Ultraviolet radiation in sunlight damages DNA in plants, but little is understood about the types, lesion capacity, and coordination of repair pathways. We challenged intact alfalfa seedlings with UV doses that induced different initial levels of cyclobutyl pyrimidine dimers and measured repair by excision and photoreactivation. By using alkaline gel electrophoresis of nonradioactive DNAs treated with a cyclobutyl pyrimidine dimer-specific UV endonuclease, we quantitated ethidium-stained DNA by electronic imaging and calculated lesion frequencies from the number average molecular lengths. At low initial dimer frequencies (less than ~30 dimers per million bases), the seedlings used only photoreactivation to repair dimers; excision repair was not significant. At higher damage levels, both excision and photorepair contributed significantly. This strategy would allow plants with low damage levels to use error-free repair requiring only an external light energy source, whereas seedlings subjected to higher damage frequencies could call on additional repair processes requiring cellular energy. Characterization of repair in plants thus requires an investigation of a range of conditions, including the level of initial damage.
Ultraviolet radiation in sunlight damages DNA in plants, but little is understood about the types, lesion capacity, and coordination of repair pathways. We challenged intact alfalfa seedlings with UV doses that induced different initial levels of cyclobutyl pyrimidine dimers and measured repair by excision and photoreactivation. By using alkaline gel electrophoresis of nonradioactive DNAs treated with a cyclobutyl pyrimidine dimer-specific UV endonuclease, we quantitated ethidium-stained DNA by electronic imaging and calculated lesion frequencies from the number average molecular lengths. At low initial dimer frequencies (less than ~30 dimers per million bases), the seedlings used only photoreactivation to repair dimers; excision repair was not significant. At higher damage levels, both excision and photorepair contributed significantly. This strategy would allow plants with low damage levels to use error-free repair requiring only an external light energy source, whereas seedlings subjected to higher damage frequencies could call on additional repair processes requiring cellular energy. Characterization of repair in plants thus requires an investigation of a range of conditions, including the level of initial damage.
Quantitation of UV-induced DNA damages in nanogram quantities of non-radioactive DNA from irradiated plants by gel electrophoresis requires a prompt, efficient, high-yield method of isolating DNA yielding high-molecular-weight, enzymatically digestible DNA. To meet these criteria we devised a high-yield method for isolating from plant tissue, DNA whose single-strand molecular length is greater than about 170 kb. Leaf tissue is embedded in agarose plugs, digested with Proteinase K in the presence of detergent, and treated with phenylmethylsulfonyl fluoride (PMSF). The agarose plugs are then soaked with buffer appropriate to the desired enzyme treatment. Evaluation of the DNA on neutral and alkaline gels indicates its high molecular length and low frequency of single-strand breaks. The DNA can be digested with damage-specific and other endonucleases. The method is especially suitable for DNA damage quantitation, as tissue processing is carried out immediately after harvesting (allowing DNA lesion measurement at precisely known times after irradiation), and many samples can be easily handled at once. It should also be useful for molecular analysis of large numbers of plant samples available only in small quantities. We here use this method to quantitate DNA damage induced by 297 and 365 nm radiation, and calculate the relative damaging effects of these wavebands in today's solar spectrum.
A new dw of membrane labels was synthesized which contain a tungstate cluster (having 11 tungsten atoms) and an aliphatic organo-M moiety with various chain lengths (6, CS, C12, Cu, C22). These m o l d e s were found to insert into synthetic phospholipid vesicles and biological membranes (human d blood cell membranes). The tungstate dusters can be individually visualized in the high rcsolu-
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.