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1.
PLoS Genet ; 11(12): e1005719, 2015 Dec.
Article in English | MEDLINE | ID: mdl-26684201

ABSTRACT

During replication, mismatch repair proteins recognize and repair mispaired bases that escape the proofreading activity of DNA polymerase. In this work, we tested the model that the eukaryotic mismatch recognition complex tracks with the advancing replisome. Using yeast, we examined the dynamics during replication of the leading strand polymerase Polε using Pol2 and the eukaryotic mismatch recognition complex using Msh2, the invariant protein involved in mismatch recognition. Specifically, we synchronized cells and processed samples using chromatin immunoprecipitation combined with custom DNA tiling arrays (ChIP-chip). The Polε signal was not detectable in G1, but was observed at active origins and replicating DNA throughout S-phase. The Polε signal provided the resolution to track origin firing timing and efficiencies as well as replisome progression rates. By detecting Polε and Msh2 dynamics within the same strain, we established that the mismatch recognition complex binds origins and spreads to adjacent regions with the replisome. In mismatch repair defective PCNA mutants, we observed that Msh2 binds to regions of replicating DNA, but the distribution and dynamics are altered, suggesting that PCNA is not the sole determinant for the mismatch recognition complex association with replicating regions, but may influence the dynamics of movement. Using biochemical and genomic methods, we provide evidence that both MutS complexes are in the vicinity of the replisome to efficiently repair the entire spectrum of mutations during replication. Our data supports the model that the proximity of MutSα/ß to the replisome for the efficient repair of the newly synthesized strand before chromatin reassembles.


Subject(s)
DNA Polymerase II/genetics , DNA Replication/genetics , DNA-Directed DNA Polymerase/genetics , DNA/biosynthesis , MutS Homolog 2 Protein/genetics , Saccharomyces cerevisiae Proteins/genetics , DNA/genetics , DNA Mismatch Repair/genetics , DNA Repair/genetics , MutS DNA Mismatch-Binding Protein/genetics , Mutation , Saccharomyces cerevisiae
2.
DNA Repair (Amst) ; 12(2): 97-109, 2013 Feb 01.
Article in English | MEDLINE | ID: mdl-23261051

ABSTRACT

DNA mismatch repair during replication is a conserved process essential for maintaining genomic stability. Mismatch repair is also implicated in cell-cycle arrest and apoptosis after DNA damage. Because yeast and human mismatch repair systems are well conserved, we have employed the budding yeast Saccharomyces cerevisiae to understand the regulation and function of the mismatch repair gene MSH2. Using a luciferase-based transcriptional reporter, we defined a 218-bp region upstream of MSH2 that contains cell-cycle and DNA damage responsive elements. The 5' end of the MSH2 transcript was mapped by primer extension and was found to encode a small upstream open reading frame (uORF). Mutagenesis of the uORF start codon or of the uORF stop codon, which creates a continuous reading frame with MSH2, increased Msh2 steady-state protein levels ∼2-fold. Furthermore, we found that the cell-cycle transcription factors Swi6, Swi4, and Mbp1-along with SCB/MCB cell-cycle binding sites upstream of MSH2-are all required for full basal expression of MSH2. Mutagenesis of the cell-cycle boxes resulted in a minor reduction in basal Msh2 levels and a 3-fold defect in mismatch repair. Disruption of the cell-cycle boxes also affected growth in a DNA polymerase-defective strain background where mismatch repair is essential, particularly in the presence of the DNA damaging agent methyl methane sulfonate (MMS). Promoter replacements conferring constitutive expression of MSH2 revealed that the transcriptional induction in response to MMS is required to maintain induced levels of Msh2. Turnover experiments confirmed an elevated rate of degradation in the presence of MMS. Taken together, the data show that the DNA damage regulation of Msh2 occurs at the transcriptional and post-transcriptional levels. The transcriptional and translational control elements identified are conserved in mammalian cells, underscoring the use of yeast as a model system to examine the regulation of MSH2.


