Analysis of Saccharomyces cerevisiae genetic background and mitochondrial DNA polymerase variants on maintenance of the mitochondrial genome.

Young, Matthew J.

10 September 2008

The contribution of yeast strain background, specifically auxotrophic markers, to stability and fidelity of mtDNA replication was investigated. In summary, the ade2, his3delta200, and hap1 mutations have complex effects on mitochondrial functions, the severity of which appears to depend on other components in the genetic background of the strain. These results are important as many commonly used laboratory strains are related to the respiratory hampered S288c strain and are used for studies of orthologous human mutations associated with various mitochondrial diseases. These observations have added to our understanding of fungal mtDNA replication and have informed the mitochondrial community of problematic strains that need to be considered when using this model organism. The function of the yeast mitochondrial DNA polymerase (Mip1p) carboxyl-terminal extension (CTE) was investigated both in vivo and in vitro by genetically engineering various truncations of the CTE. The respiratory competence of mip1delta175 and mip1delta205 cells, in which Mip1p lacks the C-terminal 175 and 205 residues respectively, are indistinguishable from that of wild-type. In contrast, strains harbouring Mip1pdelta351, Mip1pdelta279, Mip1pdelta241, and Mip1pdelta222 rapidly lose mtDNA. At a low frequency, mip1delta216 cells grow poorly on glycerol. Fluorescence microscopy and Southern blot analysis revealed lower levels of mtDNA in these cells, and rapid loss of mtDNA during fermentative growth. Therefore, only the polymerase-proximal segment of the Mip1p CTE is necessary for mitochondrial function. To determine more precisely the defects associated with polymerase truncation variants, these proteins were overexpressed in yeast and used in a novel non-radioactive mtDNA polymerase assay. The threonine-661 and alanine-661 variants, shown by others to be responsible for the increased mtDNA mutability of various laboratory yeast strains at increased temperature, were examined in combination with CTE-truncations. These experiments suggest that exonuclease function is not effected in the alanine-661 variant at 37 degrees Celsius whereas polymerase activity is, and this higher relative level of exonuclease activity could be a contributing factor to mtDNA instability in S288c-related strains. Lastly, isogenic CTE truncation variants all have less DNA polymerase activity than their parental wild-type. Based on these results, several possible roles for the function of the CTE in mtDNA replication are suggested. / October 2008

mitochondria

yeast

mitochondrial DNA polymerase

S288c

phylogeny

Saccharomyces cerevisiae

Evolution of DNA polymerase active site /

Patel, Premal Harshad.

January 2001

Thesis (Ph. D.)--University of Washington, 2001. / Vita. Includes bibliographical references (leaves 107-114).

Foamy virus polymerase : enzymatic activities and assembly /

Stenbak, Carolyn Rinke.

January 2003

Thesis (Ph. D.)--University of Washington, 2003. / Vita. Includes bibliographical references (leaves 141-164).

Analysis of Saccharomyces cerevisiae genetic background and mitochondrial DNA polymerase variants on maintenance of the mitochondrial genome.

Young, Matthew J.

10 September 2008

The contribution of yeast strain background, specifically auxotrophic markers, to stability and fidelity of mtDNA replication was investigated. In summary, the ade2, his3delta200, and hap1 mutations have complex effects on mitochondrial functions, the severity of which appears to depend on other components in the genetic background of the strain. These results are important as many commonly used laboratory strains are related to the respiratory hampered S288c strain and are used for studies of orthologous human mutations associated with various mitochondrial diseases. These observations have added to our understanding of fungal mtDNA replication and have informed the mitochondrial community of problematic strains that need to be considered when using this model organism. The function of the yeast mitochondrial DNA polymerase (Mip1p) carboxyl-terminal extension (CTE) was investigated both in vivo and in vitro by genetically engineering various truncations of the CTE. The respiratory competence of mip1delta175 and mip1delta205 cells, in which Mip1p lacks the C-terminal 175 and 205 residues respectively, are indistinguishable from that of wild-type. In contrast, strains harbouring Mip1pdelta351, Mip1pdelta279, Mip1pdelta241, and Mip1pdelta222 rapidly lose mtDNA. At a low frequency, mip1delta216 cells grow poorly on glycerol. Fluorescence microscopy and Southern blot analysis revealed lower levels of mtDNA in these cells, and rapid loss of mtDNA during fermentative growth. Therefore, only the polymerase-proximal segment of the Mip1p CTE is necessary for mitochondrial function. To determine more precisely the defects associated with polymerase truncation variants, these proteins were overexpressed in yeast and used in a novel non-radioactive mtDNA polymerase assay. The threonine-661 and alanine-661 variants, shown by others to be responsible for the increased mtDNA mutability of various laboratory yeast strains at increased temperature, were examined in combination with CTE-truncations. These experiments suggest that exonuclease function is not effected in the alanine-661 variant at 37 degrees Celsius whereas polymerase activity is, and this higher relative level of exonuclease activity could be a contributing factor to mtDNA instability in S288c-related strains. Lastly, isogenic CTE truncation variants all have less DNA polymerase activity than their parental wild-type. Based on these results, several possible roles for the function of the CTE in mtDNA replication are suggested.

