Repetitive nucleic acid sequences, which occur in abundance throughout the mammalian genome, are of enormous research interest due to their potential to adopt fascinating and unusual molecular structures such as the i-motif. In remarkable contrast to the DNA double helix, i-motif conformations are stabilized by protonated cytosine base pairs, (Cyt)H + (Cyt), that are centrally located in the core of the i-motif and intercalated vertically in an antiparallel fashion. An in-depth understanding of how modifications influence the stability of i-motif conformations is a prerequisite to understanding their biological functions and the development of effective means of tuning their stability for specific medical and technological applications. Here, the influence of the 2′-and 3′-hydroxy substituents of the sugar moieties and 5-methylation of the cytosine nucleobases on the base-pairing interactions of protonated cytidine nucleoside analogue base pairs, (xCyd)H + (xCyd), are examined by complementary threshold collision-induced dissociation techniques and computational methods. The xCyd nucleosides examined include the canonical DNA and RNA cytidine nucleosides, 2′-deoxycytidine (dCyd) and cytidine (Cyd), as well as several modified cytidine nucleoside analogues, 2′,3′-dideoxycytidine (ddCyd), 5-methyl-2′-deoxycytidine (m 5 dCyd), and 5-methylcytidine (m 5 Cyd). Comparisons among these model base pairs indicate that the 2′-and 3′-hydroxy substituents of the sugar moieties have very little influence on the strength of the base-pairing interactions, whereas 5-methylation of the cytosine nucleobases is found to enhance the strength of the base-pairing interactions. The increase in stability resulting from 5-methylation is only modest but is more than twice as large for the DNA than RNA protonated cytidine base pair. Overall, present results suggest that canonical DNA i-motif conformations should be more stable than analogous RNA i-motif conformations and that 5-methylation of cytosine residues, a significant epigenetic marker, provides greater stabilization to DNA than RNA i-motif conformations.
Ionic liquids (ILs) have become increasingly
popular due to their
useful and unique properties, yet there are still many unanswered
questions regarding their fundamental interactions. In particular,
details regarding the nature and strength of the intrinsic cation–anion
interactions and how they influence the macroscopic properties of
ILs are still largely unknown. Elucidating the molecular-level details
of these interactions is essential to the development of better models
for describing ILs and enabling the purposeful design of ILs with
properties tailored for specific applications. Current uses of ILs
are widespread and diverse and include applications for energy storage,
electrochemistry, designer/green solvents, separations, and space
propulsion. To advance the understanding of the energetics, conformations,
and dynamics of gas-phase IL clustering relevant to space propulsion,
threshold collision-induced dissociation approaches are used to measure
the bond dissociation energies (BDEs) of the 2:1 clusters of 1-alkyl-3-methylimidazolium
cations and tetrafluoroborate, [2C
n
mim:BF4]+. The cation, [C
n
mim]+, is varied across the series, 1-ethyl-3-methylimidazolium
[C2mim]+, 1-butyl-3-methylimidazolium [C4mim]+, 1-hexyl-3-methylimidazolium [C6mim]+, and 1-octyl-3-methylimidazolium [C8mim]+, to examine the structural and energetic effects of the size
of the 1-alkyl substituent on binding. Complementary electronic structure
calculations are performed to determine the structures and energetics
of the [C
n
mim]+ and [BF4]− ions and their binding preferences in
the (C
n
mim:BF4) ion pairs and
[2C
n
mim:BF4]+ clusters.
Several levels of theory, B3LYP, B3LYP-GD3BJ, and M06-2X, using the
6-311+G(d,p) basis set for geometry optimizations and frequency analyses
and the 6-311+G(2d,2p) basis set for energetics, are benchmarked to
examine their abilities to properly describe the nature of the binding
interactions and to reproduce the measured BDEs. The modest structural
variation among these [C
n
mim]+ cations produces only minor structural changes and variation in
the measured BDEs of the [2C
n
mim:BF4]+ clusters. Present findings indicate that the
dominant cation–anion interactions involve the 3-methylimidazolium
moieties and that these clusters are sufficiently small that differences
in packing effects associated with the variable length of the 1-alkyl
substituents are not yet significant.
Cisplatin, (NH3)2PtCl2, has been known as a successful metal-based anticancer drug for more than half a century. Its analogue, Argplatin, arginine-linked cisplatin, (Arg)PtCl2, is being investigated because it exhibits reactivity...
Uridine (Urd) is one of the naturally occurring pyrimidine nucleosides of RNA. 2'-Deoxyuridine (dUrd) is a naturally occurring modified form of Urd, but is not one of the canonical DNA nucleosides. In order to understand the effects of sodium cationization on the conformations and energetics of Urd and dUrd, infrared multiple photon dissociation (IRMPD) action spectroscopy experiments and density functional theory (DFT) calculations are performed. By comparing the calculated IR spectra of [Urd+Na] and [dUrd+Na] with the measured IRMPD spectra, the stable low-energy conformers populated in the experiments are determined. Anti oriented bidentate O2 and O2' binding conformers of [Urd+Na] are the dominant conformers populated in the experiments, whereas syn oriented tridentate O2, O4', and O5' binding conformers of [dUrd+Na] are dominantly populated in the experiments. The 2'-hydroxyl substituent of Urd stabilizes the anti oriented O2 binding conformers of [Urd+Na]. Significant differences between the measured IRMPD and calculated IR spectra for complexes of [Urd+Na] and [dUrd+Na] involving minor tautomeric forms of the nucleobase make it obvious that none are populated in the experiments. Survival yield analyses based on energy-resolved collision-induced dissociation (ER-CID) experiments suggest that the relative stabilities of protonated and sodium cationized Urd and dUrd follow the order: [dUrd+H] < [Urd+H] < [dUrd+Na] < [Urd+Na]. The 2'-deoxy modification is found to weaken the glycosidic bond of dUrd versus that of Urd for the sodium cationized uridine nucleosides.
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