Regulation of the Expression of Mouse Ribonucleotide Reductase Small Subunit at the Levels of Transcription and Protein Degradation

Deoxyribonucleic acid (DNA) carries all the genetic information of a cell. Ribonucleotide reductase (RNR) provides balanced pools of all four dNTPs, the building blocks of DNA. These building blocks are needed during DNA synthesis and repair. A failure in the control of the dNTP levels and/or their relative amounts leads to cell death or genetic abnormalities. Because of its central role in dNTP metabolism, RNR is highly regulated on multiple levels. The active RNR enzyme consists of two non-identical subunits called proteins R1 and R2. In mammalian cells, during an unperturbed cell cycle, the activity of RNR is highest during S and G2 phases. This is achieved by de novo synthesis of the limiting R2 protein at the onset of S phase, and by controlled degradation of the R2 protein during mitosis. This thesis deals with both the S phase-specific transcription of the mouse R2 gene, and the M phase-specific degradation of the mouse R2 protein. Sequence comparison of the mouse R2 promoter to human and guinea pig R2 promoters revealed some conserved elements. These putative regulatory elements were tested in both in vitro and in vivo transcription assays. We demonstrated that the previously identified, NF-Y binding CCAAT box is essential for high-level expression from the R2 promoter, but not for its S phase specificity. In addition, the conserved TATA box is dispensable both for basal and S phase-specific R2 transcription as long as the first 17 basepairs of the 5’ untranslated region are present. However, if this 5’ untranslated region is absent, the TATA box is needed for correct initiation of transcription. Focusing on the S phase specificity of the R2 gene expression, we demonstrated that the S phase-specific activity of the mouse R2 promoter is dependent on a protein-binding region located ~500 basepairs upstream of the transcription start site and an E2F binding site close to the transcription start site. Deletion of the upstream activating region results in an inactive promoter. In contrast, mutation of the E2F site leads to premature promoter activation in G1 and increased overall promoter activity. However, if the activating mutation of the E2F site is combined with mutation of the upstream activating region, the promoter becomes inactive. These results suggest that the E2F-dependent regulation is important but not sufficient for cell-cycle specific R2 transcription, and that the upstream activating region is crucial for the overall R2 promoter activity. In our studies of the M phase-specific R2 degradation, we found that it is dependent on a KEN sequence in the N-terminus of the R2 protein, recognized by the Cdh1-APC complex. Mutating the KEN box stabilizes the R2 protein during mitosis and G1 phase. In summary, these studies further extend our understanding of the regulation of the limiting R2 subunit of the enzyme ribonucleotide reductase. The S phase-specific transcription of the R2 gene and the M phase-specific degradation of the R2 protein may serve as important mechanisms to protect the cell against unscheduled DNA synthesis

Regulation of the Expression of Mouse Ribonucleotide Reductase Small Subunit at the Levels of Transcription and Protein Degradation

Deoxyribonucleic acid (DNA) carries all the genetic information of a cell. Ribonucleotide reductase (RNR) provides balanced pools of all four dNTPs, the building blocks of DNA. These building blocks are needed during DNA synthesis and repair. A failure in the control of the dNTP levels and/or their relative amounts leads to cell death or genetic abnormalities. Because of its central role in dNTP metabolism, RNR is highly regulated on multiple levels. The active RNR enzyme consists of two non-identical subunits called proteins R1 and R2. In mammalian cells, during an unperturbed cell cycle, the activity of RNR is highest during S and G2 phases. This is achieved by de novo synthesis of the limiting R2 protein at the onset of S phase, and by controlled degradation of the R2 protein during mitosis. This thesis deals with both the S phase-specific transcription of the mouse R2 gene, and the M phase-specific degradation of the mouse R2 protein. Sequence comparison of the mouse R2 promoter to human and guinea pig R2 promoters revealed some conserved elements. These putative regulatory elements were tested in both in vitro and in vivo transcription assays. We demonstrated that the previously identified, NF-Y binding CCAAT box is essential for high-level expression from the R2 promoter, but not for its S phase specificity. In addition, the conserved TATA box is dispensable both for basal and S phase-specific R2 transcription as long as the first 17 basepairs of the 5’ untranslated region are present. However, if this 5’ untranslated region is absent, the TATA box is needed for correct initiation of transcription. Focusing on the S phase specificity of the R2 gene expression, we demonstrated that the S phase-specific activity of the mouse R2 promoter is dependent on a protein-binding region located ~500 basepairs upstream of the transcription start site and an E2F binding site close to the transcription start site. Deletion of the upstream activating region results in an inactive promoter. In contrast, mutation of the E2F site leads to premature promoter activation in G1 and increased overall promoter activity. However, if the activating mutation of the E2F site is combined with mutation of the upstream activating region, the promoter becomes inactive. These results suggest that the E2F-dependent regulation is important but not sufficient for cell-cycle specific R2 transcription, and that the upstream activating region is crucial for the overall R2 promoter activity. In our studies of the M phase-specific R2 degradation, we found that it is dependent on a KEN sequence in the N-terminus of the R2 protein, recognized by the Cdh1-APC complex. Mutating the KEN box stabilizes the R2 protein during mitosis and G1 phase. In summary, these studies further extend our understanding of the regulation of the limiting R2 subunit of the enzyme ribonucleotide reductase. The S phase-specific transcription of the R2 gene and the M phase-specific degradation of the R2 protein may serve as important mechanisms to protect the cell against unscheduled DNA synthesis

Simultaneous determination of ribonucleoside and deoxyribonucleoside triphosphates in biological samples by hydrophilic interaction liquid chromatography coupled with tandem mass spectrometry

Information about the intracellular concentration of dNTPs and NTPs is important for studies of the mechanisms of DNA replication and repair, but the low concentration of dNTPs and their chemical similarity to NTPs present a challenge for their measurement. Here, we describe a new rapid and sensitive method utilizing hydrophilic interaction liquid chromatography coupled with tandem mass spectrometry for the simultaneous determination of dNTPs and NTPs in biological samples. The developed method showed linearity (R2 > 0.99) in wide concentration ranges and could accurately quantify dNTPs and NTPs at low pmol levels. The intra-day and inter-day precision were below 13%, and the relative recovery was between 92% and 108%. In comparison with other chromatographic methods, the current method has shorter analysis times and simpler sample pre-treatment steps, and it utilizes an ion-pair-free mobile phase that enhances mass-spectrometric detection. Using this method, we determined dNTP and NTP concentrations in actively dividing and quiescent mouse fibroblasts

Elimination of rNMPs from mitochondrial DNA has no effect on its stability

Ribonucleotides (rNMPs) incorporated in the nuclear genome are a well-established threat to genome stability and can result in DNA strand breaks when not removed in a timely manner. However, the presence of a certain level of rNMPs is tolerated in mitochondrial DNA (mtDNA) although aberrant mtDNA rNMP content has been identified in disease models. We investigated the effect of incorporated rNMPs on mtDNA stability over the mouse life span and found that the mtDNA rNMP content increased during early life. The rNMP content of mtDNA varied greatly across different tissues and was defined by the rNTP/dNTP ratio of the tissue. Accordingly, mtDNA rNMPs were nearly absent in SAMHD1 -/- mice that have increased dNTP pools. The near absence of rNMPs did not, however, appreciably affect mtDNA copy number or the levels of mtDNA molecules with deletions or strand breaks in aged animals near the end of their life span. The physiological rNMP load therefore does not contribute to the progressive loss of mtDNA quality that occurs as mice age