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2. An NmrA-like enzyme-catalysed redox-mediated Diels–Alder cycloaddition with anti-selectivity

Author

Liu, Zhiwen, Rivera, Sebastian, Newmister, Sean A, Sanders, Jacob N, Nie, Qiuyue, Liu, Shuai, Zhao, Fanglong, Ferrara, Joseph D, Shih, Hao-Wei, Patil, Siddhant, Xu, Weijun, Miller, Mitchell D, Phillips, George N, Houk, KN, Sherman, David H, and Gao, Xue

Subjects
Organic Chemistry, Chemical Sciences, Cycloaddition Reaction, Catalysis, Oxidoreductases, Chemistry Techniques, Synthetic, Oxidation-Reduction, Chemical sciences
Abstract

The Diels-Alder cycloaddition is one of the most powerful approaches in organic synthesis and is often used in the synthesis of important pharmaceuticals. Yet, strictly controlling the stereoselectivity of the Diels-Alder reactions is challenging, and great efforts are needed to construct complex molecules with desired chirality via organocatalysis or transition-metal strategies. Nature has evolved different types of enzymes to exquisitely control cyclization stereochemistry; however, most of the reported Diels-Alderases have been shown to only facilitate the energetically favourable diastereoselective cycloadditions. Here we report the discovery and characterization of CtdP, a member of a new class of bifunctional oxidoreductase/Diels-Alderase, which was previously annotated as an NmrA-like transcriptional regulator. We demonstrate that CtdP catalyses the inherently disfavoured cycloaddition to form the bicyclo[2.2.2]diazaoctane scaffold with a strict α-anti-selectivity. Guided by computational studies, we reveal a NADP+/NADPH-dependent redox mechanism for the CtdP-catalysed inverse electron demand Diels-Alder cycloaddition, which serves as the first example of a bifunctional Diels-Alderase that utilizes this mechanism.

Published
2023

3. Molecular investigation of harmful cyanobacteria reveals hidden risks and niche partitioning in Kenyan Lakes

Author

Achieng, Dorine, Barker, Katelyn B., Basweti, George M., Beal, Max, Brown, Katelyn M., Byrne, Aidan, Drouillard, Ken G., Getabu, Albert, Kiteresi, Linet I., Lawrence, Theodore, Lomeo, Davide, Miruka, Jared B., Mohney, Samantha, Njiru, James, Okutoyi, Pamela, Omondi, Reuben, Otieno, Dennis, Owino, Omondi A., Owoko, Winnie, Owuor, Bethwell, Shitandi, Anakalo, Stoll, Jordyn, Swaleh, Miriam, Tebbs, Emma, Varga, Emily, Wagner, Ryan S., Zepernick, Brittany N., Hart, Lauren N., Chase, Emily E., Natwora, Kaela E., Obuya, Julia A., Olokotum, Mark, Houghton, Katelyn A., Kiledal, E. Anders, Sheik, Cody S., Sherman, David H., Dick, Gregory J., Wilhelm, Steven W., Sitoki, Lewis, Otiso, Kefa M., McKay, R. Michael L., and Bullerjahn, George S.

Published
2024
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5. Data Science-Driven Analysis of Substrate-Permissive Diketopiperazine Reverse Prenyltransferase NotF: Applications in Protein Engineering and Cascade Biocatalytic Synthesis of (−)-Eurotiumin A

Author

Kelly, Samantha P, Shende, Vikram V, Flynn, Autumn R, Dan, Qingyun, Ye, Ying, Smith, Janet L, Tsukamoto, Sachiko, Sigman, Matthew S, and Sherman, David H

Subjects
Organic Chemistry, Chemical Sciences, Animals, Dimethylallyltranstransferase, Diketopiperazines, Data Science, Indole Alkaloids, Protein Engineering, Biological Products, Flavins, Mixed Function Oxygenases, Solvents, Carbon, Substrate Specificity, General Chemistry, Chemical sciences, Engineering
Abstract

Prenyltransfer is an early-stage carbon-hydrogen bond (C-H) functionalization prevalent in the biosynthesis of a diverse array of biologically active bacterial, fungal, plant, and metazoan diketopiperazine (DKP) alkaloids. Toward the development of a unified strategy for biocatalytic construction of prenylated DKP indole alkaloids, we sought to identify and characterize a substrate-permissive C2 reverse prenyltransferase (PT). As the first tailoring event within the biosynthesis of cytotoxic notoamide metabolites, PT NotF catalyzes C2 reverse prenyltransfer of brevianamide F. Solving a crystal structure of NotF (in complex with native substrate and prenyl donor mimic dimethylallyl S-thiolodiphosphate (DMSPP)) revealed a large, solvent-exposed active site, intimating NotF may possess a significantly broad substrate scope. To assess the substrate selectivity of NotF, we synthesized a panel of 30 sterically and electronically differentiated tryptophanyl DKPs, the majority of which were selectively prenylated by NotF in synthetically useful conversions (2 to >99%). Quantitative representation of this substrate library and development of a descriptive statistical model provided insight into the molecular origins of NotF's substrate promiscuity. This approach enabled the identification of key substrate descriptors (electrophilicity, size, and flexibility) that govern the rate of NotF-catalyzed prenyltransfer, and the development of an "induced fit docking (IFD)-guided" engineering strategy for improved turnover of our largest substrates. We further demonstrated the utility of NotF in tandem with oxidative cyclization using flavin monooxygenase, BvnB. This one-pot, in vitro biocatalytic cascade enabled the first chemoenzymatic synthesis of the marine fungal natural product, (-)-eurotiumin A, in three steps and 60% overall yield.

Published
2022

6. Engineering P450 TamI as an Iterative Biocatalyst for Selective Late-Stage C–H Functionalization and Epoxidation of Tirandamycin Antibiotics

Author

Espinoza, Rosa V, Haatveit, Kersti Caddell, Grossman, S Wald, Tan, Jin Yi, McGlade, Caylie A, Khatri, Yogan, Newmister, Sean A, Schmidt, Jennifer J, Garcia-Borràs, Marc, Montgomery, John, Houk, KN, and Sherman, David H

Subjects
Generic health relevance, biocatalysis, enzyme engineering, cytochrome P450, C-H functionalization, natural products, antibiotics, C–H functionalization, Inorganic Chemistry, Organic Chemistry, Chemical Engineering
Abstract

Iterative P450 enzymes are powerful biocatalysts for selective late-stage C-H oxidation of complex natural product scaffolds. These enzymes represent useful tools for selectivity and cascade reactions, facilitating direct access to core structure diversification. Recently, we reported the structure of the multifunctional bacterial P450 TamI and elucidated the molecular basis of its substrate binding and strict reaction sequence at distinct carbon atoms of the substrate. Here, we report the design and characterization of a toolbox of TamI biocatalysts, generated by mutations at Leu101, Leu244, and/or Leu295, that alter the native selectivity, step sequence, and number of reactions catalyzed, including the engineering of a variant capable of catalyzing a four-step oxidative cascade without the assistance of the flavoprotein and oxidative partner TamL. The tuned enzymes override inherent substrate reactivity, enabling catalyst-controlled C-H functionalization and alkene epoxidation of the tetramic acid-containing natural product tirandamycin. Five bioactive tirandamycin derivatives (6-10) were generated through TamI-mediated enzymatic synthesis. Quantum mechanics calculations and MD simulations provide important insights into the basis of altered selectivity and underlying biocatalytic mechanisms for enhanced continuous oxidation of the iterative P450 TamI.

