Your search keyword '"Elwood A. Mullins"' showing total 20 results

1. Structural evolution of a DNA repair self-resistance mechanism targeting genotoxic secondary metabolites

Author

Elwood A. Mullins, Jonathan Dorival, Gong-Li Tang, Dale L. Boger, and Brandt F. Eichman

Subjects

Science

Abstract

Microbial DNA glycosylases associated with the biosynthesis of DNA-damaging antibiotics have evolved self-resistance for their cognate natural products. Here, the authors provide evidence that cellular self-resistance is enabled by reduced affinity of the glycosylases for the excision products of the corresponding DNA lesions.

Published

2021

2. A mechanistic model of primer synthesis from catalytic structures of DNA polymerase α–primase

Author

Elwood A. Mullins, Lauren E. Salay, Clarissa L. Durie, Jane E. Jackman, Melanie D. Ohi, Walter J. Chazin, and Brandt F. Eichman

Subjects

Article

Abstract

The mechanism by which polymerase α–primase (polα–primase) synthesizes chimeric RNA-DNA primers of defined length and composition, necessary for replication fidelity and genome stability, is unknown. Here, we report cryo-EM structures of polα–primase in complex with primed templates representing various stages of DNA synthesis. Our data show how interaction of the primase regulatory subunit with the primer 5′-end facilitates handoff of the primer to polα and increases polα processivity, thereby regulating both RNA and DNA composition. The structures detail how flexibility within the heterotetramer enables synthesis across two active sites and provide evidence that termination of DNA synthesis is facilitated by reduction of polα and primase affinities for the varied conformations along the chimeric primer/template duplex. Together, these findings elucidate a critical catalytic step in replication initiation and provide a comprehensive model for primer synthesis by polα–primase.

Published

2023

3. Functional dissection of the bipartite active site of the class I coenzyme A (CoA)-transferase succinyl-CoA:acetate CoA-transferase

Author

Jesse Ray Murphy, Elwood Arthur Mullins, and T Joseph Kappock

Subjects

Acyltransferases, Enzyme mechanism, acidophile, central metabolism, Substrate analogue, Chemistry, QD1-999

Abstract

Coenzyme A (CoA)-transferases catalyze the reversible transfer of CoA from acyl-CoA thioesters to free carboxylates. Class I CoA-transferases produce acylglutamyl anhydride intermediates that undergo attack by CoA thiolate on either the internal or external carbonyl carbon atoms, forming distinct tetrahedral intermediates less than 3 Å apart. In this study, crystal structures of succinyl-CoA:acetate CoA-transferase (AarC) from Acetobacter aceti are used to examine how the Asn347 carboxamide stabilizes the internal oxyanion intermediate. A structure of the active mutant AarC-N347A bound to CoA revealed both solvent replacement of the missing contact and displacement of the adjacent Glu294, indicating that Asn347 both polarizes and orients the essential glutamate. AarC was crystallized with the nonhydrolyzable acetyl-CoA (AcCoA) analogue dethiaacetyl-CoA (1a) in an attempt to trap a closed enzyme complex containing a stable analogue of the external oxyanion intermediate. One active site contained an acetylglutamyl anhydride adduct and truncated 1a, an unexpected result hinting at an unprecedented cleavage of the ketone moiety in 1a. Solution studies confirmed that 1a decomposition is accompanied by production of near-stoichiometric acetate, in a process that seems to depend on microbial contamination but not AarC. A crystal structure of AarC bound to the postulated 1a truncation product (2a) showed complete closure of one active site per dimer but no acetylglutamyl anhydride, even with acetate added. These findings suggest that an activated acetyl donor forms during 1a decomposition; a working hypothesis involving ketone oxidation is offered. The ability of 2a to induce full active site closure furthermore suggests that it subverts a system used to impede inappropriate active site closure on unacylated CoA.

Published

2016

4. A New Family of HEAT-Like Repeat Proteins Lacking a Critical Substrate Recognition Motif Present in Related DNA Glycosylases.

