Your search keyword '"WARREN, MARTIN"' showing total 19 results

1. Iron-sulfur proteins as initiators of radical chemistry.

Author

Marquet A, Bui BT, Smith AG, and Warren MJ

Subjects

Molecular Structure, Enzymes metabolism, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism

Abstract

Iron-sulfur proteins are very versatile biological entities for which many new functions are continuously being unravelled. This review focus on their role in the initiation of radical chemistry, with special emphasis on radical-SAM enzymes, since several members of the family catalyse key steps in the biosynthetic pathways of cofactors such as biotin, lipoate, thiamine, heme and the molybdenum cofactor. It will also include other examples to show the chemical logic which is emerging from the presently available data on this family of enzymes. The common step in all the (quite different) reactions described here is the monoelectronic reductive cleavage of SAM by a reduced [4Fe-4S](1+) cluster, producing methionine and a highly oxidising deoxyadenosyl radical, which can initiate chemically difficult reactions. This set of enzymes, which represent a means to perform oxidation under reductive conditions, are often present in anaerobic organisms. Some other, non-SAM-dependent, radical reactions obeying the same chemical logic are also covered.

Published

2007

2. Evolution of enzymes and pathways for the biosynthesis of cofactors.

Author

Holliday GL, Thornton JM, Marquet A, Smith AG, Rébeillé F, Mendel R, Schubert HL, Lawrence AD, and Warren MJ

Subjects

Biological Evolution, Coenzymes biosynthesis, Enzymes metabolism, Models, Biological

Abstract

The evolution of metabolic pathways is discussed with reference to the biosynthesis of a number of vitamins and cofactors. Retrograde and patchwork models are highlighted and their relevance to our knowledge of pathway processes and enzymes is examined. Pathway complexity is explained in terms of the acquisition of broad specificity enzymes.

Published

2007

3. Elucidation of the anaerobic pathway for the corrin component of cobalamin (vitamin B₁₂)

Author

Moore, Simon J., Lawrence, Andrew D., Biedendieck, Rebekka, Deery, Evelyne, Frank, Stefanie, Howard, Mark J., Rigby, Stephen E. J., and Warren, Martin J.

Published

2013

4. Molecular hijacking of siroheme for the synthesis of heme and d₁s heme

Author

Bali, Shilpa, Lawrence, Andrew D., Lobo, Susana A., Saraiva, Lígia M., Golding, Bernard T., Palmer, David J., Howard, Mark J., Ferguson, Stuart J., and Warren, Martin J.

Published

2011

5. Evolution in a family of chelatases facilitated by the introduction of active site asymmetry and protein oligomerization

Author

Romão, Célia V., Ladakis, Dimitrios, Lobo, Susana A. L., Carrondo, Maria A., Brindley, Amanda A., Deery, Evelyne, Matias, Pedro M., Pickersgill, Richard W., Saraiva, Lígia M., Warren, Martin J., and Matthews, Rowena G.

Published

2011

6. Finding the Final Pieces of the Vitamin $B_{12}$ Biosynthetic Jigsaw

Author

Warren, Martin J.

Published

2006

7. Structure of porphobilinogen deaminase reveals a flexible multidomain polymerase with a single catalytic site

Author

Louie, Gordon V., Brownlie, Paul D., Lambert, Richard, Cooper, Jonathan B., Blundell, Tom L., Wood, Steve P., Warren, Martin J., Woodcock, Sarah C., and Jordan, Peter M.

Subjects

Porphobilinogen -- Research, Enzymes, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

Porphobilinogen deaminase (PBGD), an important enzyme in the biosynthetic pathway of tetrapyrroles, is structurally similar to the transferrins and periplasmic binding proteins. PBGD's dipyrromethane cofactor is covalently associated with domain 3 but is also attached to the salt-bridges and hydrogen-bonds in the cleft separating domains 1 and 2 in a location that corresponds to the binding sites for small-molecule ligands in the protein analogues. This structure, verified by X-ray analysis, indicates that PBGD has one catalytic site.

Published

1992

8. Elucidation of the anaerobic pathway for the corrin component of cobalamin (vitamin B12).

Author

Moore, Simon J., Lawrence, Andrew D., Biedendieck, Rebekka, Deery, Evelyne, Frank, Stefanie, Howard, Mark J., Rigby, Stephen E. J., and Warren, Martin J.

