Your search keyword '"Almabruk KH"' showing total 13 results

1. De novo synthesis of a vertebrate sunscreen compound

Author

Osborn, AR, primary, Almabruk, KH, additional, Holzwarth, G, additional, Asamizu, S, additional, LaDu, J, additional, Kean, KM, additional, Karplus, PA, additional, Tanguay, RL, additional, Bakalinsky, AT, additional, and Mahmud, T, additional

Published

2015

2. Modification of rifamycin polyketide backbone leads to improved drug activity against rifampicin-resistant M. tuberculosis

Author

Almabruk, KH, primary, Nigam, A, additional, Saxena, A, additional, Yang, J, additional, Zakharov, L, additional, Lal, R, additional, and Mahmud, T, additional

Published

2014

3. Mutasynthesis of Fluorinated Pactamycin Analogues and their Antimalarial Activity

Author

Almabruk, KH, primary, Lu, W, additional, Li, Y, additional, Abugreen, M, additional, Kelly, JX, additional, and Mahmud, T, additional

Published

2013

4. Self-Resistance of Natural Product Producers: Past, Present, and Future Focusing on Self-Resistant Protein Variants.

Author

Almabruk KH, Dinh LK, and Philmus B

Subjects

Animals, Bacterial Physiological Phenomena genetics, Drug Resistance, Bacterial genetics, Fungi genetics, Fungi physiology, Multigene Family genetics, Plant Physiological Phenomena genetics, Protein Isoforms genetics, Vertebrates genetics, Vertebrates physiology, Biological Products metabolism, Drug Resistance, Bacterial physiology, Protein Isoforms physiology

Abstract

Nature is a prolific producers of bioactive natural products with an array of biological activities and impact on human and animal health. But with great power comes great responsibility, and the organisms that produce a bioactive compound must be resistant to its biological effects to survive during production/accumulation. Microorganisms, particularly bacteria, have developed different strategies to prevent self-toxicity. Here, we review a few of the major mechanisms including the mechanism of resistance with a focus on self-resistant protein variants, target proteins that contain amino acid substitutions to reduce the binding of the bioactive natural product, and therefore its inhibitory effects are highlighted in depth. We also try to identify some future avenues of research and challenges that need to be addressed.

Published

2018

5. Biochemical Characterization and Structural Basis of Reactivity and Regioselectivity Differences between Burkholderia thailandensis and Burkholderia glumae 1,6-Didesmethyltoxoflavin N-Methyltransferase.

Author

Fenwick MK, Almabruk KH, Ealick SE, Begley TP, and Philmus B

Subjects

Bacterial Proteins chemistry, Bacterial Proteins genetics, Binding Sites, Catalytic Domain, Crystallography, X-Ray, Histidine chemistry, Hydrogen Bonding, Methylation, Methyltransferases chemistry, Methyltransferases genetics, Multigene Family, Oxidation-Reduction, Phylogeny, Protein Conformation, Pyrimidinones chemical synthesis, Pyrimidinones chemistry, Recombinant Proteins chemistry, Recombinant Proteins metabolism, S-Adenosylhomocysteine chemistry, S-Adenosylhomocysteine metabolism, S-Adenosylmethionine chemistry, Species Specificity, Stereoisomerism, Triazines chemistry, Bacterial Proteins metabolism, Burkholderia enzymology, Methyltransferases metabolism, Models, Molecular, Pyrimidinones metabolism, S-Adenosylmethionine metabolism, Triazines metabolism