Author

Elwood A Mullins, Rongxin Shi, Lyle A Kotsch, and Brandt F Eichman

Subjects

Medicine, Science

Abstract

DNA glycosylases are important repair enzymes that eliminate a diverse array of aberrant nucleobases from the genomes of all organisms. Individual bacterial species often contain multiple paralogs of a particular glycosylase, yet the molecular and functional distinctions between these paralogs are not well understood. The recently discovered HEAT-like repeat (HLR) DNA glycosylases are distributed across all domains of life and are distinct in their specificity for cationic alkylpurines and mechanism of damage recognition. Here, we describe a number of phylogenetically diverse bacterial species with two orthologs of the HLR DNA glycosylase AlkD. One ortholog, which we designate AlkD2, is substantially less conserved. The crystal structure of Streptococcus mutans AlkD2 is remarkably similar to AlkD but lacks the only helix present in AlkD that penetrates the DNA minor groove. We show that AlkD2 possesses only weak DNA binding affinity and lacks alkylpurine excision activity. Mutational analysis of residues along this DNA binding helix in AlkD substantially reduced binding affinity for damaged DNA, for the first time revealing the importance of this structural motif for damage recognition by HLR glycosylases.

Published

2015

5. Emerging Roles of DNA Glycosylases and the Base Excision Repair Pathway

Author

Brandt F. Eichman, Alyssa A. Rodriguez, Elwood A. Mullins, and Noah P. Bradley

Subjects

chemistry.chemical_classification, 0303 health sciences, DNA Repair, Genome integrity, DNA repair, DNA damage, DNA, Base excision repair, Computational biology, Biology, Biochemistry, Article, DNA Glycosylases, Nucleobase, 03 medical and health sciences, 0302 clinical medicine, Enzyme, Base Excision Repair Pathway, chemistry, DNA glycosylase, Humans, Molecular Biology, 030217 neurology & neurosurgery, DNA Damage, 030304 developmental biology

Abstract

The base excision repair (BER) pathway historically has been associated with maintaining genome integrity by eliminating nucleobases with small chemical modifications. In the past several years, however, BER was found to play additional roles in genome maintenance and metabolism, including sequence-specific restriction modification and repair of bulky adducts and interstrand crosslinks. Central to this expanded biological utility are specialized DNA glycosylases, enzymes that selectively excise damaged, modified, or mismatched nucleobases. In this review, we discuss the newly identified roles of the BER pathway and examine the structural and mechanistic features of the DNA glycosylases that enable these functions.

Published

2019

6. Selective base excision repair of <scp>DNA</scp> damage by the non‐base‐flipping <scp>DNA</scp> glycosylase AlkC

Author

Xing-Xing Shen, Elwood A. Mullins, Sheila S. David, Rongxin Shi, Philip K. Yuen, Brandt F. Eichman, Kori T. Lay, and Antonis Rokas

Subjects

Models, Molecular, 0301 basic medicine, Alkylation, DNA Repair, Protein Conformation, DNA damage, DNA repair, Sequence Homology, Crystallography, X-Ray, General Biochemistry, Genetics and Molecular Biology, DNA Glycosylases, AP endonuclease, DNA Adducts, 03 medical and health sciences, 0302 clinical medicine, Bacillus cereus, Catalytic Domain, AP site, Amino Acid Sequence, Molecular Biology, General Immunology and Microbiology, biology, Adenine, General Neuroscience, Articles, Base excision repair, Very short patch repair, 030104 developmental biology, Biochemistry, DNA glycosylase, biology.protein, 030217 neurology & neurosurgery, DNA Damage, Nucleotide excision repair

Abstract

DNA glycosylases preserve genome integrity and define the specificity of the base excision repair pathway for discreet, detrimental modifications, and thus, the mechanisms by which glycosylases locate DNA damage are of particular interest. Bacterial AlkC and AlkD are specific for cationic alkylated nucleobases and have a distinctive HEAT‐like repeat (HLR) fold. AlkD uses a unique non‐base‐flipping mechanism that enables excision of bulky lesions more commonly associated with nucleotide excision repair. In contrast, AlkC has a much narrower specificity for small lesions, principally N3‐methyladenine (3mA). Here, we describe how AlkC selects for and excises 3mA using a non‐base‐flipping strategy distinct from that of AlkD. A crystal structure resembling a catalytic intermediate complex shows how AlkC uses unique HLR and immunoglobulin‐like domains to induce a sharp kink in the DNA, exposing the damaged nucleobase to active site residues that project into the DNA. This active site can accommodate and excise N3‐methylcytosine (3mC) and N1‐methyladenine (1mA), which are also repaired by AlkB‐catalyzed oxidative demethylation, providing a potential alternative mechanism for repair of these lesions in bacteria.

