The role of residue Y955 of mitochondrial DNA polymerase [gamma] in nucleotide binding and discrimination

Estep, Patricia Ann

14 February 2012

The human mitochondrial polymerase (pol γ) is a nuclearly-encoded polymerase that is solely responsible for the faithful replication and repair of the mitochondrial genome. The Y955C mutation in pol γ results in early onset progressive external ophthalmoplegia, premature ovarian failure, and Parkinson’s disease. It is believed that the position of this Y955 residue on the catalytic helix in the polymerase makes it responsible for stabilizing the incoming nucleotide. I have investigated the kinetic effect of the Y955C mutation. Mutation of the tyrosine to a cysteine resulted in a decreased maximum rate of polymerization and increased the dissociation constant for incoming nucleotide. In turn, this decreased catalytic efficiency by 30 to 100-fold. In addition, the polymerase did not incorporate all bases with the same efficiency, it was most efficient when incorporating dGTP opposite a dC, but showed less efficient catalysis when faced with an A:T or T:A base-pair. The polymerase also showed reduced discrimination against misincorporation events. However, when presented with an oxidatively-damaged base, 8-oxo-deoxyguanosine, the polymerase chose to incorporate the base in the correct conformation opposite a dC, discriminating against the mutagenic incorporation of 8-oxo-dGTP opposite a dA. The results presented in this thesis suggest that the severe clinical symptoms of patients with this mutation are at least due in part to the reduced efficiency and discrimination of this polymerase γ mutation. / text

Pre-steady state kinetics

DNA polymerase gamma

MnSOD AND AUTOPHAGY IN PREVENTION OF OXIDATIVE MITOCHONDRIAL INJURIES INDUCED BY UVB IN MURINE SKIN

Bakthavatchalu, Vasudevan

01 January 2012

UVB radiation is a known environmental carcinogen that causes DNA damage and increase ROS generation in mitochondria. Accumulating evidence suggests that mtDNA damage and increased ROS generation trigger mitochondrial translocation of p53. Within mitochondria, p53 interacts with nucleoid macromolecular complexes such as mitochondrial antioxidant MnSOD, mitochondrial DNA polymerase Polγ, and mtDNA. Mitochondria are considered to be a potential source for damage-associated molecular patterns (DAMPs) such as mtDNA, cytochrome C, ATP, and formyl peptides. Intracytoplasmic release of DAMPs can trigger inflammasome formation and programmed cell death processes. Autophagic clearance of mitochondria with compromised integrity can inhibit inflammatory and cell death processes. In this study we investigated whether and how MnSOD plays a protective role in UVB-induced mitochondrial damage. The possibility of MnSOD participating in the mtDNA repair process was addressed in vivo using transgenic and pharmacological approaches. The results demonstrate that MnSOD functions as a fidelity protein that maintains the activity of Polγ by preventing UVB-induced nitration and inactivation of Polγ and that MnSOD coordinates with p53 to prevent mtDNA damage. We also investigated whether autophagy is an adaptive response mechanism by which skin cells respond to mitochondrial injury, using mouse keratinocytes (JB6 cells) and C57/BL6 mice as in vitro and in vivo models. The results demonstrate that UVB induces autophagy initiation in murine skin tissues and that down regulation of AKTmTOR levels triggers initiation of autophagy processes. These results suggest that autophagy may play a role in scavenging damaged mitochondria. Taken together, the results from these studies suggest that MnSOD plays a protective role against UVB-induced mitochondria injury beyond its known antioxidant function. Within the mitochondrial matrix, MnSOD acts as an antioxidant and fidelity protein by prevention of UVB-induced nitration of Polγ. The functions of MnSOD may be to enhance mitochondrial membrane integrity and to prevent the genesis of oxidatively damaged mitochondrial components and subsequent intracytoplasmic spillage. Activation of autophagy serves as an additional response that scavenges damaged mitochondria.

MnSOD

Polymerase gamma

Autophagy

UVB

Mitochondria

Medical Toxicology

Characterization of the Cellular and Organellar Dynamics that Occur with a Partial Depletion of Mitochondrial DNA when Arabidopsis Organellar DNA Polymerase IB is Mutated

Cupp, John D.

