DNA polymerases in midgestation mouse embryo, trophoblast, and decidua

DNA polymerase of a basidiomycete fungus, Coprinus cinereus

DNA polymerase activity was studied in Coprinus cinereus, a basidiomycete fungus. Only one from of the enzyme could be demonstrated, whether by affinity or ion-exchange chromatography; this enzyme had a molecular weight of 185000 on Sephadex G-200, and was inhibited by mercaptoethanol. Coprinus, a representative of the most advanced type of the filamentous fungi, resembles other eukaryotic micro-organisms in its lack of a mammalian beta-type DNA polymerase. The properties of the polymerase are compared with those of two other fungi, and found to resemble most closely the yeast polymerase A in Mg2+ requirements and template preference.

DNA polymerase activity in preimplantation mouse embryos

DNA polymerase activity was measured in mouse embryos at stages before implantation to determine whether it increases in proportion to the amount of DNA synthesis, as it does in populations of differentiated mammalian cells, or remains constant, as it does in early sea urchin embryos. Total enzyme activity was found to be relatively unchanged following fertilization and in the first few cleavage stages. However, between the 12- and 120-cell (blastocyst) stage, the amount of activity increased by several-fold. These results indicate that the relationship between amount of DNA polymerase activity and DNA synthesis in mouse embryos exhibits two phases: in the early cleavage phase it is similar to that in sea urchin embryos, whereas, in the blastocyst phase, it is similar to that in differentiated mammalian cells.

Identity of DNA polymerase gamma from synaptosomal mitochondria and rat-brain nuclei

DNA polymerase gamma and mitochondrial DNA polymerase were isolated from brain nuclei and synaptosomes respectively. The presence of a single DNA polymerase in synaptosomal mitochondria was established by chromatography on DEAE-cellulose, phosphocellulose and DNA-cellulose, as well as by sedimentation analysis and isoelectric focusing. A great similarity between the purified nuclear DNA polymerase gamma and the mitochondrial enzyme was found by the following criteria: chromatographic behaviour in three column systems; essentially complete inhibition by N-ethyl-maleimide (2 mM); optimal requirements of Mn2+ (0.1 mM), Mg2+ (5 mM) and pH (8.0); template preferences, poly(A) - (dT)20-25 larger than activated DNA larger than poly(dA) - (dT)12-18; lack of activity on single-stranded polynucleotides and (dT)12-primed mRNA; molecular weight (180000), sedimentation (9.2 S) and isoelectric point (pI 5.4). We therefore conclude that brain nuclear DNA polymerase gamma and synaptosomal mitochondrial DNA polymerase are closely related and may even be identical.

Variation of deoxyribonucleic acid polymerase activities during avian erythropoiesis

Amounts of DNA polymerase alpha and beta were determined in extracts of chicken erythroid cells at various stages of development. Concentrations of both polymerase activities are high in erythroblasts which are still dividing, decline after the cells cease dividing and begin maturation, and become almost undetectable in the fully mature erythrocytes. While DNA polymerase alpha activity declines gradually, firmly bound DNA polymerase beta activity in the nuclei drops abruptly after the cells finish DNA synthesis and dividing. The amount of a low molecular weight DNA polymerase extractable with the cytoplasmic fraction, possibly DNA polymerase beta, is low in erythroblasts, increases in the more mature erythroid population and then declines to an undectable level in the fully mature erythrocytes.

The relationship between two murine DNA-dependent DNA polymerases from the cytosol and the low molecular weight DNA polymerase

After aqueous subcellular fractionation and partial purification by phosphocellulose chromatography, murine cells are found to contain a low molecular weight DNA-dependent DNA polymerase (beta) in the nuclear fraction and two distinguishable DNA-dependent DNA polymerases (C-I and C-II) in the cytosol. Both C-I and C-II are found in testis, liver, and regenerating liver; the amount of C-I being several fold increased in the regenerating liver and in immature testis. C-I and C-II are distinguishable by the criteria of salt sensitivity, inhibition by single-stranded DNA, elution from phosphocellulose, inhibition by 0.3 mM N-ethylmaleimide, template preference, and sedimentation coefficient. C-II is dissociated by 0.25 M KC1 to an active form of DNA polymerase of sedimentation coefficient 3.5 S while C-I is not dissociated, maintaining its sedimentation coefficient of 7.2 S. Many similar chemical and physical properties of C-II and the low molecular weight nuclear DNA polymerase (beta) suggest that C-II may represent an aggregate state of beta monomers, The size, reaction properties and the increase in enzyme activity under conditions of rapid cellular proliferation suggest C-I is analogous to the alpha DNA polymerase.