Subjects

VITAMIN B12, BACILLUS megaterium, UROPORPHYRINOGEN, BIOSYNTHESIS, ENZYMES, CHEMICAL derivatives

Abstract

It has been known for the past 20 years that two pathways exist in nature for the de novo biosynthesis of the coenzyme form of vitamin B12, adenosylcobalamin, representing aerobic and anaerobic routes. In contrast to the aerobic pathway, the anaerobic route has remained enigmatic because many of its intermediates have proven technically challenging to isolate, because of their inherent instability. However, by studying the anaerobic cobalamin biosynthetic pathway in Bacillus megaterium and using homologously overproduced enzymes, it has been possible to isolate all of the intermediates between uroporphyrinogen III and cobyrinic acid. Consequently, it has been possible to detail the activities of purified cobinamide biosynthesis (Cbi) proteins CbiF, CbiG, CbiD, CbiJ, CbiET, and CbiC, as well as show the direct in vitro conversion of 5-aminolevulinic acid into cobyrinic acid using a mixture of 14 purified enzymes. This approach has resulted in the isolation of the long sought intermediates, cobalt-precorrin-6A and -6B and cobalt-precorrin-8. EPR, in particular, has proven an effective technique in following these transformations with the cobalt(II) paramagnetic electron in the dyz orbital, rather than the typical dz2. This result has allowed us to speculate that the metal ion plays an unexpected role in assisting the interconversion of pathway intermediates. By determining a function for all of the pathway enzymes, we complete the tool set for cobalamin biosynthesis and pave the way for not only enhancing cobalamin production, but also design of cobalamin derivatives through their combinatorial use and modification. [ABSTRACT FROM AUTHOR]

Published

2013

9. Bacillus megaterium Has Both a Functional BluB Protein Required for DMB Synthesis and a Related Flavoprotein That Forms a Stable Radical Species.

Author

Collins, Hannah F., Biedendieck, Rebekka, Leech, Helen K., Gray, Michael, Escalante-Semerena, Jorge C., McLean, Kirsty J., Munro, Andrew W., Rigby, Stephen E. J., Warren, Martin J., and Lawrence, Andrew D.

Subjects

BACILLUS megaterium, FLAVOPROTEINS, VITAMIN B12 synthesis, BENZIMIDAZOLE derivatives, SOIL microbiology, RECOMBINANT proteins, GENE expression, CATALYSIS, SEMIQUINONE

Abstract

Despite the extensive study of the biosynthesis of the complex molecule B12 (cobalamin), the mechanism by which the lower ligand 5,6-dimethylbenzimidazole (DMB) is formed has remained something of a mystery. However, recent work has identified and characterized a DMB-synthase (BluB) responsible for the oxygen-dependent, single enzyme conversion of FMN to DMB. In this work, we have identified BluB homologs from the aerobic purple, nonsulfur, photosynthetic bacterium Rhodobacter capsulatus and the aerobic soil bacterium Bacillus megaterium and have demonstrated DMB synthesis by the use of a novel complementation assay in which a B12 deficient strain, substituted with the precursor cobinamide is recovered either by the addition of DMB or by the recombinant expression of a bluB gene. The DMB-synthetic activity of the purified recombinant BluB enzymes was further confirmed in vitro by providing the enzyme with FMNH2 and oxygen and observing the formation of DMB by HPLC. The formation of a 4a-peroxyflavin intermediate, the first step in the oxygen dependent mechanism of DMB biosynthesis, is reported here and is the first intermediate in the enzyme catalysed reaction to be demonstrated experimentally to date. The identification and characterization of an FMN-binding protein found on the cobI operon of B. megaterium, CbiY, is also detailed, revealing an FMN-containing enzyme which is able to stabilize a blue flavin semiquinone upon reduction with a 1-electron donor. [ABSTRACT FROM AUTHOR]

Published

2013

10. Molecular hijacking of siroheme for the synthesis of heme and d1 heme.

Author

Bali, Shilpa, Lawrence, Andrew D., Lobo, Susana A., Saraiva, Lígia M., Golding, Bernard T., Palmer, David J., Howard, Mark J., Ferguson, Stuart J., and Warren, Martin J.

