Project description:During DNA synthesis, DNA polymerases must select against ribonucleotides, present at much higher levels compared with deoxyribonucleotides. Most DNA polymerases are equipped to exclude ribonucleotides from their active site through a bulky side chain residue that can sterically block the 2'-hydroxyl group of the ribose ring. However, many nuclear replicative and repair DNA polymerases incorporate ribonucleotides into DNA, suggesting that the exclusion mechanism is not perfect. In this study, we show that the human mitochondrial DNA polymerase ? discriminates ribonucleotides efficiently but differentially based on the base identity. Whereas UTP is discriminated by 77,000-fold compared with dTTP, the discrimination drops to 1,100-fold for GTP versus dGTP. In addition, the efficiency of the enzyme was reduced 3-14-fold, depending on the identity of the incoming nucleotide, when it extended from a primer containing a 3'-terminal ribonucleotide. DNA polymerase ? is also proficient in performing single-nucleotide reverse transcription reactions from both DNA and RNA primer terminus, although its bypass efficiency is significantly diminished with increasing stretches of ribonucleotides in template DNA. Furthermore, we show that the E895A mutant enzyme is compromised in its ability to discriminate ribonucleotides, mainly due to its defects in deoxyribonucleoside triphosphate binding, and is also a poor reverse transcriptase. The potential biochemical defects of a patient harboring a disease mutation in the same amino acid (E895G) are discussed.

Project description:Mitochondrial respiratory chain disease represents one of the most common inborn errors of metabolism and is genetically heterogeneous, with biochemical defects arising from mutations in the mitochondrial genome (mtDNA) or the nuclear genome. As such, inheritance of mitochondrial respiratory chain disease can either follow dominant or recessive autosomal (Mendelian) inheritance patterns, the strictly matrilineal inheritance observed with mtDNA point mutations or X-linked inheritance. Parental consanguinity in respiratory chain disease is often assumed to infer an autosomal recessive inheritance pattern, and the analysis of mtDNA may be overlooked in the pursuit of a presumed nuclear genetic defect. We report the histochemical, biochemical and molecular genetic investigations of two patients with suspected mitochondrial disease who, despite being born to consanguineous first-cousin parents, were found to harbour well-characterised pathogenic mtDNA mutations, both of which were maternally transmitted. Our findings highlight that any diagnostic algorithm for the investigation of mitochondrial respiratory chain disease must include a full and complete analysis of the entire coding sequence of the mitochondrial genome in a clinically relevant tissue. An autosomal basis for respiratory chain disease should not be assumed in consanguineous families and that 'maternally inherited consanguineous' mitochondrial disease may thus be going undiagnosed.

Project description:Rev1 is a translesion DNA synthesis (TLS) polymerase involved in the bypass of adducted-guanine bases and abasic sites during DNA replication. During damage bypass, Rev1 utilizes a protein-template mechanism of DNA synthesis, where the templating DNA base is evicted from the Rev1 active site and replaced by an arginine side chain that preferentially binds incoming dCTP. Here, we utilize X-ray crystallography and molecular dynamics simulations to obtain structural insight into the dCTP specificity of Rev1. We show the Rev1 R324 protein-template forms sub-optimal hydrogen bonds with incoming dTTP, dGTP, and dATP that prevents Rev1 from adopting a catalytically competent conformation. Additionally, we show the Rev1 R324 protein-template forms optimal hydrogen bonds with incoming rCTP. However, the incoming rCTP adopts an altered sugar pucker, which prevents the formation of a catalytically competent Rev1 active site. This work provides novel insight into the mechanisms for nucleotide discrimination by the TLS polymerase Rev1.

Project description:DNA polymerase γ (pol γ), encoded by POLG, is responsible for replicating human mitochondrial DNA. About 150 mutations in the human POLG have been identified in patients with mitochondrial diseases such as Alpers syndrome, progressive external ophthalmoplegia, and ataxia-neuropathy syndromes. Because many of the mutations are described in single citations with no genotypic family history, it is important to ascertain which mutations cause or contribute to mitochondrial disease. The vast majority of data about POLG mutations has been generated from biochemical characterizations of recombinant pol γ. However, recently, the study of mitochondrial dysfunction in Saccharomyces cerevisiae and mouse models provides important in vivo evidence for the role of POLG mutations in disease. Also, the published 3D-structure of the human pol γ assists in explaining some of the biochemical and genetic properties of the mutants. This review summarizes the current evidence that identifies and explains disease-causing POLG mutations.

