A 5' to 3' exonuclease functionally interacts with calf DNA polymerase epsilon

Structure-specific endonucleolytic cleavage of nucleic acids by eubacterial DNA polymerases

Previously known 5' exonucleases of several eubacterial DNA polymerases have now been shown to be structure-specific endonucleases that cleave single-stranded DNA or RNA at the bifurcated end of a base-paired duplex. Cleavage was not coupled to synthesis, although primers accelerated the rate of cleavage considerably. The enzyme appeared to gain access to the cleavage site by moving from the free end of a 5' extension to the bifurcation of the duplex, where cleavage took place. Single-stranded 5' arms up to 200 nucleotides long were cleaved from such a duplex. Essentially any linear single-stranded nucleic acid can be targeted for specific cleavage by the 5' nuclease of DNA polymerase through hybridization with an oligonucleotide that converts the desired cleavage site into a substrate.

Lagging strand DNA synthesis by calf thymus DNA polymerases alpha, beta, delta and epsilon in the presence of auxiliary proteins

By using a defined gapped DNA substrate that mimics a lagging strand of 230 nucleotides and that contains a defined pause site, we have analyzed calf thymus DNA polymerases (pol) alpha, beta, delta, and epsilon in the presence of the three auxiliary proteins proliferating cell nuclear antigen (PCNA), replication factor C (RF-C) and replication protein A (RP-A) for their ability to complete an Okazaki fragment. Pol alpha alone could fill the gap to near completion, but was strongly stopped by the pause site. Addition of low amounts of RP-A resulted in an increased synthesis by pol alpha past the pause site. In contrast, high amounts of RP-A strongly inhibited gap filling by pol alpha. Further inhibition was evident when the two other auxiliary proteins, PCNA and RF-C, were added in addition to RP-A. Pol beta could completely fill the gap without specific pausing and also was strongly inhibited by RP-A. PCNA and RF-C had no detectable effect on pol beta. Pol delta, relied as expected, on all three auxiliary proteins for complete gap filling synthesis and could, upon longer incubation, perform a limited amount of strand displacement synthesis. Pol epsilon core enzyme was able to fill the gap completely, but like pol alpha, essentially stopped at the pause site. This pausing could only be overcome upon addition of PCNA, RF-C and E. coli single-stranded DNA binding protein. Thus pol epsilon holoenzyme preferentially synthesized to the end of the gap without pausing. Ligation of the DNA products indicated that pol beta core enzyme, pol delta and pol epsilon holoenzymes (but not pol alpha and pol epsilon core enzyme) synthesized products that were easily ligatable. Our results indicate that pol epsilon holoenzyme fills a defined lagging strand gapped template to exact completion and is able to pass a pause site. The data favour the hypothesis of Burgers (Burgers, P.M.J. (1991) J. Biol. Chem. 266, 22698-22706) that pol epsilon might be a candidate for the second replication enzyme at the lagging strand of the replication fork.