Your search keyword '"Bowman ME"' showing total 7 results

1. Biosynthesis of Dictyostelium discoideum differentiation-inducing factor by a hybrid type I fatty acid-type III polyketide synthase.

Author

Austin MB, Saito T, Bowman ME, Haydock S, Kato A, Moore BS, Kay RR, and Noel JP

Subjects

Acyltransferases chemistry, Acyltransferases genetics, Amino Acid Sequence, Animals, Catalytic Domain, Cloning, Molecular, Crystallography, X-Ray, Dimerization, Fatty Acid Synthases chemistry, Fatty Acid Synthases genetics, Hexanones chemistry, Hydrocarbons, Chlorinated chemistry, Models, Molecular, Molecular Sequence Data, Mutation, Protein Conformation, Protozoan Proteins chemistry, Protozoan Proteins genetics, Sequence Homology, Amino Acid, Acyltransferases metabolism, Dictyostelium enzymology, Dictyostelium genetics, Dictyostelium growth & development, Dictyostelium metabolism, Fatty Acid Synthases metabolism, Hexanones metabolism, Hydrocarbons, Chlorinated metabolism, Protozoan Proteins metabolism

Abstract

Differentiation-inducing factors (DIFs) are well known to modulate formation of distinct communal cell types from identical Dictyostelium discoideum amoebas, but DIF biosynthesis remains obscure. We report complimentary in vivo and in vitro experiments identifying one of two approximately 3,000-residue D. discoideum proteins, termed 'steely', as responsible for biosynthesis of the DIF acylphloroglucinol scaffold. Steely proteins possess six catalytic domains homologous to metazoan type I fatty acid synthases (FASs) but feature an iterative type III polyketide synthase (PKS) in place of the expected FAS C-terminal thioesterase used to off load fatty acid products. This new domain arrangement likely facilitates covalent transfer of steely N-terminal acyl products directly to the C-terminal type III PKS active sites, which catalyze both iterative polyketide extension and cyclization. The crystal structure of a steely C-terminal domain confirms conservation of the homodimeric type III PKS fold. These findings suggest new bioengineering strategies for expanding the scope of fatty acid and polyketide biosynthesis.

Published

2006

2. Crystal structure of a bacterial type III polyketide synthase and enzymatic control of reactive polyketide intermediates.

Author

Austin MB, Izumikawa M, Bowman ME, Udwary DW, Ferrer JL, Moore BS, and Noel JP

Subjects

Acyltransferases metabolism, Asparagine chemistry, Aspartic Acid chemistry, Binding Sites, Catalysis, Catalytic Domain, Chromatography, High Pressure Liquid, Chromatography, Thin Layer, Codon, Crystallography, X-Ray, Cysteine chemistry, Escherichia coli metabolism, Evolution, Molecular, Hydrogen-Ion Concentration, Magnetic Resonance Spectroscopy, Models, Chemical, Models, Molecular, Mutagenesis, Site-Directed, Mutation, Naphthols chemistry, Naphthoquinones chemistry, Oxalic Acid chemistry, Polyketide Synthases chemistry, Protein Conformation, Protein Structure, Tertiary, Serine chemistry, Streptomyces metabolism, Streptomyces coelicolor metabolism, Acyltransferases chemistry, Streptomyces coelicolor enzymology

Abstract

In bacteria, a structurally simple type III polyketide synthase (PKS) known as 1,3,6,8-tetrahydroxynaphthlene synthase (THNS) catalyzes the iterative condensation of five CoA-linked malonyl units to form a pentaketide intermediate. THNS subsequently catalyzes dual intramolecular Claisen and aldol condensations of this linear intermediate to produce the fused ring tetrahydroxynaphthalene (THN) skeleton. The type III PKS-catalyzed polyketide extension mechanism, utilizing a conserved Cys-His-Asn catalytic triad in an internal active site cavity, is fairly well understood. However, the mechanistic basis for the unusual production of THN and dual cyclization of its malonyl-primed pentaketide is obscure. Here we present the first bacterial type III PKS crystal structure, that of Streptomyces coelicolor THNS, and identify by mutagenesis, structural modeling, and chemical analysis the unexpected catalytic participation of an additional THNS-conserved cysteine residue in facilitating malonyl-primed polyketide extension beyond the triketide stage. The resulting new mechanistic model, involving the use of additional cysteines to alter and steer polyketide reactivity, may generally apply to other PKS reaction mechanisms, including those catalyzed by iterative type I and II PKS enzymes. Our crystal structure also reveals an unanticipated novel cavity extending into the "floor" of the traditional active site cavity, providing the first plausible structural and mechanistic explanation for yet another unusual THNS catalytic activity: its previously inexplicable extra polyketide extension step when primed with a long acyl starter. This tunnel allows for selective expansion of available active site cavity volume by sequestration of aliphatic starter-derived polyketide tails, and further suggests another distinct protection mechanism involving maintenance of a linear polyketide conformation.

