cofactor utilized in ∼4% of primary metabolism and central to fatty acid, polyketide, and nonribosomal peptide synthases. Using a combination of recombinant engineering and chemical synthesis, we show that the disulfide of N-pantoylglycyl-2-aminoethanethiol (GlyPan), with one fewer carbon than pantetheine, can rescue a mutant E. coli strain MG1655ΔpanC lacking a functional pantothenate synthetase. Using mass spectrometry, we show that the GlyPan variant is accepted by the downstream CoA biosynthetic machinery, ultimately being incorporated into essential acyl carrier proteins. These findings point to further flexibility in CoA-dependent pathways and offer the opportunity to incorporate orthogonal analogues.

Stabilized Cyclopropane Analogs of the Splicing Inhibitor FD-895

Co-reporter:Reymundo Villa ; Manoj Kumar Kashyap ; Deepak Kumar ; Thomas J. Kipps ; Januario E. Castro ; James J. La Clair

Journal of Medicinal Chemistry 2013 Volume 56(Issue 17) pp:6576-6582

Publication Date(Web):August 6, 2013

DOI:10.1021/jm400861t

Targeting the spliceosome with small molecule inhibitors provides a new avenue to target cancer by intercepting alternate splicing pathways. Although our understanding of alternate mRNA splicing remains poorly understood, it provides an escape pathway for many cancers resistant to current therapeutics. These findings have encouraged recent academic and industrial efforts to develop natural product spliceosome inhibitors, including FD-895 (1a), pladienolide B (1b), and pladienolide D (1c), into next-generation anticancer drugs. The present study describes the application of semisynthesis and total synthesis to reveal key structure–activity relationships for the spliceosome inhibition by 1a. This information is applied to deliver new analogs with improved stability and potent activity at inhibiting splicing in patient derived cell lines.

Probing the Selectivity and Protein⋅Protein Interactions of a Nonreducing Fungal Polyketide Synthase Using Mechanism-Based Crosslinkers

Co-reporter:Joel Bruegger, Bob Haushalter, Anna Vagstad, Gaurav Shakya, Nathan Mih, Craig A. Townsend, Michael D. Burkart, Shiou-Chuan Tsai

Chemistry & Biology 2013 Volume 20(Issue 9) pp:1135-1146

Publication Date(Web):19 September 2013

DOI:10.1016/j.chembiol.2013.07.012

•An activity-based crosslinker successfully detects PKS interdomain interactions•The crosslinking efficiency is correlated with starter unit specificity of KSs•The ACPs and KSs from NR-PKSs are interchangeable for crosslinking•Mutations identify KS surface residues important for ACP⋅KS interactionsProtein⋅protein interactions, which often involve interactions among an acyl carrier protein (ACP) and ACP partner enzymes, are important for coordinating polyketide biosynthesis. However, the nature of such interactions is not well understood, especially in the fungal nonreducing polyketide synthases (NR-PKSs) that biosynthesize toxic and pharmaceutically important polyketides. Here, we employ mechanism-based crosslinkers to successfully probe ACP and ketosynthase (KS) domain interactions in NR-PKSs. We found that crosslinking efficiency is closely correlated with the strength of ACP⋅KS interactions and that KS demonstrates strong starter unit selectivity. We further identified positively charged surface residues by KS mutagenesis, which mediates key interactions with the negatively charged ACP surface. Such complementary/matching contact pairs can serve as “adapter surfaces” for future efforts to generate new polyketides using NR-PKSs.Figure optionsDownload full-size imageDownload high-quality image (245 K)Download as PowerPoint slide

Spirohexenolide A Targets Human Macrophage Migration Inhibitory Factor (hMIF)

Co-reporter:Wei-Lun Yu ; Brian D. Jones ; MinJin Kang ; Justin C. Hammons ; James J. La Clair

Journal of Natural Products 2013 Volume 76(Issue 5) pp:817-823

Publication Date(Web):May 9, 2013

DOI:10.1021/np3004497

Spirohexenolides A and B comprise a unique family of spirotetronate natural products. We report on the identification of their binding to and modulation of human macrophage migration inhibitor factor (hMIF). Using an immunoaffinity–fluorescent labeling method, the properties of this interaction are detailed and evidence is provided that hMIF plays a key role in the cytostatic activity of the spirohexenolides.

