Your search keyword '"Paul G. House"' showing total 4 results

1. Reactions of molecular nitrogen and triethylamine with coordinatively unsaturated iron carbonyls: spin effects on reactions

Author

Eric Weitz and Paul G. House

Subjects

chemistry.chemical_compound, Molecular nitrogen, Reaction rate constant, chemistry, Inorganic chemistry, General Physics and Astronomy, Physical and Theoretical Chemistry, Spin (physics), Triethylamine, Gas phase

Abstract

Rate constants for the reactions of N 2 + Fe(CO) 3 , N 2 + Fe(CO) 4 , CO + Fe(CO) 3 (N 2 ), N(C 2 H 5 ) 3 + Fe(CO) 3 , and N(C 2 H 5 ) 3 + Fe(CO) 4 are reported. The magnitudes of these rate constants are compared to rate constants for other reactions of Fe(CO) 3 and Fe(CO) 4 in the gas phase. The aforementioned reactions involving Fe(CO) 4 and Fe(CO) 3 (N 2 ) are anticipated to be formally spin disallowed. Factors that could influence the magnitude of the rate constants in these systems are discussed.

Published

1997

2. Reaction intermediates in the catalytic mechanism of Escherichia coli MutY DNA glycosylase

Author

Paul G. House, Amanda K. McCullough, Andrew J. Kurtz, Kenichi Hitomi, Raymond C. Manuel, John A. Tainer, M. L. Dodson, R. Stephen Lloyd, and Andrew S. Arvai

Subjects

Models, Molecular, Guanine, Time Factors, Stereochemistry, Protein Conformation, Glutamic Acid, Reaction intermediate, Crystallography, X-Ray, Biochemistry, Catalysis, DNA Glycosylases, chemistry.chemical_compound, Catalytic Domain, Escherichia coli, AP site, Lyase activity, Molecular Biology, Bond cleavage, Aspartic Acid, Binding Sites, biology, Dose-Response Relationship, Drug, Chemistry, Adenine, Lysine, Active site, Cell Biology, DNA, Lyase, Kinetics, Models, Chemical, DNA glycosylase, Mutation, biology.protein, Mutagenesis, Site-Directed

Abstract

The Escherichia coli adenine DNA glycosylase, MutY, plays an important role in the maintenance of genomic stability by catalyzing the removal of adenine opposite 8-oxo-7,8-dihydroguanine or guanine in duplex DNA. Although the x-ray crystal structure of the catalytic domain of MutY revealed a mechanism for catalysis of the glycosyl bond, it appeared that several opportunistically positioned lysine side chains could participate in a secondary beta-elimination reaction. In this investigation, it is established via site-directed mutagenesis and the determination of a 1.35-A structure of MutY in complex with adenine that the abasic site (apurinic/apyrimidinic) lyase activity is alternatively regulated by two lysines, Lys142 and Lys20. Analyses of the crystallographic structure also suggest a role for Glu161 in the apurinic/apyrimidinic lyase chemistry. The beta-elimination reaction is structurally and chemically uncoupled from the initial glycosyl bond scission, indicating that this reaction occurs as a consequence of active site plasticity and slow dissociation of the product complex. MutY with either the K142A or K20A mutation still catalyzes beta and beta-delta elimination reactions, and both mutants can be trapped as covalent enzyme-DNA intermediates by chemical reduction. The trapping was observed to occur both pre- and post-phosphodiester bond scission, establishing that both of these intermediates have significant half-lives. Thus, the final spectrum of DNA products generated reflects the outcome of a delicate balance of closely related equilibrium constants.

Published

2004

3. Potential double-flipping mechanism by E. coli MutY

Author

David G. Gorenstein, R. Stephen Lloyd, David E. Volk, Bruce A. Luxon, Paul G. House, Raymond C. Manuel, and Varatharasa Thiviyanathan

Subjects

Base Pair Mismatch, chemistry.chemical_compound, Protein structure, chemistry, Biochemistry, DNA glycosylase, Stereochemistry, DNA repair, Proteolytic enzymes, Biology, DNA-(apurinic or apyrimidinic site) lyase, Protein secondary structure, DNA

Abstract

To understand the structural basis of the recognition and removal of specific mismatched bases in double-stranded DNAs by the DNA repair glycosylase MutY, a series of structural and functional analyses have been conducted. MutY is a 39-kDa enzyme from Escherichia coli, which to date has been refractory to structural determination in its native, intact conformation. However, following limited proteolytic digestion, it was revealed that the MutY protein is composed of two modules, a 26-kDa domain that retains essential catalytic function (designated p26MutY) and a 13-kDa domain that is implicated in substrate specificity and catalytic efficiency. Several structures of the 26-kDa domain have been solved by X-ray crystallographic methods to a resolution of up to 1.2 A. The structure of a catalytically incompetent mutant of p26MutY complexed with an adenine in the substrate-binding pocket allowed us to propose a catalytic mechanism for MutY. Since reporting the structure of p26MutY, significant progress has been made in solving the solution structure of the noncatalytic C-terminal 13-kDa domain of MutY by NMR spectroscopy. The topology and secondary structure of this domain are very similar to that of MutT, a pyrophosphohydrolase. Molecular modeling techniques employed to integrate the two domains of MutY with DNA suggest that MutY can wrap around the DNA and initiate catalysis by potentially flipping adenine and 8-oxoguanine out of the DNA helix.

Published

2001

4. [Untitled]

Author

David E. Volk, David G. Gorenstein, Varatharasa Thiviyanathan, R. Stephen Lloyd, and Paul G. House

Subjects

biology, DNA repair, Guanine, Active site, Biochemistry, chemistry.chemical_compound, chemistry, DNA glycosylase, biology.protein, A-DNA, DNA mismatch repair, Spectroscopy, DNA, Cytosine

Abstract

MutY from Escherichia coli is a DNA mismatch repair enzyme involved in the base excision repair pathway. It is an adenine glycosylase which removes adenine when mispaired with guanine, cytosine or 7,8dihydro-8-oxoguanine (8-oxoG). 8-oxoG is a common DNA oxidative damage lesion and mutant strains of E. coli that lack MutY activity have elevated rates of G:C to T:A tranversions (Nghiem et al., 1988). Trypsin produced an N-terminal domain of residues 1–225, p26, and a C-terminal domain of 226–350, p13 (Manuel et al., 1996). The catalytic activity of the enzyme was found solely in the N-terminal domain. Recent work has determined the crystal structure of the p26 domain; the protein has a helix-hairpin-helix structural motif in common with a number of DNA glycosylases and DNA glycosylase/AP lysases (Guan et al., 1998). The crystal structure suggests that MutY utilizes a nucleotide flipping mechanism, in which the adenine is moved to an extrahelical position within the DNA, into an active site pocket where it is excised. Studies of intact MutY and the N-terminal domain show that the C-terminal domain affects substrate binding and mismatch repair activity. Manuel and Lloyd (1997) found that the largest differences between MutY and p26 in binding of natural substrates involved A:G and in mismatch activity A:C. Recent biochemical data suggest that the C-terminal domain is the principal determinant of 8-oxoG specificity (Noll et al., 1999).

Published

1999