Abstract

Burkholderia glumae converts the guanine base of guanosine triphosphate into an azapteridine and methylates both the pyrimidine and triazine rings to make toxoflavin. Strains of Burkholderia thailandensis and Burkholderia pseudomallei have a gene cluster encoding seven putative biosynthetic enzymes that resembles the toxoflavin gene cluster. Four of the enzymes are similar in sequence to BgToxBCDE, which have been proposed to make 1,6-didesmethyltoxoflavin (1,6-DDMT). One of the remaining enzymes, BthII1283 in B. thailandensis E264, is a predicted S-adenosylmethionine (SAM)-dependent N-methyltransferase that shows a low level of sequence identity to BgToxA, which sequentially methylates N6 and N1 of 1,6-DDMT to form toxoflavin. Here we show that, unlike BgToxA, BthII1283 catalyzes a single methyl transfer to N1 of 1,6-DDMT in vitro. In addition, we investigated the differences in reactivity and regioselectivity by determining crystal structures of BthII1283 with bound S-adenosylhomocysteine (SAH) or 1,6-DDMT and SAH. BthII1283 contains a class I methyltransferase fold and three unique extensions used for 1,6-DDMT recognition. The active site structure suggests that 1,6-DDMT is bound in a reduced form. The plane of the azapteridine ring system is orthogonal to its orientation in BgToxA. In BthII1283, the modeled SAM methyl group is directed toward the p orbital of N1, whereas in BgToxA, it is first directed toward an sp 2 orbital of N6 and then toward an sp 2 orbital of N1 after planar rotation of the azapteridine ring system. Furthermore, in BthII1283, N1 is hydrogen bonded to a histidine residue whereas BgToxA does not supply an obvious basic residue for either N6 or N1 methylation.

Published

2017

6. Evolution and Distribution of C 7 -Cyclitol Synthases in Prokaryotes and Eukaryotes.

Author

Osborn AR, Kean KM, Alseud KM, Almabruk KH, Asamizu S, Lee JA, Karplus PA, and Mahmud T

Subjects

Amino Acid Sequence, Catalytic Domain, Computational Biology, Conserved Sequence, Crystallography, X-Ray, Cyclitols chemistry, Eukaryotic Cells, Ligases chemistry, Ligases genetics, Phylogeny, Prokaryotic Cells, Sequence Homology, Amino Acid, Biological Evolution, Cyclitols metabolism, Ligases metabolism

Abstract

2-Epi-5-epi-valiolone synthase (EEVS), a C 7 -sugar phosphate cyclase (SPC) homologous to 3-dehydroquinate synthase (DHQS), was discovered during studies of the biosynthesis of the C 7 N-aminocyclitol family of natural products. EEVS was originally thought to be present only in certain actinomycetes, but analyses of genome sequences showed that it is broadly distributed in both prokaryotes and eukaryotes, including vertebrates. Another SPC, desmethyl-4-deoxygadusol synthase (DDGS), was later discovered as being involved in the biosynthesis of mycosporine-like amino acid sunscreen compounds. Current database annotations are quite unreliable, with many EEVSs reported as DHQS, and most DDGSs reported as EEVS, DHQS, or simply hypothetical proteins. Here, we identify sequence features useful for distinguishing these enzymes, report a crystal structure of a representative DDGS showing the high similarity of the EEVS and DDGS enzymes, identify notable active site differences, and demonstrate the importance of two of these active site residues for catalysis by point mutations. Further, we functionally characterized two representatives of a distinct clade equidistant from known EEVS and known DDGS groups and show them to be authentic EEVSs. Moreover, we document and discuss the distribution of genes that encode EEVS and DDGS in various prokaryotes and eukaryotes, including pathogenic bacteria, plant symbionts, nitrogen-fixing bacteria, myxobacteria, cyanobacteria, fungi, stramenopiles, and animals, suggesting their broad potential biological roles in nature.

Published

2017

7. Total Synthesis of (±)-Isoperbergins and Correction of the Chemical Structure of Perbergin.

Author

Almabruk KH, Chang JH, and Mahmud T

Subjects

Anti-Bacterial Agents chemistry, Anti-Bacterial Agents pharmacology, Dalbergia chemistry, Escherichia coli drug effects, Gram-Negative Bacteria drug effects, Microbial Sensitivity Tests, Molecular Structure, Nuclear Magnetic Resonance, Biomolecular, Pseudomonas aeruginosa drug effects, Rhodococcus drug effects, Staphylococcus aureus drug effects, Anti-Bacterial Agents chemical synthesis, Isoflavones chemical synthesis, Isoflavones chemistry, Monoterpenes chemical synthesis, Monoterpenes chemistry

Abstract

On the basis of its reported chemical structure, perbergin, a Rhodococcus fascians virulence quencher from the bark of Dalbergia pervillei, and its isomer were synthesized in nine steps with a 13.5% yield. However, the NMR spectra of the synthetic products were inconsistent with those reported in the literature. Re-evaluation of the 1D and 2D NMR spectra of the natural product perbergin revealed that the geranyl moiety of this compound is located at C-6 and has an E-configuration, instead of the reported C-8 geranylation with a Z-configuration. Interestingly, the synthetic isoperbergins demonstrated good antibacterial activity against R. fascians, Mycobacterium smegmatis, and Staphylococcus aureus, but not against the Gram-negative bacteria Pseudomonas aeruginosa and Escherichia coli.

