Your search keyword '"Lance, Bigelow"' showing total 10 results

1. 3D domain swapping in the TIM barrel of the α subunit ofStreptococcus pneumoniaetryptophan synthase

Author

Marcin Kowiel, Lance Bigelow, Matthias Endres, Andrzej Joachimiak, Miroslaw Gilski, Mariusz Jaskolski, and Karolina Michalska

Subjects

Protein Folding, animal structures, Stereochemistry, Dimer, Allosteric regulation, Population, protein oligomerization, Tryptophan synthase, Catalysis, chemistry.chemical_compound, Allosteric Regulation, Protein Domains, Structural Biology, Catalytic Domain, TIM barrel, Tryptophan Synthase, Protein oligomerization, TRPA, education, 3D domain swapping, education.field_of_study, Molecular Structure, biology, Chemistry, Research Papers, Heterotetramer, Streptococcus pneumoniae, biology.protein, Protein Multimerization

Abstract

The structure of Streptococcus pneumoniae TrpA, which is the α subunit of tryptophan synthase, reveals 3D domain swapping, which has never before been observed for a TIM-barrel protein., Tryptophan synthase catalyzes the last two steps of tryptophan biosynthesis in plants, fungi and bacteria. It consists of two protein chains, designated α and β, encoded by trpA and trpB genes, that function as an αββα complex. Structural and functional features of tryptophan synthase have been extensively studied, explaining the roles of individual residues in the two active sites in catalysis and allosteric regulation. TrpA serves as a model for protein-folding studies. In 1969, Jackson and Yanofsky observed that the typically monomeric TrpA forms a small population of dimers. Dimerization was postulated to take place through an exchange of structural elements of the monomeric chains, a phenomenon later termed 3D domain swapping. The structural details of the TrpA dimer have remained unknown. Here, the crystal structure of the Streptococcus pneumoniae TrpA homodimer is reported, demonstrating 3D domain swapping in a TIM-barrel fold for the first time. The N-terminal domain comprising the H0–S1–H1–S2 elements is exchanged, while the hinge region corresponds to loop L2 linking strand S2 to helix H2′. The structural elements S2 and L2 carry the catalytic residues Glu52 and Asp63. As the S2 element is part of the swapped domain, the architecture of the catalytic apparatus in the dimer is recreated from two protein chains. The homodimer interface overlaps with the α–β interface of the tryptophan synthase αββα heterotetramer, suggesting that the 3D domain-swapped dimer cannot form a complex with the β subunit. In the crystal, the dimers assemble into a decamer comprising two pentameric rings.

Published

2020

2. Conservation of the structure and function of bacterial tryptophan synthases

Author

Grazyna Joachimiak, Boguslaw Nocek, Lance Bigelow, Besnik Bajrami, Robert Jedrzejczak, Matthias Endres, Samantha Wellington, Stephen Johnston, Karolina Michalska, Stewart L. Fisher, Catherine Hatzos-Skintges, Deborah T. Hung, Changsoo Chang, Partha P. Nag, Andrzej Joachimiak, and Jennifer P. Gale

Subjects

crystal structure, enzyme inhibitors, Tryptophan synthase, medicine.disease_cause, Biochemistry, Legionella pneumophila, drug discovery, 03 medical and health sciences, enzyme mechanisms, medicine, General Materials Science, tryptophan, tryptophan synthase, protein structure, Francisella tularensis, Escherichia coli, 030304 developmental biology, X-ray crystallography, Indole test, 0303 health sciences, Crystallography, biology, catalysis, Chemistry, 030302 biochemistry & molecular biology, Tryptophan, Pathogenic bacteria, General Chemistry, Condensed Matter Physics, biology.organism_classification, Research Papers, allosteric regulation, structure determination, Streptococcus pneumoniae, QD901-999, biology.protein, molecular recognition, Bacteria