Published
2021

7. Structural Diversification of Hapalindole and Fischerindole Natural Products via Cascade Biocatalysis

Author

Hohlman, Robert M, Newmister, Sean A, Sanders, Jacob N, Khatri, Yogan, Li, Shasha, Keramati, Nikki R, Lowell, Andrew N, Houk, KN, and Sherman, David H

Subjects
Biological Sciences, Organic Chemistry, Chemical Sciences, Generic health relevance, Stig cyclase, Fam prenyltransferase, hapalindole, fischerindole, diversification, biocatalysis, Inorganic Chemistry, Chemical Engineering, Industrial biotechnology, Organic chemistry, Physical chemistry
Abstract

Hapalindoles and related compounds (ambiguines, fischerindoles, welwitindolinones) are a diverse class of indole alkaloid natural products. They are typically isolated from the Stigonemataceae order of cyanobacteria and possess a broad scope of biological activities. Recently the biosynthetic pathway for assembly of these metabolites has been elucidated. In order to generate the core ring system, L-tryptophan is converted into the cis-indole isonitrile subunit before being prenylated with geranyl pyrophosphate at the C-3 position. A class of cyclases (Stig) catalyzes a three-step process including a Cope rearrangement, 6-exo-trig cyclization and electrophilic aromatic substitution to create a polycyclic core. Formation of the initial alkaloid is followed by diverse late-stage tailoring reactions mediated by additional biosynthetic enzymes to give rise to the wide array of structural variations observed in this compound class. Herein, we demonstrate the versatility and utility of the Fam prenyltransferase and Stig cyclases toward core structural diversification of this family of indole alkaloids. Through synthesis of cis-indole isonitrile subunit derivatives, and aided by protein engineering and computational analysis, we have employed cascade biocatalysis to generate a range of derivatives, and gained insights into the basis for substrate flexibility in this system.

Published
2021

9. Molecular Basis of Iterative C–H Oxidation by TamI, a Multifunctional P450 Monooxygenase from the Tirandamycin Biosynthetic Pathway

Author

Newmister, Sean A, Srivastava, Kinshuk Raj, Espinoza, Rosa V, Haatveit, Kersti Caddell, Khatri, Yogan, Martini, Rachel M, Garcia-Borràs, Marc, Podust, Larissa M, Houk, KN, and Sherman, David H

Subjects
Generic health relevance, natural product, biosynthesis, cytochrome P450, enzyme structure, molecular dynamics, antibiotics, Inorganic Chemistry, Organic Chemistry, Chemical Engineering
Abstract

Biocatalysis offers an expanding and powerful strategy to construct and diversify complex molecules by C─H bond functionalization. Due to their high selectivity, enzymes have become an essential tool for C─H bond functionalization and offer complementary reactivity to small-molecule catalysts. Hemoproteins, particularly cytochromes P450, have proven effective for selective oxidation of unactivated C─H bonds. Previously, we reported the in vitro characterization of an oxidative tailoring cascade in which TamI, a multifunctional P450 functions co-dependently with the TamL flavoprotein to catalyze regio- and stereoselective hydroxylations and epoxidation to yield tirandamycin A and tirandamycin B. TamI follows a defined order including 1) C10 hydroxylation, 2) C11/C12 epoxidation, and 3) C18 hydroxylation. Here we present a structural, biochemical, and computational investigation of TamI to understand the molecular basis of its substrate binding, diverse reactivity, and specific reaction sequence. The crystal structure of TamI in complex with tirandamycin C together with molecular dynamics simulations and targeted mutagenesis suggest that hydrophobic interactions with the polyene chain of its natural substrate are critical for molecular recognition. QM calculations and molecular dynamics simulations of TamI with variant substrates provided detailed information on the molecular basis of sequential reactivity, and pattern of regio- and stereo-selectivity in catalyzing the three-step oxidative cascade.

Published
2020

10. Computational-Based Mechanistic Study and Engineering of Cytochrome P450 MycG for Selective Oxidation of 16-Membered Macrolide Antibiotics

Author

Yang, Song, DeMars, Matthew D, Grandner, Jessica M, Olson, Noelle M, Anzai, Yojiro, Sherman, David H, and Houk, KN

Subjects
Chemical Sciences, Bioengineering, Anti-Bacterial Agents, Cytochrome P-450 Enzyme System, Macrolides, Molecular Conformation, Molecular Dynamics Simulation, Oxidation-Reduction, Protein Engineering, General Chemistry, Chemical sciences, Engineering
Abstract

MycG is a cytochrome P450 that performs two sequential oxidation reactions on the 16-membered ring macrolide M-IV. The enzyme evolved to oxidize M-IV preferentially over M-III and M-VI, which differ only by the presence of methoxy vs free hydroxyl groups on one of the macrolide sugar moieties. We utilized a two-pronged computational approach to study both the chemoselective reactivity and substrate specificity of MycG. Density functional theory computations determined that epoxidation of the substrate hampers its ability to undergo C-H abstraction, primarily due to a loss of hyperconjugation in the transition state. Metadynamics and molecular dynamics simulations revealed a hydrophobic sugar-binding pocket that is responsible for substrate recognition/specificity and was not apparent in crystal structures of the enzyme/substrate complex. Computational results also led to the identification of other interactions between the enzyme and its substrates that had not previously been observed in the cocrystal structures. Site-directed mutagenesis was then employed to test the effects of mutations hypothesized to broaden the substrate scope and alter the product profile of MycG. The results of these experiments validated this complementary effort to engineer MycG variants with improved catalytic activity toward earlier stage mycinamicin substrates.