Published

2016

8. De novo synthesis of a sunscreen compound in vertebrates.

Author

Osborn AR, Almabruk KH, Holzwarth G, Asamizu S, LaDu J, Kean KM, Karplus PA, Tanguay RL, Bakalinsky AT, and Mahmud T

Subjects

Amino Acids genetics, Amino Acids metabolism, Animals, Cyclohexanols chemistry, Fishes, Fungi, Organisms, Genetically Modified, Vertebrates, Amino Acids biosynthesis, Cyclohexanols metabolism, Radiation-Protective Agents chemistry, Ultraviolet Rays

Abstract

Ultraviolet-protective compounds, such as mycosporine-like amino acids (MAAs) and related gadusols produced by some bacteria, fungi, algae, and marine invertebrates, are critical for the survival of reef-building corals and other marine organisms exposed to high-solar irradiance. These compounds have also been found in marine fish, where their accumulation is thought to be of dietary or symbiont origin. In this study, we report the unexpected discovery that fish can synthesize gadusol de novo and that the analogous pathways are also present in amphibians, reptiles, and birds. Furthermore, we demonstrate that engineered yeast containing the fish genes can produce and secrete gadusol. The discovery of the gadusol pathway in vertebrates provides a platform for understanding its role in these animals, and the possibility of engineering yeast to efficiently produce a natural sunscreen and antioxidant presents an avenue for its large-scale production for possible use in pharmaceuticals and cosmetics.

Published

2015

9. Modification of rifamycin polyketide backbone leads to improved drug activity against rifampicin-resistant Mycobacterium tuberculosis.

Author

Nigam A, Almabruk KH, Saxena A, Yang J, Mukherjee U, Kaur H, Kohli P, Kumari R, Singh P, Zakharov LN, Singh Y, Mahmud T, and Lal R

Subjects

Protein Engineering, Acyltransferases genetics, Acyltransferases metabolism, Antibiotics, Antitubercular biosynthesis, Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism, Drug Resistance, Bacterial, Mycobacterium tuberculosis, Polyketide Synthases chemistry, Polyketide Synthases genetics, Polyketide Synthases metabolism, Rifampin analogs & derivatives, Rifampin metabolism

Abstract

Rifamycin B, a product of Amycolatopsis mediterranei S699, is the precursor of clinically used antibiotics that are effective against tuberculosis, leprosy, and AIDS-related mycobacterial infections. However, prolonged usage of these antibiotics has resulted in the emergence of rifamycin-resistant strains of Mycobacterium tuberculosis. As part of our effort to generate better analogs of rifamycin, we substituted the acyltransferase domain of module 6 of rifamycin polyketide synthase with that of module 2 of rapamycin polyketide synthase. The resulting mutants (rifAT6::rapAT2) of A. mediterranei S699 produced new rifamycin analogs, 24-desmethylrifamycin B and 24-desmethylrifamycin SV, which contained modification in the polyketide backbone. 24-Desmethylrifamycin B was then converted to 24-desmethylrifamycin S, whose structure was confirmed by MS, NMR, and X-ray crystallography. Subsequently, 24-desmethylrifamycin S was converted to 24-desmethylrifampicin, which showed excellent antibacterial activity against several rifampicin-resistant M. tuberculosis strains.

Published

2014

10. Mutasynthesis of fluorinated pactamycin analogues and their antimalarial activity.

Author

Almabruk KH, Lu W, Li Y, Abugreen M, Kelly JX, and Mahmud T

Subjects

Antimalarials chemistry, Chloroquine pharmacology, Drug Resistance drug effects, Drug Resistance, Multiple drug effects, Hydrocarbons, Fluorinated chemistry, Molecular Structure, Pactamycin chemistry, Plasmodium falciparum drug effects, Streptomyces chemistry, Streptomyces genetics, Streptomyces metabolism, meta-Aminobenzoates, Antimalarials chemical synthesis, Antimalarials pharmacology, Hydrocarbons, Fluorinated chemical synthesis, Hydrocarbons, Fluorinated pharmacology, Pactamycin analogs & derivatives, Pactamycin chemical synthesis, Pactamycin pharmacology

Abstract

A mutasynthetic strategy has been used to generate fluorinated TM-025 and TM-026, two biosynthetically engineered pactamycin analogues produced by Streptomyces pactum ATCC 27456. The fluorinated compounds maintain excellent activity and selectivity toward chloroquine-sensitive and multidrug-resistant strains of malarial parasites as the parent compounds. The results also provide insights into the biosynthesis of 3-aminobenzoic acid in S. pactum.