A Tandem Chemoenzymatic Methylation by S-Adenosyl-L-methionine

Co-reporter:Joseph M. Lipson;Marie Thomsen; Bradley S. Moore;Dr. Rasmus P. Clausen;Dr. James J. La Clair; Michael D. Burkart

ChemBioChem 2013 Volume 14( Issue 8) pp:

Publication Date(Web):

DOI:10.1002/cbic.201300221

Structure of FD-895 Revealed through Total Synthesis

Co-reporter:Reymundo Villa, Alexander L. Mandel, Brian D. Jones, James J. La Clair, and Michael D. Burkart

Organic Letters 2012 Volume 14(Issue 21) pp:5396-5399

Publication Date(Web):October 16, 2012

DOI:10.1021/ol3023006

The total synthesis of FD-895 was completed through a strategy that featured the use of a tandem esterification ring-closing metathesis (RCM) process to construct the 12-membered macrolide and a modified Stille coupling to append the side chain. These studies combined with detailed analysis of all four possible C16–C17 stereoisomers were used to confirm the structure of FD-895 and identify an analog with an enhanced subnanomolar bioactivity.

The Antibiotic CJ-15,801 Is an Antimetabolite that Hijacks and Then Inhibits CoA Biosynthesis

Co-reporter:Renier van der Westhuyzen, Justin C. Hammons, Jordan L. Meier, Samira Dahesh, Wessel J.A. Moolman, Stephen C. Pelly, Victor Nizet, Michael D. Burkart, Erick Strauss

Chemistry & Biology 2012 Volume 19(Issue 5) pp:559-571

Publication Date(Web):25 May 2012

DOI:10.1016/j.chembiol.2012.03.013

The natural product CJ-15,801 is an inhibitor of Staphylococcus aureus, but not other bacteria. Its close structural resemblance to pantothenic acid, the vitamin precursor of coenzyme A (CoA), and its Michael acceptor moiety suggest that it irreversibly inhibits an enzyme involved in CoA biosynthesis or utilization. However, its mode of action and the basis for its specificity have not been elucidated to date. We demonstrate that CJ-15,801 is transformed by the uniquely selective S. aureus pantothenate kinase, the first CoA biosynthetic enzyme, into a substrate for the next enzyme, phosphopantothenoylcysteine synthetase, which is inhibited through formation of a tight-binding structural mimic of its native reaction intermediate. These findings reveal CJ-15,801 as a vitamin biosynthetic pathway antimetabolite with a mechanism similar to that of the sulfonamide antibiotics and highlight CoA biosynthesis as a viable antimicrobial drug target.Graphical AbstractFigure optionsDownload full-size imageDownload high-quality image (373 K)Download as PowerPoint slideHighlights► CJ-15,801 is a natural product inhibitor of coenzyme A (CoA) biosynthesis ► Its unique selectivity is due to the gatekeeping action of pantothenate kinase ► The first two CoA biosynthetic enzymes convert it into a tight-binding inhibitor ► Pantothenamides (precursors of known CoA antimetabolites) increase its potency

Resin-based investigation of acyl carrier protein interaction networks in Escherichia coli

Co-reporter:Michael Rothmann, Sherry Niessen, Robert W. Haushalter, Benjamin F. Cravatt, Michael D. Burkart

Bioorganic & Medicinal Chemistry 2012 Volume 20(Issue 2) pp:667-671

Publication Date(Web):15 January 2012

DOI:10.1016/j.bmc.2011.10.053

Protein–protein interactions play an integral role in metabolic regulation. Elucidation of these networks is complicated by the changing identity of the proteins themselves. Here we demonstrate a resin-based technique that leverages the unique tools for acyl carrier protein (ACP) modification with non-hydrolyzable linkages. ACPs from Escherichia coli and Shewanella oneidensis MR-1 are bound to Affigel-15 with varying acyl groups attached and introduced to proteomic samples. Isolation of these binding partners is followed by MudPIT analysis to identify each interactome with the variable of ACP-tethered substrates. These techniques allow for investigation of protein interaction networks with the changing identity of a given protein target.

Dehydratase-Specific Probes for Fatty Acid and Polyketide Synthases

Co-reporter:Fumihiro Ishikawa ; Robert W. Haushalter

Journal of the American Chemical Society 2011 Volume 134(Issue 2) pp:769-772

Publication Date(Web):December 21, 2011

DOI:10.1021/ja2082334

We targeted the development of a dehydratase (DH)-specific reactive probe that can facilitate detection, enrichment, and identification of DH enzymes in fatty acid synthases (FASs) and polyketide synthases (PKSs). The first reported mechanism-based inactivator, 3-decynoyl-N-acetylcysteamine (3-decynoyl-NAC), while active against the Escherichia coli β-hydroxydecanoyl thiol ester DH FabA, translates poorly to an activity-based probe because of nonspecific reactivity of the thioester moiety. Here we describe the design, synthesis, and utility of a DH-specific probe that contains a sulfonyl 3-alkyne reactive warhead engineered to avoid hydrolysis or nonenzymatic inactivation. When coupled with a fluorescent tag, this probe targets DH enzymes from recombinant type I and type II FAS and PKS enzyme systems and in whole proteomes. Activity studies, including FabA inactivation and antibiotic susceptibility, suggest that this sulfonyl 3-alkyne scaffold selectively targets a common DH mechanism. These studies indicate that the DH-specific mechanism-based probe can greatly accelerate both the functional characterization and molecular identification of virtually any type of FAS and PKS in complex proteomes.

