Knut H Lauritzen

Publications (5)32.84 Total impact

• Article: Mitochondrial DNA toxicity compromises mitochondrial dynamics and induces hippocampal antioxidant defenses.

  Knut H Lauritzen, Chang Cheng, Hege Wiksen, Linda H Bergersen, Arne Klungland
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  ABSTRACT: Mitochondria are highly dynamic organelles that can be actively transported within the cell to satisfy local requirements. They are vital for providing cellular energy, but are also an important endogenous source of reactive oxygen species. The distribution of mitochondria is particularly important for neurons because of the morphological complexity of these cells, and because neural processing is metabolically expensive. Defects in mitochondrial distribution, observed in several neurodegenerative diseases, can result in synaptic dysfunction. We have generated transgenic mice expressing an enzyme in forebrain neurons that causes mitochondrial DNA (mtDNA) damage in the form of abasic-sites, creating mtDNA toxicity. Here, we report that mitochondrial distribution is disturbed in hippocampal neurons of these mice. Moreover, mtDNA copy number and mitochondrial transcription are reduced, and oxidative stress is increased. There is also a loss of receptors at excitatory glutamatergic synapses in the dentate gyrus, and the size of the postsynaptic density in this region is abnormal. We speculate that the loss of synaptic mitochondria caused by accumulation in the neuronal cell body contributes to the observed synaptic abnormalities, as well as the overall loss of mtDNA and diminished mitochondrial transcription. Collectively, these changes lead to mitochondria with reduced function and increased oxidative stress.
  DNA repair 06/2011; 10(6):639-53. · 4.20 Impact Factor
• Article: Modeling the impact of mitochondrial DNA damage in forebrain neurons and beyond.

  Knut H Lauritzen, Bjørn Dalhus, Johan F Storm, Magnar Bjørås, Arne Klungland
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  ABSTRACT: We have generated an inducible transgenic mouse model, which expresses a mutated version of UNG1 (mutUNG1) that removes thymine, in addition to uracil from mitochondrial DNA. The abasic-sites (AP-sites) generated by removal of thymine or uracil are a threat to genomic integrity, and are particularly harmful in mitochondria due to inhibition of mitochondrial DNA polymerase. MutUNG1, accompanied by a luciferase reporter-gene, is controlled by the Tet-on system. Transgene expression is spatially regulated by the forebrain specific CaMKIIα-promoter, and temporally by the addition of doxycycline. Mice harboring this transgene develop compromised mitochondrial dynamics, neurodegeneration and impaired behavior.
  Mechanisms of ageing and development 02/2011; 132(8-9):424-8. · 4.18 Impact Factor
• Article: Mitochondrial DNA toxicity in forebrain neurons causes apoptosis, neurodegeneration, and impaired behavior.

  Knut H Lauritzen, Olve Moldestad, Lars Eide, Harald Carlsen, Gaute Nesse, Johan F Storm, Isabelle M Mansuy, Linda H Bergersen, Arne Klungland
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  ABSTRACT: Mitochondrial dysfunction underlying changes in neurodegenerative diseases is often associated with apoptosis and a progressive loss of neurons, and damage to the mitochondrial genome is proposed to be involved in such pathologies. In the present study we designed a mouse model that allows us to specifically induce mitochondrial DNA toxicity in the forebrain neurons of adult mice. This is achieved by CaMKIIalpha-regulated inducible expression of a mutated version of the mitochondrial UNG DNA repair enzyme (mutUNG1). This enzyme is capable of removing thymine from the mitochondrial genome. We demonstrate that a continual generation of apyrimidinic sites causes apoptosis and neuronal death. These defects are associated with behavioral alterations characterized by increased locomotor activity, impaired cognitive abilities, and lack of anxietylike responses. In summary, whereas mitochondrial base substitution and deletions previously have been shown to correlate with premature and natural aging, respectively, we show that a high level of apyrimidinic sites lead to mitochondrial DNA cytotoxicity, which causes apoptosis, followed by neurodegeneration.
  Molecular and cellular biology 03/2010; 30(6):1357-67. · 6.06 Impact Factor
• Article: Repair deficient mice reveal mABH2 as the primary oxidative demethylase for repairing 1meA and 3meC lesions in DNA.

  Jeanette Ringvoll, Line M Nordstrand, Cathrine B Vågbø, Vivi Talstad, Karen Reite, Per Arne Aas, Knut H Lauritzen, Nina Beate Liabakk, Alexandra Bjørk, Richard William Doughty, Pål Ø Falnes, Hans E Krokan, Arne Klungland
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  ABSTRACT: Two human homologs of the Escherichia coli AlkB protein, denoted hABH2 and hABH3, were recently shown to directly reverse 1-methyladenine (1meA) and 3-methylcytosine (3meC) damages in DNA. We demonstrate that mice lacking functional mABH2 or mABH3 genes, or both, are viable and without overt phenotypes. Neither were histopathological changes observed in the gene-targeted mice. However, in the absence of any exogenous exposure to methylating agents, mice lacking mABH2, but not mABH3 defective mice, accumulate significant levels of 1meA in the genome, suggesting the presence of a biologically relevant endogenous source of methylating agent. Furthermore, embryonal fibroblasts from mABH2-deficient mice are unable to remove methyl methane sulfate (MMS)-induced 1meA from genomic DNA and display increased cytotoxicity after MMS exposure. In agreement with these results, we found that in vitro repair of 1meA and 3meC in double-stranded DNA by nuclear extracts depended primarily, if not solely, on mABH2. Our data suggest that mABH2 and mABH3 have different roles in the defense against alkylating agents.
  The EMBO Journal 06/2006; 25(10):2189-98. · 9.20 Impact Factor
• Article: Repair deficient mice reveal mABH2 as the primary oxidative demethylase for repairing 1meA and 3meC lesions in DNA

  Jeanette Ringvoll, Line M Nordstrand, Cathrine B V|[aring]|gb|[oslash, Vivi Talstad, Karen Reite, Per Arne Aas, Knut H Lauritzen, Nina Beate Liabakk, Alexandra Bj|[oslash]|rk, Richard William Doughty, P|[aring]|l |[Oslash]| Falnes, Hans E Krokan, Arne Klungland
  [show abstract] [hide abstract]
  ABSTRACT: Two human homologs of the Escherichia coli AlkB protein, denoted hABH2 and hABH3, were recently shown to directly reverse 1-methyladenine (1meA) and 3-methylcytosine (3meC) damages in DNA. We demonstrate that mice lacking functional mABH2 or mABH3 genes, or both, are viable and without overt phenotypes. Neither were histopathological changes observed in the gene-targeted mice. However, in the absence of any exogenous exposure to methylating agents, mice lacking mABH2, but not mABH3 defective mice, accumulate significant levels of 1meA in the genome, suggesting the presence of a biologically relevant endogenous source of methylating agent. Furthermore, embryonal fibroblasts from mABH2-deficient mice are unable to remove methyl methane sulfate (MMS)-induced 1meA from genomic DNA and display increased cytotoxicity after MMS exposure. In agreement with these results, we found that in vitro repair of 1meA and 3meC in double-stranded DNA by nuclear extracts depended primarily, if not solely, on mABH2. Our data suggest that mABH2 and mABH3 have different roles in the defense against alkylating agents.
  The EMBO Journal 04/2006; 25(10):2189-2198. · 9.20 Impact Factor