Published
2020

11. Structure and Function of NzeB, a Versatile C–C and C–N Bond-Forming Diketopiperazine Dimerase

Author

Shende, Vikram V, Khatri, Yogan, Newmister, Sean A, Sanders, Jacob N, Lindovska, Petra, Yu, Fengan, Doyon, Tyler J, Kim, Justin, Houk, KN, Movassaghi, Mohammad, and Sherman, David H

Subjects
Organic Chemistry, Chemical Sciences, Bioengineering, Generic health relevance, Alkaloids, Amination, Biocatalysis, Biological Products, Carbon, Cytochrome P-450 Enzyme System, Diketopiperazines, Dimerization, Models, Molecular, Molecular Conformation, Mutagenesis, Site-Directed, Nitrogen, Streptomyces, Substrate Specificity, General Chemistry, Chemical sciences, Engineering
Abstract

The dimeric diketopiperazine (DKPs) alkaloids are a diverse family of natural products (NPs) whose unique structural architectures and biological activities have inspired the development of new synthetic methodologies to access these molecules. However, catalyst-controlled methods that enable the selective formation of constitutional and stereoisomeric dimers from a single monomer are lacking. To resolve this long-standing synthetic challenge, we sought to characterize the biosynthetic enzymes that assemble these NPs for application in biocatalytic syntheses. Genome mining enabled identification of the cytochrome P450, NzeB (Streptomyces sp. NRRL F-5053), which catalyzes both intermolecular carbon-carbon (C-C) and carbon-nitrogen (C-N) bond formation. To identify the molecular basis for the flexible site-selectivity, stereoselectivity, and chemoselectivity of NzeB, we obtained high-resolution crystal structures (1.5 Å) of the protein in complex with native and non-native substrates. This, to our knowledge, represents the first crystal structure of an oxidase catalyzing direct, intermolecular C-H amination. Site-directed mutagenesis was utilized to assess the role individual active-site residues play in guiding selective DKP dimerization. Finally, computational approaches were employed to evaluate plausible mechanisms regarding NzeB function and its ability to catalyze both C-C and C-N bond formation. These results provide a structural and computational rationale for the catalytic versatility of NzeB, as well as new insights into variables that control selectivity of CYP450 diketopiperazine dimerases.

Published
2020

12. Concanamycin A counteracts HIV-1 Nef to enhance immune clearance of infected primary cells by cytotoxic T lymphocytes

Author

Painter, Mark M, Zimmerman, Gretchen E, Merlino, Madeline S, Robertson, Andrew W, Terry, Valeri H, Ren, Xuefeng, McLeod, Megan R, Gomez-Rodriguez, Lyanne, Garcia, Kirsten A, Leonard, Jolie A, Leopold, Kay E, Neevel, Andrew J, Lubow, Jay, Olson, Eli, Piechocka-Trocha, Alicja, Collins, David R, Tripathi, Ashootosh, Raghavan, Malini, Walker, Bruce D, Hurley, James H, Sherman, David H, and Collins, Kathleen L

Subjects
Medical Microbiology, Biomedical and Clinical Sciences, Immunology, Infectious Diseases, HIV/AIDS, Sexually Transmitted Infections, 2.1 Biological and endogenous factors, 1.1 Normal biological development and functioning, Inflammatory and immune system, Infection, Good Health and Well Being, Cells, Cultured, HIV Infections, HIV-1, Histocompatibility Antigens Class I, Host-Pathogen Interactions, Humans, Macrolides, T-Lymphocytes, Cytotoxic, nef Gene Products, Human Immunodeficiency Virus, HIV, MHC-I, Nef, cytotoxic T lymphocytes, concanamycin A
Abstract

Nef is an HIV-encoded accessory protein that enhances pathogenicity by down-regulating major histocompatibility class I (MHC-I) expression to evade killing by cytotoxic T lymphocytes (CTLs). A potent Nef inhibitor that restores MHC-I is needed to promote immune-mediated clearance of HIV-infected cells. We discovered that the plecomacrolide family of natural products restored MHC-I to the surface of Nef-expressing primary cells with variable potency. Concanamycin A (CMA) counteracted Nef at subnanomolar concentrations that did not interfere with lysosomal acidification or degradation and were nontoxic in primary cell cultures. CMA specifically reversed Nef-mediated down-regulation of MHC-I, but not CD4, and cells treated with CMA showed reduced formation of the Nef:MHC-I:AP-1 complex required for MHC-I down-regulation. CMA restored expression of diverse allotypes of MHC-I in Nef-expressing cells and inhibited Nef alleles from divergent clades of HIV and simian immunodeficiency virus, including from primary patient isolates. Lastly, we found that restoration of MHC-I in HIV-infected cells was accompanied by enhanced CTL-mediated clearance of infected cells comparable to genetic deletion of Nef. Thus, we propose CMA as a lead compound for therapeutic inhibition of Nef to enhance immune-mediated clearance of HIV-infected cells.

Published
2020

14. Molecular Basis for Spirocycle Formation in the Paraherquamide Biosynthetic Pathway

Author

Fraley, Amy E, Haatveit, Kersti Caddell, Ye, Ying, Kelly, Samantha P, Newmister, Sean A, Yu, Fengan, Williams, Robert M, Smith, Janet L, Houk, KN, and Sherman, David H

Subjects
Organic Chemistry, Chemical Sciences, General Chemistry, Chemical sciences, Engineering
Abstract

The paraherquamides are potent anthelmintic natural products with complex heptacyclic scaffolds. One key feature of these molecules is the spiro-oxindole moiety that lends a strained three-dimensional architecture to these structures. The flavin monooxygenase PhqK was found to catalyze spirocycle formation through two parallel pathways in the biosynthesis of paraherquamides A and G. Two new paraherquamides (K and L) were isolated from a ΔphqK strain of Penicillium simplicissimum, and subsequent enzymatic reactions with these compounds generated two additional metabolites, paraherquamides M and N. Crystal structures of PhqK in complex with various substrates provided a foundation for mechanistic analyses and computational studies. While it is evident that PhqK can react with various substrates, reaction kinetics and molecular dynamics simulations indicated that the dioxepin-containing paraherquamide L is the favored substrate. Through this effort, we have elucidated a key step in the biosynthesis of the paraherquamides and provided a rationale for the selective spirocyclization of these powerful anthelmintic agents.

Published
2020

15. Repurposing the GNAT Fold in the Initiation of Polyketide Biosynthesis

Author

Skiba, Meredith A, Tran, Collin L, Dan, Qingyun, Sikkema, Andrew P, Klaver, Zachary, Gerwick, William H, Sherman, David H, and Smith, Janet L

Subjects
Biochemistry and Cell Biology, Biological Sciences, Acetyltransferases, Crystallography, X-Ray, Humans, Models, Molecular, Polyketides, Protein Domains, Protein Folding, Protein Structure, Secondary, GCN5-related N-acetyltransferase, biosynthesis, natural products, polyketide synthase, Chemical Sciences, Information and Computing Sciences, Biophysics, Biological sciences, Chemical sciences
Abstract

Natural product biosynthetic pathways are replete with enzymes repurposed for new catalytic functions. In some modular polyketide synthase (PKS) pathways, a GCN5-related N-acetyltransferase (GNAT)-like enzyme with an additional decarboxylation function initiates biosynthesis. Here, we probe two PKS GNAT-like domains for the dual activities of S-acyl transfer from coenzyme A (CoA) to an acyl carrier protein (ACP) and decarboxylation. The GphF and CurA GNAT-like domains selectively decarboxylate substrates that yield the anticipated pathway starter units. The GphF enzyme lacks detectable acyl transfer activity, and a crystal structure with an isobutyryl-CoA product analog reveals a partially occluded acyltransfer acceptor site. Further analysis indicates that the CurA GNAT-like domain also catalyzes only decarboxylation, and the initial acyl transfer is catalyzed by an unidentified enzyme. Thus, PKS GNAT-like domains are re-classified as GNAT-like decarboxylases. Two other decarboxylases, malonyl-CoA decarboxylase and EryM, reside on distant nodes of the superfamily, illustrating the adaptability of the GNAT fold.