Published

2017

7. Toxicity and repair of DNA adducts produced by the natural product yatakemycin

Author

Rongxin Shi, Brandt F. Eichman, and Elwood A. Mullins

Subjects

0301 basic medicine, Indoles, DNA Repair, DNA repair, DNA damage, Biology, 010402 general chemistry, 01 natural sciences, Genome, Article, 03 medical and health sciences, chemistry.chemical_compound, DNA Adducts, Duocarmycins, Drug Resistance, Bacterial, Pyrroles, Molecular Biology, Duocarmycin, Biological Products, Natural product, Molecular Structure, Cell Biology, 0104 chemical sciences, 030104 developmental biology, chemistry, Biochemistry, DNA glycosylase, Toxicity, DNA, DNA Damage

Abstract

Yatakemycin (YTM) is an extraordinarily toxic DNA alkylating agent with potent antimicrobial and antitumor properties and is the most recent addition to the CC-1065 and duocarmycin family of natural products. Though bulky DNA lesions the size of those produced by YTM are normally removed from the genome by the nucleotide-excision repair (NER) pathway, YTM adducts are also a substrate for the bacterial DNA glycosylases AlkD and YtkR2, unexpectedly implicating base-excision repair (BER) in their elimination. The reason for the extreme toxicity of these lesions and the molecular basis for the way they are eliminated by BER have been unclear. Here, we describe the structural and biochemical properties of YTM adducts that are responsible for their toxicity, and define the mechanism by which they are excised by AlkD. These findings delineate an alternative strategy for repair of bulky DNA damage and establish the cellular utility of this pathway relative to that of NER.

Published

2017

8. A Catalytic Role for C–H/π Interactions in Base Excision Repair by Bacillus cereus DNA Glycosylase AlkD

Author

Joshua M. Bland, Elwood A. Mullins, Zachary D. Parsons, and Brandt F. Eichman

Subjects

DNA, Bacterial, 0301 basic medicine, DNA Repair, DNA repair, Stereochemistry, Biochemistry, Article, Catalysis, DNA Glycosylases, Nucleobase, 03 medical and health sciences, chemistry.chemical_compound, Colloid and Surface Chemistry, Protein structure, Bacillus cereus, biology, Active site, General Chemistry, Base excision repair, 030104 developmental biology, Deoxyribose, chemistry, DNA glycosylase, Biocatalysis, biology.protein, DNA

Abstract

DNA glycosylases protect genomic integrity by locating and excising aberrant nucleobases. Substrate recognition and excision usually takes place in an extrahelical conformation, which is often stabilized by π-stacking interactions between the lesion nucleobase and aromatic side chains in the glycosylase active site. Bacillus cereus AlkD is the only DNA glycosylase known to catalyze base excision without extruding the damaged nucleotide from the DNA helix. Instead of contacting the nucleobase itself, the AlkD active site interacts with the lesion deoxyribose through a series of C-H/π interactions. These interactions are ubiquitous in protein structures, but evidence for their catalytic significance in enzymology is lacking. Here, we show that the CH/π interactions between AlkD and the lesion deoxyribose participate in catalysis of glycosidic bond cleavage. This is the first demonstration of a catalytic role for C-H/π interactions as intermolecular forces important to DNA repair.

Published

2016

9. Structure of a DNA glycosylase that unhooks interstrand cross-links

Author

Garrett M. Warren, Elwood A. Mullins, Brandt F. Eichman, and Noah P. Bradley

Subjects

0301 basic medicine, DNA, Bacterial, Models, Molecular, Protein Folding, Microbial DNA, DNA repair, Protein Conformation, Biology, Naphthalenes, 01 natural sciences, Gene Expression Regulation, Enzymologic, DNA Glycosylases, 03 medical and health sciences, chemistry.chemical_compound, Bacterial Proteins, A-DNA, education, education.field_of_study, Multidisciplinary, 010405 organic chemistry, Base excision repair, Gene Expression Regulation, Bacterial, Biological Sciences, Azinomycin B, Streptomyces, 0104 chemical sciences, Anti-Bacterial Agents, 030104 developmental biology, chemistry, Biochemistry, DNA glycosylase, Mutation, Intercellular Signaling Peptides and Proteins, Peptides, DNA, Nucleotide excision repair, Protein Binding

