Your search keyword '"Montfort, William R."' showing total 7 results

1. Transitive homology-guided structural studies lead to discovery of Cro proteins with 40% sequence identity but different folds

Author

Roessler, Christian G., Hall, Branwen M., Anderson, William J., Ingram, Wendy M., Roberts, Sue A., Montfort, William R., and Cordes, Matthew H.J.

Subjects

X-ray crystallography -- Methods, Protein folding -- Research, Proteins -- Natural history, Proteins -- Properties, Proteins -- Structure, Science and technology

Abstract

Proteins that share common ancestry may differ in structure and function because of divergent evolution of their amino acid sequences. For a typical diverse protein superfamily, the properties of a few scattered members are known from experiment. A satisfying picture of functional and structural evolution in relation to sequence changes, however, may require characterization of a larger, well chosen subset. Here, we employ a ''stepping-stone' method, based on transitive homology, to target sequences intermediate between two related proteins with known divergent properties. We apply the approach to the question of how new protein folds can evolve from preexisting folds and, in particular, to an evolutionary change in secondary structure and oligomeric state in the Cro family of bacteriophage transcription factors, initially identified by sequence-structure comparison of distant homologs from phages P22 and [lambda]. We report crystal structures of two Cro proteins, Xfaso 1 and Pfl 6, with sequences intermediate between those of P22 and [lambda]. The domains show 40% sequence identity but differ by switching of s-helix to [beta]-sheet in a C-terminal region spanning [approximately equal to]25 residues. Sedimentation analysis also suggests a correlation between helix-to-sheet conversion and strengthened dimerization. conformational switching | structural evolution | transitive homology | x-ray crystallography

Published

2008

2. Heme-assisted S-nitrosation of a proximal thiolate in a nitric oxide transport protein

Author

Weichsel, Andrzej, Maes, Estelle M., Andersen, John F., Valenzuela, Jesus G., Shokhireva, Tatjana Kh., Walker, F. Ann, and Montfort, William R.

Subjects

Proteins -- Research, Heme -- Research, Science and technology

Abstract

Certain bloodsucking insects deliver nitric oxide (NO) while feeding, to induce vasodilation and inhibit blood coagulation. We have I expressed, characterized, and determined the crystal structure of the Cimex lectularius (bedbug) nitrophorin, the protein responsible for NO storage and delivery, to understand how the insect successfully handles this reactive molecule. Surprisingly, NO binds not only to the ferric nitrophorin heme, but it can also be stored as an S-nitroso (SNO) conjugate of the proximal heme cysteine (Cys-60) when present at higher concentrations. EPR- and UV-visible spectroscopies, and a crystallographic structure determination to 1.75-[Angstrom] resolution, reveal SNO formation to proceed with reduction of the heme iron, yielding an Fe-NO complex. Stopped-flow kinetic measurements indicate that an ordered reaction mechanism takes place: initial NO binding occurs at the ferric heme and is followed by heine reduction, Cys-60 release from the heine iron, and SNO formation. Release of NO occurs through a reversal of these steps. These data provide, to our knowledge, the first view of reversible metal-assisted SNO formation in a protein and suggest a mechanism for its role in NO release from ferrous heme. This mechanism and Cimex nitrophorin structure are completely unlike those of the nitrophorins from Rhodnius prolixus, where NO protection is provided by a large conformational change that buries the heine nitrosyl complex, highlighting the remarkable evolution of proteins that assist insects in bloodfeeding. crystal structure | heme protein | nitrophorin | S-nitrosocysteine | S-nitroso

Published

2005

3. Crystal structure and electron transfer kinetics of CueO, a multicopper oxidase required for copper homeostasis in Escherichia coli

Author

Roberts, Sue A., Weichsel, Andrzej, Grass, Gregor, Thakali, Keshari, Hazzard, James T., Tollin, Gordon, Rensing, Christopher, and Montfort, William R.