07 August 2012

Plant mitochondrial genomes are large and complex, and the mechanisms for maintaining mitochondrial DNA (mtDNA) remain unclear. Arabidopsis thaliana has two DNA polymerase genes, polIA and polIB, that have been shown to be dual localized to mitochondria and chloroplasts but are unequally expressed within primary plant tissues involved in cell division or cell expansion. PolIB expression is observed at higher levels in both shoot and root apexes, suggesting a possible role in organelle DNA replication in rapidly dividing or expanding cells. It is proposed that both polIA and polIB are required for mtDNA replication under wild type conditions. An Arabidopsis T-DNA polIB mutant has a 30% reduction in mtDNA levels but also a 70% induction in polIA gene expression. The polIB mutant shows an increase relative to wild type plants in the number of mitochondria that are significantly smaller in relative size, observed within hypocotyl epidermis cells that have a reduced rate of cell expansion. These mutants exhibit a significant increase in gene expression for components of mitorespiration and photosynthesis, and there is evidence for an increase in both light to dark (transitional) and light respiration levels. There is not a significant difference in dark adjusted total respiration between mutant and wild type plants. Chloroplast numbers are not significantly different in isolated mesophyll protoplasts, but mesophyll cells from the mutant are significantly smaller than wild type. PolIB mutants exhibit a three-day delay in chloroplast development but after 7dpi (days post-imbibition) there is no difference in relative plastid DNA levels between the mutant and wild type. Overall, the polIB mutant exhibits an adjustment in cell homeostasis, which enables the maintenance of functional mitochondria but at the cost of normal cell expansion rates.

polymerase gamma

PolIA

PolIB

TWINKLE

mitochondria

DNA replication

Microbiology

Approaching the crystal structure of the polymerase γ catalytic complex / Approaching the crystal structure of the polymerase [gamma] catalytic complex

Meng, Qingchao, master of arts in cell and molecular biology

02 November 2011

In this thesis, a 4.7Å crystal structure of the human mitochondria DNA polymerase γ catalytic complex is reported. Though the DNA substrate-binding site is not identifiable in the structure, two conformational changes in the enzyme architecture are described: 1) rotation of the distal monomer of the accessory subunit towards the catalytic subunit, and 2) shift of the thumb motif of the polymerase domain towards the active site. Both conformational changes suggest a structure of Pol γ in the DNA-bound state and in its active site “closed” conformation. / text

Pol γ

Crystal structure

Catalytic complex

Polymerase γ

Pol gamma

Polymerase gamma

Human mitochondria DNA polymerase gamma

DNA

DNA binding site

Human mitochondria DNA polymerase γ

Kinetics and specificity of human mitochondrial DNA polymerase gamma and HIV-1 reverse transcriptase

Ziehr, Jessica Lea

10 September 2015

The human mitochondrial DNA (mtDNA) genome must be faithfully maintained by the mitochondrial DNA replication machinery. Deficiencies in mtDNA maintenance result in the accumulation of mutations and deletions, which have been associated with a number of neuromuscular degenerative disorders including, mtDNA depletion syndrome, Alpers syndrome, progressive external opthalmoplegia (PEO), and sensory ataxic neuropathy, dysarthria, and opthalmoparesis (SANDO). The mtDNA replication machinery is comprised of a nuclearly-encoded DNA polymerase gamma (Pol γ), single-stranded DNA binding protein (mtSSB), and a hexameric mtDNA helicase. In this work, we employed quantitative pre-steady state kinetic techniques to establish the mechanisms responsible for the replication of the human mitochondrial DNA by Pol γ and explored the effects of point mutations that are observed in heritable diseases. With our biochemical characterization of mutants of Pol γ, we have shown unique characteristics that would lead to profound physiological consequences over time. Additionally, we have made significant progress towards reconstitution of the mitochondrial DNA replisome by monitoring DNA polymerization that is dependent on helicase unwinding of double stranded DNA. Overall, this work provides a better understanding of the mechanism of mtDNA replication and has important implications toward understanding the role of mitochondrial DNA replication in mitochondrial disease, ageing and cancer. In addition to the work on the mtDNA replisome, we have applied pre-steady state kinetic techniques to better understand the mechanism of RNA-dependent DNA polymerization by HIV reverse transcriptase (HIV-RT). This enzyme is responsible for the replication of the viral genome in HIV and is a common target for anti-HIV drugs. We have characterized the role of enzyme conformational changes in the kinetics of incorporation of correct nucleotide and the Nucleotide Reverse Transcriptase Inhibitor (NRTI) AZT by wild-type enzyme, as well as a mutant with clinical resistance to AZT. This work provides a better understanding of the complete mechanism of RNA-dependent DNA polymerization, the changes in the mechanism in the presence of inhibitor and the development of resistance to this nucleoside analog; and thereby this work contributes to the long-term goal of designing more effective drugs that can possibly deter resistance and be used successfully for treatment of HIV. / text

DNA polymerase

Pre-steady state kinetics

HIV reverse transcriptase

Polymerase gamma