Published

2004

3. An aldol switch discovered in stilbene synthases mediates cyclization specificity of type III polyketide synthases.

Author

Austin MB, Bowman ME, Ferrer JL, Schröder J, and Noel JP

Subjects

Acyltransferases chemistry, Acyltransferases genetics, Amino Acid Sequence, Crystallography, X-Ray, Cyclization, Models, Molecular, Molecular Sequence Data, Mutagenesis, Site-Directed, Resveratrol, Stilbenes metabolism, Substrate Specificity, Acyltransferases metabolism

Abstract

Stilbene synthase (STS) and chalcone synthase (CHS) each catalyze the formation of a tetraketide intermediate from a CoA-tethered phenylpropanoid starter and three molecules of malonyl-CoA, but use different cyclization mechanisms to produce distinct chemical scaffolds for a variety of plant natural products. Here we present the first STS crystal structure and identify, by mutagenic conversion of alfalfa CHS into a functional stilbene synthase, the structural basis for the evolution of STS cyclization specificity in type III polyketide synthase (PKS) enzymes. Additional mutagenesis and enzymatic characterization confirms that electronic effects rather than steric factors balance competing cyclization specificities in CHS and STS. Finally, we discuss the problematic in vitro reconstitution of plant stilbenecarboxylate pathways, using insights from existing biomimetic polyketide cyclization studies to generate a novel mechanistic hypothesis to explain stilbenecarboxylate biosynthesis.

Published

2004

4. Expanding the biosynthetic repertoire of plant type III polyketide synthases by altering starter molecule specificity.

Author

Jez JM, Bowman ME, and Noel JP

Subjects

Acetic Acid chemistry, Aniline Compounds chemistry, Binding Sites, Chromatography, Thin Layer, Crystallography, X-Ray, Gas Chromatography-Mass Spectrometry, Kinetics, Malonyl Coenzyme A chemistry, Models, Chemical, Models, Molecular, Mutagenesis, Site-Directed, Mutation, Phenylalanine chemistry, Protein Binding, Protein Conformation, Pyrones chemistry, Serine chemistry, Acyltransferases chemistry, Alkaloids chemistry, Multienzyme Complexes chemistry

Abstract

Type III polyketide synthases (PKS) generate an array of natural products by condensing multiple acetyl units derived from malonyl-CoA to thioester-linked starter molecules covalently bound in the PKS active site. One strategy adopted by Nature for increasing the functional diversity of these biosynthetic enzymes involves modifying polyketide assembly by altering the preference for starter molecules. Chalcone synthase (CHS) is a ubiquitous plant PKS and the first type III PKS described functionally and structurally. Guided by the three-dimensional structure of CHS, Phe-215 and Phe-265, which are situated at the active site entrance, were targeted for site-directed mutagenesis to diversify CHS activity. The resulting mutants were screened against a panel of aliphatic and aromatic CoA-linked starter molecules to evaluate the degree of starter molecule specificity in CHS. Although wild-type CHS accepts a number of natural CoA thioesters, it does not use N-methylanthraniloyl-CoA as a substrate. Substitution of Phe-215 by serine yields a CHS mutant that preferentially accepts this CoA-thioester substrate to generate a novel alkaloid, namely N-methylanthraniloyltriacetic acid lactone. These results demonstrate that a point mutation in CHS dramatically shifts the molecular selectivity of this enzyme. This structure-based approach to metabolic redesign represents an initial step toward tailoring the biosynthetic activity of plant type III PKS.

