Gas-phase studies of substrates for the DNA mismatch repair enzyme MutY.

The gas-phase thermochemical properties (tautomeric energies, acidity, and proton affinity) have been measured and calculated for adenine and six adenine analogues that were designed to test features of the catalytic mechanism used by the adenine glycosylase MutY. The gas-phase intrinsic properties are correlated to possible excision mechanisms and MutY excision rates to gain insight into the MutY mechanism. The data support a mechanism involving protonation at N7 and hydrogen bonding to N3 of adenine. We also explored the acid-catalyzed (non-enzymatic) depurination of these substrates, which appears to follow a different mechanism than that employed by MutY, which we elucidate using calculations.

Proteomic analysis of Bacillus anthracis Sterne vegetative cells.

Mass spectrometry and proteomics have found increasing use as tools for the rapid detection of pathogenic bacteria, even when they are in a mixture of non-pathogenic relatives. The success of this technique is greatly augmented by the availability of publicly accessible proteomic databases for specific pathogenic bacteria. To aid proteomic detection analyses for the causative agent of anthrax, we have constructed a comprehensive proteomic catalogue of vegetative Bacillus anthracis Sterne cells using liquid chromatography tandem-mass spectrometry. Proteins were separated by molecular weight or isoelectric point prior to tryptic digestion. Alternatively, the whole protein extract was digested and tryptic peptides were separated by cation exchange chromatography prior to Reverse Phase-LC-MS/MS. The use of three complementary, pre-analytical separation techniques resulted in the identification of 1048 unique proteins, including 694 cytosolic, 153 membrane (including 27 cell wall), and 30 secreted proteins, accounting for 19% of the total predicted proteome. Each identified protein was functionally categorized using the gene attribute database from TIGR CMR. These results provide a large proteomic catalogue of vegetative B. anthracis cells and, coupled with the recent proteomic catalogue of B. anthracis spore proteins, form a thorough summary of proteins expressed in the active and dormant stages of this organism.

Escherichia coli MutY and Fpg utilize a processive mechanism for target location.

MutY and formamidopyrimidine-DNA-glycosylase (Fpg) are base-excision repair (BER) enzymes involved in the 8-oxoguanine repair pathway in Escherichia coli. An impressive feature of these enzymes is the ability to locate 8-oxoguanine lesions among a large excess of undamaged DNA. To provide insight into the mechanism of target location, the ability of these enzyme to utilize a one-dimensional processive search (DNA sliding) or distributive (random diffusion-mediated) mechanism was investigated. Each enzyme was incubated with double-stranded concatemeric polynucleotides containing a site-specific target site at 25-nucleotide (nt) intervals. The products of each reaction were analyzed after further treatment and denaturation. A rapid accumulation of predominantly 25-nt fragments would indicate the utilization of a processive mechanism, whereas oligomeric multiples of 25-nt fragments would form if a distributive mechanism were used. Both Fpg and MutY were found to function processively on concatemers containing 7,8-dihydro-8-oxo-2'-deoxyguanosine (OG).C and G.A mispairs, respectively. An increase in sodium chloride concentration results in the modulation from a processive to distributive mechanism for both enzymes. Interestingly, processive behavior was not observed in the reaction of MutY with concatemers containing OG.A mispairs. A truncated form of MutY (Stop 225) containing only the N-terminal domain was found to behave in a manner consistent with a processive mechanism with both OG.A- and G.A-containing substrates. This suggests that the C-terminal domain of MutY plays an important role in the mechanism by which the enzyme detects OG.A base pairs in DNA.

Probing the requirements for recognition and catalysis in Fpg and MutY with nonpolar adenine isosteres.

The Escherichia coli DNA repair enzymes Fpg and MutY are involved in the prevention of mutations resulting from 7,8-dihydro-8-oxo-2'-deoxyguanosine (OG) in DNA. The nonpolar isosteres of 2'-deoxyadenosine, 4-methylbenzimidazole beta-deoxynucleoside (B), and 9-methyl-1H-imidazo[4,5-b]pyridine beta-deoxynucleoside (Q), were used to examine the importance of hydrogen bonding within the context of DNA repair. Specifically, the rate of base removal under single-turnover conditions by the MutY and Fpg glycosylases from duplexes containing OG:B and OG:Q mismatches, relative to OG:A mismatches, was evalulated. The reaction of Fpg revealed a 5- and 10-fold increase in rate of removal of OG from duplexes containing OG:B and OG:Q base pairs, respectively, relative to an OG:A mispair. These results suggest that the lack of the ability to hydrogen bond to the opposite base facilitates removal of OG. In contrast, adenine removal catalyzed by MutY was much more efficient from an OG:A mispair-containing duplex (k2 = 12 +/- 2 min(-1)) compared to the removal of B from an OG:B duplex (k(obs) < 0.002 min(-1)). Surprisingly, MutY was able to catalyze base removal from the OG:Q-containing substrate (k2 = 1.2 +/- 0.2 min(-1)). Importantly, the B and Q analogues are not deleterious to high-affinity DNA binding by MutY. In addition, the B and Q analogues are more susceptible to acid-catalyzed depurination illustrating that the enzyme-catalyzed mechanism is distinct from the nonenzymatic mechanism. Taken together, these results point to the importance of both N7 and N3 in the mechanism of adenine excision catalyzed by MutY.