Abstract
Two forms of DNA polymerase II (epsilon) of Saccharomyces cerevisiae, Pol II* and Pol II, were purified to near homogeneity from yeast cells. Pol II* is a four-subunit complex containing a 256-kDa catalytic polypeptide, whereas Pol II consists solely of a 145-kDa polypeptide derived from the N-terminal half of the 256-kDa polypeptide of Pol II*. We show that Pol II* and Pol II are indistinguishable with respect to the processivity and rate of DNA-chain elongation. The equilibrium dissociation constants of the complexes of Pol II* and Pol II with the DNA template showed that the stability of these complexes is almost the same. However, when the rates of dissociation of the Pol II* and Pol II from the DNA template were measured using single-stranded DNA as a trap for the dissociated polymerase, Pol II* dissociated 75-fold faster than Pol II. Furthermore, the rate of dissociation of Pol II* from the DNA template became faster as the concentration of the single-stranded DNA was increased. These results indicate that the rapid dissociation of Pol II* from the DNA template is actively promoted by single-stranded DNA. The dissociation of Pol II from the DNA template was also shown to be promoted by single-stranded DNA, although at a much slower rate. These results suggest that the site for sensing single-stranded DNA resides within the 145-kDa N-terminal portion of the catalytic subunit and that the efficiency for sensing single-stranded DNA by this site is positively modulated by either the C-terminal half of the catalytic subunit and/or the other subunits.
Highlights
Variety of genetic markers throughout the genome supports the idea that participation of the polymerase in chromosomal DNA replication is not restricted to certain sites on the genome [6]
Pol II* or Pol II was pre-incubated with the singly primed circular X174 ssDNA coated with replication factor A (RF-A) in the presence of dATP, dGTP, and dCTP, and DNA synthesis was initiated by adding 32P-labeled dTTP
Because the levels of incorporation during the burst DNA synthesis were less than 3% of the total incorporation obtained when all the input template primers were utilized and fully elongated, these results indicated that both Pol II* and Pol II started elongation uniformly and that the polymerases have a capacity to elongate DNA all the way around the viral DNA circle without dissociating from it
Summary
Variety of genetic markers throughout the genome supports the idea that participation of the polymerase in chromosomal DNA replication is not restricted to certain sites on the genome [6]. The reaction was chased with circular single-stranded X174 DNA, samples were removed at different time points, and the level of the remaining Pol:DNA replication complexes was quantified by measuring DNA synthesis.
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