Abstract

The tryptophan synthases from three human pathogens show remarkable structural conservation, but at the same time display local differences in both their catalytic and allosteric sites that may be responsible for the observed differences in catalysis and inhibitor binding. This functional dissimilarity may be exploited in the design of species-specific enzyme inhibitors., Tryptophan biosynthesis is one of the most characterized processes in bacteria, in which the enzymes from Salmonella typhimurium and Escherichia coli serve as model systems. Tryptophan synthase (TrpAB) catalyzes the final two steps of tryptophan biosynthesis in plants, fungi and bacteria. This pyridoxal 5′-phosphate (PLP)-dependent enzyme consists of two protein chains, α (TrpA) and β (TrpB), functioning as a linear αββα heterotetrameric complex containing two TrpAB units. The reaction has a complicated, multistep mechanism resulting in the β-replacement of the hydroxyl group of l-serine with an indole moiety. Recent studies have shown that functional TrpAB is required for the survival of pathogenic bacteria in macrophages and for evading host defense. Therefore, TrpAB is a promising target for drug discovery, as its orthologs include enzymes from the important human pathogens Streptococcus pneumoniae, Legionella pneumophila and Francisella tularensis, the causative agents of pneumonia, legionnaires’ disease and tularemia, respectively. However, specific biochemical and structural properties of the TrpABs from these organisms have not been investigated. To fill the important phylogenetic gaps in the understanding of TrpABs and to uncover unique features of TrpAB orthologs to spearhead future drug-discovery efforts, the TrpABs from L. pneumophila, F. tularensis and S. pneumoniae have been characterized. In addition to kinetic properties and inhibitor-sensitivity data, structural information gathered using X-ray crystallo­graphy is presented. The enzymes show remarkable structural conservation, but at the same time display local differences in both their catalytic and allosteric sites that may be responsible for the observed differences in catalysis and inhibitor binding. This functional dissimilarity may be exploited in the design of species-specific enzyme inhibitors.

Published

2019

3. Structure of Calcarisporiella thermophila Hsp104 disaggregase that antagonizes diverse proteotoxic misfolding events

Author

Meredith E. Jackrel, Lance Bigelow, Grigore D. Pintilie, Wah Chiu, Karolina Michalska, Edward Chuang, Zachary M. March, Catherine Hatzos-Skintges, Leann Miles, Laura M. Castellano, Kaiming Zhang, James Shorter, Andrzej Joachimiak, and Robert Jedrzejczak

Subjects

Models, Molecular, Protein Conformation, alpha-Helical, Saccharomyces cerevisiae, Computational biology, Crystallography, X-Ray, Article, Fungal Proteins, 03 medical and health sciences, Protein structure, Structural Biology, Humans, Calcarisporiella, Proteostasis Deficiencies, Molecular Biology, 030304 developmental biology, Adenosine Triphosphatases, 0303 health sciences, biology, Extramural, Thermophile, 030302 biochemistry & molecular biology, Cryoelectron Microscopy, biology.organism_classification, DNA-Binding Proteins, Chaperone (protein), biology.protein, Mucorales, alpha-Synuclein, CLPB, Peptides

Abstract

Summary Hsp104 is an AAA+ protein disaggregase with powerful amyloid-remodeling activity. All nonmetazoan eukaryotes express Hsp104 while eubacteria express an Hsp104 ortholog, ClpB. However, most studies have focused on Hsp104 from Saccharomyces cerevisiae and ClpB orthologs from two eubacterial species. Thus, the natural spectrum of Hsp104/ClpB molecular architectures and protein-remodeling activities remains largely unexplored. Here, we report two structures of Hsp104 from the thermophilic fungus Calcarisporiella thermophila (CtHsp104), a 2.70A crystal structure and 4.0A cryo-electron microscopy structure. Both structures reveal left-handed, helical assemblies with all domains clearly resolved. We thus provide the highest resolution and most complete view of Hsp104 hexamers to date. We also establish that CtHsp104 antagonizes several toxic protein-misfolding events in vivo where S. cerevisiae Hsp104 is ineffective, including rescue of TDP-43, polyglutamine, and α-synuclein toxicity. We suggest that natural Hsp104 variation is an invaluable, untapped resource for illuminating therapeutic disaggregases for fatal neurodegenerative diseases.

Published

2018

4. Crystal Structures of SgcE6 and SgcC, the Two-Component Monooxygenase That Catalyzes Hydroxylation of a Carrier Protein-Tethered Substrate during the Biosynthesis of the Enediyne Antitumor Antibiotic C-1027 in Streptomyces globisporus

Author

Ragothaman M. Yennamalli, Craig A. Bingman, Ben Shen, Jeremy R. Lohman, Kemin Tan, Hongnan Cao, Lance Bigelow, George N. Phillips, Gyorgy Babnigg, Jeffrey D. Rudolf, Chin-Yuan Chang, Ming Ma, Andrzej Joachimiak, Weijun Xu, and Xiaohui Yan