Binding and pKa Modulation of a Polycyclic Substrate Analogue in a Type II Polyketide Acyl Carrier Protein

Co-reporter:Robert W. Haushalter, Fabian V. Filipp, Kwang-seuk Ko, Ricky Yu, Stanley J. Opella, and Michael D. Burkart

ACS Chemical Biology 2011 Volume 6(Issue 5) pp:413

Publication Date(Web):January 26, 2011

DOI:10.1021/cb200004k

Type II polyketide synthases are biosynthetic enzymatic pathways responsible for the production of complex aromatic natural products with important biological activities. In these systems, biosynthetic intermediates are covalently bound to a small acyl carrier protein that associates with the synthase enzymes and delivers the bound intermediate to each active site. In the closely related fatty acid synthases of bacteria and plants, the acyl carrier protein acts to sequester and protect attached intermediates within its helices. Here we investigate the type II polyketide synthase acyl carrier protein from the actinorhodin biosynthetic pathway and demonstrate its ability to internalize the tricyclic, polar molecule emodic acid. Elucidating the interaction of acyl carrier proteins with bound analogues resembling late-stage intermediates in the actinorhodin pathway could prove valuable in efforts to engineer these systems toward rational design and biosynthesis of novel compounds.

Activity-guided engineering of natural product carrier proteins

Co-reporter:Andrew S. Worthington, Gene H. Hur and Michael D. Burkart

Molecular BioSystems 2011 vol. 7(Issue 2) pp:365-370

Publication Date(Web):24 Dec 2010

DOI:10.1039/C0MB00251H

A panel of chimeric carrier proteins was developed and screened for functional activity with essential enzymes involved in carrier protein-mediated biosynthesis. Regions on either side of the recognition helix II within three carrier proteins (CPs) from distinct biosynthetic pathways were swapped in all combinations to generate 24 mutated CPs. This panel of chimeric carrier proteins was tested using two previously established and one novel carrier protein assays. The results suggest a significant contribution from multiple structural units within carrier protein structure, rather than universal recognition helix, is necessary for proper recognition and activity with partner enzymes.

Convergent Route to the Spirohexenolide Macrocycle

Co-reporter:Brian D. Jones, James J. La Clair, Curtis E. Moore, Arnold L. Rheingold, and Michael D. Burkart

Organic Letters 2010 Volume 12(Issue 20) pp:4516-4519

Publication Date(Web):September 17, 2010

DOI:10.1021/ol1018163

Using key functional dissections, the synthesis of spirohexenolides is examined through a three-component strategy that features a 1,2-addition to couple tetronate and aldehyde components forming the C2−C3 bond and a Stille coupling to install the third sulfone-containing component. The macrocycle is completed by an intramolecular Julia−Kocienski reaction to form the C10−C11 trans-disubstituted olefin. Application of this strategy is described in progress toward the synthesis of (±)-spirohexenolide B.

Metabolic probes for imaging endosymbiotic bacteria within toxic dinoflagellates

Co-reporter:Carolina P. Reyes, James J. La Clair and Michael D. Burkart

Chemical Communications 2010 vol. 46(Issue 43) pp:8151-8153

Publication Date(Web):06 Oct 2010

DOI:10.1039/C0CC02876B

Fluorescence microscopy offers an important tool for the study of complex biological phenomena such as symbiosis. Here we identify a strategy that adapts the unique differences between the secondary metabolism in host and guest symbiotic species to selectively image endosymbiotic organisms. The method is demonstrated by application to the complex symbiotic relationships in toxic marine dinoflagellates.

Synthetic studies on the mycolactone core

Co-reporter:Kwang-Seuk Ko, Matthew D. Alexander, Shaun D. Fontaine, James E. Biggs-Houck, James J. La Clair and Michael D. Burkart

Organic & Biomolecular Chemistry 2010 vol. 8(Issue 22) pp:5159-5165

Publication Date(Web):19 Aug 2010

DOI:10.1039/C0OB00540A

Two approaches are presented for the synthesis of the macrolide core of the mycolactone polyketides. The first intertwines ring closing metathesis (RCM) within a two-step Julia olefination protocol, while the second intercepts the optimized routes of Kishi, thereby providing formal access to the mycolactones.

