Ribonucleotide Misincorporation and Reverse Transcriptase Activities of Plasmodium falciparum Apicoplast DNA Polymerase.

Plasmodium falciparumis the most common and harmful causative agent of malaria worldwide. As a member of the phylum Apicomplexa, P. falciparum is characterized by the presence of a unique and essential organelle called the apicoplast. Reminiscent of an algal chloroplast, the apicoplast possesses its own genome, which is maintained by a single apicoplast DNA polymerase (apPol). Ribonucleotides misincorporated into the genome are among the most common lesions encountered by DNA polymerases, and the ability to replicate past these lesions varies widely among characterized enzymes. Here, we have investigated the ribonucleotide (rNTP) misincorporation frequency of apPol and determined its reverse transcriptase (RT) activity across templating ribonucleotides. Pre-steady-state kinetic experiments indicate that apPol does not have an unusually high discrimination between deoxy and ribonucleotides, with frequencies ranging between 104 and 106 depending on the identity of the ribonucleotide. Once incorporated into its template, apPol can replicate across ribonucleotides using its RT activity, but extension of a deoxynucleotide basepaired with the ribonucleotide is slow relative to a canonical basepair. Exonuclease assays indicate that apPol proofreads ribonucleotides an order of magnitude faster than extension, suggesting that most, but not all, misincorporated ribonucleotides will be excised. Although the components have not been identified, ribonucleotide excision repair or other tolerance mechanisms may exist in the P. falciparum apicoplast, and more targeted proteomic efforts will be needed to elucidate them.

Fidelity, mismatch extension, and proofreading activity of the Plasmodium falciparum apicoplast DNA polymerase.

Plasmodium falciparum, a parasitic organism and one of the causative agents of malaria, contains an unusual organelle called the apicoplast. The apicoplast is a nonphotosynthetic plastid responsible for supplying the parasite with isoprenoid units and is therefore indispensable. Like mitochondria and the chloroplast, the apicoplast contains its own genome and harbors the enzymes responsible for its replication. In this report, we determine the relative probabilities of nucleotide misincorporation by the apicoplast polymerase (apPOL), examine the kinetics and sequence dependence of mismatch extension, and determine the rates of mismatch removal by the 3' to 5' proofreading activity of the DNA polymerase. While the intrinsic polymerase fidelity varies by >50-fold for the 12 possible nucleotide misincorporations, the most dominant selection step for overall polymerase fidelity is conducted at the level of mismatch extension, which varies by >350-fold. The efficiency of mismatch extension depends on both the nature of the DNA mismatch and the templating base. The proofreading activity of the 12 possible mismatches varies <3-fold. The data for these three determinants of polymerase-induced mutations indicate that the overall mutation frequency of apPOL is highly dependent on both the intrinsic fidelity of the polymerase and the identity of the template surrounding the potential mismatch.

A High-Throughput Assay to Identify Inhibitors of the Apicoplast DNA Polymerase from Plasmodium falciparum.

Infection by Plasmodium falciparum is the leading cause of malaria in humans. The parasite contains a unique and essential plastid-like organelle called the apicoplast that, similar to the mitochondria and chloroplast, houses its own genome that must undergo replication and repair. The putative apicoplast replicative DNA polymerase, POM1, has no direct orthologs in mammals, making the P. falciparum POM1 an attractive antimalarial drug target. Here, we report on a fluorescent high-throughput DNA polymerase assay that relies on the ability of POM1 to perform strand-displacement synthesis through the stem of a DNA hairpin substrate, thereby separating a Cy3 dye from a quencher. Assay-validation experiments were performed using 384-well plates and resulted in a signal window of 7.90 and aZ' factor of 0.71. A pilot screen of a 2880-compound library identified 62 possible inhibitors that cause more than 50% inhibition of polymerase activity. The simplicity and statistical robustness of the assay suggest it is well suited for the screening of novel apicoplast polymerase inhibitors that may serve as lead compounds in antimalarial drug-discovery efforts.