DNA Accessibility: A Determinant of Mammalian Cell Differentiation?
- 1 February 1983
- journal article
- research article
- Published by JSTOR in Radiation Research
- Vol. 93 (2) , 312-318
- https://doi.org/10.2307/3575986
Abstract
Rats bearing intracerebral 9L tumors were whole-brain irradiated with 1250-5000 rad, and the in situ DNA repair kinetics of the undifferentiated tumor cells and terminally differentiated cerebellar neurons were examined by alkaline sucrose gradient sedimentation in zonal rotors with gradient reorienting capability. Biphasic repair kinectics were observed for both tumor cells and cerebellar neurons. Quantitation and analysis of the slow phase of the repair process suggest that the dividing tumor cell genome is completely accessible to the enzymatic repair machinery, while it is possible that the genome of the permanently nondividing neuron may contain a region that is inaccessible to this repair machinery.This publication has 7 references indexed in Scilit:
- Structural Alterations of the DNA in Cerebellar Neurons after Whole-Brain IrradiationRadiation Research, 1981
- Radiation Sensitivity of DNA Molecules in Situ in Normal and Neoplastic Tissues of MiceActa Radiologica: Oncology, 1980
- Improved microfluorometric DNA determination in biological material using 33258 HoechstAnalytical Biochemistry, 1979
- DNA Polymerase β from Brain Neurons Is a Repair EnzymeEuropean Journal of Biochemistry, 1979
- Radiation-induced DNA Strand Breaks and Their Repair in the Developing Rat BrainInternational Journal of Radiation Biology, 1979
- Induction and repair of strand breaks and 3′-hydroxy terminals in the DNA of mouse brain following gamma irradiationBiochimica et Biophysica Acta (BBA) - Nucleic Acids and Protein Synthesis, 1978
- Repair of X-Ray-Induced DNA Damage in Rat Cerebellar Neurons and Brain Tumor CellsRadiation Research, 1978