Subjects

0301 basic medicine, Streptomyces globisporus, Stereochemistry, Flavin group, Crystallography, X-Ray, Hydroxylation, Biochemistry, Streptomyces, Article, Catalysis, 03 medical and health sciences, Sarcoglycans, Enediyne, Moiety, Humans, 030102 biochemistry & molecular biology, biology, Chemistry, Active site, Monooxygenase, biology.organism_classification, Anti-Bacterial Agents, 030104 developmental biology, Aminoglycosides, FAD binding, biology.protein, Enediynes

Abstract

C-1027 is a chromoprotein enediyne antitumor antibiotic produced by Streptomyces globisporus. In the last step of biosynthesis of the (S)-3-chloro-5-hydroxy-β-tyrosine moiety of the C-1027 enediyne chromophore, SgcE6 and SgcC compose a two-component monooxygenase that hydroxylates the C-5 position of (S)-3-chloro-β-tyrosine. This two-component monooxygenase is remarkable for two reasons. (i) SgcE6 specifically reacts with FAD and NADH, and (ii) SgcC is active with only the peptidyl carrier protein (PCP)-tethered substrate. To address the molecular details of substrate specificity, we determined the crystal structures of SgcE6 and SgcC at 1.66 and 2.63 Å resolution, respectively. SgcE6 shares a similar β-barrel fold with the class I HpaC-like flavin reductases. A flexible loop near the active site of SgcE6 plays a role in FAD binding, likely by providing sufficient space to accommodate the AMP moiety of FAD, when compared to that of FMN-utilizing homologues. SgcC shows structural similarity to a few other known FADH2-dependent monooxygenases and sheds light on some biochemically but not structurally characterized homologues. The crystal structures reported here provide insights into substrate specificity, and comparison with homologues provides a catalytic mechanism of the two-component, FADH2-dependent monooxygenase (SgcE6 and SgcC) that catalyzes the hydroxylation of a PCP-tethered substrate.

Published

2016

5. Structural characterization of AtmS13, a putative sugar aminotransferase involved in indolocarbazole AT2433 aminopentose biosynthesis

Author

Jon S. Thorson, Craig A. Bingman, George N. Phillips, Fengbin Wang, Matthias Endres, Lance Bigelow, Youngchang Kim, Andrzej Joachimiak, Shanteri Singh, Madan K. Kharel, and Gyorgy Babnigg

Subjects

chemistry.chemical_classification, biology, Chemistry, Stereochemistry, Disaccharide, Active site, Pentose, Carbohydrate, Indolocarbazole, Biochemistry, chemistry.chemical_compound, Biosynthesis, Structural Biology, biology.protein, Transferase, Sugar, Molecular Biology

Abstract

AT2433 from Actinomadura melliaura is an indolocarbazole antitumor antibiotic structurally distinguished by its unique aminodideoxypentose-containing disaccharide moiety. The corresponding sugar nucleotide-based biosynthetic pathway for this unusual sugar derives from comparative genomics where AtmS13 has been suggested as the contributing sugar aminotransferase (SAT). Determination of the AtmS13 X-ray structure at 1.50-A resolution reveals it as a member of the aspartate aminotransferase fold type I (AAT-I). Structural comparisons of AtmS13 with homologous SATs that act upon similar substrates implicate potential active site residues that contribute to distinctions in sugar C5 (hexose vs. pentose) and/or sugar C2 (deoxy vs. hydroxyl) substrate specificity.

Published

2015

6. The crystal structure of BlmI as a model for nonribosomal peptide synthetase peptidyl carrier proteins

Author

George N. Phillips, Jessica Bearden, Ben Shen, Ming Ma, Andrzej Joachimiak, Marianne E. Cuff, Lance Bigelow, Jeremy R. Lohman, and Gyorgy Babnigg

Subjects

chemistry.chemical_classification, ved/biology, ved/biology.organism_classification_rank.species, Context (language use), Biology, Biochemistry, Protein–protein interaction, Structural genomics, Protein structure, chemistry, Structural Biology, Nonribosomal peptide, Streptomyces verticillus, Polyketide synthase, biology.protein, Molecular Biology, Peptide sequence