Subjects

HEME, TETRAPYRROLES, ENZYMES, BIOSYNTHESIS, DECARBOXYLATION

Abstract

Modified tetrapyrroles such as chlorophyll, heme, siroheme, vitamin B12, coenzyme F430, and heme d1 underpin a wide range of essential biological functions in all domains of life, and it is therefore surprising that the syntheses of many of these life pigments remain poorly understood. It is known that the construction of the central molecular framework of modified tetrapyrroles is mediated via a common, core pathway. Herein a further branch of the modified tetrapyrrole biosynthesis pathway is described in denitrifying and sulfate-reducing bacteria as well as the Archaea. This process entails the hijacking of siroheme, the prosthetic group of sulfite and nitrite reductase, and its processing into heme and d1 heme. The initial step in these transformations involves the decarboxylation of siroheme to give didecarboxysiroheme. For d1 heme synthesis this intermediate has to undergo the replacement of two propionate side chains with oxygen functionalities and the introduction of a double bond into a further peripheral side chain. For heme synthesis didecarboxysiroheme is converted into Fe-coproporphyrin by oxidative loss of two acetic acid side chains. Fe-coproporphyrin is then transformed into heme by the oxidative decarboxylation of two propionate side chains. The mechanisms of these reactions are discussed and the evolutionary significance of another role for siroheme is examined. [ABSTRACT FROM AUTHOR]

Published

2011

11. Structure of PduT, a trimeric bacterial microcompartment protein with a 4Fe-4S cluster-binding site.

Author

Pang, Allan, Warren, Martin J., and Pickersgill, Richard W.

Subjects

*PROTEINS, *BINDING sites, *BACTERIA, *CARBON dioxide, *CELL compartmentation, *ENZYMES

Abstract

The article discusses the structure of the bacterial microcompartment (BMC) protein PduT, which is a trimeric bacterial microcompartment protein with a 4Fe-4S cluster-binding site. It claims that BMCs are polyhedral cellular inclusions with a protein shell that houses a particular metabolic process. It also cites the propanediol-utilization (Pdu) microcompartment shell that is made from thousands of hexagonal-shaped protein complexes.

Published

2011

12. Enzyme Sequence and Its Relationship to Hyperbaric Stability of Artificial and Natural Fish Lactate Dehydrogenases.

Author

Brindley, Amanda A., Pickersgill, Richard W., Partridge, Julian C., Dunstan, David J., Hunt, David M., and Warren, Martin J.

Subjects

ENZYMES, HYPERBARIC oxygenation, FISHES, LACTATE dehydrogenase, ESCHERICHIA coli, AMINO acids, IMINO acids, LOW temperatures

Abstract

The cDNAs of lactate dehydrogenase b (LDH-b) from both deep-sea and shallow living fish species, Corphaenoides armatus and Gadus morhua respectively, have been isolated, sequenced and their encoded products overproduced as recombinant enzymes in E. coli. The proteins were characterised in terms of their kinetic and physical properties and their ability to withstand high pressures. Although the two proteins are very similar in terms of their primary structure, only 21 differences at the amino acid level exist between them, the enzyme from the deep-sea species has a significantly increased tolerance to pressure and a higher thermostability. It was possible to investigate whether the changes in the N-terminal or C-terminal regions played a greater role in barophilic adaptation by the construction of two chimeric enzymes by use of a common restriction site within the cDNAs. One of these hybrids was found to have even greater pressure stability than the recombinant enzyme from the deep-living fish species. It was possible to conclude that the major adaptive changes to pressure tolerance must be located in the N-terminal region of the protein. The types of changes that are found and their spatial location within the protein structure are discussed. An analysis of the kinetic parameters of the enzymes suggests that there is clearly a trade off between Km and kcat values, which likely reflects the necessity of the deep-sea enzyme to operate at low temperatures. [ABSTRACT FROM AUTHOR]

Published

2008

13. Finding the final pieces of the vitamin B12 biosynthetic jigsaw.

Author

Warren, Martin J.

Subjects

ENZYMES, FLAVINS, VITAMIN B12, GENES, BIOSYNTHESIS

Abstract

The article comments on a study by G.R.O. Campbell and colleagues about an enzyme that appears to play a key role in the transformation of flavin in dimethylbenzimidazole (DMB). According to the author, the team proved that a mutant in bluB gene was able to grow in the presence of either vitamin B12 or DMB but not in the presence of cobinamide. He also mentions the limitations of Campell's study.

Published

2006

14. Isolation and characterization of 14 additional genes specifying the anaerobic biosynthesis of cobalamin (vitamin B[sub 12]) in Propionibacterium freudenreichii (P. shermanii).

Author

Roessner, Charles A., Ke-xue Huang, Warren, Martin J., Raux, Evelyn, and Scott, A. Ian

Subjects

*PROPIONIBACTERIUM, *VITAMIN B12, *ENZYMES

Abstract

Investigates the synthesis of cobalamin (vitamin b[sub 12]) in Propionibacterium freudenreichii. Isolation of gene encoding enzymes; Linkage among the subunits of transcarboxylase to the hemYHBXRL gene cluster; Proposal on the mechanism for the regulation of cobalamin and propionic acid production.