mitochondria

yeast

mitochondrial DNA polymerase

S288c

phylogeny

Saccharomyces cerevisiae

Analysis of Saccharomyces cerevisiae genetic background and mitochondrial DNA polymerase variants on maintenance of the mitochondrial genome.

Young, Matthew J.

10 September 2008

The contribution of yeast strain background, specifically auxotrophic markers, to stability and fidelity of mtDNA replication was investigated. In summary, the ade2, his3delta200, and hap1 mutations have complex effects on mitochondrial functions, the severity of which appears to depend on other components in the genetic background of the strain. These results are important as many commonly used laboratory strains are related to the respiratory hampered S288c strain and are used for studies of orthologous human mutations associated with various mitochondrial diseases. These observations have added to our understanding of fungal mtDNA replication and have informed the mitochondrial community of problematic strains that need to be considered when using this model organism. The function of the yeast mitochondrial DNA polymerase (Mip1p) carboxyl-terminal extension (CTE) was investigated both in vivo and in vitro by genetically engineering various truncations of the CTE. The respiratory competence of mip1delta175 and mip1delta205 cells, in which Mip1p lacks the C-terminal 175 and 205 residues respectively, are indistinguishable from that of wild-type. In contrast, strains harbouring Mip1pdelta351, Mip1pdelta279, Mip1pdelta241, and Mip1pdelta222 rapidly lose mtDNA. At a low frequency, mip1delta216 cells grow poorly on glycerol. Fluorescence microscopy and Southern blot analysis revealed lower levels of mtDNA in these cells, and rapid loss of mtDNA during fermentative growth. Therefore, only the polymerase-proximal segment of the Mip1p CTE is necessary for mitochondrial function. To determine more precisely the defects associated with polymerase truncation variants, these proteins were overexpressed in yeast and used in a novel non-radioactive mtDNA polymerase assay. The threonine-661 and alanine-661 variants, shown by others to be responsible for the increased mtDNA mutability of various laboratory yeast strains at increased temperature, were examined in combination with CTE-truncations. These experiments suggest that exonuclease function is not effected in the alanine-661 variant at 37 degrees Celsius whereas polymerase activity is, and this higher relative level of exonuclease activity could be a contributing factor to mtDNA instability in S288c-related strains. Lastly, isogenic CTE truncation variants all have less DNA polymerase activity than their parental wild-type. Based on these results, several possible roles for the function of the CTE in mtDNA replication are suggested.

mitochondria

yeast

mitochondrial DNA polymerase

S288c

phylogeny

Saccharomyces cerevisiae

Genetic factors of cytomegalovirus and other herpesviruses that influence outcomes of antiviral therapy in transplantation

Iwasenko, Jenna Maree, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW

January 2009

The clinical impact of human cytomegalovirus (CMV) and progression to CMV disease in immunocompromised patients has been reduced by therapeutic strategies using ganciclovir, valganciclovir, foscarnet and cidofovir. However, extensive antiviral therapy increases the risk of antiviral resistance due to mutations in the UL97 protein kinase and UL54 DNA polymerase. Co-infection with HHV-6 or HHV-7 is also associated with increased CMV reactivation and disease. Genotypic CMV antiviral resistance was identified in 38% of Australian immunocompromised patients. While UL97 mutations only were identified in 23% of patients, additional UL54 mutations, with the potential to confer multidrug resistance, were detected in 15% of patients. Antiviral resistant CMV strains were found to emerge rapidly in highly immunocompromised patients, and some strains were able to persist in the absence of selective pressure. Three new mutations were identified (UL97 - N597D, UL54 - F412S, D485N). N597D was characterised by recombinant phenotyping and conferred minimal ganciclovir resistance. Neither baculovirus nor coupled transcription/translation yielded full-length UL54 protein (pUL54; ~140 kDa) for activity assays. However, truncated pUL54 (~66 kDa) was purified after prokaryotic expression. HHV-6 and HHV-7 co-infection was a common clinical occurrence; with 36% of liver transplant recipients infected with HHV-6 (11% persistent) and 80% with HHV-7 (52% persistent). ValGCV therapy did not significantly alter the incidence of HHV-6, HHV-7 or co-infection. The most prevalent co-infection pattern was CMV, HHV-6 and HHV-7 (46%) and both CMV and HHV-7 (38%). CMV reactivation was predominantly independent of HHV-6/HHV-7, although 27% of patients had initial HHV-7 reactivation. Despite frequent co-infection, HHV-6 and HHV-7 were not associated with clinical disease, with possible exception of HHV-7 and acute cellular rejection. CMV antiviral resistance remains a significant issue in transplantation, emphasising the importance of antiviral resistance testing in an era of widespread prophylaxis. New mutations in UL97 and UL54 continue to be identified. Further characterisation of UL54 mutations using polymerase activity assays would increase our knowledge of enzymological basis of antiviral resistance. Co-infection with HHV-6 and HHV-7 is common in transplant recipients, but does not play a significant role in disease. Similar co-infection rates between valGCV-treated and untreated patients indicate that valGCV is not highly effective against HHV-6 and HHV-7.