Abstract

Carrier proteins (CPs) play a critical role in the biosynthesis of various natural products, especially in nonribosomal peptide synthetase (NRPS) and polyketide synthase (PKS) enzymology, where the CPs are referred to as peptidyl-carrier proteins (PCPs) or acyl-carrier proteins (ACPs), respectively. CPs can either be a domain in large multifunctional polypeptides or standalone proteins, termed Type I and Type II, respectively. There have been many biochemical studies of the Type I PKS and NRPS CPs, and of Type II ACPs. However, recently a number of Type II PCPs have been found and biochemically characterized. In order to understand the possible interaction surfaces for combinatorial biosynthetic efforts we crystallized the first characterized and representative Type II PCP member, BlmI, from the bleomycin biosynthetic pathway from Streptomyces verticillus ATCC 15003. The structure is similar to CPs in general but most closely resembles PCPs. Comparisons with previously determined PCP structures in complex with catalytic domains reveals a common interaction surface. This surface is highly variable in charge and shape, which likely confers specificity for interactions. Previous nuclear magnetic resonance (NMR) analysis of a prototypical Type I PCP excised from the multimodular context revealed three conformational states. Comparison of the states with the structure of BlmI and other PCPs reveals that only one of the NMR states is found in other studies, suggesting the other two states may not be relevant. The state represented by the BlmI crystal structure can therefore serve as a model for both Type I and Type II PCPs.

Published

2013

7. Crystal structure of SgcJ, an NTF2-like superfamily protein involved in biosynthesis of the nine-membered enediyne antitumor antibiotic C-1027

Author

Ragothaman M. Yennamalli, Xiaohui Yan, Lance Bigelow, Gyorgy Babnigg, S. Clancy, Ivana Crnovcic, Chin-Yuan Chang, Craig A. Bingman, Ming Ma, Andrzej Joachimiak, Tingting Huang, Ben Shen, Changsoo Chang, George N. Phillips, Dong Yang, Youngchang Kim, Jeffrey D. Rudolf, and Jeremy R. Lohman

Subjects

0301 basic medicine, DNA, Bacterial, Streptomyces globisporus, Stereochemistry, Polyenes, C-1027, Streptomyces, Article, Structural genomics, 03 medical and health sciences, Polyketide, Protein structure, Bacterial Proteins, Drug Discovery, Enediyne, Amino Acid Sequence, Peptide sequence, nuclear transport factor 2-like superfamily, Pharmacology, Antibiotics, Antineoplastic, biology, Active site, neocarzinostatin, biology.organism_classification, Protein Structure, Tertiary, 030104 developmental biology, Aminoglycosides, Biochemistry, biology.protein, enediyne, Enediynes, biosynthesis, Polyketide Synthases

Abstract

Comparative analysis of the enediyne biosynthetic gene clusters revealed sets of conserved genes serving as outstanding candidates for the enediyne core. Here we report the crystal structures of SgcJ and its homologue NCS-Orf16, together with gene inactivation and site-directed mutagenesis studies, to gain insight into enediyne core biosynthesis. Gene inactivation in vivo establishes that SgcJ is required for C-1027 production in Streptomyces globisporus. SgcJ and NCS-Orf16 share a common structure with the nuclear transport factor 2-like superfamily of proteins, featuring a putative substrate binding or catalytic active site. Site-directed mutagenesis of the conserved residues lining this site allowed us to propose that SgcJ and its homologues may play a catalytic role in transforming the linear polyene intermediate, along with other enediyne polyketide synthase-associated enzymes, into an enzyme-sequestered enediyne core intermediate. These findings will help formulate hypotheses and design experiments to ascertain the function of SgcJ and its homologues in nine-membered enediyne core biosynthesis.

Published

2016

8. Interaction of J-Protein Co-Chaperone Jac1 with Fe–S Scaffold Isu Is Indispensable In Vivo and Conserved in Evolution

Author

Rafal Dutkiewicz, Jerzy Osipiuk, Rory Mulligan, Brenda Schilke, Szymon J. Ciesielski, Andrzej Joachimiak, Jaroslaw Marszalek, Julia Majewska, Lance Bigelow, and Elizabeth A. Craig

Subjects

Iron-Sulfur Proteins, Models, Molecular, Scaffold protein, Saccharomyces cerevisiae Proteins, Saccharomyces cerevisiae, Plasma protein binding, yeast, Mitochondrion, medicine.disease_cause, Article, Evolution, Molecular, Mitochondrial Proteins, Structural Biology, medicine, HSP70 Heat-Shock Proteins, Fe–S cluster biogenesis, Escherichia coli, Molecular Biology, biology, Jac1/HscB, biology.organism_classification, mitochondria, Co-chaperone, Biochemistry, Chaperone (protein), biology.protein, Isu/IscU, Biogenesis, Molecular Chaperones, Protein Binding