Preparation of FRET reporters to support chemical probe development

Co-reporter:Timothy L. Foley, Adam Yasgar, Christopher J. Garcia, Ajit Jadhav, Anton Simeonov and Michael D. Burkart

Organic & Biomolecular Chemistry 2010 vol. 8(Issue 20) pp:4601-4606

Publication Date(Web):20 Aug 2010

DOI:10.1039/C0OB00322K

In high throughput screening (HTS) campaigns, the quality and cost of commercial reagents suitable for pilot studies often create obstacles upon scale-up to a full screen. We faced such challenges in our efforts to implement an HTS for inhibitors of the phosphopantetheinyl transferase Sfp using an assay that had been validated using commercially available reagents. Here we demonstrate a facile route to the synthetic preparation of reactive tetraethylrhodamine and quencher probes, and their application to economically produce fluorescent and quencher-modified substrates. These probes were prepared on a scale that would allow a full, quantitative HTS of more than 350,000 compounds.

Mechanism-based crosslinking as a gauge for functional interaction of modular synthases

Co-reporter:Andrew S. Worthington, Douglas F. Porter and Michael D. Burkart

Organic & Biomolecular Chemistry 2010 vol. 8(Issue 8) pp:1769-1772

Publication Date(Web):17 Feb 2010

DOI:10.1039/B925966J

Protein-protein interactions between domains within fatty acid and polyketide synthases are critical to catalysis, but their contributions remain incompletely characterized. A practical, quantitative system for establishing functional interactions between modifying enzymes and the acyl carrier protein that tethers the nascent polymer would offer a valuable tool for understanding and engineering these enzyme systems. Mechanism-based crosslinking of modular domains offers a potential diagnostic to highlight selective interactions between modular pairs. Here kinetic activity analysis and isothermal titration calorimetry are shown to correlate the efficiency of a ketosynthase-carrier protein crosslinking method to the binding affinity and transacylase activity that occurs in ketosynthase chain elongation.

A mechanism based protein crosslinker for acyl carrier protein dehydratases

Co-reporter:Jordan L. Meier, Robert W. Haushalter, Michael D. Burkart

Bioorganic & Medicinal Chemistry Letters 2010 Volume 20(Issue 16) pp:4936-4939

Publication Date(Web):15 August 2010

DOI:10.1016/j.bmcl.2010.06.028

Recent advances in the structural study of fatty acid synthase (FAS) and polyketide synthase (PKS) biosynthetic enzymes have illuminated our understanding of modular enzymes of the acetate pathway. However, one significant and persistent challenge in such analyses is resolution of the acyl carrier protein (ACP), a small (∼9 kDa) protein to which biosynthetic intermediates are tethered throughout the biosynthetic cycle. Here we report a chemoenzymatic crosslinking strategy in which the installation of a historical suicide substrate scaffold upon the 4′-phosphopantetheine (PPant) arm of the ACP is used to capture the active site of acyl carrier protein dehydratase (DH) domains in FAS. Through the synthesis of a small panel of related probes we identify structural features essential for ACP–DH crosslinking, and apply gel-based assays to demonstrate the stability as well as purification strategies for isolation of the chemoenzymatically modified ACP. Applying these carrier protein crosslinking techniques to the structural analysis of FAS and PKS complexes has the potential to provide snapshots of these biosynthetic assembly lines at work.A chemoenzymatic method for the crosslinking of protein partners of the fatty acid biosynthetic pathway is detailed.

The chemical biology of modular biosynthetic enzymes

Co-reporter:Jordan L. Meier and Michael D. Burkart

Chemical Society Reviews 2009 vol. 38(Issue 7) pp:2012-2045

Publication Date(Web):27 Mar 2009

DOI:10.1039/B805115C

Fatty acid synthase (FAS), polyketide synthase (PKS), and nonribosomal peptide synthetase (NRPS) modular biosynthetic enzymes are responsible for the production of a multitude of structurally diverse and biologically important small molecule natural products. Traditional biochemical and genetic studies of these enzymes have contributed substantially to the understanding of their underlying biosynthetic mechanisms. More recently these investigations have been aided by the skillful application of a combination of chemical and biological techniques to aid in overcoming the unique challenges associated with the enzymology of these large multifunctional enzymes. This critical review provides a historical context and details studies (through July 2008) which aim to identify and characterize these enzymes using synthetically and/or chemoenzymatically generated small molecule probes (233 references).