Published

2002

15. Structural Insights into Higher Order Assembly and Function of the Bacterial Microcompartment Protein PduA.

Author

Pang, Allan, Frank, Stefanie, Brown, Ian, Warren, Martin J., and Pickersgill, Richard W.

Subjects

*PROTEINS, *CYTOPLASM, *ENZYMES, *PROPYLENE glycols, *ESCHERICHIA coli, *AMINO acid residues, *GLYCERIN, *CRYSTAL lattices

Abstract

Bacterial microcompartments are large proteinaceous assemblies that are found in the cytoplasm of some bacteria. These structures consist of proteins constituting a shell that houses a number of enzymes involved in specific metabolic processes. The 1,2-propanediol-utilizing microcompartment is assembled from seven different types of shell proteins, one of which is PduA. It is one of the more abundant components of the shell and intriguingly can form nanotubule-like structures when expressed on its own in the cytoplasm of Escherichia coli. We propose a model that accounts for the size and appearance of these PduA structures and underpin our model using a combinatorial approach. Making strategic mutations at Lys-26, Val- 51, and Arg-79, we targeted residues predicted to be important for PduA assembly. We present the effect of the amino acid residue substitution on the phenotype of the PduA higher order assemblies (transmission electron microscopy) and the crystal structure of the K26D mutant with one glycerol molecule bound to the central pore. Our results support the view that the hexamer- hexamer interactions seen in PduA crystals persist in the cytoplasmic structures and reveal the profound influence of the two key amino acids, Lys-26 and Arg-79, on tiling, not only in the crystal lattice but also in the bacterial cytoplasm. Understanding and controlling PduA assemblies is valuable in order to inform manipulation for synthetic biology and biotechnological applications. [ABSTRACT FROM AUTHOR]

Published

2014

16. Elucidation of the anaerobic pathway for the corrin component of cobalamin (vitamin B12).

Author

Moore, Simon J., Lawrence, Andrew D., Biedendieck, Rebekka, Deery, Evelyne, Frank, Stefanie, Howard, Mark J., Rigby, Stephen E. J., and Warren, Martin J.

Subjects

*VITAMIN B12, *BACILLUS megaterium, *UROPORPHYRINOGEN, *BIOSYNTHESIS, *ENZYMES, *CHEMICAL derivatives

Abstract

It has been known for the past 20 years that two pathways exist in nature for the de novo biosynthesis of the coenzyme form of vitamin B12, adenosylcobalamin, representing aerobic and anaerobic routes. In contrast to the aerobic pathway, the anaerobic route has remained enigmatic because many of its intermediates have proven technically challenging to isolate, because of their inherent instability. However, by studying the anaerobic cobalamin biosynthetic pathway in Bacillus megaterium and using homologously overproduced enzymes, it has been possible to isolate all of the intermediates between uroporphyrinogen III and cobyrinic acid. Consequently, it has been possible to detail the activities of purified cobinamide biosynthesis (Cbi) proteins CbiF, CbiG, CbiD, CbiJ, CbiET, and CbiC, as well as show the direct in vitro conversion of 5-aminolevulinic acid into cobyrinic acid using a mixture of 14 purified enzymes. This approach has resulted in the isolation of the long sought intermediates, cobalt-precorrin-6A and -6B and cobalt-precorrin-8. EPR, in particular, has proven an effective technique in following these transformations with the cobalt(II) paramagnetic electron in the dyz orbital, rather than the typical dz2. This result has allowed us to speculate that the metal ion plays an unexpected role in assisting the interconversion of pathway intermediates. By determining a function for all of the pathway enzymes, we complete the tool set for cobalamin biosynthesis and pave the way for not only enhancing cobalamin production, but also design of cobalamin derivatives through their combinatorial use and modification. [ABSTRACT FROM AUTHOR]

Published

2013

17. Identification and Characterization of a Novel Vitamin B12 (Cobalamin) Biosynthetic Enzyme (CobZ) from Rhodobacter capsulatus, Containing Flavin, Heme, and Fe-S Cofactors.

Author

McGoldrick, Helen M., Roessner, Charles A., Raux, Evelyne, Lawrence, Andrew D., McLean, Kirsty J., Munro, Andrew W., Santabarbara, Stefano, Rigby, Stephen E. J., Heathcote, Peter, Scott, A. Ian, and Warren, Martin J.