Published
2020

16. Exploring the molecular basis for substrate specificity in homologous macrolide biosynthetic cytochromes P450

Author

DeMars, Matthew D, Samora, Nathan L, Yang, Song, Garcia-Borràs, Marc, Sanders, Jacob N, Houk, KN, Podust, Larissa M, and Sherman, David H

Subjects
Biochemistry and Cell Biology, Chemical Sciences, Biological Sciences, Underpinning research, 1.1 Normal biological development and functioning, Amino Acid Substitution, Bacterial Proteins, Binding Sites, Cytochrome P-450 Enzyme System, Molecular Dynamics Simulation, Protein Binding, Streptomyces, Substrate Specificity, Tylosin, cytochrome P450, natural product biosynthesis, substrate specificity, enzyme structure, molecular dynamics, protein chimera, macrolide antibiotics, Medical and Health Sciences, Biochemistry & Molecular Biology, Biological sciences, Biomedical and clinical sciences, Chemical sciences
Abstract

Cytochromes P450 (P450s) are nature's catalysts of choice for performing demanding and physiologically vital oxidation reactions. Biochemical characterization of these enzymes over the past decades has provided detailed mechanistic insight and highlighted the diversity of substrates P450s accommodate and the spectrum of oxidative transformations they catalyze. Previously, we discovered that the bacterial P450 MycCI from the mycinamicin biosynthetic pathway in Micromonospora griseorubida possesses an unusually broad substrate scope, whereas the homologous P450 from tylosin-producing Streptomyces fradiae (TylHI) exhibits a high degree of specificity for its native substrate. Here, using biochemical, structural, and computational approaches, we aimed to understand the molecular basis for the disparate reactivity profiles of these two P450s. Turnover and equilibrium binding experiments with substrate analogs revealed that TylHI strictly prefers 16-membered ring macrolides bearing the deoxyamino sugar mycaminose. To help rationalize these results, we solved the X-ray crystal structure of TylHI in complex with its native substrate at 1.99-Å resolution and assayed several site-directed mutants. We also conducted molecular dynamics simulations of TylHI and MycCI and biochemically characterized a third P450 homolog from the chalcomycin biosynthetic pathway in Streptomyces bikiniensis These studies provided a basis for constructing P450 chimeras to gain further insight into the features dictating the differences in reaction profile among these structurally and functionally related enzymes, ultimately unveiling the central roles of key loop regions in influencing substrate binding and turnover. Our work highlights the complex nature of P450/substrate interactions and raises interesting questions regarding the evolution of functional diversity among biosynthetic enzymes.

Published
2019

17. Fungal indole alkaloid biogenesis through evolution of a bifunctional reductase/Diels–Alderase

Author

Dan, Qingyun, Newmister, Sean A, Klas, Kimberly R, Fraley, Amy E, McAfoos, Timothy J, Somoza, Amber D, Sunderhaus, James D, Ye, Ying, Shende, Vikram V, Yu, Fengan, Sanders, Jacob N, Brown, W Clay, Zhao, Le, Paton, Robert S, Houk, KN, Smith, Janet L, Sherman, David H, and Williams, Robert M

Subjects
Biotechnology, Emerging Infectious Diseases, Vaccine Related, Ascomycota, Biocatalysis, Cycloaddition Reaction, Indole Alkaloids, Models, Molecular, Molecular Structure, Oxidoreductases, Chemical Sciences, Organic Chemistry
Abstract

Prenylated indole alkaloids such as the calmodulin-inhibitory malbrancheamides and anthelmintic paraherquamides possess great structural diversity and pharmaceutical utility. Here, we report complete elucidation of the malbrancheamide biosynthetic pathway accomplished through complementary approaches. These include a biomimetic total synthesis to access the natural alkaloid and biosynthetic intermediates in racemic form and in vitro enzymatic reconstitution to provide access to the natural antipode (+)-malbrancheamide. Reductive cleavage of an L-Pro-L-Trp dipeptide from the MalG non-ribosomal peptide synthetase (NRPS) followed by reverse prenylation and a cascade of post-NRPS reactions culminates in an intramolecular [4+2] hetero-Diels-Alder (IMDA) cyclization to furnish the bicyclo[2.2.2]diazaoctane scaffold. Enzymatic assembly of optically pure (+)-premalbrancheamide involves an unexpected zwitterionic intermediate where MalC catalyses enantioselective cycloaddition as a bifunctional NADPH-dependent reductase/Diels-Alderase. The crystal structures of substrate and product complexes together with site-directed mutagenesis and molecular dynamics simulations demonstrate how MalC and PhqE (its homologue from the paraherquamide pathway) catalyse diastereo- and enantioselective cyclization in the construction of this important class of secondary metabolites.

Published
2019

18. Structural Basis of Polyketide Synthase O‑Methylation

Author

Skiba, Meredith A, Bivins, Marissa M, Schultz, John R, Bernard, Steffen M, Fiers, William D, Dan, Qingyun, Kulkarni, Sarang, Wipf, Peter, Gerwick, William H, Sherman, David H, Aldrich, Courtney C, and Smith, Janet L

Subjects
Genetics, Bacterial Proteins, Catalytic Domain, Cyanobacteria, Methylation, Methyltransferases, Mutagenesis, Site-Directed, Mutation, Myxococcales, Polyketide Synthases, Polyketides, Protein Conformation, Protein Domains, Substrate Specificity, Chemical Sciences, Biological Sciences, Organic Chemistry
Abstract

Modular type I polyketide synthases (PKSs) produce some of the most chemically complex metabolites in nature through a series of multienzyme modules. Each module contains a variety of catalytic domains to selectively tailor the growing molecule. PKS O-methyltransferases ( O-MTs) are predicted to methylate β-hydroxyl or β-keto groups, but their activity and structure have not been reported. We determined the domain boundaries and characterized the catalytic activity and structure of the StiD and StiE O-MTs, which methylate opposite β-hydroxyl stereocenters in the myxobacterial stigmatellin biosynthetic pathway. Substrate stereospecificity was demonstrated for the StiD O-MT. Key catalytic residues were identified in the crystal structures and investigated in StiE O-MT via site-directed mutagenesis and further validated with the cyanobacterial CurL O-MT from the curacin biosynthetic pathway. Initial structural and biochemical analysis of PKS O-MTs supplies a new chemoenzymatic tool, with the unique ability to selectively modify hydroxyl groups during polyketide biosynthesis.