Crosslinking Studies of Protein-Protein Interactions in Nonribosomal Peptide Biosynthesis

Co-reporter:Gene H. Hur, Jordan L. Meier, Jeremy Baskin, Julian A. Codelli, Carolyn R. Bertozzi, Mohamed A. Marahiel, Michael D. Burkart

Chemistry & Biology 2009 Volume 16(Issue 4) pp:372-381

Publication Date(Web):24 April 2009

DOI:10.1016/j.chembiol.2009.02.009

Selective protein-protein interactions between nonribosomal peptide synthetase (NRPS) proteins, governed by communication-mediating (COM) domains, are responsible for proper translocation of biosynthetic intermediates to produce the natural product. In this study, we developed a crosslinking assay, utilizing bioorthogonal probes compatible with carrier protein modification, for probing the protein interactions between COM domains of NRPS enzymes. Employing the Huisgen 1,3-dipolar cycloaddition of azides and alkynes, we examined crosslinking of cognate NRPS modules within the tyrocidine pathway and demonstrated the sensitivity of our panel of crosslinking probes toward the selective protein interactions of compatible COM domains. These studies indicate that copper-free crosslinking substrates uniquely offer a diagnostic probe for protein-protein interactions. Likewise, these crosslinking probes serve as ideal chemical tools for structural studies between NRPS modules where functional assays are lacking.

An Orthogonal Active Site Identification System (OASIS) for Proteomic Profiling of Natural Product Biosynthesis

Co-reporter:Jordan L. Meier, Sherry Niessen, Heather S. Hoover, Timothy L. Foley, Benjamin F. Cravatt and Michael D. Burkart

ACS Chemical Biology 2009 Volume 4(Issue 11) pp:948

Publication Date(Web):September 29, 2009

DOI:10.1021/cb9002128

A significant gap exists between genetics-based investigations of polyketide synthase (PKS) and nonribosomal peptide synthetase (NRPS) biosynthetic pathways and our understanding of their regulation, interaction, and activity in living systems. To help bridge this gap, here we present an orthogonal active site identification system (OASIS) for the proteomic identification and analysis of PKS/NRPS biosynthetic enzymes. OASIS probes target conserved features of PKS/NRPS active sites to provide activity-based enrichment of modular synthases, followed by analysis through multidimensional protein identification technology (MudPIT) LC-MS/MS analysis. When applied to the model bacterium Bacillus subtilis, this functional proteomics method detects and quantifies all four modular synthases in the organism. Furthermore, tandem application of multiple OASIS probes enhances identification of specific PKS/NRPS modules from complex proteomic mixtures. By expanding the dynamic range of proteomic analysis for PKS/NRPS enzymes, OASIS offers a valuable tool for strain comparison, culture condition optimization, and enzyme discovery.

A homogeneous resonance energy transfer assay for phosphopantetheinyl transferase

Co-reporter:Timothy L. Foley, Michael D. Burkart

Analytical Biochemistry 2009 Volume 394(Issue 1) pp:39-47

Publication Date(Web):1 November 2009

DOI:10.1016/j.ab.2009.06.037

Phosphopantetheinyl transferase plays an essential role in activating fatty acid, polyketide, and nonribosomal peptide biosynthetic pathways, catalyzing covalent attachment of a 4′-phosphopantetheinyl group to a conserved residue within carrier protein domains. This enzyme has been validated as an essential gene to primary metabolism and presents a target for the identification of antibiotics with a new mode of action. Here we report the development of a homogeneous resonance energy transfer assay using fluorescent coenzyme A derivatives and a surrogate peptide substrate that can serve to identify inhibitors of this enzyme class. This assay lays a blueprint for translation of these techniques to other transferase enzymes that accept fluorescent substrate analogues.

In Vivo Modification of Native Carrier Protein Domains

Co-reporter:Andrew C. Mercer Dr.;Jordan L. Meier;Justin W. Torpey Dr.

ChemBioChem 2009 Volume 10( Issue 6) pp:1091-1100

Publication Date(Web):

DOI:10.1002/cbic.200800838

The unusual macrocycle forming thioesterase of mycolactone

Co-reporter:Jordan L. Meier, Tiffany Barrows-Yano, Timothy L. Foley, Candice L. Wike and Michael D. Burkart

Molecular BioSystems 2008 vol. 4(Issue 6) pp:663-671

Publication Date(Web):16 Apr 2008

DOI:10.1039/B801397G

Mycolactone is a polyketide natural product secreted by Mycobacterium ulcerans, the organism responsible for the tropical skin disease Buruli ulcer. The finding that this small molecule virulence factor is sufficient to reconstitute the necrotic pathology associated with Buruli ulcer suggests that a better understanding of mycolactone biosynthesis, particularly the processes which are distinct from those in human metabolism, may provide a unique avenue for the development of selective therapeutics. In the present study we have cloned, expressed, and biochemically characterized the putative macrocycle forming thioesterase for mycolactone, MLSA2 TE. We have evaluated the enzyme both as the truncated thioesterase domain and as a carrier protein-linked didomain construct. The results of these analyses distinguish MLSA2 TE from traditional fatty acid and polyketide synthase TE-domains in terms of its sequence, kinetic parameters, and susceptibility to traditional active-site directed inhibitors. These findings suggest that MLSA2 TE utilizes a unique biochemical mechanism for macrocycle formation.