Subject(s)
Cell Cycle , DNA Damage , DNA Mismatch Repair , Gene Expression Regulation, Fungal , MutS Homolog 2 Protein/genetics , Saccharomyces cerevisiae Proteins/genetics , Saccharomyces cerevisiae/genetics , Base Sequence , Cell Cycle/genetics , Codon, Initiator/metabolism , Codon, Terminator/metabolism , DNA, Fungal/drug effects , DNA, Fungal/metabolism , Methyl Methanesulfonate/toxicity , Molecular Sequence Data , MutS Homolog 2 Protein/metabolism , Mutation , Open Reading Frames , RNA Stability , RNA, Messenger/metabolism , Response Elements , Saccharomyces cerevisiae/cytology , Saccharomyces cerevisiae/metabolism , Saccharomyces cerevisiae Proteins/metabolism , Transcription Factors/metabolism , Transcription, Genetic
3.
J Immunol ; 186(4): 2201-9, 2011 Feb 15.
Article in English | MEDLINE | ID: mdl-21239722

ABSTRACT

Autophagy is a highly regulated and evolutionarily conserved process of cellular self-digestion. Recent evidence suggests that this process plays an important role in regulating T cell homeostasis. In this study, we used Rag1(-/-) (recombination activating gene 1(-/-)) blastocyst complementation and in vitro embryonic stem cell differentiation to address the role of Beclin 1, one of the key autophagic proteins, in lymphocyte development. Beclin 1-deficient Rag1(-/-) chimeras displayed a dramatic reduction in thymic cellularity compared with control mice. Using embryonic stem cell differentiation in vitro, we found that the inability to maintain normal thymic cellularity is likely caused by impaired maintenance of thymocyte progenitors. Interestingly, despite drastically reduced thymocyte numbers, the peripheral T cell compartment of Beclin 1-deficient Rag1(-/-) chimeras is largely normal. Peripheral T cells displayed normal in vitro proliferation despite significantly reduced numbers of autophagosomes. In addition, these chimeras had greatly reduced numbers of early B cells in the bone marrow compared with controls. However, the peripheral B cell compartment was not dramatically impacted by Beclin 1 deficiency. Collectively, our results suggest that Beclin 1 is required for maintenance of undifferentiated/early lymphocyte progenitor populations. In contrast, Beclin 1 is largely dispensable for the initial generation and function of the peripheral T and B cell compartments. This indicates that normal lymphocyte development involves Beclin 1-dependent, early-stage and distinct, Beclin 1-independent, late-stage processes.


Subject(s)
Apoptosis Regulatory Proteins/physiology , Autophagy/immunology , Cell Differentiation/immunology , Lymphocyte Subsets/immunology , Animals , Apoptosis Regulatory Proteins/deficiency , Apoptosis Regulatory Proteins/genetics , B-Lymphocyte Subsets/cytology , B-Lymphocyte Subsets/immunology , B-Lymphocyte Subsets/pathology , Beclin-1 , Cell Differentiation/genetics , Coculture Techniques , Embryonic Stem Cells/immunology , Embryonic Stem Cells/pathology , Embryonic Stem Cells/transplantation , Female , Humans , Lymphocyte Subsets/metabolism , Lymphocyte Subsets/pathology , Male , Mice , Mice, 129 Strain , Mice, Inbred C57BL , Mice, Knockout , Radiation Chimera/genetics , Radiation Chimera/immunology , T-Lymphocyte Subsets/cytology , T-Lymphocyte Subsets/immunology , T-Lymphocyte Subsets/pathology , Time Factors
4.
Proc Natl Acad Sci U S A ; 107(51): 22140-4, 2010 Dec 21.
Article in English | MEDLINE | ID: mdl-21078984

ABSTRACT

Increasing evidence suggests that parentally supplied RNA plays crucial roles during eukaryotic development. This epigenetic contribution may regulate gene expression from the earliest stages. Although present in a variety of eukaryotes, maternally inherited characters are especially prominent in ciliated protozoa, in which parental noncoding RNA molecules instruct whole-genome reorganization. This includes removal of nearly all noncoding DNA and sorting the remaining fragments, producing extremely gene-rich somatic genomes. Chromosome fragmentation and extensive replication produce variable DNA copy numbers in the somatic genome. Understanding the forces that drive and regulate copy number change is fundamental. We show that RNA molecules present in parental cells during sexual reproduction can regulate chromosome copy number in the developing nucleus of the ciliate Oxytricha. Experimentally induced changes in RNA abundance can both increase and decrease the levels of corresponding DNA molecules in progeny, demonstrating epigenetic inheritance of chromosome copy number. These results suggest that maternal RNA, in addition to controlling gene expression or DNA processing, can also program DNA amplification levels.


Subject(s)
Chromosomes/metabolism , Ciliophora/metabolism , DNA Copy Number Variations/physiology , DNA, Protozoan/metabolism , Epigenesis, Genetic/physiology , Genome, Protozoan/physiology , Chromosomes/genetics , Ciliophora/genetics , DNA, Protozoan/genetics
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