Published
2018

19. A human MUTYH variant linking colonic polyposis to redox degradation of the [4Fe4S]2+ cluster

Author

McDonnell, Kevin J, Chemler, Joseph A, Bartels, Phillip L, O’Brien, Elizabeth, Marvin, Monica L, Ortega, Janice, Stern, Ralph H, Raskin, Leon, Li, Guo-Min, Sherman, David H, Barton, Jacqueline K, and Gruber, Stephen B

Subjects
Chemical Sciences, Colo-Rectal Cancer, Digestive Diseases, Genetics, Cancer, Adenomatous Polyposis Coli, Colonic Neoplasms, DNA Glycosylases, Genetic Variation, Humans, Iron-Sulfur Proteins, Mutation, Oxidation-Reduction, Organic Chemistry, Chemical sciences
Abstract

The human DNA repair enzyme MUTYH excises mispaired adenine residues in oxidized DNA. Homozygous MUTYH mutations underlie the autosomal, recessive cancer syndrome MUTYH-associated polyposis. We report a MUTYH variant, p.C306W (c.918C>G), with a tryptophan residue in place of native cysteine, that ligates the [4Fe4S] cluster in a patient with colonic polyposis and family history of early age colon cancer. In bacterial MutY, the [4Fe4S] cluster is redox active, allowing rapid localization to target lesions by long-range, DNA-mediated signalling. In the current study, using DNA electrochemistry, we determine that wild-type MUTYH is similarly redox-active, but MUTYH C306W undergoes rapid oxidative degradation of its cluster to [3Fe4S]+, with loss of redox signalling. In MUTYH C306W, oxidative cluster degradation leads to decreased DNA binding and enzyme function. This study confirms redox activity in eukaryotic DNA repair proteins and establishes MUTYH C306W as a pathogenic variant, highlighting the essential role of redox signalling by the [4Fe4S] cluster.

Published
2018

20. Biosynthesis of t‑Butyl in Apratoxin A: Functional Analysis and Architecture of a PKS Loading Module

Author

Skiba, Meredith A, Sikkema, Andrew P, Moss, Nathan A, Lowell, Andrew N, Su, Min, Sturgis, Rebecca M, Gerwick, Lena, Gerwick, William H, Sherman, David H, and Smith, Janet L

Subjects
Acyl Carrier Protein, Amino Acid Sequence, Bacterial Proteins, Carboxy-Lyases, Catalytic Domain, Cyanobacteria, Decarboxylation, Depsipeptides, Methylation, Methyltransferases, Multifunctional Enzymes, Polyketide Synthases, Substrate Specificity, Chemical Sciences, Biological Sciences, Organic Chemistry
Abstract

The unusual feature of a t-butyl group is found in several marine-derived natural products including apratoxin A, a Sec61 inhibitor produced by the cyanobacterium Moorea bouillonii PNG 5-198. Here, we determine that the apratoxin A t-butyl group is formed as a pivaloyl acyl carrier protein (ACP) by AprA, the polyketide synthase (PKS) loading module of the apratoxin A biosynthetic pathway. AprA contains an inactive "pseudo" GCN5-related N-acetyltransferase domain (ΨGNAT) flanked by two methyltransferase domains (MT1 and MT2) that differ distinctly in sequence. Structural, biochemical, and precursor incorporation studies reveal that MT2 catalyzes unusually coupled decarboxylation and methylation reactions to transform dimethylmalonyl-ACP, the product of MT1, to pivaloyl-ACP. Further, pivaloyl-ACP synthesis is primed by the fatty acid synthase malonyl acyltransferase (FabD), which compensates for the ΨGNAT and provides the initial acyl-transfer step to form AprA malonyl-ACP. Additionally, images of AprA from negative stain electron microscopy reveal multiple conformations that may facilitate the individual catalytic steps of the multienzyme module.

Published
2018

21. Structural basis of the Cope rearrangement and cyclization in hapalindole biogenesis

Author

Newmister, Sean A, Li, Shasha, Garcia-Borràs, Marc, Sanders, Jacob N, Yang, Song, Lowell, Andrew N, Yu, Fengan, Smith, Janet L, Williams, Robert M, Houk, KN, and Sherman, David H

Subjects
Biological Sciences, Organic Chemistry, Chemical Sciences, Theoretical and Computational Chemistry, Alkaloids, Calcium, Catalysis, Catalytic Domain, Cloning, Molecular, Cyanobacteria, Cyclization, DNA Mutational Analysis, Dimerization, Indole Alkaloids, Indoles, Ions, Molecular Conformation, Molecular Dynamics Simulation, Molecular Structure, Protein Binding, Quantum Theory, Recombinant Proteins, Stereoisomerism, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medicinal and biomolecular chemistry
Abstract

Hapalindole alkaloids are a structurally diverse class of cyanobacterial natural products defined by their varied polycyclic ring systems and diverse biological activities. These complex metabolites are generated from a common biosynthetic intermediate by the Stig cyclases in three mechanistic steps: a rare Cope rearrangement, 6-exo-trig cyclization, and electrophilic aromatic substitution. Here we report the structure of HpiC1, a Stig cyclase that catalyzes the formation of 12-epi-hapalindole U in vitro. The 1.5-Å structure revealed a dimeric assembly with two calcium ions per monomer and with the active sites located at the distal ends of the protein dimer. Mutational analysis and computational methods uncovered key residues for an acid-catalyzed [3,3]-sigmatropic rearrangement, as well as specific determinants that control the position of terminal electrophilic aromatic substitution, leading to a switch from hapalindole to fischerindole alkaloids.

Published
2018

22. Synthesis of Diverse 11- and 12-Membered Macrolactones from a Common Linear Substrate Using a Single Biocatalyst

Author

Gilbert, Michael M, DeMars, Matthew D, Yang, Song, Grandner, Jessica M, Wang, Shoulei, Wang, Hengbin, Narayan, Alison RH, Sherman, David H, Houk, KN, and Montgomery, John

Subjects
Chemical Sciences
Abstract

The diversification of late stage synthetic intermediates provides significant advantages in efficiency in comparison to conventional linear approaches. Despite these advantages, accessing varying ring scaffolds and functional group patterns from a common intermediate poses considerable challenges using existing methods. The combination of regiodivergent nickel-catalyzed C-C couplings and site-selective biocatalytic C-H oxidations using the cytochrome P450 enzyme PikC addresses this problem by enabling a single late-stage linear intermediate to be converted to macrolactones of differing ring size and with diverse patterns of oxidation. The approach is made possible by a novel strategy for site-selective biocatalytic oxidation using a single biocatalyst, with site selectivity being governed by a temporarily installed directing group. Site selectivities of C-H oxidation by this directed approach can overcome positional bias due to C-H bond strength, acidity, inductive influences, steric accessibility, or immediate proximity to the directing group, thus providing complementarity to existing approaches.