Affinity Analyses on Moldable Optical Polycarbonate

Co-reporter:Kwang-Seuk Ko Dr.;Peyman Najmabadi Dr.;James J. La Clair Dr. Dr.

ChemBioChem 2008 Volume 9( Issue 2) pp:201-205

Publication Date(Web):

DOI:10.1002/cbic.200700468

Probing the Compatibility of Type II KetosynthaseCarrier Protein Partners

Co-reporter:Andrew S. Worthington;Gene H. Hur;Jordan L. Meier;Qian Cheng Dr.;Bradley S. Moore

ChemBioChem 2008 Volume 9( Issue 13) pp:2096-2103

Publication Date(Web):

DOI:10.1002/cbic.200800198

Abstract

Drug discovery often begins with the screening of large compound libraries to identify lead compounds. Recently, the enzymes that are involved in the biosynthesis of natural products have been investigated for their potential to generate new, diverse compound libraries. There have been several approaches toward this end, including altering the substrate specificities of the enzymes involved in natural product biosynthesis and engineering functional communication between enzymes from different biosynthetic pathways. While there exist assays to assess the substrate specificity of enzymes involved in these pathways, there is no simple method for determining whether enzymes from different synthases will function cooperatively to generate the desired product(s). Herein we report a method that provides insight into both substrate specificity and compatibility of protein–protein interactions between the acyl carrier protein (ACP) and ketosynthase (KS) domains involved in fatty acid and polyketide biosynthesis. Our technique uses a one-pot chemoenzymatic method to generate post-translationally modified ACPs that are capable of covalently interacting with KS domains from different biosynthetic systems. The extent of interaction between ACPs and KSs from different systems is easily detected and quantified by a gel-based method. Our results are consistent with previous studies of substrate specificity and ACP–KS binding interactions and provide new insight into unnatural substrate and protein interactions.

The ubiquitous carrier protein—a window to metabolitebiosynthesis

Co-reporter:Andrew C. Mercer and Michael D. Burkart

Natural Product Reports 2007 vol. 24(Issue 4) pp:750-773

Publication Date(Web):03 Apr 2007

DOI:10.1039/B603921A

Covering: 1970 to 2006

The Old Is New Again: Asparagine Oxidation in Calcium-Dependent Antibiotic Biosynthesis

Co-reporter:Andrew S. Worthington and Michael D. Burkart

ACS Chemical Biology 2007 Volume 2(Issue 3) pp:152

Publication Date(Web):March 16, 2007

DOI:10.1021/cb700053g

Non-ribosomal peptides are built from both proteinogenic and non-proteinogenic amino acids. The latter resemble amino acids but contain modifications not found in proteins. The recent characterization of a non-heme Fe2+ and α-ketoglutarate-dependent oxygenase that stereospecifically generates β-hydroxyasparagine, an unnatural amino acid building block for the biosynthesis of calcium-dependent antibiotic, a lipopeptide antibiotic. This work improves our understanding of how these non-proteinogenic amino acids are synthesized.

A systems perspective to digital structures in molecular analysis

Co-reporter:Peyman Najmabadi, James J. La Clair and Michael D. Burkart

Organic & Biomolecular Chemistry 2007 vol. 5(Issue 2) pp:214-222

Publication Date(Web):28 Nov 2006

DOI:10.1039/B614507H

Within the last decade, the advance of miniaturization has opened the window to new systems that permit digital and molecular science to intersect, suggesting a new role for organic chemistry. Currently, fusion of molecules and electronic digits, as well as molecular-based digital structures, have expanded the conventional interpretation of the digit. This emergence has already generated new technological platforms with unique applications for molecular analysis and computation. We provide a brief overview of the conventional understanding of digital devices, examine the concept of molecular-based digits, and suggest new architectures by examining studies conducted on the compact discs. This analysis presents a perspective for the unique interaction of molecules and digits and the development of digital-based platforms for molecular analysis.

Synthesis of the mycolactone core by ring-closing metathesis

Co-reporter:Matthew D. Alexander, Shaun D. Fontaine, James J. La Clair, Antonio G. DiPasquale, Arnold L. Rheingold and Michael D. Burkart

Chemical Communications 2006 (Issue 44) pp:4602-4604

Publication Date(Web):21 Sep 2006

DOI:10.1039/B609408B

The undecenolide core of mycolactone was synthesized by ring-closing metathesis and the structure confirmed using single-crystal X-ray diffraction techniques.

Geometry in digital molecular arrays

Co-reporter:James J. La Clair and Michael D. Burkart

Organic & Biomolecular Chemistry 2006 vol. 4(Issue 16) pp:3052-3055

Publication Date(Web):11 Jul 2006

DOI:10.1039/B605411K

The development of digital molecular devices arises through the appropriate geometric positioning of a molecular assay. A detailed evaluation of the digital media reveals the critical aspects of geometric positioning in terms of developing an analytically-robust system for molecular analysis. This study reveals an explicit digital compact disc based assay for molecular affinity events.