Abstract

DNA glycosylases are important editing enzymes that protect genomic stability by excising chemically modified nucleobases that alter normal DNA metabolism. These enzymes have been known only to initiate base excision repair of small adducts by extrusion from the DNA helix. However, recent reports have described both vertebrate and microbial DNA glycosylases capable of unhooking highly toxic interstrand cross-links (ICLs) and bulky minor groove adducts normally recognized by Fanconi anemia and nucleotide excision repair machinery, although the mechanisms of these activities are unknown. Here we report the crystal structure of Streptomyces sahachiroi AlkZ (previously Orf1), a bacterial DNA glycosylase that protects its host by excising ICLs derived from azinomycin B (AZB), a potent antimicrobial and antitumor genotoxin. AlkZ adopts a unique fold in which three tandem winged helix-turn-helix motifs scaffold a positively charged concave surface perfectly shaped for duplex DNA. Through mutational analysis, we identified two glutamine residues and a β-hairpin within this putative DNA-binding cleft that are essential for catalytic activity. Additionally, we present a molecular docking model for how this active site can unhook either or both sides of an AZB ICL, providing a basis for understanding the mechanisms of base excision repair of ICLs. Given the prevalence of this protein fold in pathogenic bacteria, this work also lays the foundation for an emerging role of DNA repair in bacteria-host pathogenesis.

Published

2017

10. Base Excision Repair of Bulky DNA Adducts Generated by the Antitumor Drug Yatakemycin

Author

Elwood A. Mullins, Brandt F. Eichman, Yasuhiro Igarashi, and Rongxin Shi

Subjects

0301 basic medicine, Drug, Chemistry, media_common.quotation_subject, Base excision repair, Yatakemycin, Biochemistry, Adduct, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Genetics, Cancer research, Molecular Biology, DNA, Biotechnology, media_common

Published

2016

11. Formyl-coenzyme A (CoA):oxalate CoA-transferase from the acidophile Acetobacter aceti has a distinctive electrostatic surface and inherent acid stability

Author

Courtney M. Starks, Lee Sael, T. Joseph Kappock, Daisuke Kihara, Elwood A. Mullins, and Julie A. Francois

Subjects

biology, Decarboxylation, Stereochemistry, biology.organism_classification, Biochemistry, Oxalate, Acetic acid, chemistry.chemical_compound, Residue (chemistry), chemistry, Transferase, Surface charge, Acetobacter, Molecular Biology, Acetobacter aceti

Abstract

Bacterial formyl-CoA:oxalate CoA-transferase (FCOCT) and oxalyl-CoA decarboxylase work in tandem to perform a proton-consuming decarboxylation that has been suggested to have a role in generalized acid resistance. FCOCT is the product of uctB in the acidophilic acetic acid bacterium Acetobacter aceti. As expected for an acid-resistance factor, UctB remains folded at the low pH values encountered in the A. aceti cytoplasm. A comparison of crystal structures of FCOCTs and related proteins revealed few features in UctB that would distinguish it from nonacidophilic proteins and thereby account for its acid stability properties, other than a strikingly featureless electrostatic surface. The apparently neutral surface is a result of a "speckled" charge decoration, in which charged surface residues are surrounded by compensating charges but do not form salt bridges. A quantitative comparison among orthologs identified a pattern of residue substitution in UctB that may be a consequence of selection for protein stability by constant exposure to acetic acid. We suggest that this surface charge pattern, which is a distinctive feature of A. aceti proteins, creates a stabilizing electrostatic network without stiffening the protein or compromising protein-solvent interactions.

Published

2012

12. Metal stopping reagents facilitate discontinuous activity assays of the de novo purine biosynthesis enzyme PurE

Author

Elwood A. Mullins, Kelly L. Sullivan, T. Joseph Kappock, Michael E. Johnson, and Loredana C. Huma

Subjects

Ribonucleotide, High-throughput screening, Biophysics, Biochemistry, Enzymes and Coenzymes, Chelation, Isomerases, Purine metabolism, Molecular Biology, Enzyme Assays, chemistry.chemical_classification, biology, Purine biosynthesis, Aminoimidazole, Substrate depletion, Chemistry, Substrate (chemistry), Medicinal-Pharmaceutical Chemistry, Cell Biology, Ribonucleotides, Zinc Sulfate, Enzyme assay, High-Throughput Screening Assays, Enzyme, Purines, Reagent, biology.protein

