Evidence for B-C transition in ultraviolet-irradiated DNA. An infrared linear dichroism study

Linearly Polarized Infrared Spectroscopy for the Analysis of Biological Materials

The analysis of biological samples with polarized infrared spectroscopy (p-IR) has long been a widely practiced method for the determination of sample orientation and structural properties. In contrast to earlier works, which employed this method to investigate the fundamental chemistry of biological systems, recent interests are moving toward "real-world" applications for the evaluation and diagnosis of pathological states. This focal point review provides an up-to-date synopsis of the knowledge of biological materials garnered through linearly p-IR on biomolecules, cells, and tissues. An overview of the theory with special consideration to biological samples is provided. Different modalities which can be employed along with their capabilities and limitations are outlined. Furthermore, an in-depth discussion of factors regarding sample preparation, sample properties, and instrumentation, which can affect p-IR analysis is provided. Additionally, attention is drawn to the potential impacts of analysis of biological samples with inherently polarized light sources, such as synchrotron light and quantum cascade lasers. The vast applications of p-IR for the determination of the structure and orientation of biological samples are given. In conclusion, with considerations to emerging instrumentation, findings by other techniques, and the shift of focus toward clinical applications, we speculate on the future directions of this methodology.

NaDNA-bipyridyl-(ethylenediamine)platinum (II) complex: structure in oriented wet-spun films and fibers

Complexes of NaDNA with bipyridyl-(ethylenediamine)platinum(II) (abbreviated [(bipy)Pt(en)](2+)) in solid, oriented films, prepared with a wet-spinning method, have been studied using x-ray diffraction, elastic neutron scattering, two-dimensional magic-angle-spinning nuclear magnetic resonance (NMR), infrared (IR) linear dichroism, and IR absorption. All of these experiments indicate that the DNA in this complex is in the B conformation. The neutron diffraction experiments reveal that the rise per residue is 3.31 A, indicating that the [(bipy)Pt(en)](2+) molecular ion causes a small distortion of the B conformation. The neutron data in the direction perpendicular to the helical axis are consistent with a centered orthorhombic unit cell with a=22.65 A and b=32.2 A. The NMR and IR experiments show that the orientation of phosphate groups in the DNA small middle dot[(bipy)Pt(en)](2+) complex is the same as that observed for pure DNA in the B conformation. The IR experiments also show that the [(bipy)Pt(en)](2+) molecular ion stabilizes the B conformation of DNA down to 59% relative humidity, a low water activity. Mechanochemical experiments on wet-spun NaDNA fibers in 68% ethanol with and without [(bipy)Pt(en)](2+) reveal a 9% elongation of the DNA fibers as the complex is formed.

Linear dichroism spectroscopy of nucleic acids

This review will consider solution studies of structure and interactions of DNA and DNA complexes using linear dichroism spectroscopy, with emphasis on the technique of orientation by flow. The theoretical and experimental background to be given may serve, in addition, as a general introduction into the state of the art of linear dichroism spectroscopy, particularly as it is applied to biophysical problems.

Action spectra for survival and spore photoproduct formation of Bacillus subtilis irradiated with short-wavelength (200-300 nm) UV at atmospheric pressure and in vacuo

Spores of Bacillus subtilis are approximately ten times less likely to survive UV light irradiation in a vacuum than under atmospheric conditions. Photoproduct formation was studied in spores irradiated under ultrahigh vacuum (UHV) conditions and in spores irradiated at atmospheric pressure. In addition to the "spore photoproduct" 5-thyminyl-5,6-dihydrothymine (TDHT), which is produced in response to irradiation at atmospheric pressure, two additional photoproducts, known as the cis-syn and trans-syn isomers of thymine dimer, are produced on irradiation in vacuo. The spectral efficiencies for photoproduct formation in spores are reduced under vacuum conditions compared with atmospheric conditions by a factor of 2-6, depending on the wavelength. Because formation of TDHT does not increase after irradiation in vacuo, TDHT cannot be responsible for the observed vacuum effect. Vacuum specific photoproducts may cause a synergistic response of spores to the simultaneous action of UV light and UHV. An increased quantum efficiency, destruction of repair systems and formation of irreparable lesions are postulated for the enhanced sensitivity of B. subtilis spores to UV radiation in vacuo.

A new conformation-specific infrared band of A-DNA in films

A band at 1185 cm-1 occurs in the infrared spectra of nucleic acids in their A-type conformation which has been reproduced in the literature, too. The absorbance of this band is proportional to the fraction of the A form of DNA samples containing a mixture of different forms. The 1185 cm-1 band has been assigned tentatively to a vibration of the sugar-phosphate backbone with a fairly high contribution from the sugar moiety. Drastic dehydration of the DNA films is accompanied by a continuous intensity decrease of the 1185 cm-1 band indicating a collapse of the A form.

An electrochemical analysis of changes in properties of DNA caused by ionizing and ultraviolet radiations

Electrooxidation and electroreduction of gamma- and u.v.-irradiated DNA were studied by means of differential pulse voltammetry at the graphite electrode and differential pulse polarography at the dropping mercury electrode. Two separated voltammetric oxidation peaks G and A were used for monitoring conformational changes in guanine . cytosoine (GC) and adenine . thyminde (AT) pairs respectively in irradiated double-stranded (ds) DNA. Pulse-polarographic reduction peak III was used for detection of denatured DNA in the irradiated samples of ds DNA. It was found that the heights of peaks G and A of ds DNA did not change with the radiation dose after relatively low doses of gamma- and u.v.-radiations (up to ca. 40 krads and 1 X 10(4) Jm-2, respectively, when no single-stranded (ss) DNA was detected in the irradiated DNA samples. After higher doses of radiation the occurrence of ss DNA or ss segments in the irradiated samples of ds DNA was accompanied by an increase of peaks G and A; however, peak A grew more rapidly with the increasing dose than peak G. It was concluded that the results obtained support the assumption, according to which regions of ds DNA rich in AT pairs are more susceptible to denaturation caused by gamma- and u.v.-radiations.

Infrared dichroism of the DNA-caffeine complex. A new method for determination of the ligand orientation

Infrared linear dichroism (LD) measurements on films of the DNA-caffeine complex in terms of the relative humidity (r.h.) show two main effects. Firstly, there is an insertion of caffeine molecules into the DNA double helix (B form), as evidenced by a very strong parallel LD behaviour of the 745 cm-1 band due to the C-H out-of-plane deformation vibration of caffeine. Furthermore, a high r.h. values a modified B form occurs in the complex similar to the B form recently reported by BRAHMS and coworkers for DNA-polypeptide complexes. The reversible B-A transition of the DNA in dependence of the r.h. is not affected in general in the presence of caffeine.