Published
2017

23. A Mononuclear Iron-Dependent Methyltransferase Catalyzes Initial Steps in Assembly of the Apratoxin A Polyketide Starter Unit

Author

Skiba, Meredith A, Sikkema, Andrew P, Moss, Nathan A, Tran, Collin L, Sturgis, Rebecca M, Gerwick, Lena, Gerwick, William H, Sherman, David H, and Smith, Janet L

Subjects
Depsipeptides, Escherichia coli, Gene Expression Regulation, Bacterial, Gene Expression Regulation, Enzymologic, Iron, Methyltransferases, Models, Molecular, Molecular Structure, Polyketides, Protein Conformation, Protein Domains, Chemical Sciences, Biological Sciences, Organic Chemistry
Abstract

Natural product biosynthetic pathways contain a plethora of enzymatic tools to carry out difficult biosynthetic transformations. Here, we discover an unusual mononuclear iron-dependent methyltransferase that acts in the initiation steps of apratoxin A biosynthesis (AprA MT1). Fe3+-replete AprA MT1 catalyzes one or two methyl transfer reactions on the substrate malonyl-ACP (acyl carrier protein), whereas Co2+, Fe2+, Mn2+, and Ni2+ support only a single methyl transfer. MT1 homologues exist within the "GNAT" (GCN5-related N-acetyltransferase) loading modules of several modular biosynthetic pathways with propionyl, isobutyryl, or pivaloyl starter units. GNAT domains are thought to catalyze decarboxylation of malonyl-CoA and acetyl transfer to a carrier protein. In AprA, the GNAT domain lacks both decarboxylation and acyl transfer activity. A crystal structure of the AprA MT1-GNAT di-domain with bound Mn2+, malonate, and the methyl donor S-adenosylmethionine (SAM) reveals that the malonyl substrate is a bidentate metal ligand, indicating that the metal acts as a Lewis acid to promote methylation of the malonyl α-carbon. The GNAT domain is truncated relative to functional homologues. These results afford an expanded understanding of MT1-GNAT structure and activity and permit the functional annotation of homologous GNAT loading modules both with and without methyltransferases, additionally revealing their rapid evolutionary adaptation in different biosynthetic contexts.

Published
2017

24. A Single Active Site Mutation in the Pikromycin Thioesterase Generates a More Effective Macrocyclization Catalyst

Author

Koch, Aaron A, Hansen, Douglas A, Shende, Vikram V, Furan, Lawrence R, Houk, KN, Jiménez-Osés, Gonzalo, and Sherman, David H

Subjects
Generic health relevance, Biocatalysis, Catalytic Domain, Cyclization, Gain of Function Mutation, Kinetics, Macrolides, Molecular Dynamics Simulation, Mutation, Polyketide Synthases, Substrate Specificity, Thiolester Hydrolases, Chemical Sciences, General Chemistry
Abstract

Macrolactonization of natural product analogs presents a significant challenge to both biosynthetic assembly and synthetic chemistry. In the preceding paper , we identified a thioesterase (TE) domain catalytic bottleneck processing unnatural substrates in the pikromycin (Pik) system, preventing the formation of epimerized macrolactones. Here, we perform molecular dynamics simulations showing the epimerized hexaketide was accommodated within the Pik TE active site; however, intrinsic conformational preferences of the substrate resulted in predominately unproductive conformations, in agreement with the observed hydrolysis. Accordingly, we engineered the stereoselective Pik TE to yield a variant (TES148C) with improved reaction kinetics and gain-of-function processing of an unnatural, epimerized hexaketide. Quantum mechanical comparison of model TES148C and TEWT reaction coordinate diagrams revealed a change in mechanism from a stepwise addition-elimination (TEWT) to a lower energy concerted acyl substitution (TES148C), accounting for the gain-of-function and improved reaction kinetics. Finally, we introduced the S148C mutation into a polyketide synthase module (PikAIII-TE) to impart increased substrate flexibility, enabling the production of diastereomeric macrolactones.

Published
2017

25. Function and Structure of MalA/MalA′, Iterative Halogenases for Late-Stage C–H Functionalization of Indole Alkaloids

Author

Fraley, Amy E, Garcia-Borràs, Marc, Tripathi, Ashootosh, Khare, Dheeraj, Mercado-Marin, Eduardo V, Tran, Hong, Dan, Qingyun, Webb, Gabrielle P, Watts, Katharine R, Crews, Phillip, Sarpong, Richmond, Williams, Robert M, Smith, Janet L, Houk, KN, and Sherman, David H

Subjects
Organic Chemistry, Chemical Sciences, Ascomycota, Biosynthetic Pathways, Fungal Proteins, Halogenation, Indole Alkaloids, Kinetics, Models, Molecular, General Chemistry, Chemical sciences, Engineering
Abstract

Malbrancheamide is a dichlorinated fungal indole alkaloid isolated from both Malbranchea aurantiaca and Malbranchea graminicola that belongs to a family of natural products containing a characteristic bicyclo[2.2.2]diazaoctane core. The introduction of chlorine atoms on the indole ring of malbrancheamide differentiates it from other members of this family and contributes significantly to its biological activity. In this study, we characterized the two flavin-dependent halogenases involved in the late-stage halogenation of malbrancheamide in two different fungal strains. MalA and MalA' catalyze the iterative dichlorination and monobromination of the free substrate premalbrancheamide as the final steps in the malbrancheamide biosynthetic pathway. Two unnatural bromo-chloro-malbrancheamide analogues were generated through MalA-mediated chemoenzymatic synthesis. Structural analysis and computational studies of MalA' in complex with three substrates revealed that the enzyme represents a new class of zinc-binding flavin-dependent halogenases and provides new insights into a potentially unique reaction mechanism.