Abstract

The conversion of 5-aminoimidazole ribonucleotide (AIR) to 4-carboxy-AIR (CAIR) represents an unusual divergence in purine biosynthesis: microbes and nonmetazoan eukaryotes use class I PurEs while animals use class II PurEs. Class I PurEs are therefore a potential antimicrobial target; however, no enzyme activity assay is suitable for high throughput screening (HTS). Here we report a simple chemical quench that fixes the PurE substrate/product ratio for 24 h, as assessed by the Bratton-Marshall assay (BMA) for diazotizable amines. The ZnSO4 stopping reagent is proposed to chelate CAIR, enabling delayed analysis of this acid-labile product by BMA or other HTS methods

Published

2014

13. A Specialized Citric Acid Cycle Requiring Succinyl-Coenzyme A (CoA):Acetate CoA-Transferase (AarC) Confers Acetic Acid Resistance on the Acidophile Acetobacter aceti

Author

Julie A. Francois, T. Joseph Kappock, and Elwood A. Mullins

Subjects

DNA, Bacterial, Physiology and Metabolism, Citric Acid Cycle, Molecular Sequence Data, Microbiology, chemistry.chemical_compound, Acetic acid, Bacterial Proteins, Drug Resistance, Bacterial, Gene Order, Acetobacter, Citrate synthase, Acetic acid bacteria, Molecular Biology, Acetic Acid, Acetobacter aceti, Ethanol, biology, Sequence Analysis, DNA, Metabolism, biology.organism_classification, Anti-Bacterial Agents, Molecular Weight, Citric acid cycle, Kinetics, chemistry, Biochemistry, biology.protein, Acyl Coenzyme A, Coenzyme A-Transferases, Bacteria

Abstract

Microbes tailor macromolecules and metabolism to overcome specific environmental challenges. Acetic acid bacteria perform the aerobic oxidation of ethanol to acetic acid and are generally resistant to high levels of these two membrane-permeable poisons. The citric acid cycle (CAC) is linked to acetic acid resistance in Acetobacter aceti by several observations, among them the oxidation of acetate to CO 2 by highly resistant acetic acid bacteria and the previously unexplained role of A. aceti citrate synthase (AarA) in a cetic a cid r esistance at a low pH. Here we assign specific biochemical roles to the other components of the A. aceti strain 1023 aarABC region. AarC is succinyl-coenzyme A (CoA):acetate CoA-transferase, which replaces succinyl-CoA synthetase in a variant CAC. This new bypass appears to reduce metabolic demand for free CoA, reliance upon nucleotide pools, and the likely effect of variable cytoplasmic pH upon CAC flux. The putative aarB gene is reassigned to SixA, a known activator of CAC flux. Carbon overflow pathways are triggered in many bacteria during metabolic limitation, which typically leads to the production and diffusive loss of acetate. Since acetate overflow is not feasible for A. aceti , a CO 2 loss strategy that allows acetic acid removal without substrate-level (de)phosphorylation may instead be employed. All three aar genes, therefore, support flux through a complete but unorthodox CAC that is needed to lower cytoplasmic acetate levels.

Published

2008

14. The DNA glycosylase AlkD uses a non-base-flipping mechanism to excise bulky lesions

Author

Sheila S. David, Yasuhiro Igarashi, Elwood A. Mullins, Brandt F. Eichman, Philip K. Yuen, Zachary D. Parsons, and Rongxin Shi

Subjects

Models, Molecular, Indoles, DNA Repair, DNA damage, DNA repair, Stereochemistry, Base pair, Crystallography, X-Ray, Nucleobase, AP endonuclease, DNA Glycosylases, chemistry.chemical_compound, DNA Adducts, Duocarmycins, Bacillus cereus, Catalytic Domain, Nucleotide, Pyrroles, Base Pairing, chemistry.chemical_classification, Multidisciplinary, biology, Biochemistry, chemistry, DNA glycosylase, biology.protein, Biocatalysis, DNA, DNA Damage