Subjects

Homeostasis -- Physiological aspects, Copper -- Physiological aspects, Oxidation-reduction reaction -- Analysis, Enzymes -- Structure-activity relationship, Science and technology

Abstract

CueO (YacK), a multicopper oxidase, is part of the copper-regulatory cue operon in Escherichia coli. The crystal structure of CueO has been determined to 1.4-[Angstrom] resolution by using multiple anomalous dispersion phasing and an automated building procedure that yielded a nearly complete model without manual intervention. This is the highest resolution multicopper oxidase structure yet determined and provides a particularly clear view of the four coppers at the catalytic center. The overall structure is similar to those of laccase and ascorbate oxidase, but contains an extra 42-residue insert in domain 3 that includes 14 methionines, nine of which lie in a helix that covers the entrance to the type I (T1, blue) copper site. The trinuclear copper cluster has a conformation not previously seen: the Cu-O-Cu binuclear species is nearly linear (Cu-O-Cu bond angle = 170 [degrees]) and the third (type II) copper lies only 3.1 [Angstrom] from the bridging oxygen. CueO activity was maximal at pH 6.5 and in the presence of >100 [micro]M Cu(II). Measurements of intermolecular and intramolecular electron transfer with laser flash photolysis in the absence of Cu(II) show that, in addition to the normal reduction of the T1 copper, which occurs with a slow rate (k = 4 x [10.sup.7] [M.sup.-1]*[s.sup.-1]), a second electron transfer process occurs to an unknown site, possibly the trinuclear cluster, with k = 9 x [10.sup.7] [M.sup.-1].[s.sup.-1], followed by a slow intramolecular electron transfer to T1 copper (k ~ 10 [s.sup.-1]). These results suggest the methionine-rich helix blocks access to the T1 site in the absence of excess copper.

Published

2002

4. Promotion of purine nucleotide binding to thymidylate synthase by a potent folate analogue inhibitor, 1843U89

Author

Weichsel, Andrzej, Montfort, William R., Ciesla, Jaroslaw, and Maley, Frank

Subjects

Purines -- Analysis, Folic acid -- Antagonists, Nucleotides -- Analysis, Science and technology

Abstract

A study of the interactions of 1843U89 (U89) with thymidylate synthase (TS) by CD analysis shows that U89 increases the binding of 5-fluoro-2'-deoxyuridine-5-monophosphate and dUMP to TS of Escherichia coli and dGMP, GMP, dIMP, and IMP. The x-ray diffraction analysis indicates high stacking reaction between hydrogen bonds used in dUMP binding, the benzoquinazoline ring of U89 and guanine of dGMP. FdUMP, dUMP, GMP, dGMP and dIMP all exhibit specific ellipticity patterns with the folate analogue.

Published

1995

5. Rational reprogramming of fungal polyketide first-ring cyclization.

Author

Yuquan Xu, Tong Zhou, Zhengfu Thou, Shiyou Su, Roberts, Sue A., Montfort, William R., Jia Zeng, Ming Chen, Wei Zhang, Min Lin, Jixun Zhan, and Molnár, István

Subjects

DOPA, POLYKETIDE synthases, RING formation (Chemistry), HYDROQUINONE, BIOSYNTHESIS, PLURIPOTENT stem cells

Abstract

Resorcylic acid lactones and dihydroxyphenylacetic acid lactones represent important pharmacophores with heat shock response and immune system modulatory activities. The biosynthesis of these fungal polyketides involves a pair of collaborating iterative polyketide synthases (iPKSs): a highly reducing iPKS with product that is further elaborated by a nonreducing iPKS (nrPKS) to yield a 1,3-benzenediol moiety bridged by a macrolactone. Biosynthesis of unreduced polyketides requires the sequestration and programmed cyclization of highly reactive poly-β-ketoacyl intermediates to channel these uncommitted, pluripotent substrates to defined subsets of the polyketide structural space. Catalyzed by product template (PT) domains of the fungal nrPKSs and discrete aromatase/cyclase enzymes in bacteria, regiospecific first-ring aldol cyclizations result in characteristically different polyketide folding modes. However, a few fungal polyketides, including the dihydroxyphenylacetic acid lactone dehydrocurvularin, derive from a folding event that is analogous to the bacterial folding mode. The structural basis of such a drastic difference in the way a PT domain acts has not been investigated until now. We report here that the fungal vs. bacterial folding mode difference is portable on creating hybrid enzymes, and we structurally characterize the resulting unnatural products. Using structure-guided active site engineering, we unravel structural contributions to regiospecific aldol condensations and show that reshaping the cyclization chamber of a PT domain by only three selected point mutations is sufficient to reprogram the dehydrocurvularin nrPKS to produce polyketides with a fungal fold. Such rational control of first-ring cyclizations will facilitate efforts to the engineered biosynthesis of novel chemical diversity from natural unreduced polyketides. [ABSTRACT FROM AUTHOR]

Published

2013

6. Heme-assisted 5-nitrosation of a proximal thiolate in a nitric oxide transport protein.

Author

Weichsel, Andrzej, Maes, Estelle M., Andersen, John F., Valenzuela, Jesus G., Shokhireva, Tatjana Kh., Walker, F. Ann, and Montfort, William R.