One-pot chemo-enzymatic synthesis of reporter-modified proteins

Co-reporter:Andrew S. Worthington and Michael D. Burkart

Organic & Biomolecular Chemistry 2006 vol. 4(Issue 1) pp:44-46

Publication Date(Web):24 Nov 2005

DOI:10.1039/B512735A

To meet recent advancements in the covalent reporter labeling of proteins, we propose a flexible synthesis for reporter analogs. Here we demonstrate a one-pot chemo-enzymatic synthesis of reporter-labeled proteins that allows the covalent tethering of any amine-terminal fluorescent or affinity label to a carrier protein or fusion construct. This two-reaction sequence consists of activated panthothenate coupling, biosynthetic conversion to the coenzyme A (CoA) analog, and enzymatic carrier protein modification via phosphopantetheinyltransferase (PPTase). We also probe substrate specificity for CoAA, the first enzyme in the pathway. With this approach CoA analogs may be rapidly prepared, thus permitting the regiospecific attachment of reporter moieties from a variety of molecular species.

Fluorescent Multiplex Analysis of Carrier Protein Post-Translational Modification

Co-reporter:Andrew C. Mercer;James J. La Clair Dr. Dr.

ChemBioChem 2005 Volume 6(Issue 8) pp:

Publication Date(Web):5 JUL 2005

DOI:10.1002/cbic.200500051

A multiplex assay to investigate the functional specificity between carrier proteins, phosphopantheinyl transferases, and coenzyme A (CoA) derivatives is shown. This system offers a multicolored tool for the biophysical study of biosynthetic pathways and orthogonally designed fusion proteins.

Molecular screening on a compact disc

Co-reporter:James J. La Clair and Michael D. Burkart

Organic & Biomolecular Chemistry 2003 vol. 1(Issue 18) pp:3244-3249

Publication Date(Web):12 Aug 2003

DOI:10.1039/B306391G

A method is described to screen the recognition between small molecule ligands and biomolecules using a conventional compact disc (CD) player. A procedure was developed to attach ligands to the reading face of a CD by activating the terminus of polycarbonate, a common polymer composite within the reading face of a CD. Terminal residues of the polycarbonate surface 1 were phosphorylated by reaction with ethyl-(N,N)-diisopropylamine-buffered dichloro-(N,N)-diisopropylaminophosphate to yield surface-bound chlorophosphate 2. Ligands containing a primary alcohol were condensed with 2 providing a polycarbonate capped with phosphodiester linked ligands 3–6. Displays were generated on the surface of a CD by printing tracks of ligands 3–6 on the disc with an inkjet printer. Using this method, discs were created with entire assemblies of ligand molecules distributed into separate blocks. A molecular array was developed by assembling collections of these blocks to correlate with the CDROM-XA formatted data stored within the digital layer of the disc. Regions of the disc containing a given ligand or set of ligands was marked by its spatial position using the tracking and header information. Recognition between surface expressed ligands and biomolecules was screened by an error determination routine.

Data from mass spectrometry, NMR spectra, GC–MS of fatty acid esters produced by Lasiodiplodia theobromae

Co-reporter:Carla C. Uranga, Joris Beld, Anthony Mrse, Iván Córdova-Guerrero, Michael D. Burkart, Rufina Hernández-Martínez

Data in Brief (September 2016) Volume 8() pp:31-39

Publication Date(Web):1 September 2016

DOI:10.1016/j.dib.2016.05.003

The data described herein is related to the article with the title “Fatty acid esters produced by Lasiodiplodia theobromae function as growth regulators in tobacco seedlings” C.C. Uranga, J. Beld, A. Mrse, I. Cordova-Guerrero, M.D. Burkart, R. Hernandez-Martinez (2016) [1]. Data includes nuclear magnetic resonance spectroscopy and GC–MS data used for the identification and characterization of fatty acid esters produced by L. theobromae. GC–MS traces are also shown for incubations in defined substrate, consisting in Vogel׳s salts supplemented with either 5% grapeseed oil or 5% glucose, the two combined, or 5% fructose. Traces for incubations in the combination of 5% grapeseed oil and 5% glucose for different fungal species are also included. Images of mycelium morphology when grown in 5% glucose with or without 5% grapeseed oil are shown due to the stark difference in mycelial pigmentation in the presence of triglycerides. High concentration gradient data for the plant model Nicotiana tabacum germinated in ethyl stearate (SAEE) and ethyl linoleate (LAEE) is included to show the transition between growth inhibition and growth induction in N. tabacum by these compounds.