transplantation

cytomegalovirus

antiviral resistance

herpesvirus

coinfection

UL54 DNA polymerase

Characterization of the in vivo functions of Y-Family DNA polymerases kappa and Rev1

Kosarek, Jayme Nicole

January 2008

Dissertation (Ph.D.) -- University of Texas Southwestern Medical Center at Dallas, 2008. / Vita. Bibliography: p. 117-123.

Divergence in repetitive DNA sequences among three sitopsis wheat species

Madsen, Susan M.

January 1998

Thesis (Ph. D.)--University of Missouri-Columbia, 1998. / Typescript. Vita. Includes bibliographical references (leaves 77-85). Also available on the Internet.

Divergence in repetitive DNA sequences among three sitopsis wheat species /

Madsen, Susan M.

January 1998

Thesis (Ph. D.)--University of Missouri-Columbia, 1998. / Typescript. Vita. Includes bibliographical references (leaves 77-85). Also available on the Internet.

Development of Selective Inhibitors of DNA Polymerase Delta: A Thesis

Talanian, Robert Vincent

01 August 1989

This thesis is divided into three parts, united by the theme of the development of selective inhibitors of mammalian cell DNA polymerase delta (pol δ). The first part consists of an investigation of the cytotoxic mechanism(s) of certain 2-substituted adenine analogs, selected on the basis of their inhibitory properties towards DNA polymerase alpha (pol α) and mammalian cell DNA synthesis. The second is a direct search for inhibitors of isolated pol δ, and an investigation of inhibitory mechanisms. The third consists of measurement of the effects of a selective pol δ inhibitor on cellular DNA synthesis. Mechanism of Cytotoxicity of 2-substituted adenine analoqs. The mechanism of inhibition by 2-(p-n-butylanilino)-2'-deoxyadenosine (BuAdA), and related compounds, of Chinese hamster ovary (CHO) cell ([3H]thymidine [3H]TdR) incorporation, was investigated. The potency of the compound could largely be explained by its potency (IC50 = 23 μM) as an inhibitor of CHO cell [3H]TdR uptake. BuAdA inhibited incorporation by CHO cells of [32p]phosphate into DNA relatively weakly, displaying an IC50value of 80 μM. Differential inhibition of DNA polymerases alpha and delta. Known DNA polymerase inhibitors of a structurally wide range were screened for their ability to inhibit pol δ derived from calf thymus selectively with respect to pol α derived from the same tissue. Pyrophosphate (PPi) and difluoromethanediphosphonate each inhibited pol δ weakly, but with greater potency than pol α. Based on this lead, an expanded series of PPi analogs was screened. Carbonyldiphosphonate (COMDP) inhibited pol δ with a potency (Ki = 1.8 μM) twenty-two times greater than that displayed for pol α. Kinetic studies indicated that COMDP inhibited pol δ competitively with the dNTP specified by the template, but not competitively with the template:primer. Analogous experiments with pol α showed that the compound inhibited that enzyme uncompetitively with the dNTP, and not competitively with the template:primer. COMDP was a weak inhibitor of the 3' → 5' exonuclease activity of pol δ, displaying an IC50value greater than 1 mM. Inhibition of permeabilized cell DNA synthesis bv a selective pol δ inhibitor. The potency of COMDP as an inhibitor of permeabilized CHO cell DNA synthesis (IC50= 200 μM) did not clearly indicate the participation of pol δ in cellular DNA replication. Prospectus. The thesis concludes with a prospectus for the development of pol δ inhibitors with improved properties compared to COMDP.

DNA-Directed DNA Polymerase

Enzymes and Coenzymes

Genetic Phenomena