Can the tricyanomethanide anion improve CO2 absorption by acetate-based ionic liquids?

Carbon dioxide absorption by mixtures of two ionic liquids with a common cation-1-butyl-3-methylimidazolium acetate, [C4C1Im][OAc], and 1-butyl-3-methylimidazolium tricyanomethanide, [C4C1Im][C(CN)3]-was determined experimentally at pressures below atmospheric pressure as a function of temperature between 303 K and 343 K, and at 303 K as a function of pressure up to 10 bar. It is observed that the absorption of carbon dioxide decreases with increasing tricyanomethanide anion concentration and with increasing temperature, showing a maximum of 0.4 mole fraction of carbon dioxide in pure [C4C1Im][OAc] at 303 K. At this temperature, the CO2 absorption in the mixtures [C4C1Im][OAc](1-x)[C(CN)3]x is approximately the mole-fraction average of that in the pure ionic liquids. By applying an appropriate thermodynamic treatment, after identification of the species in solution, it was possible to calculate both the equilibrium constant, Keq, and Henry's law constant, KH, in the different mixtures studied thus obtaining an insight into the relative contribution of chemical and physical absorption of the gas. It is shown that chemical sorption proceeds through a 1 : 2 stoichiometry between CO2 and acetate-based ionic liquid. The presence of the C(CN)3- anion does not significantly affect the chemical reaction of the gas with the solvent (Keq = 75 ± 2 at 303 K) but leads to lower Henry's law constants (from KH = 77.8 ± 0.6 bar to KH = 49.5 ± 0.5 bar at 303 K), thus pointing towards larger physical absorption of the gas. The tricyanomethanide anion considerably improves the mass transfer by increasing the fluidity of the absorbent as proven by the larger diffusivities of all the ions when the concentration of the C(CN)3- anion increases in the mixtures.

Tailoring the properties of acetate-based ionic liquids using the tricyanomethanide anion.

The equilibrium and transport properties of mixtures of two ionic liquids - [C4C1Im][OAc] and [C4C1Im][C(CN)3] - were determined and interpreted at the molecular level using vibration spectroscopy, NMR and molecular dynamics simulation. The non-ideality of the mixtures [C4C1Im][OAc](1-x)[C(CN)3]x was characterized by V(E) = +0.28 cm(3) mol(-1) (293 K, x = 0.65) and H(E) = -2.2 kJ mol(-1) for x = 0.5. These values could be explained by a rearrangement of the hydrogen-bond network of the mixture that favours the interaction of the acetate anion with the imidazolium cation at position C2. The dynamic properties of the mixture are also dramatically influenced by the composition with a decrease of the viscosity and an increase of self-diffusion coefficients of the ions when the amount of tricyanomethanide anion increases in the mixture.

Relationship between hexamerization and ssDNA binding affinity in the uvsY recombination protein of bacteriophage T4.

In bacteriophage T4, homologous genetic recombination events are catalyzed by a presynaptic filament containing stoichiometric quantities of the T4 uvsX recombinase bound cooperatively to single-stranded DNA (ssDNA). The formation of this filament requires the displacement of cooperatively bound gp32 (the T4 ssDNA-binding protein) from the ssDNA, a thermodynamically unfavorable reaction. This displacement is mediated by the T4 uvsY protein (15.8 kDa, 137 amino acids), which interacts with both uvsX- and gp32-ssDNA complexes and modulates their properties. Previously, we showed that uvsY exists as a hexamer under physiological conditions and that uvsY hexamers bind noncooperatively but with high affinity to ssDNA. We also showed that a fusion protein containing the N-terminal 101 amino acid residues of uvsY lacks interactions with uvsX and gp32 but retains both weak ssDNA-binding activity and a residual ability to stimulate uvsX-catalyzed recombination functions. Here, we present quantitative data on the oligomeric structure and ssDNA-binding properties of a closely related fusion protein designated uvsY. Sedimentation velocity and equilibrium results establish that uvsY, unlike native uvsY, behaves as a monomer in solution (M(app) = 14.2 kDa, = 2.1). Like native uvsY, uvsY binds noncooperatively to an etheno-DNA (epsilonDNA) lattice with a binding site size of 4 nucleotides/monomer; however at physiological ionic strength, the association constant for uvsY-epsilonDNA is decreased 10(4)-fold relative to native uvsY. Nevertheless, the magnitude of the salt effect on the association constant (K) is essentially unchanged between uvsY and uvsY, indicating that disruption of the C-terminus does not disrupt the electrostatic ssDNA-binding determinants found within each protomer of uvsY. Instead, the large difference in ssDNA-binding affinities reflects the loss of hexamerization ability by uvsY, suggesting that a form of intrahexamer synergism or cooperativity between binding sites within the uvsY hexamer leads to its high observed affinity for ssDNA.

Single-stranded DNA binding properties of the UvsX recombinase of bacteriophage T4: binding parameters and effects of nucleotides.

Bacteriophage T4 provides an important model for the biochemistry and genetics of DNA metabolism. Phage-encoded proteins conduct all essential steps of T4 DNA replication, repair, and recombination. Central to these three processes is the T4 UvsX protein, a member of the filamentous, ATP-dependent class of general recombination enzymes typified by the Escherichia coli RecA protein. Like RecA, UvsX forms presynaptic filaments on single-stranded (ss) DNA, which are the obligatory nucleoprotein intermediates in recombination. Aspects of the T4 presynaptic filament are explored by quantitative characterization of the UvsX-ssDNA interaction using an etheno-derivitized single-stranded DNA molecule, epsilonDNA, whose fluorescence is enhanced by UvsX binding. Studies with this model lattice show that UvsX exhibits a moderate level of cooperativity (omega=100) when binding to epsilonDNA with a binding-site size (n) equal to four nucleotide residues. Salt-stability studies of this complex reveal that the non-hydrolyzable ATP analog, ATPgammaS, induces a high-affinity binding mode that is distinguishable from complexes formed with ADP or in the absence of a nucleotide cofactor. With this new information, both functional relationships between the UvsX and RecA recombinases, and implications for UvsX interactions with the other proteins of the T4 presynaptic filament (UvsY and gp32) may be further explored.

Genetic analysis of a large kindred exhibiting type I protein C deficiency and associated thrombosis.

A previously described large Vermont kindred possessing a high incidence of venous thromboembolism with associated Type I protein C deficiency (1) has been genetically analyzed. All nine exons of the protein C gene, including both coding and non-coding regions, have been amplified from blood cell genomic DNA using the Tag DNA polymerase chain reaction (PCR) and primers corresponding to flanking intronic regions, and the products directly sequenced. An initial mutation (C-->T) resulting in Thr298-->Met was observed in one arm of the family exhibiting a history of thrombosis and protein C deficiency and was designated protein CVERMONT IIa. However, examination of the kindred member parent (male) of this arm and members of other arms of the kindred demonstrated that the mutation entered the arm via the genetically unrelated spouse. Further analysis of the father and members of other arms of the kindred revealed a different mutation (C insertion: CAT-->CCAT), resulting in a frameshift beginning at amino acid #107 (His-->Pro) and truncation of the protein at codon #119 of the mature protein. This mutation, called protein CVERMONT IIb, is associated with protein C deficiency and thrombosis throughout the kindred.