Published

2002

5. Structure-guided programming of polyketide chain-length determination in chalcone synthase.

Author

Jez JM, Bowman ME, and Noel JP

Subjects

Acyltransferases genetics, Acyltransferases metabolism, Amino Acid Sequence, Binding Sites, Coenzyme A chemistry, Coenzyme A metabolism, Crystallography, X-Ray, Estrogen Antagonists chemistry, Estrogen Antagonists metabolism, Flavonoids chemistry, Flavonoids metabolism, Models, Molecular, Molecular Sequence Data, Molecular Structure, Mutagenesis, Site-Directed, Protein Binding, Protein Structure, Tertiary, Sequence Alignment, Acyltransferases chemistry, Flavanones

Abstract

Chalcone synthase (CHS) belongs to the family of type III polyketide synthases (PKS) that catalyze formation of structurally diverse polyketides. CHS synthesizes a tetraketide by sequential condensation of three acetyl anions derived from malonyl-CoA decarboxylation to a p-coumaroyl moiety attached to an active site cysteine. Gly256 resides on the surface of the CHS active site that is in direct contact with the polyketide chain derived from malonyl-CoA. Thus, position 256 serves as an ideal target to probe the link between cavity volume and polyketide chain-length determination in type III PKS. Functional examination of CHS G256A, G256V, G256L, and G256F mutants reveals altered product profiles from that of wild-type CHS. With p-coumaroyl-CoA as a starter molecule, the G256A and G256V mutants produce notably more tetraketide lactone. Further restrictions in cavity volume such as that seen in the G256L and G256F mutants yield increasing levels of the styrylpyrone bis-noryangonin from a triketide intermediate. X-ray crystallographic structures of the CHS G256A, G256V, G256L, and G256F mutants establish that these substitutions reduce the size of the active site cavity without significant alterations in the conformations of the polypeptide backbones. The side chain volume of position 256 influences both the number of condensation reactions during polyketide chain extension and the conformation of the triketide and tetraketide intermediates during the cyclization reaction. These results viewed in conjunction with the natural sequence variation of residue 256 suggest that rapid diversification of product specificity without concomitant loss of substantial catalytic activity in related CHS-like enzymes can occur by site-specific evolution of side chain volume at position 256.

Published

2001

6. Structure and mechanism of chalcone synthase-like polyketide synthases.

Author

Jez JM, Ferrer JL, Bowman ME, Austin MB, Schröder J, Dixon RA, and Noel JP

Subjects

Acyltransferases genetics, Amino Acid Sequence, Chalcone metabolism, Medicago sativa chemistry, Medicago sativa genetics, Models, Molecular, Molecular Sequence Data, Multienzyme Complexes genetics, Rhizobium chemistry, Rhizobium genetics, Structure-Activity Relationship, Acyltransferases chemistry, Acyltransferases metabolism, Medicago sativa enzymology, Multienzyme Complexes chemistry, Multienzyme Complexes metabolism, Rhizobium enzymology

Abstract

Polyketide synthases (PKS) produce an array of natural products with different biological activities and pharmacological properties by varying the starter and extender molecules that form the final polyketide. Recent studies of the simplest PKS, the chalcone synthase (CHS)-like enzymes involved in the biosynthesis of flavonoids, anthocyanin pigments, and antimicrobial phytoalexins, have yielded insight on the molecular basis of this biosynthetic versatility. Understanding the structure-function relationship in these PKS provides a foundation for manipulating polyketide formation and suggests strategies for further increasing the scope of polyketide biosynthetic diversity.

Published

2001

7. Structure of chalcone synthase and the molecular basis of plant polyketide biosynthesis.

Author

Ferrer JL, Jez JM, Bowman ME, Dixon RA, and Noel JP

Subjects

Acyltransferases genetics, Amino Acid Sequence, Cerulenin chemistry, Chalcone chemistry, Crystallography, X-Ray, Flavonoids chemistry, Models, Molecular, Molecular Sequence Data, Mutagenesis, Protein Conformation, Resveratrol, Sequence Homology, Amino Acid, Stilbenes chemistry, Acyltransferases chemistry, Cerulenin metabolism, Chalcone metabolism, Flavanones, Flavonoids metabolism, Plants metabolism, Stilbenes metabolism

Abstract

Chalcone synthase (CHS) is pivotal for the biosynthesis of flavonoid antimicrobial phytoalexins and anthocyanin pigments in plants. It produces chalcone by condensing one p-coumaroyl- and three malonyl-coenzyme A thioesters into a polyketide reaction intermediate that cyclizes. The crystal structures of CHS alone and complexed with substrate and product analogs reveal the active site architecture that defines the sequence and chemistry of multiple decarboxylation and condensation reactions and provides a molecular understanding of the cyclization reaction leading to chalcone synthesis. The structure of CHS complexed with resveratrol also suggests how stilbene synthase, a related enzyme, uses the same substrates and an alternate cyclization pathway to form resveratrol. By using the three-dimensional structure and the large database of CHS-like sequences, we can identify proteins likely to possess novel substrate and product specificity. The structure elucidates the chemical basis of plant polyketide biosynthesis and provides a framework for engineering CHS-like enzymes to produce new products.

Published

1999