A DNA primase was partially purified from rat liver mitochondria and separated from the bulk of DNA polymerase gamma and mtRNA polymerase by heparin-agarose chromatography. The primase was distinguished from mtRNA polymerase by its response to pH, monoand divalent cations, and ATP concentrations. In the absence of an active DNA polymerase and using poly(dT) as template, primase synthesized mixed polynucleotide products consisting of units of oligo(A) 1-12 alternating with units of oligo(dA)25-40. Contributions to these products by contaminating DNA polymerase gamma were eliminated by the addition of dideoxy-ATP. Addition of 50 microM dATP to the primase reaction caused a 50% inhibition of AMP incorporation as compared to reactions containing low levels of dATP present only as a contaminant of the ATP added. The inhibition was due primarily to a reduction of new chain initiations. The dATP did not "lock" the primase reaction into the DNA mode of synthesis since the proportion of internal and 3'-terminal RNA segments was little affected. However, the addition of both 50 microM dATP and exogenous DNA polymerase to the primase reaction greatly reduced the amount of internal and 3'-terminal RNA segments, presumably due to the displacement of primase by DNA polymerase. Our data are consistent with the hypothesis (Hu, S.-Z., Wang, T.S.-F., and Korn, D. (1984) J. Biol. Chem. 259, 2602-2609) that the physiologically significant primer is a mixed 5'-oligoribonucleotide-3'-oligodeoxyribonucleotide and that the formation of the RNA to DNA junction is inherently a primase function.