Project description:Several strands of evidence question the dogma that human mitochondrial DNA (mtDNA) is inherited exclusively down the maternal line, most recently in three families where several individuals harbored a 'heteroplasmic haplotype' consistent with biparental transmission. Here we report a similar genetic signature in 7 of 11,035 trios, with allelic fractions of 5-25%, implying biparental inheritance of mtDNA in 0.06% of offspring. However, analysing the nuclear whole genome sequence, we observe likely large rare or unique nuclear-mitochondrial DNA segments (mega-NUMTs) transmitted from the father in all 7 families. Independently detecting mega-NUMTs in 0.13% of fathers, we see autosomal transmission of the haplotype. Finally, we show the haplotype allele fraction can be explained by complex concatenated mtDNA-derived sequences rearranged within the nuclear genome. We conclude that rare cryptic mega-NUMTs can resemble paternally mtDNA heteroplasmy, but find no evidence of paternal transmission of mtDNA in humans.

Project description:Nucleoside analog reverse transcriptase inhibitors (NRTIs) are the essential components of highly active antiretroviral (HAART) therapy targeting HIV reverse transcriptase (RT). NRTI triphosphates (NRTI-TP), the biologically active forms, act as chain terminators of viral DNA synthesis. Unfortunately, NRTIs also inhibit human mitochondrial DNA polymerase (Pol ?), causing unwanted mitochondrial toxicity. Understanding the structural and mechanistic differences between Pol ? and RT in response to NRTIs will provide invaluable insight to aid in designing more effective drugs with lower toxicity. The NRTIs emtricitabine [(-)-2,3'-dideoxy-5-fluoro-3'-thiacytidine, (-)-FTC] and lamivudine, [(-)-2,3'-dideoxy-3'-thiacytidine, (-)-3TC] are both potent RT inhibitors, but Pol ? discriminates against (-)-FTC-TP by two orders of magnitude better than (-)-3TC-TP. Furthermore, although (-)-FTC-TP is only slightly more potent against HIV RT than its enantiomer (+)-FTC-TP, it is discriminated by human Pol ? four orders of magnitude more efficiently than (+)-FTC-TP. As a result, (-)-FTC is a much less toxic NRTI. Here, we present the structural and kinetic basis for this striking difference by identifying the discriminator residues of drug selectivity in both viral and human enzymes responsible for substrate selection and inhibitor specificity. For the first time, to our knowledge, this work illuminates the mechanism of (-)-FTC-TP differential selectivity and provides a structural scaffold for development of novel NRTIs with lower toxicity.

Project description:The human mitochondrial DNA polymerase (pol γ) is responsible for the replication of the mitochondrial genome. Mutation Y955C in the active site of pol γ results in early onset progressive external ophthalmoplegia, premature ovarian failure, and Parkinson's disease. In single-turnover kinetic studies, we show that the Y955C mutation results in a decrease in the maximal rate of polymerization and an increase in the K(m) for correct incorporation. The mutation decreased the specificity constant for correct incorporation of dGTP, TTP, and ATP to values of 1.5, 0.35, and 0.044 μM(-1) s(-1), respectively, representing reductions of 30-, 110-, and 1300-fold, respectively, relative to the value for the wild-type enzyme. The fidelity of incorporation was reduced 6-130-fold, largely because of the significant decrease in the specificity constant for correct dATP:T incorporation. For example, k(cat)/K(m) for forming a TTP:T mismatch was decreased 10-fold from 0.0002 to 0.00002 μM(-1) s(-1) by the Y955C mutant, but the 1300-fold slower incorporation of the correct dATP:T relative to that of the wild type led to a 130-fold lower fidelity. While correct incorporation of 8-oxo-dGTP was largely unchanged, the level of incorporation of 8-oxo-dG with dA in the template strand was reduced 500-fold. These results support a role for Y955 in stabilizing A:T base pairs at the active site of pol γ and suggest that the severe clinical symptoms of patients with this mutation may be due, in part, to the reduced efficiency of incorporation of dATP opposite T, and that the autosomal dominant phenotype may arise from the resulting higher mutation frequency.

