Multiple replication factors augment DNA synthesis by the two eukaryotic DNA polymerases, alpha and delta.

DNA synthesis by two eukaryotic DNA polymerases, alpha and delta, was studied using a single-strand M13 DNA template primed at a unique site. In the presence of low amounts of either DNA polymerase alpha or delta, DNA synthesis was limited and short DNA strands of approximately 100 bases were produced. Addition of replication factors RF-A, PCNA and RF-C, which were previously shown to be required for SV40 DNA replication in vitro, differentially stimulated the activity of both DNA polymerases. RF-A and RF-C independently stimulated DNA polymerase alpha activity 4- to 6-fold, yielding relatively short DNA strands (less than 1 kb) and PCNA had no effect. In contrast, polymerase delta activity was stimulated co-operatively by PCNA, RF-A and RF-C approximately 25- to 30-fold, yielding relatively long DNA strands (up to 4 kb). Neither RF-C nor RF-A appear to correspond to known polymerase stimulatory factors. RF-A was previously shown to be required for initiation of DNA replication at the SV40 origin. Results presented here suggest that it also functions during elongation. The differential effects of these three replication factors on DNA polymerases alpha and delta is consistent with the model that the polymerases function at the replication fork on the lagging and leading strand templates respectively. We further suggest that co-ordinated synthesis of these strands requires dynamic protein-protein interactions between these replication factors and the two DNA polymerases.