Claudius Mundoma scite author profile

Thiourea, (H2N)2CS, aminoiminomethanesulfinic acid, H2N(HN)CSO2H (AIMSA), and aminoiminomethanesulfonic acid, H2N(HN=)CSO3H (AIMSOA) are all oxidized by mild oxidizing agents to a sulfate and an organic residue. AIMSA and AIMSOA are the postulated intermediates in the oxidation pathway of thiourea to sulfate. The oxidation of AIMSOA is accompanied by a cleavage of the C−S bond to form sulfate. Surprisingly, freshly prepared solutions of AIMSOA are oxidized by the common oxidants (oxyhalogens and halogens) at rates that are much slower than oxidation rates of AIMSA by the same oxidants. These results seem to suggest that AIMSOA may be structurally different from AIMSA and that the decomposition of AIMSOA to HSO3 - is the prerequisite to its oxidation. The oxidation pathway of AIMSA to SO4 2- also proceeds through the formation of HSO3 - and not predominantly through AIMSOA.

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Probing of Metal-Binding Domains of RNA Hairpin Loops by Laser-Induced Lanthanide(III) Luminescence

Greenbaum

Mundoma

Peterman

2001

Biochemistry

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Direct laser excitation of aqueous Eu(III) bound to specific RNA fragments was used to probe the metal-binding sites of the anticodon loop of tRNA(Phe) from E. coli and of a tetraloop containing a GNRA consensus sequence. Binding of Mg(II) or Eu(III) to either RNA fragment resulted in a higher melting transition, but no global change in structure was observed. Aqueous Eu(III) exhibits a single weak excitation peak at 17273 cm(-1), the intensity of which increased upon addition of the tRNA loop fragment. Analysis of incremental increases in the luminescence intensity upon complexation with the tRNA loop indicated a stoichiometry of one high-affinity Eu(III)-binding site per loop fragment, with a Kd of 1.3 +/- 0.2 microM. Competition experiments between Eu(III) and Mg(II) were consistent with the two metal ions binding to a common site and with an approximately 30-fold lesser affinity of the tRNA loop for Mg(II) than for Eu(III). The rate of luminescence decay following excitation of Eu(III) bound to the tRNA loop corresponded to displacement of up to 4-5 (of a possible 9) waters of hydration on binding to the tRNA loop. By comparison, Eu(III) binds to the DNA analogue of the tRNA loop with an 8-fold lesser affinity and one fewer direct coordination site than to the RNA sequence, suggesting that a 2'OH of RNA is one of the direct ligands. In contrast with the absence of a shift in the excitation peak of aqueous Eu(III) upon formation of the tRNA loop complex, direct excitation of Eu(III) bound to a GNRA tetraloop fragment resulted in a substantially blue-shifted excitation peak (17290 cm(-1)). The tetraloop fragment also has a single Eu(III)-binding site, with a Kd of 12 +/- 3 microM. The bound Eu(III) was competed by Mg(II), although the relative affinity for Mg(II) was approximately 150-450-fold less than that for Eu(III). The Eu(III)-binding site of the tetraloop site is highly dehydrated, with approximately 7 water molecules displaced upon binding by RNA ligands, suggesting that the blue-shift of the excitation peak is the result of Eu(III) specifically bound in a nonpolar site within the GNRA loop structure.

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Reactive Oxygen Species in the Aerobic Decomposition of Sodium Hydroxymethanesulfinate

Макаров

Mundoma

Svarovsky

et al. 1999

Archives of Biochemistry and Biophysics

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Sequestering of Eu(III) by a GAAA RNA Tetraloop

Mundoma

Greenbaum

2002

J. Am. Chem. Soc.

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The site-specific binding of metal ions maintains an important role in the structure, thermal stability, and function of folded RNA structures. RNA tetraloops of the "GNRA" family (where N = any base and R = any purine), which owe their unusual stability to base stacking and an extensive hydrogen bonding network, have been observed to bind metal ions having different chemical and geometric properties. We have used laser-induced lanthanide luminescence and isothermal titration calorimetry (ITC) to examine the metal-binding properties of an RNA stem loop of the GNRA family. Previous research has shown that a single Eu(III) ion binds the stem loop fragment in a highly dehydrated site with a K(d) of approximately 12 microM. Curve-fitting analysis of the broad luminescence excitation spectrum of Eu(III) upon complexation with the tetraloop fragment indicates the possibility of two microenvironments that do not differ in hydration number. Binding of Eu(III) to the loop was accompanied by positive enthalpic changes, consistent with energetic cost of removal of water molecules and suggesting that the binding is entropically driven. By comparison, binding of Mg(II) or Mn(II) to the RNA loop, or Eu(III) to the DNA analogue of the loop, was associated with exothermic changes, consistent with predominantly outer-sphere coordination. These results suggest specific binding, most probably involving ligands on the 5' side of the loop.

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