Functional oligomeric state of avian sarcoma virus integrase

Retroviral integrase, one of only three enzymes encoded by the virus, catalyzes the essential step of inserting a DNA copy of the viral genome into the host during infection. Using the avian sarcoma virus integrase, we demonstrate that the enzyme functions as a tetramer. In presteady-state active site titrations, four integrase protomers were required for a single catalytic turnover. Volumetric determination of integrase-DNA complexes imaged by atomic force microscopy during the initial turnover additionally revealed substrate-induced assembly of a tetramer. These results suggest that tetramer formation may be a requisite step during catalysis with ramifications for antiviral design strategies targeting the structurally homologous human immunodeficiency virus, type 1 (HIV-1) integrase.

Flipping duplex DNA inside out: a double base-flipping reaction mechanism by Escherichia coli MutY adenine glycosylase

The Escherichia coli MutY adenine glycosylase plays a critical role in repairing mismatches in DNA between adenine and the oxidatively damaged guanine base 8-oxoguanine. Crystallographic studies of the catalytic core domain of MutY show that the scissile adenine is extruded from the DNA helix to be bound in the active site of the enzyme (Guan, Y., Manuel, R. C., Arvai, A. S., Parikh, S. S., Mol, C. D., Miller, J. H., Lloyd, S., and Tainer, J. A. (1998) Nat. Struct. Biol. 5, 1058-1064). However, the structural and mechanistic bases for the recognition of the 8-oxoguanine remain poorly understood. In experiments using a single-stranded 8-bromoguanine-containing synthetic oligodeoxyribonucleotide alone and in a duplex construct mismatched to an adenine, we observed UV cross-linking between MutY and the 8-bromoguanine probe. We further observed enhanced cross-linking in the single strand experiments, suggesting that neither the duplex context nor the mismatch with adenine is required for recognition of the 8-oxoguanine moiety. Stopped-flow fluorescence studies using 2-aminopurine-containing oligodeoxyribonucleotides further revealed the sequential extrusion of the 8-oxoguanine at 108 s(-1) followed by the adenine at 16 s(-1). A protein isomerization step following base flipping at 1.9 s(-1) was also observed and is postulated to provide additional stabilization of the extruded adenine thereby facilitating its capture by the active site for excision.

Presteady-state analysis of avian sarcoma virus integrase. I. A splicing activity and structure-function implications for cognate site recognition

Integrase catalyzes insertion of a retroviral genome into the host chromosome. After reverse transcription, integrase binds specifically to the ends of the duplex retroviral DNA, endonucleolytically cleaves two nucleotides from each 3'-end (the processing activity), and inserts these ends into the host DNA (the joining activity) in a concerted manner. In first-turnover experiments with synapsed DNA substrates, we observed a novel splicing activity that resembles an integrase joining reaction but uses unprocessed ends. This splicing reaction showed an initial exponential phase (k(splicing) = 0.02 s(-1)) of product formation and generated products macroscopically indistinguishable from those created by the processing and joining activities, thus bringing into question methods previously used to quantitate these reactions in a time regime where multiple turnovers of the enzyme have occurred. With a presteady-state assay, however, we were able to distinguish between different pathways that led to formation of identical products. Furthermore, the splicing reaction allowed characterization of substrate binding and specificity. Although integrase requires only a 3' hydroxyl with respect to nucleophiles derived from DNA, it specifically favors the cognate sequence CATT as the electrophile. These experimental results support a two-site "switching" model for binding and catalysis of all three integrase activities.

Presteady-state analysis of avian sarcoma virus integrase. II. Reverse-polarity substrates identify preferential processing of the U3-U5 pair

The integrase-catalyzed insertion of the retroviral genome into the host chromosome involves two reactions in vivo: 1) the binding and endonucleolytic removal of the terminal dinucleotides of the viral DNA termini and 2) the recombination of the ends with the host DNA. Kukolj and Skalka (Kukolj, G., and Skalka, A. M. (1995) Genes Dev. 9, 2556-2567) have previously shown that tethering of the termini enhances the endonucleolytic activities of integrase. We have used 5'-5' phosphoramidites to design reverse-polarity tethers that allowed us to examine the reactivity of two viral long terminal repeat-derived sequences when concurrently bound to integrase and, additionally, developed presteady-state assays to analyze the initial exponential phase of the reaction, which is a measure of the amount of productive nucleoprotein complexes formed during preincubation of integrase and DNA. Furthermore, the reverse-polarity tether circumvents the integrase-catalyzed splicing reaction (Bao, K., Skalka, A. M., and Wong, I. (2002) J. Biol. Chem. 277, 12089-12098) that obscures accurate analysis of the reactivities of synapsed DNA substrates. Consequently, we were able to establish a lower limit of 0.2 s(-1) for the rate constant of the processing reaction. The analysis showed the physiologically relevant U3/U5 pair of viral ends to be the preferred substrate for integrase with the U3/U3 combination favored over the U5/U5 pair.