Published
2017

26. Solution Conformations and Dynamics of Substrate-Bound Cytochrome P450 MycG

Author

Tietz, Drew R, Podust, Larissa M, Sherman, David H, and Pochapsky, Thomas C

Subjects
Bacterial Proteins, Cytochrome P-450 Enzyme System, Models, Molecular, Molecular Dynamics Simulation, Nuclear Magnetic Resonance, Biomolecular, Protein Conformation, Solutions, Substrate Specificity, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology
Abstract

MycG is a P450 monooxygenase that catalyzes the sequential hydroxylation and epoxidation of mycinamicin IV (M-IV), the last two steps in the biosynthesis of mycinamicin II, a macrolide antibiotic isolated from Micromonospora griseorubida. The crystal structure of MycG with M-IV bound was previously determined but showed the bound substrate in an orientation that did not rationalize the observed regiochemistry of M-IV hydroxylation. Nuclear magnetic resonance paramagnetic relaxation enhancements provided evidence of an orientation of M-IV in the MycG active site more compatible with the observed chemistry, but substrate-induced changes in the enzyme structure were not characterized. We now describe the use of amide 1H-15N residual dipolar couplings as experimental restraints in solvated "soft annealing" molecular dynamics simulations to generate solution structural ensembles of M-IV-bound MycG. Chemical shift perturbations, hydrogen-deuterium exchange, and 15N relaxation behavior provide insight into the dynamic and electronic perturbations in the MycG structure in response to M-IV binding. The solution and crystallographic structures are compared, and the possibility that the crystallographic orientation of bound M-IV represents an inhibitory mode is discussed.

Published
2017

30. The Phormidolide Biosynthetic Gene Cluster: A trans‐AT PKS Pathway Encoding a Toxic Macrocyclic Polyketide

Author

Bertin, Matthew J, Vulpanovici, Alexandra, Monroe, Emily A, Korobeynikov, Anton, Sherman, David H, Gerwick, Lena, and Gerwick, William H

Subjects
Biological Sciences, Genetics, Acyltransferases, Amino Acid Sequence, Computational Biology, Conserved Sequence, Cyanobacteria, Macrolides, Multigene Family, Polyketide Synthases, Sequence Alignment, biosynthesis, macrolactones, phormidolide, polyketide synthase, trans-AT, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Organic Chemistry, Biochemistry and cell biology, Medicinal and biomolecular chemistry
Abstract

Phormidolide is a polyketide produced by a cultured filamentous marine cyanobacterium and incorporates a 16-membered macrolactone. Its complex structure is recognizably derived from a polyketide synthase pathway, but possesses unique and intriguing structural features that prompted interest in investigating its biosynthetic origin. Stable isotope incorporation experiments confirmed the polyketide nature of this compound. We further characterized the phormidolide gene cluster (phm) through genome sequencing followed by bioinformatic analysis. Two discrete trans-type acyltransferase (trans-AT) ORFs along with KS-AT adaptor regions (ATd) within the polyketide synthase (PKS) megasynthases, suggest that the phormidolide gene cluster is a trans-AT PKS. Insights gained from analysis of the mode of acetate incorporation and ensuing keto reduction prompted our reevaluation of the stereochemistry of phormidolide hydroxy groups located along the linear polyketide chain.

Published
2016

31. Fungal-derived brevianamide assembly by a stereoselective semipinacolase

Author

Ye, Ying, Du, Lei, Zhang, Xingwang, Newmister, Sean A., McCauley, Morgan, Alegre-Requena, Juan V., Zhang, Wei, Mu, Shuai, Minami, Atsushi, Fraley, Amy E., Adrover-Castellano, Maria L., Carney, Nolan A., Shende, Vikram V., Qi, Feifei, Oikawa, Hideaki, Kato, Hikaru, Tsukamoto, Sachiko, Paton, Robert S., Williams, Robert M., Sherman, David H., and Li, Shengying

Published
2020
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33. Synthesis of a Truncated Microcystin Tetrapeptide Molecule from a Partial Mcy Gene Cluster in Microcystis Cultures and Blooms

Author

Yancey, Colleen E., Hart, Lauren, Lad, Apurva Chandrakant, Birbeck, Johnna A., Song, Siliang, Mohamed, Osama G., Fribley, Andrew M., Haller, Steven T., Tripathi, Ashootosh, Kennedy, David J., Westrick, Judy A., Sherman, David H., and Dick, Gregory J.

Abstract

Microcystisspp. threaten freshwater ecosystems through the proliferation of cyanobacterial harmful algal blooms (cyanoHABs) and production of the hepatotoxin, microcystin. While microcystin and its biosynthesis pathway, encoded by the mcygenes, have been well studied for over 50 years, a recent study found that Microcystispopulations in western Lake Erie contain a transcriptionally active partial mcyoperon, in which the A2 domain of mcyAand mcyB-Care present but the mcyD-Jgenes are absent. Here, we investigate the potential biosynthetic products and the evolutionary history of this partial operon. Our results reveal two candidate tetrapeptide constructs, with an X variable position, to be produced by strains with the partial operon. The partial operon appears necessary and sufficient for tetrapeptide biosynthesis and likely evolved from a single ancestor hundreds to tens of thousands of years ago. Bioactivity screens using Hep3B cells indicate a mild elevation of some markers of hepatotoxicity and inflammation, suggesting the need to further assess the effects of these novel secondary metabolites on freshwater ecosystems and public health. The need to assess these effects is even more pressing given the detection of tetrapeptides in both culture and western Lake Erie, which is a vital source of fresh water. Results from this study emphasize previous findings in which novel bacterial secondary metabolites may be derived from the molecular evolution of existing biosynthetic machinery under different environmental forcings.

Published
2024
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34. Directing Group-Controlled Regioselectivity in an Enzymatic C–H Bond Oxygenation

Author

Negretti, Solymar, Narayan, Alison RH, Chiou, Karoline C, Kells, Petrea M, Stachowski, Jessica L, Hansen, Douglas A, Podust, Larissa M, Montgomery, John, and Sherman, David H

Subjects
Medicinal and Biomolecular Chemistry, Organic Chemistry, Chemical Sciences, Biotechnology, Amino Sugars, Biocatalysis, Cytochrome P-450 Enzyme System, Hydroxylation, Macrolides, Models, Molecular, Stereoisomerism, Substrate Specificity, General Chemistry, Chemical sciences, Engineering
Abstract

Highly regioselective remote hydroxylation of a natural product scaffold is demonstrated by exploiting the anchoring mechanism of the biosynthetic P450 monooxygenase PikCD50N-RhFRED. Previous studies have revealed structural and biochemical evidence for the role of a salt bridge between the desosamine N,N-dimethylamino functionality of the natural substrate YC-17 and carboxylate residues within the active site of the enzyme, and selectivity in subsequent C-H bond functionalization. In the present study, a substrate-engineering approach was conducted that involves replacing desosamine with varied synthetic N,N-dimethylamino anchoring groups. We then determined their ability to mediate enzymatic total turnover numbers approaching or exceeding that of the natural sugar, while enabling ready introduction and removal of these amino anchoring groups from the substrate. The data establish that the size, stereochemistry, and rigidity of the anchoring group influence the regioselectivity of enzymatic hydroxylation. The natural anchoring group desosamine affords a 1:1 mixture of regioisomers, while synthetic anchors shift YC-17 analogue C-10/C-12 hydroxylation from 20:1 to 1:4. The work demonstrates the utility of substrate engineering as an orthogonal approach to protein engineering for modulation of regioselective C-H functionalization in biocatalysis.