Subjects

*VITAMIN B12, *ENZYMES, *FLAVINS, *HEME, *ESCHERICHIA coli, *BIOCHEMISTRY, *BIOCHEMICAL engineering

Abstract

One of the most intriguing steps during cobalamin (vitamin B12) biosynthesis is the ring contraction process that leads to the extrusion of one of the integral macrocyclic carbon atoms from the tetrapyrrole-derived framework. The aerobic cobalamin pathway requires the action of a monooxygenase called CobG (precorrin-3B synthase), which generates a hydroxylactone intermediate that is subsequently ring-contracted by CobJ. However, in the photosynthetic bacterium Rhodobacter capsulatus, which harbors an aerobic-like pathway, there is no cobG in the main cobalamin biosynthetic operon although it does contain an additional uncharacterized gene called orf663. To demonstrate the involvement of Orf663 in cobalamin synthesis, the first dedicated 10 genes of the B12 pathway (including orf663), encoding enzymes for the transformation of uroporphyrinogen III into hydrogenobyrinic acid (HBA), were sequentially cloned into a plasmid to generate an artificial operon, which, when transformed into Escherichia coli, endowed the host with the ability to make HBA. Deletion of orf663 from this operon prevented HBA synthesis, demonstrating that it was essential for corrin construction. HBA synthesis was restored to this recombinant strain either by returning orf663 or by substituting it with cobG. Recombinant overproduction of Orf663, now renamed CobZ, allowed the characterization of a novel cofactor-rich protein, housing two Fe-S centers, a flavin, and a heme group, which like B12 itself is a modified tetrapyrrole. A mechanism for Orf663 (CobZ) in cobalamin biosynthesis is proposed. [ABSTRACT FROM AUTHOR]

Published

2005

18. Structure/Function Studies on a S-Adenosyl-<ce:small-caps xmlns:ce="http://www.elsevier.com/xml/common/dtd">l-methionine-dependent Uroporphyrinogen III C Methyltransferase (SUMT), a Key Regulatory Enzyme of Tetrapyrrole Biosynthesis

Author

Vévodová, Jitka, Graham, Ross M., Raux, Evelyne, Schubert, Heidi L., Roper, David I., Brindley, Amanda A., Ian Scott, A., Roessner, Charles A., Stamford, N. Patrick J., Elizabeth Stroupe, M., Getzoff, Elizabeth D., Warren, Martin J., and Wilson, Keith S.

Subjects

*METHIONINE, *METHYLTRANSFERASES, *BIOSYNTHESIS, *ENZYMES

Abstract

The crystallographic structure of the Pseudomonas denitrificans S-adenosyl-l-methionine-dependent uroporphyrinogen III methyltransferase (SUMT), which is encoded by the cobA gene, has been solved by molecular replacement to 2.7Å resolution. SUMT is a branchpoint enzyme that plays a key role in the biosynthesis of modified tetrapyrroles by controlling flux to compounds such as vitamin B12 and sirohaem, and catalysing the transformation of uroporphyrinogen III into precorrin-2. The overall topology of the enzyme is similar to that of the SUMT module of sirohaem synthase (CysG) and the cobalt-precorrin-4 methyltransferase CbiF and, as with the latter structures, SUMT has the product S-adenosyl-l-homocysteine bound in the crystal. The roles of a number of residues within the SUMT structure are discussed with respect to their conservation either across the broader family of cobalamin biosynthetic methyltransferases or within the sub-group of SUMT members. The D47N, L49A, F106A, T130A, Y183A and M184A variants of SUMT were generated by mutagenesis of the cobA gene, and tested for SAM binding and enzymatic activity. Of these variants, only D47N and L49A bound the co-substrate S-adenosyl-l-methionine. Consequently, all the mutants were severely restricted in their capacity to synthesise precorrin-2, although both the D47N and L49A variants produced significant quantities of precorrin-1, the monomethylated derivative of uroporphyrinogen III. The activity of these variants is interpreted with respect to the structure of the enzyme. [Copyright &y& Elsevier]

Published

2004

19. A Story of Chelatase Evolution.

Author

Brindley, Amanda A., Raux, Evelyne, Leech, Helen K., Schubert, Heidi L., and Warren, Martin J.

Subjects

*VITAMIN B12, *RECOMBINANT proteins, *ENZYMES

Abstract

Describes the cloning of the cobalamin (CbiX) gene from two methanogens, the overproduction of CbiX as a recombinant protein, and its inherent enzymatic activity in order to demonstrate that CbiX represents a compact cobalt chelatase in methanogens. Protein expression; Structural topology predictions for the CbiX[supS] and CbiX[supL] enzymes.

Published

2003