Browsing by Author "Battistin, Umberto"

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    Crystal structures of a dodecameric multicopper oxidase from Marinithermus hydrothermalis
    (International Union of Crystallography, 2021) Paavola, Joseph L.; Battistin, Umberto; Ogata, Craig M.; Georgiadis, Millie M.; Biochemistry and Molecular Biology, School of Medicine
    Multicopper oxidases (MCOs) represent a diverse family of enzymes that catalyze the oxidation of either an organic or a metal substrate with concomitant reduction of dioxygen to water. These enzymes contain variable numbers of cupredoxin domains, two, three or six per subunit, and rely on four copper ions, a single type I copper and three additional copper ions organized in a trinuclear cluster (TNC), with one type II and two type III copper ions, to catalyze the reaction. Here, two crystal structures and the enzymatic characterization of Marinithermus hydrothermalis MCO, a two-domain enzyme, are reported. This enzyme decolorizes Congo Red dye at 70°C in the presence of high halide concentrations and may therefore be useful in the detoxification of industrial waste that contains dyes. In two distinct crystal structures, MhMCO forms the trimers seen in other two-domain MCOs, but differs from these enzymes in that four trimers interact to create a dodecamer. This dodecamer of MhMCO forms a closed ball-like structure and has implications for the sequestration of bound divalent metal ions as well as substrate accessibility. In each subunit of the dodecameric structures, a Trp residue, Trp351, located between the type I and TNC sites exists in two distinct conformations, consistent with a potential role in facilitating electron transfer in the enzyme.
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    Role of nucleobase-specific interactions in the binding and bending of DNA by human male sex determination factor SRY
    (American Society for Biochemistry and Molecular Biology, 2024) Racca, Joseph D.; Chen, Yen-Shan; Brabender, Adam R.; Battistin, Umberto; Weiss, Michael A.; Georgiadis, Millie M.; Biochemistry and Molecular Biology, School of Medicine
    Y-chromosome-encoded master transcription factor SRY functions in the embryogenesis of therian mammals to initiate male development. Through interactions of its conserved high-mobility group box within a widened DNA minor groove, SRY and related Sox factors induce sharp bends at specific DNA target sites. Here, we present the crystal structure of the SRY high-mobility group domain bound to a DNA site containing consensus element 5'-ATTGTT. The structure contains three complexes in the asymmetric unit; in each complex, SRY forms 10 hydrogen bonds with minor-groove base atoms in 5'-CATTGT/ACAATG-3', shifting the recognition sequence by one base pair (italics). These nucleobase interactions involve conserved residues Arg7, Asn10, and Tyr74 on one side of intercalated Ile13 (the cantilever) and Arg20, Asn32, and Ser36 on the other. Unlike the less-bent NMR structure, DNA bend angles (69-84°) of the distinct box-DNA complexes are similar to those observed in homologous Sox domain-DNA structures. Electrophoretic studies indicate that respective substitutions of Asn32, Ser36, or Tyr74 by Ala exhibit slightly attenuated specific DNA-binding affinity and bend angles (70-73°) relative to WT (79°). By contrast, respective substitutions of Arg7, Asn10, or Arg20 by Ala markedly impaired DNA-binding affinity in association with much smaller DNA bend angles (53-65°). In a rodent cell-based model of the embryonic gonadal ridge, full-length SRY variants bearing these respective Ala substitutions exhibited significantly decreased transcriptional activation of SRY's principal target gene (Sox9). Together, our findings suggest that nucleobase-specific hydrogen bonds by SRY are critical for specific DNA binding, bending, and transcriptional activation.