Published
2014

35. High‐Throughput Screen of Natural Product Extracts in A Yeast Model of Polyglutamine Proteotoxicity

Author

Walter, Gladis M, Raveh, Avi, Mok, Sue‐Ann, McQuade, Thomas J, Arevang, Carl J, Schultz, Pamela J, Smith, Matthew C, Asare, Samuel, Cruz, Patricia G, Wisen, Susanne, Matainaho, Teatulohi, Sherman, David H, and Gestwicki, Jason E

Subjects
Rare Diseases, Huntington's Disease, Brain Disorders, Neurodegenerative, Neurosciences, Neurological, Animals, Biological Products, Dactinomycin, Gene Expression Regulation, High-Throughput Screening Assays, Humans, Models, Biological, PC12 Cells, Peptides, Protein Aggregation, Pathological, Rats, Saccharomyces cerevisiae, heat shock protein 70, high throughput screening, Huntington's disease, molecular chaperones, Biochemistry and Cell Biology, Biophysics, Medicinal & Biomolecular Chemistry
Abstract

Proteins with expanded polyglutamine (polyQ) segments cause a number of fatal neurodegenerative disorders, including Huntington's disease (HD). Previous high-throughput screens in cellular and biochemical models of HD have revealed compounds that mitigate polyQ aggregation and proteotoxicity, providing insight into the mechanisms of disease and leads for potential therapeutics. However, the structural diversity of natural products has not yet been fully mobilized toward these goals. Here, we have screened a collection of ~11 000 natural product extracts for the ability to recover the slow growth of ΔProQ103-expressing yeast cells in 384-well plates (Z' ~ 0.7, CV ~ 8%). This screen identified actinomycin D as a strong inhibitor of polyQ aggregation and proteotoxicity at nanomolar concentrations (~50-500 ng/mL). We found that a low dose of actinomycin D increased the levels of the heat-shock proteins Hsp104, Hsp70 and Hsp26 and enhanced binding of Hsp70 to the polyQ in yeast. Actinomycin also suppressed aggregation of polyQ in mammalian cells, suggesting a conserved mechanism. These results establish natural products as a rich source of compounds with interesting mechanisms of action against polyQ disorders.

Published
2014

40. Characterization of cyanobacterial hydrocarbon composition and distribution of biosynthetic pathways.

Author

Coates, R Cameron, Podell, Sheila, Korobeynikov, Anton, Lapidus, Alla, Pevzner, Pavel, Sherman, David H, Allen, Eric E, Gerwick, Lena, and Gerwick, William H

Subjects
Cyanobacteria, Hydrocarbons, Aldehyde Oxidoreductases, Fatty Acids, Bayes Theorem, Computational Biology, Phylogeny, Species Specificity, Models, Genetic, Gas Chromatography-Mass Spectrometry, Biosynthetic Pathways, Models, Genetic, General Science & Technology
Abstract

Cyanobacteria possess the unique capacity to naturally produce hydrocarbons from fatty acids. Hydrocarbon compositions of thirty-two strains of cyanobacteria were characterized to reveal novel structural features and insights into hydrocarbon biosynthesis in cyanobacteria. This investigation revealed new double bond (2- and 3-heptadecene) and methyl group positions (3-, 4- and 5-methylheptadecane) for a variety of strains. Additionally, results from this study and literature reports indicate that hydrocarbon production is a universal phenomenon in cyanobacteria. All cyanobacteria possess the capacity to produce hydrocarbons from fatty acids yet not all accomplish this through the same metabolic pathway. One pathway comprises a two-step conversion of fatty acids first to fatty aldehydes and then alkanes that involves a fatty acyl ACP reductase (FAAR) and aldehyde deformylating oxygenase (ADO). The second involves a polyketide synthase (PKS) pathway that first elongates the acyl chain followed by decarboxylation to produce a terminal alkene (olefin synthase, OLS). Sixty-one strains possessing the FAAR/ADO pathway and twelve strains possessing the OLS pathway were newly identified through bioinformatic analyses. Strains possessing the OLS pathway formed a cohesive phylogenetic clade with the exception of three Moorea strains and Leptolyngbya sp. PCC 6406 which may have acquired the OLS pathway via horizontal gene transfer. Hydrocarbon pathways were identified in one-hundred-forty-two strains of cyanobacteria over a broad phylogenetic range and there were no instances where both the FAAR/ADO and the OLS pathways were found together in the same genome, suggesting an unknown selective pressure maintains one or the other pathway, but not both.

Published
2014

44. Structure–Activity Relationships of Natural and Semisynthetic Plecomacrolides Suggest Distinct Pathways for HIV‑1 Immune Evasion and Vacuolar ATPase-Dependent Lysosomal Acidification.

Author

McCauley, Morgan, Huston, Matthew, Condren, Alanna R., Pereira, Filipa, Cline, Joel, Yaple-Maresh, Marianne, Painter, Mark M., Zimmerman, Gretchen E., Robertson, Andrew W., Carney, Nolan, Goodall, Christopher, Terry, Valeri, Müller, Rolf, Sherman, David H., and Collins, Kathleen L.

Published
2024
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50. N-to-SAcyl Transfer as an Enabling Strategy in Asymmetric and Chemoenzymatic Synthesis

Author

Jo, Woonkee S., Curtis, Brian J., Rehan, Mohammad, Adrover-Castellano, Maria L., Sherman, David H., and Healy, Alan R.

Abstract

The observation of thioester-mediated acyl transfer processes in nature has inspired the development of novel protein synthesis and functionalization methodologies. The chemoselective transfer of an acyl group from S-to-Nis the basis of several powerful ligation strategies. In this work, we sought to apply the reverse process, the transfer of an acyl group from N-to-S, as a method to convert stable chiral amides into more reactive thioesters. To this end, we developed a novel cysteine-derived oxazolidinone that serves as both a chiral imide auxiliary and an acyl transfer agent. This auxiliary combines the desirable features of rigid chiral imides as templates for asymmetric transformations with the synthetic applicability of thioesters. We demonstrate that the auxiliary can be applied in a range of highly selective asymmetric transformations. Subsequent intramolecular N-to-Sacyl transfer of the chiral product and in situ trapping of the resulting thioester provides access to diverse carboxylic acid derivatives under mild conditions. The oxazolidinone thioester products can also be isolated and used in Pd-mediated transformations to furnish highly valuable chiral scaffolds, such as noncanonical amino acids, cyclic ketones, tetrahydropyrones, and dihydroquinolinones. Finally, we demonstrate that the oxazolidinone thioesters can also serve as a surrogate for SNAC-thioesters, enabling their seamless use as non-native substrates in biocatalytic transformations.

Published
2024
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