Abstract

Threats to genomic integrity arising from DNA damage are mitigated by DNA glycosylases, which initiate the base excision repair pathway by locating and excising aberrant nucleobases. How these enzymes find small modifications within the genome is a current area of intensive research. A hallmark of these and other DNA repair enzymes is their use of base flipping to sequester modified nucleotides from the DNA helix and into an active site pocket. Consequently, base flipping is generally regarded as an essential aspect of lesion recognition and a necessary precursor to base excision. Here we present the first, to our knowledge, DNA glycosylase mechanism that does not require base flipping for either binding or catalysis. Using the DNA glycosylase AlkD from Bacillus cereus, we crystallographically monitored excision of an alkylpurine substrate as a function of time, and reconstructed the steps along the reaction coordinate through structures representing substrate, intermediate and product complexes. Instead of directly interacting with the damaged nucleobase, AlkD recognizes aberrant base pairs through interactions with the phosphoribose backbone, while the lesion remains stacked in the DNA duplex. Quantum mechanical calculations revealed that these contacts include catalytic charge-dipole and CH-π interactions that preferentially stabilize the transition state. We show in vitro and in vivo how this unique means of recognition and catalysis enables AlkD to repair large adducts formed by yatakemycin, a member of the duocarmycin family of antimicrobial natural products exploited in bacterial warfare and chemotherapeutic trials. Bulky adducts of this or any type are not excised by DNA glycosylases that use a traditional base-flipping mechanism. Hence, these findings represent a new model for DNA repair and provide insights into catalysis of base excision.

Published

2015

15. A New Family of HEAT-Like Repeat Proteins Lacking a Critical Substrate Recognition Motif Present in Related DNA Glycosylases

Author

Lyle A. Kotsch, Rongxin Shi, Brandt F. Eichman, and Elwood A. Mullins

Subjects

Models, Molecular, DNA Repair, DNA repair, DNA damage, Amino Acid Motifs, DNA Mutational Analysis, lcsh:Medicine, Sequence alignment, Biology, DNA-binding protein, DNA Glycosylases, Streptococcus mutans, 03 medical and health sciences, chemistry.chemical_compound, Amino Acid Sequence, lcsh:Science, Structural motif, Phylogeny, 030304 developmental biology, Genetics, 0303 health sciences, Multidisciplinary, lcsh:R, 030302 biochemistry & molecular biology, DNA, Protein Structure, Tertiary, chemistry, DNA glycosylase, lcsh:Q, Research Article, DNA Damage

Abstract

DNA glycosylases are important repair enzymes that eliminate a diverse array of aberrant nucleobases from the genomes of all organisms. Individual bacterial species often contain multiple paralogs of a particular glycosylase, yet the molecular and functional distinctions between these paralogs are not well understood. The recently discovered HEAT-like repeat (HLR) DNA glycosylases are distributed across all domains of life and are distinct in their specificity for cationic alkylpurines and mechanism of damage recognition. Here, we describe a number of phylogenetically diverse bacterial species with two orthologs of the HLR DNA glycosylase AlkD. One ortholog, which we designate AlkD2, is substantially less conserved. The crystal structure of Streptococcus mutans AlkD2 is remarkably similar to AlkD but lacks the only helix present in AlkD that penetrates the DNA minor groove. We show that AlkD2 possesses only weak DNA binding affinity and lacks alkylpurine excision activity. Mutational analysis of residues along this DNA binding helix in AlkD substantially reduced binding affinity for damaged DNA, for the first time revealing the importance of this structural motif for damage recognition by HLR glycosylases.

Published

2015

16. Metalation in hydrocarbon solvents: the mechanistic aspects of substrate-promoted ortho-metalations

Author

R. W. Holman, Seth Dumbris, Scott Brown, Amy Walstrom, Phillip Shelton, J Micah Wilcox, Elwood A. Mullins, Gina Jackson, Jonathan Ray, Donald W. Slocum, and Roslyn LaMastus

Subjects

chemistry.chemical_classification, Metalation, Aryl, Activated complex, Organic Chemistry, Substrate (chemistry), Carbon-13 NMR, Biochemistry, Medicinal chemistry, Catalysis, chemistry.chemical_compound, Hydrocarbon, chemistry, Drug Discovery, Organic chemistry, Solubility

Abstract

The methoxy-substituted aromatic reagents 1,2- and 1,3-dimethoxybenzene (1,2-DMB and 1,3-DMB) and 1,2,4-trimethoxybenzene (1,2,4-TMB) each undergo directed ortho-metalation in high yield in n-BuLi/hydrocarbon media without the aid of a catalyst. These reactions, coined ‘substrate-promoted ortho-metalations’, proceed with the methoxy aromatic substrate functioning as both the directing metalation group (DMG) and as the deoligomerization agent. Evidence that the substrates themselves serve to deoligomerize n-BuLi comes from 13C NMR. The relative extent of metalated product formed as a function of time for each of the three aromatics directly correlates with the substrate's time-dependent ability to coordinate to n-BuLi as measured by 13C NMR. The interpretation of NMR results from experiments involving 1,2,4-TMB is consistent with the metalation proceeding via the activated complex [(1,2,4-TMB)2·(n-BuLi)2]. Finally, conclusions from solubility experiments are that for every substrate-promoted metalation investigated, a precipitate forms in the hydrocarbon solvent, and this precipitate mostly contains the ortho-lithiated aryl intermediate.

