Preparation of bioplastic consisting of salmon milt DNA

The microplastic that pollutes the ocean is a serious problem around the world. The bioplastic consisting of biopolymers which is degraded in nature, is one of the strategies to solve this problem. Although the bioplastics consisting of protein, polysaccharide, polylactic acid, etc., have been reported, which consist of DNA, one of the most important materials in the genetic process, have not been reported to the best of our knowledge. In addition, a large amount of DNA-containing materials, such as salmon milts, is discarded as industrial waste around the world. Therefore, we demonstrated the preparation of a bioplastic consisting of salmon milt DNA. The DNA plastic was prepared by the immersion of a DNA pellet in a formaldehyde (HCHO) solution and heating. As a result, the water-stable DNA plastics were obtained at the HCHO concentration of 20% or more. Particularly, the DNA plastic with a 25% HCHO treatment showed water-insoluble, thermally stable, and highly mechanical properties. These are due to the formation of a three-dimensional network via the crosslinking reaction between the DNA chains. In addition, since DNA in plastic possesses the double-stranded structure, these plastics effectively accumulated the DNA intercalator, such as ethidium bromide. Furthermore, the DNA plastics indicated a biodegradable property in a nuclease-containing aqueous solution and the biodegradable stability was able to be controlled by the HCHO concentration. Therefore, salmon milt DNA has shown the potential to be a biodegradable plastic.

Ultrafast energy exchange via water-phosphate interactions in hydrated DNA

The ionic phosphate groups in the DNA backbone play a key role for DNA hydration. We study ultrafast vibrational dynamics and local interactions of phosphate groups and water by femtosecond two-color pump-probe spectroscopy. The asymmetric (PO(2))(-) stretching vibration nu(AS)(PO(2))(-) of artificial DNA oligomers containing 23 alternating adenine-thymine base pairs displays a lifetime of 340 fs, independent of the hydration level. For DNA at zero relative humidity, excess energy from the decay of the phosphate excitation is transferred within DNA on a 20 ps time scale. For fully hydrated DNA, the water shells around the phosphates serve as a primary heat sink accepting vibrational excess energy from DNA on a femtosecond time scale. OH stretching excitation of water molecules around fully hydrated DNA induces an ultrafast nu(AS)(PO(2))(-) response which includes rearrangements of the hydration shell and a reduction of the average number of phosphate-water hydrogen bonds.

Stabilization of the B conformation in unoriented films of calf thymus DNA by NaCl: a Raman and IR study

Unoriented films of calf thymus NaDNA with either 3.0 or 5.0 NaCl per base pair were prepared by dehydrating unstressed gels. These films were studied by Raman and ir spectroscopy. The 5.0 samples showed very strong vibrational modes characteristic of the B conformation at relative humidities (RH) as low as 30%, indicating that those samples were entirely in the B conformation. The 3.0 samples showed weaker features: some of the DNA in these samples were in the B conformation at 80% RH while the DNA is essentially in a disordered phase at 30% RH.

The infrared and Raman spectra of the duplex of d(GGTATACC) in the crystal show bands due to both the A-form and the B-form of DNA

The deoxyoligonucleotide, d(GGTATACC), forms a duplex structure that crystallizes in the DNA A form. This has been shown by both X-ray diffraction studies and Raman spectroscopy (1,2). The presence of the DNA B form has been reported using diffuse X-ray scattering from a crystal of the closely related sequence d(GGBrUABrUACC)(3). In this paper the infrared spectrum of the d(GGTATACC) crystal is presented and curve resolution of both the Raman and IR spectra have been carried out. The percentage of A and B forms have been estimated. The %B form in the crystal has been estimated from the IR spectra to be about 15% and from Raman to be about 20%. Moreover the IR spectrum of the A conformation in the crystal is slightly different from the IR spectrum of the A conformation in polynucleotide fibers in particular in the region of the phosphate stretching vibrations and of the in-plane double bond vibrations of the bases. We show that it is feasible to obtain IR as well as Raman spectra of small crystals of oligonucleotides and that this is a good method of identifying all of the different conformations that may be in the crystal.

Backbone conformational change in the A to B Transition of deoxyribonucleic acid

Infrared linear dichroism studies of A-and B-DNA films reveal six bands between 2800 and 3000 cm-1 which must arise from deoxyribose and thymine methyl CH stretching motions. The band at 2890 is perpendicularly polarized in A-DNA but parallel polarized in B-DNA. This band most probably originates in the C'(5)H2 symmetric stretch; the polarization flip is consistent with the structural change occurring at C'(5) during the A to B transition, according to models derived from x-ray work.