Abstract

The ubiquitous mitochondrial J-protein Jac1, called HscB in Escherichia coli, and its partner Hsp70 play a critical role in the transfer of Fe–S clusters from the scaffold protein Isu to recipient proteins. Biochemical results from eukaryotic and prokaryotic systems indicate that formation of the Jac1–Isu complex is important for both targeting of the Isu for Hsp70 binding and stimulation of Hsp70's ATPase activity. However, in apparent contradiction, we previously reported that an 8-fold decrease in Jac1's affinity for Isu1 is well tolerated in vivo, raising the question as to whether the Jac1:Isu interaction actually plays an important biological role. Here, we report the determination of the structure of Jac1 from Saccharomyces cerevisiae. Taking advantage of this information and recently published data from the homologous bacterial system, we determined that a total of eight surface-exposed residues play a role in Isu binding, as assessed by a set of biochemical assays. A variant having alanines substituted for these eight residues was unable to support growth of a jac1-Δ strain. However, replacement of three residues caused partial loss of function, resulting in a significant decrease in the Jac1:Isu1 interaction, a slow growth phenotype, and a reduction in the activity of Fe–S cluster-containing enzymes. Thus, we conclude that the Jac1:Isu1 interaction plays an indispensable role in the essential process of mitochondrial Fe–S cluster biogenesis.

Published

2012

9. Structural Characterization of CalS8, a TDP-α-D-Glucose Dehydrogenase Involved in Calicheamicin Aminodideoxypentose Biosynthesis

Author

Matthias Endres, Andrzej Joachimiak, Karolina Michalska, Jon S. Thorson, Craig A. Bingman, George N. Phillips, Shanteri Singh, Madan K. Kharel, Gyorgy Babnigg, Lance Bigelow, and Ragothaman M. Yennamalli

Subjects

Models, Molecular, Stereochemistry, Protein Conformation, Molecular Sequence Data, Pentoses, Biology, Crystallography, X-Ray, Biochemistry, Cofactor, chemistry.chemical_compound, Protein structure, Biosynthesis, Oxidoreductase, Calicheamicin, Amino Acid Sequence, Secondary metabolism, Molecular Biology, Peptide sequence, Ternary complex, chemistry.chemical_classification, Sequence Homology, Amino Acid, Glucose 1-Dehydrogenase, Cell Biology, carbohydrates (lipids), Kinetics, chemistry, Carbohydrate Sequence, biology.protein, Enzymology

Abstract

Classical UDP-glucose 6-dehydrogenases (UGDH; EC 1.1.1.22) catalyze the conversion of UDP-α-D-glucose (UDP-Glc) to the key metabolic precursor UDP-alpha-D-glucuronic acid (UDP-GlcA) and display specificity for UDP-Glc. The fundamental biochemical and structural study of the UGDH homolog CalS8 encoded by the calicheamicin biosynthetic gene is reported and represents one of the first studies of a UGDH homolog involved in secondary metabolism. The corresponding biochemical characterization of CalS8 reveals CalS8 as one of the first characterized base permissive UGDH homologs with a >15-fold preference for TDP-Glc over UDP-Glc. The corresponding structure elucidation of apo-CalS8 and the CalS8/substrate/cofactor ternary complex (at 2.47 angstrom and 1.95 angstrom resolution, respectively) highlight a notably high degree of conservation between CalS8 and classical UGDHs where structural divergence within the intersubunit loop structure likely contributes to the CalS8 base permissivity. As such, this study begins to provide a putative blueprint for base specificity among sugar nucleotide-dependent dehydrogenases and, in conjunction with prior studies on the base specificity of the calicheamicin aminopentosyltransferase CalG4, provides growing support for the calicheamicin aminopentose pathway as a TDP-sugar-dependent process.

Published

2015

10. Three‐dimensional Domain Swapping in the α Subunit of Tryptophan Synthase

Author

Lance Bigelow, Matthias Endres, Karolina Michalska, and Andrzej Joachimiak

Subjects

chemistry.chemical_classification, Α subunit, biology, fungi, Tryptophan synthase, biology.organism_classification, Biochemistry, Enzyme, chemistry, Domain (ring theory), Genetics, biology.protein, TRPA, Tryptophan synthesis, Molecular Biology, Gene, Bacteria, Biotechnology

Abstract

Tryptophan synthase is an enzyme participating in the last two steps of tryptophan synthesis in plants, fungi and bacteria. It consists of two protein chains, α and β, encoded by trpA and trpB gene...

Published

2015