Published

2003

17. The substrate binding interface of alkylpurine DNA glycosylase AlkD

Author

Elwood A. Mullins, Emily H. Rubinson, and Brandt F. Eichman

Subjects

Models, Molecular, Guanine, HMG-box, DNA Repair, Base pair, Protein Conformation, Biology, Biochemistry, Article, Protein Structure, Secondary, DNA Glycosylases, Substrate Specificity, Catalytic Domain, Protein–DNA interaction, Molecular Biology, Replication protein A, chemistry.chemical_classification, DNA ligase, DNA clamp, Adenine, Cell Biology, Protein Structure, Tertiary, DNA binding site, DNA-Binding Proteins, chemistry, DNA glycosylase, Mutation, Biophysics

Abstract

Tandem helical repeats have emerged as an important DNA binding architecture. DNA glycosylase AlkD, which excises N 3- and N 7-alkylated nucleobases, uses repeating helical motifs to bind duplex DNA and to selectively pause at non-Watson–Crick base pairs. Remodeling of the DNA backbone promotes nucleotide flipping of the lesion and the complementary base into the solvent and toward the protein surface, respectively. The important features of this new DNA binding architecture that allow AlkD to distinguish between damaged and normal DNA without contacting the lesion are poorly understood. Here, we show through extensive mutational analysis that DNA binding and N 3-methyladenine (3mA) and N 7-methylguanine (7mG) excision are dependent upon each residue lining the DNA binding interface. Disrupting electrostatic or hydrophobic interactions with the DNA backbone substantially reduced binding affinity and catalytic activity. These results demonstrate that residues seemingly only involved in general DNA binding are important for catalytic activity and imply that base excision is driven by binding energy provided by the entire substrate interface of this novel DNA binding architecture.

Published

2013

18. An HPLC-tandem mass spectrometry method for simultaneous detection of alkylated base excision repair products

Author

Emily H. Rubinson, Plamen P. Christov, Elwood A. Mullins, Brandt F. Eichman, M. Wade Calcutt, and Kevin N Pereira

Subjects

Saccharomyces cerevisiae Proteins, Alkylation, DNA Repair, DNA repair, DNA damage, Tandem mass spectrometry, General Biochemistry, Genetics and Molecular Biology, Article, chemistry.chemical_compound, DNA Adducts, Bacillus cereus, Bacterial Proteins, Tandem Mass Spectrometry, Humans, Molecular Biology, Chromatography, High Pressure Liquid, Chemistry, Oligonucleotide, Base excision repair, DNA, Salmonella typhi, genomic DNA, Biochemistry, DNA glycosylase, DNA Damage

Abstract

DNA glycosylases excise a broad spectrum of alkylated, oxidized, and deaminated nucleobases from DNA as the initial step in base excision repair. Substrate specificity and base excision activity are typically characterized by monitoring the release of modified nucleobases either from a genomic DNA substrate that has been treated with a modifying agent or from a synthetic oligonucleotide containing a defined lesion of interest. Detection of nucleobases from genomic DNA has traditionally involved HPLC separation and scintillation detection of radiolabeled nucleobases, which in the case of alkylation adducts can be laborious and costly. Here, we describe a mass spectrometry method to simultaneously detect and quantify multiple alkylpurine adducts released from genomic DNA that has been treated with N-methyl-N-nitrosourea (MNU). We illustrate the utility of this method by monitoring the excision of N3-methyladenine (3 mA) and N7-methylguanine (7 mG) by a panel of previously characterized prokaryotic and eukaryotic alkylpurine DNA glycosylases, enabling a comparison of substrate specificity and enzyme activity by various methods. Detailed protocols for these methods, along with preparation of genomic and oligonucleotide alkyl-DNA substrates, are also described.

