The crystal structure of the title compound (C34H47N7O9, Mr = 697.79) has been determined by single-crystal X-ray diffraction. The crystal belongs to monoclinic, space group P21 with a = 9.000(8), b = 11.360(10), c = 17.841(15) , β = 97.083(14)°, V = 1810(3) 3, Z = 2, F(000) = 744, Dc = 1.280 g/cm3, μ = 0.094 mm-1, the final R = 0.0721 and wR = 0.1942 for 2479 observed reflections with I > 2σ(I). The two methyl groups attached to the cyclobutane ring are cis oriented. An intramolecular hydrogen bond (N(6)-H(6)…O(8)) introduces rigidity into the title molecule and the crystal structure is stabilized by intermolecular N-H…O hydrogen bonds. 相似文献
The oxidative splitting process of cis-syn 1,3-dimethyluracil cyclobutane dimer(DMUD) in aqueous solution was investigated using pulse radiolysis technique.The results indicated that DMUD can be splitted into 1,3-dimethyluracil(DMU) by OH radicals(OH) and Br2 radical anions(Br2^-),but not by azide radicals(N3^).The oxidative mechanisms that an H-abstracted from DMUD for OH oxidative splitting and an electron transfer from DMUD to Br2-,were suggested.Related kinetic parameters were determined. 相似文献
In chromophore‐containing cyclobutane pyrimidine dimer (CPD) model systems, solvent effects on the splitting efficiency may depend on the length of the linker, the molecular conformation, and the oxidation potential of the donor. To further explore the relationship between chromophore structure and splitting efficiency, we prepared a series of substituted indole–T<>T model compounds 2 a – 2 g and measured their splitting quantum yields in various solvents. Two reverse solvent effects were observed: an increase in splitting efficiency in solvents of lower polarity for models 2 a – 2 d with an electron‐donating group (EDG), and vice versa for models 2 e – 2 g with an electron‐withdrawing group (EWG). According to the Hammett equation, the negative value of the slope of the Hammett plot indicates that the indole moiety during the T<>T‐splitting reaction loses negative charge, and the larger negative value implies that the repair reaction is more sensitive to substituent effects in low‐polarity solvents. The EDGs of the models 2 a – 2 d can delocalize the charge‐separated state, and low‐polarity solvents make it more stable, which leads to higher splitting efficiency in low‐polarity solvents. Conversely, the EWGs of models 2 e – 2 g favor destabilization of the charge‐separated state, and high‐polarity solvents decrease the destabilization and hence lead to more efficient splitting in high‐polarity solvents. 相似文献
On the mend : The repair reaction of the thymine dimer by DNA photolyase (see picture) is studied by hybrid quantum mechanical/molecular mechanical dynamics simulations based on the X‐ray structure of the enzyme–DNA complex. The dynamics of splitting of the thymine dimer radical anion within the DNA photolyase active site is characterized. The model includes the protein environment.
DNA repair has received heightened attention in recent years as ozone depletion threatens to significantly increase DNA damage by UVB radiation[1—6]. The major lesions formed in DNA by this radiation are cis-syn cyclobutane pyrimidine dimers, which are created by the linkage of two neighboring pyrimidine bases in DNA via C5-C5 and C6-C6 atoms by [2+2] cycloaddition[2,5—8]. This potentially lethal or mutagenic damage can be repaired either by the removal of the damaged bases by excisio… 相似文献
Cyclobutane pyrimidine dimer (CPD) is a photoproduct formed by two stacked pyrimidine bases through a cycloaddition reaction upon irradiation. Owing to its close association with skin cancer, the mechanism of CPD formation has been studied thoroughly. Among many aspects of CPD, its formation involving 5-methylcytosine (5mC) has been of special interest because the CPD yield is known to increase with C5-methylation of cytosine. In this work, high-level quantum mechanics/molecular mechanics (QM/MM) calculations are used to examine a previously experimentally detected pathway for CPD formation in hetero (thymine-cytosine and thymine-5mC) dipyrimidines, which is facilitated through intersystem crossing in thymine and formation of a triplet biradical intermediate. A DNA duplex model system containing a core sequence TmCG or TCG is used. The stabilization of a radical center in the biradical intermediate by the methyl group of 5mC can lead to increased CPD yield in TmCG compared with its non-methylated counterpart, TCG, thereby suggesting the existence of a new pathway of CPD formation enhanced by 5mC. 相似文献
UV irradiation induces DNA lesions particularly at dipyrimidine sites. Using time-resolved UV pump (250 nm) and mid-IR probe spectroscopy the triplet pathway of cyclobutane pyrimidine dimer (CPD) formation within TpC and CpT sequences was studied. The triplet state is initially localized at the thymine base but decays with 30 ns under formation of a biradical state extending over both bases of the dipyrimidine. Subsequently this state either decays back to the electronic ground state on the 100 ns time scale or forms a cyclobutane pyrimidine dimer lesion (CPD). Stationary IR spectroscopy and triplet sensitization via 2′-methoxyacetophenone (2-M) in the UVA range shows that the lesions are formed with an efficiency of approximately 1.5 %. Deamination converts the cytosine moiety of the CPD lesions on the time scale of 10 hours into uracil which gives CPD(UpT) and CPD(TpU) lesions in which the coding potential of the initial cytosine base is vanished. 相似文献