Project description:Toxicity has emerged during the clinical development of many but not all nucleotide inhibitors (NI) of hepatitis C virus (HCV). To better understand the mechanism for adverse events, clinically relevant HCV NI were characterized in biochemical and cellular assays, including assays of decreased viability in multiple cell lines and primary cells, interaction with human DNA and RNA polymerases, and inhibition of mitochondrial protein synthesis and respiration. NI that were incorporated by the mitochondrial RNA polymerase (PolRMT) inhibited mitochondrial protein synthesis and showed a corresponding decrease in mitochondrial oxygen consumption in cells. The nucleoside released by the prodrug balapiravir (R1626), 4'-azido cytidine, was a highly selective inhibitor of mitochondrial RNA transcription. The nucleotide prodrug of 2'-C-methyl guanosine, BMS-986094, showed a primary effect on mitochondrial function at submicromolar concentrations, followed by general cytotoxicity. In contrast, NI containing multiple ribose modifications, including the active forms of mericitabine and sofosbuvir, were poor substrates for PolRMT and did not show mitochondrial toxicity in cells. In general, these studies identified the prostate cell line PC-3 as more than an order of magnitude more sensitive to mitochondrial toxicity than the commonly used HepG2 cells. In conclusion, analogous to the role of mitochondrial DNA polymerase gamma in toxicity caused by some 2'-deoxynucleotide analogs, there is an association between HCV NI that interact with PolRMT and the observation of adverse events. More broadly applied, the sensitive methods for detecting mitochondrial toxicity described here may help in the identification of mitochondrial toxicity prior to clinical testing.

Project description:DNA polymerase ? (Pol ?) is one of the major replicative DNA polymerases in eukaryotic cells, catalyzing lagging strand synthesis as well as playing a role in many DNA repair pathways. The catalytic site for polymerization consists of a palm domain and mobile fingers domain that opens and closes each catalytic cycle. We explored the effect of amino acid substitutions in a region of the highly conserved sequence motif B in the fingers domain on replication fidelity. A novel substitution, A699Q, results in a marked increase in mutation rate at the yeast CAN1 locus, and is synthetic lethal with both proofreading deficiency and mismatch repair deficiency. Modeling the A699Q mutation onto the crystal structure of Saccharomyces cerevisiae Pol ? template reveals four potential contacts for A699Q but not for A699. We substituted alanine for each of these residues and determined that an interaction with multiple residues of the N-terminal domain is responsible for the mutator phenotype. The corresponding mutation in purified human Pol ? results in a similar 30-fold increase in mutation frequency when copying gapped DNA templates. Sequence analysis indicates that the most characteristic mutation is a guanine-to-adenine (G to A) transition. The increase in deoxythymidine 5'-triphosphate-G mispairs was confirmed by performing steady state single nucleotide addition studies. Our combined data support a model in which the Ala-to-Gln substitution in the fingers domain of Pol ? results in an interaction with the N-terminal domain that affects the base selectivity of the enzyme.

Project description:A nucleotide-induced change in DNA polymerase structure governs the kinetics of polymerization by high fidelity DNA polymerases. Mutation of a GAG hinge (G542A/G544A) in T7 DNA polymerase resulted in a 1000-fold slower rate of conformational change, which then limited the rate of correct nucleotide incorporation. Rates of misincorporation were comparable to that seen for wild-type enzyme so that the net effect of the mutation was a large decrease in fidelity. We demonstrate that a presumably modest change from glycine to alanine 20 Å from the active site can severely restrict the flexibility of the enzyme structure needed to recognize and incorporate correct substrates with high specificity. These results emphasize the importance of the substrate-induced conformational change in governing nucleotide selectivity by accelerating the incorporation of correct base pairs but not mismatches.