A Substrate Mimic Allows High-Throughput Assay of the FabA Protein and Consequently the Identification of a Novel Inhibitor of Pseudomonas aeruginosa FabA

Co-reporter:Lucile Moynié, Anthony G. Hope, Kara Finzel, Jason Schmidberger, ... James H. Naismith

Journal of Molecular Biology (16 January 2016) Volume 428(Issue 1) pp:108-120

Publication Date(Web):16 January 2016

DOI:10.1016/j.jmb.2015.10.027

•FabA is a promising drug target in Gram-negative bacteria.•High-throughput coupled assay for FabA using a substrate analogue has been developed.•New class of non-covalent inhibitor has been identified using the assay.•The compound inhibits the biological activity of FabA.•Crystal structure of the compound bound to FabA has been determined.Eukaryotes and prokaryotes possess fatty acid synthase (FAS) biosynthetic pathways that comprise iterative chain elongation, reduction, and dehydration reactions. The bacterial FASII pathway differs significantly from human FAS pathways and is a long-standing target for antibiotic development against Gram-negative bacteria due to differences from the human FAS, and several existing antibacterial agents are known to inhibit FASII enzymes. N-Acetylcysteamine (NAC) fatty acid thioesters have been used as mimics of the natural acyl carrier protein pathway intermediates to assay FASII enzymes, and we now report an assay of FabV from Pseudomonas aeruginosa using (E)-2-decenoyl-NAC. In addition, we have converted an existing UV absorbance assay for FabA, the bifunctional dehydration/epimerization enzyme and key target in the FASII pathway, into a high-throughput enzyme coupled fluorescence assay that has been employed to screen a library of diverse small molecules. With this approach, N-(4-chlorobenzyl)-3-(2-furyl)-1H-1,2,4-triazol-5-amine (N42FTA) was found to competitively inhibit (pIC50 = 5.7 ± 0.2) the processing of 3-hydroxydecanoyl-NAC by P. aeruginosa FabA. N42FTA was shown to be potent in blocking crosslinking of Escherichia coli acyl carrier protein and FabA, a direct mimic of the biological process. The co-complex structure of N42FTA with P. aeruginosa FabA protein rationalises affinity and suggests future design opportunities. Employing NAC fatty acid mimics to develop further high-throughput assays for individual enzymes in the FASII pathway should aid in the discovery of new antimicrobials.Download high-res image (103KB)Download full-size image

Structure and Substrate Sequestration in the Pyoluteorin Type II Peptidyl Carrier Protein PltL

Co-reporter:Matt J. Jaremko; D. John Lee; Stanley J. Opella

Journal of the American Chemical Society () pp:

Publication Date(Web):September 4, 2015

DOI:10.1021/jacs.5b04525

Type II nonribosomal peptide synthetases (NRPS) generate exotic amino acid derivatives that, combined with additional pathways, form many bioactive natural products. One family of type II NRPSs produce pyrrole moieties, which commonly arise from proline oxidation while tethered to a conserved, type II peptidyl carrier protein (PCP), as exemplified by PltL in the biosynthesis of pyoluteorin. We sought to understand the structural role of pyrrole PCPs in substrate and protein interactions through the study of pyrrole analogs tethered to PltL. Solution-phase NMR structural analysis revealed key interactions in residues of helix II and III with a bound pyrrole moiety. Conservation of these residues among PCPs in other pyrrole containing pathways suggests a conserved mechanism for formation, modification, and incorporation of pyrrole moieties. Further NOE analysis provided a unique pyrrole binding motif, offering accurate substrate positioning within the cleft between helices II and III. The overall structure resembles other PCPs but contains a unique conformation for helix III. This provides evidence of sequestration by the PCP of aromatic pyrrole substrates, illustrating the importance of substrate protection and regulation in type II NRPS systems.

Metabolic probes for imaging endosymbiotic bacteria within toxic dinoflagellates

Co-reporter:Carolina P. Reyes, James J. La Clair and Michael D. Burkart

Chemical Communications 2010 - vol. 46(Issue 43) pp:NaN8153-8153

Publication Date(Web):2010/10/06

DOI:10.1039/C0CC02876B

Chemoenzymatic exchange of phosphopantetheine on protein and peptide

Co-reporter:Nicolas M. Kosa, Kevin M. Pham and Michael D. Burkart

Chemical Science (2010-Present) 2014 - vol. 5(Issue 3) pp:NaN1186-1186

Publication Date(Web):2014/01/02

DOI:10.1039/C3SC53154F

Synthetic studies on the mycolactone core

Co-reporter:Kwang-Seuk Ko, Matthew D. Alexander, Shaun D. Fontaine, James E. Biggs-Houck, James J. La Clair and Michael D. Burkart