Published

2013

19. Formyl-coenzyme A (CoA):oxalate CoA-transferase from the acidophile Acetobacter aceti has a distinctive electrostatic surface and inherent acid stability

Author

Elwood A, Mullins, Courtney M, Starks, Julie A, Francois, Lee, Sael, Daisuke, Kihara, and T Joseph, Kappock

Subjects

Models, Molecular, Bacterial Proteins, Ethanol, Protein Stability, Static Electricity, Acetobacter, Articles, Coenzyme A-Transferases, Hydrogen-Ion Concentration, Acetic Acid, Substrate Specificity

Abstract

Bacterial formyl-CoA:oxalate CoA-transferase (FCOCT) and oxalyl-CoA decarboxylase work in tandem to perform a proton-consuming decarboxylation that has been suggested to have a role in generalized acid resistance. FCOCT is the product of uctB in the acidophilic acetic acid bacterium Acetobacter aceti. As expected for an acid-resistance factor, UctB remains folded at the low pH values encountered in the A. aceti cytoplasm. A comparison of crystal structures of FCOCTs and related proteins revealed few features in UctB that would distinguish it from nonacidophilic proteins and thereby account for its acid stability properties, other than a strikingly featureless electrostatic surface. The apparently neutral surface is a result of a “speckled” charge decoration, in which charged surface residues are surrounded by compensating charges but do not form salt bridges. A quantitative comparison among orthologs identified a pattern of residue substitution in UctB that may be a consequence of selection for protein stability by constant exposure to acetic acid. We suggest that this surface charge pattern, which is a distinctive feature of A. aceti proteins, creates a stabilizing electrostatic network without stiffening the protein or compromising protein–solvent interactions.

Published

2011

20. Function and X-Ray crystal structure of Escherichia coli YfdE

Author

T. Joseph Kappock, Elwood A. Mullins, and Kelly L. Sullivan

Subjects

Models, Molecular, Operon, lcsh:Medicine, Crystallography, X-Ray, medicine.disease_cause, Biochemistry, Substrate Specificity, chemistry.chemical_compound, Microbial Physiology, Catalytic Domain, Bacterial Physiology, lcsh:Science, Chromatography, High Pressure Liquid, Acetobacter aceti, Oxalates, 0303 health sciences, Multidisciplinary, biology, Enzyme Classes, Escherichia coli Proteins, Enzymes, Bacterial Biochemistry, sequence alignment, Prokaryotic Models, Metabolic Pathways, Research Article, crystal structure, Protein Structure, Molecular Sequence Data, Microbiology, Oxalate, 03 medical and health sciences, Model Organisms, Oxalobacter formigenes, Transferases, Genetics, Escherichia coli, medicine, Amino Acid Sequence, formates, Biology, 030304 developmental biology, centrifugation, 030306 microbiology, lcsh:R, Proteins, Active site, Bacteriology, Obligate aerobe, biology.organism_classification, Kinetics, Response regulator, Metabolism, chemistry, Genes, Bacterial, Enzyme Structure, Biocatalysis, biology.protein, lcsh:Q, Gene Function, Coenzyme A-Transferases, Protein Multimerization

Abstract

Many food plants accumulate oxalate, which humans absorb but do not metabolize, leading to the formation of urinary stones. The commensal bacterium Oxalobacter formigenes consumes oxalate by converting it to oxalyl- CoA, which is decarboxylated by oxalyl-CoA decarboxylase (OXC). OXC and the class III CoA-transferase formyl- CoA:oxalate CoA-transferase (FCOCT) are widespread among bacteria, including many that have no apparent ability to degrade or to resist external oxalate. The EvgA acid response regulator activates transcription of the Escherichia coli yfdXWUVE operon encoding YfdW (FCOCT), YfdU (OXC), and YfdE, a class III CoA-transferase that is ~ 30% identical to YfdW. YfdW and YfdU are necessary and sufficient for oxalate-induced protection against a subsequent acid challenge; neither of the other genes has a known function. We report the purification, in vitro characterization, 2.1-A crystal structure, and functional assignment of YfdE. YfdE and UctC, an orthologue fromthe obligate aerobe Acetobacter aceti, perform the reversible conversion of acetyl- CoA and oxalate to oxalyl-CoA and acetate. The annotation of YfdE as acetyl-CoA:oxalate CoA-transferase (ACOCT) expands the scope of metabolic pathways linked to oxalate catabolism and the oxalate-induced acid tolerance response. FCOCT and ACOCT active sites contain distinctive, conserved active site loops (the glycine-rich loop and the GNxH loop, respectively) that appear to encode substrate specificity.

Published

2013