Subjects

HEME, PORPHYRINS, HEMOGLOBINS, NITROSATION, CHEMICAL reactions, NITRIC oxide

Abstract

Certain bloodsucking insects deliver nitric oxide (NO) while feeding, to induce vasodilation and inhibit blood coagulation. We have expressed, characterized, and determined the crystal structure of the Cimexiectularius (bedbug) nitrophorin, the protein responsible for NO storage and delivery, to understand how the insect successfully handles this reactive molecule. Surprisingly, NO binds not only to the ferric nitrophorin heme, but it can also be stored as an S-nitroso (SNO) conjugate of the proximal heme cysteine (Cys-60) when present at higher concentrations. EPR- and UV-visible spectroscopies, and a crystallographic structure determination to 1.75-A resolution, reveal SNO formation to proceed with reduction of the heme iron, yielding an Fe-NO complex. Stopped-flow kinetic measurements indicate that an ordered reaction mechanism takes place: initial NO binding occurs at the ferric heme and is followed by heme reduction, Cys-60 release from the heme iron, and SNO formation. Release of NO occurs through a reversal of these steps. These data provide, to our knowledge, the first view of reversible metal-assisted SNO formation in a protein and suggest a mechanism for its role in NO release from ferrous heme. This mechanism and Cimex nitrophorin structure are completely unlike those of the nitrophorins from Rhodnius prolixus, where NO protection is provided by a large conformational change that buries the heme nitrosyl complex, highlighting the remarkable evolution of proteins that assist insects in blood feeding. [ABSTRACT FROM AUTHOR]

Published

2005

7. Rational reprogramming of fungal polyketide first-ring cyclization.

Author

Xu Y, Zhou T, Zhou Z, Su S, Roberts SA, Montfort WR, Zeng J, Chen M, Zhang W, Lin M, Zhan J, and Molnár I

Subjects

Aldehydes chemistry, Base Sequence, Catalytic Domain genetics, Cloning, Molecular, Cyclization physiology, Escherichia coli, Fermentation, Molecular Sequence Data, Molecular Structure, Saccharomyces cerevisiae, Sequence Analysis, DNA, Biosynthetic Pathways physiology, Models, Molecular, Polyketide Synthases metabolism, Polyketides metabolism, Protein Conformation, Protein Engineering methods, Saccharomyces cerevisiae Proteins biosynthesis

Abstract

Resorcylic acid lactones and dihydroxyphenylacetic acid lactones represent important pharmacophores with heat shock response and immune system modulatory activities. The biosynthesis of these fungal polyketides involves a pair of collaborating iterative polyketide synthases (iPKSs): a highly reducing iPKS with product that is further elaborated by a nonreducing iPKS (nrPKS) to yield a 1,3-benzenediol moiety bridged by a macrolactone. Biosynthesis of unreduced polyketides requires the sequestration and programmed cyclization of highly reactive poly-β-ketoacyl intermediates to channel these uncommitted, pluripotent substrates to defined subsets of the polyketide structural space. Catalyzed by product template (PT) domains of the fungal nrPKSs and discrete aromatase/cyclase enzymes in bacteria, regiospecific first-ring aldol cyclizations result in characteristically different polyketide folding modes. However, a few fungal polyketides, including the dihydroxyphenylacetic acid lactone dehydrocurvularin, derive from a folding event that is analogous to the bacterial folding mode. The structural basis of such a drastic difference in the way a PT domain acts has not been investigated until now. We report here that the fungal vs. bacterial folding mode difference is portable on creating hybrid enzymes, and we structurally characterize the resulting unnatural products. Using structure-guided active site engineering, we unravel structural contributions to regiospecific aldol condensations and show that reshaping the cyclization chamber of a PT domain by only three selected point mutations is sufficient to reprogram the dehydrocurvularin nrPKS to produce polyketides with a fungal fold. Such rational control of first-ring cyclizations will facilitate efforts to the engineered biosynthesis of novel chemical diversity from natural unreduced polyketides.

Published

2013