Published

2013

11. The α-ketoglutarate/Fe(II)-dependent dioxygenase VldW is responsible for the formation of validamycin B.

Author

Almabruk KH, Asamizu S, Chang A, Varghese SG, and Mahmud T

Subjects

Glycosyltransferases metabolism, Inositol analogs & derivatives, Inositol chemistry, Inositol metabolism, Stereoisomerism, Streptomyces chemistry, Dioxygenases metabolism, Ketoglutaric Acids metabolism, Streptomyces enzymology

Abstract

From A to B: Through detailed biochemical investigations, we discovered that VldW, an α-ketoglutarate/Fe(II)-dependent dioxygenase, regioselectively hydroxylates validamycin A to validamycin B. The results provide insights into the biosynthesis of hydroxylated validamycins and could be used to control the metabolic outcomes of the validamycin pathway., (Copyright © 2012 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2012

12. Mechanistic insights into validoxylamine A 7'-phosphate synthesis by VldE using the structure of the entire product complex.

Author

Cavalier MC, Yim YS, Asamizu S, Neau D, Almabruk KH, Mahmud T, and Lee YH

Subjects

Amino Acid Sequence, Binding Sites, Catalytic Domain, Crystallography, X-Ray, Cyclitols metabolism, Inositol biosynthesis, Ligands, Models, Molecular, Molecular Sequence Data, Nucleotides metabolism, Streptomyces enzymology, Glycosyltransferases chemistry, Glycosyltransferases metabolism, Inositol analogs & derivatives, Inositol Phosphates biosynthesis

Abstract

The pseudo-glycosyltransferase VldE catalyzes non-glycosidic C-N coupling between an unsaturated cyclitol and a saturated aminocyclitol with the conservation of the stereochemical configuration of the substrates to form validoxylamine A 7'-phosphate, the biosynthetic precursor of the antibiotic validamycin A. To study the molecular basis of its mechanism, the three-dimensional structures of VldE from Streptomyces hygroscopicus subsp. limoneus was determined in apo form, in complex with GDP, in complex with GDP and validoxylamine A 7'-phosphate, and in complex with GDP and trehalose. The structure of VldE with the catalytic site in both an "open" and "closed" conformation is also described. With these structures, the preferred binding of the guanine moiety by VldE, rather than the uracil moiety as seen in OtsA could be explained. The elucidation of the VldE structure in complex with the entirety of its products provides insight into the internal return mechanism by which catalysis occurs with a net retention of the stereochemical configuration of the donated cyclitol.

Published

2012

13. Pseudoglycosyltransferase catalyzes nonglycosidic C-N coupling in validamycin a biosynthesis.

Author

Asamizu S, Yang J, Almabruk KH, and Mahmud T

Subjects

Biocatalysis, Glucosyltransferases chemistry, Inositol analogs & derivatives, Inositol biosynthesis, Inositol chemistry, Molecular Conformation, Stereoisomerism, Glucosyltransferases metabolism

Abstract

Glycosyltransferases are ubiquitous in nature. They catalyze a glycosidic bond formation between sugar donors and sugar or nonsugar acceptors to produce oligo/polysaccharides, glycoproteins, glycolipids, glycosylated natural products, and other sugar-containing entities. However, a trehalose 6-phosphate synthase-like protein has been found to catalyze an unprecedented nonglycosidic C-N bond formation in the biosynthesis of the aminocyclitol antibiotic validamycin A. This dedicated 'pseudoglycosyltransferase' catalyzes a condensation between GDP-valienol and validamine 7-phosphate to give validoxylamine A 7'-phosphate with net retention of the 'anomeric' configuration of the donor cyclitol in the product. The enzyme operates in sequence with a phosphatase, which dephosphorylates validoxylamine A 7'-phosphate to validoxylamine A., (© 2011 American Chemical Society)

Published

2011