Project description:The mismatch repair (MMR) family is a highly conserved group of proteins that function in correcting base-base and insertion-deletion mismatches generated during DNA replication. To systematically investigate the mismatch repair pathway, we conducted a proteomic analysis and identified MMR-associated protein complexes using a tandem-affinity purification coupled with mass spectrometry (TAP-MS) method. In total, we identified 262 high-confidence candidate interaction proteins (HCIPs).

Project description:AID-dependent U/G mismatches in S DNA are converted by BER and MMR DNA pathways into double-stranded breaks that are required for optimal CSR in activated B cells. Deficits in MMR proteins, MSH2, MLH1, and PMS2 result in lower CSR frequencies that are coupled with impaired DSB formation. MBD4 interacts with MLH1 and has been postulated to coordinate mismatch repair of U/G. Deletions of Mbd4 targeting the 5' end of the gene in mice do not affect CSR . However, Mbd4 transcription is complex, with the propensity to create alternative transcripts, including residual transcription leading to to truncated protein expression that complicates ananlysis in these mice. We describe a novel function of MBD4 housed in the C-terminus that is critical for DSB formation, which shares several characteristics with MMR . We conclude that the 3' end of the Mbd4 gene positively contributes to CSR and likely intersects the MMR pathway. 2 independent samples for each control and Mbd4 KO group

Project description:Mass spectrometry based PTM phosphorylation analysis to study regulation mechanism of MUTL alpha, a heterodimer consisting of MLH1 and PMS2 and a key player in DNA mismatch repair (MMR). It could be demonstrated that phosphorylation of MLH1 by Casein Kinase II (CK2) at amino acid position 477 can switch off MMR activity in vitro.

Project description:The mismatch repair (MMR) family is a highly conserved group of proteins that function in correcting base-base and insertion-deletion mismatches generated during DNA replication. To systematically investigate the mismatch repair pathway, we conducted a proteomic analysis and identified MMR-associated protein complexes using a tandem-affinity purification coupled with mass spectrometry (TAP-MS) method. In total, we identified 262 high-confidence candidate interaction proteins (HCIPs).

Project description:AID-dependent U/G mismatches in S DNA are converted by BER and MMR DNA pathways into double-stranded breaks that are required for optimal CSR in activated B cells. Deficits in MMR proteins, MSH2, MLH1, and PMS2 result in lower CSR frequencies that are coupled with impaired DSB formation. MBD4 interacts with MLH1 and has been postulated to coordinate mismatch repair of U/G. Deletions of Mbd4 targeting the 5' end of the gene in mice do not affect CSR . However, Mbd4 transcription is complex, with the propensity to create alternative transcripts, including residual transcription leading to to truncated protein expression that complicates ananlysis in these mice. We describe a novel function of MBD4 housed in the C-terminus that is critical for DSB formation, which shares several characteristics with MMR . We conclude that the 3' end of the Mbd4 gene positively contributes to CSR and likely intersects the MMR pathway.

Project description:Somatic hypermutation (SHM) and class switch recombination (CSR) of immunoglobulin (Ig) genes are genomic modification events that occur in germinal center (GC) B cells and are initiated through deamination of cytidine to uracil by activation induced cytidine deaminase (AID). Resulting uracil-guanine (U-G) mismatches are subsequently processed by low-fidelity base-excision (BER) and mismatch repair (MMR) pathways to yield mutations and DNA strand lesions. Although off-target AID activity also contributes to oncogenic point mutations and chromosome translocations associated with B cell lymphomas, the role of downstream AID-associated DNA repair pathways in the pathogenesis of these lymphomas is unknown. Here, we show that simultaneous BER and MMR deficiency causes genomic instability and a shorter latency to the development of a BCL6-driven GC B cell lymphoma. In contrast, loss of BER alone is highly protective against B cell transformation while loss of MMR fosters the development of a variety of malignancies. These findings lend insight into a complex interplay between AID-associated BER and MMR pathways that produces a net protective effect against GC B cell lymphomagenesis.

Project description:We show that mismatch-repair (MMR) signature mutations can activate colorectal cancer (CRC)-specific enhancers, through analysis of enhancer DNA associated with the active enhancer histone mark H3K27ac. We demonstrate that MMR mutations activate enhancers using a xenograft metastasis model, where mutations are induced naturally via CRISPR/Cas9 inactivation of MLH1 prior to tumor cell injection.

Project description:MutLα, a heterodimer consisting of MLH1 and PMS2, is a key player of DNA mismatch repair (MMR), yet little is known about its regulation. In this study, we used mass spectrometry to identify phosphorylated residues within MLH1 and PMS2. The most frequently detected phosphorylated amino acid was serine 477 of MLH1. Isolation of nuclear and cytoplasmic fractions showed that p-MLH1S477 remains predominantly in the cytoplasm. Pharmacological treatment indicates that Casein Kinase II (CK2) could be responsible for the phosphorylation of MLH1 at serine 477 in vivo. In vitro kinase assay verified MLH1 as a substrate of CK2. Most importantly, using in vitro MMR assay we could demonstrate that p-MLH1S477 lost MMR activity while the activity of MLH1S477A, which could not be phosphorylated at position S477, was not modified. In summary, we identified that post-translational phosphorylation of MLH1 by CK2 at amino acid position 477 can switch off MMR activity in vitro. Since CK2 is overexpressed in many tumors and is able to inactivate MMR by phosphorylation of MLH1, the new mechanism here described could have an important impact on tumors overactive in CK2.

Project description:Somatic hypermutation (SHM) and class switch recombination (CSR) of immunoglobulin (Ig) genes are genomic modification events that occur in germinal center (GC) B cells and are initiated through deamination of cytidine to uracil by activation induced cytidine deaminase (AID). Resulting uracil-guanine (U-G) mismatches are subsequently processed by low-fidelity base-excision (BER) and mismatch repair (MMR) pathways to yield mutations and DNA strand lesions. Although off-target AID activity also contributes to oncogenic point mutations and chromosome translocations associated with B cell lymphomas, the role of downstream AID-associated DNA repair pathways in the pathogenesis of these lymphomas is unknown. Here, we show that simultaneous BER and MMR deficiency causes genomic instability and a shorter latency to the development of a BCL6-driven GC B cell lymphoma. In contrast, loss of BER alone is highly protective against B cell transformation while loss of MMR fosters the development of a variety of malignancies. These findings lend insight into a complex interplay between AID-associated BER and MMR pathways that produces a net protective effect against GC B cell lymphomagenesis. Representative B cell lymphomas from 3 IµHABcl6, 6 IµHABcl6 Ung-/- Msh2-/-, and 5 IµHABcl6 Msh2-/- mice were analyzed in this study. Total RNA was extracted from frozen tumor cells and processed according to Illumina standard protocols.

Project description:Biases of DNA repair can shape the nucleotide landscape of genomes at evolutionary timescales. However, such biases have not yet been measured in chromatin for lack of technologies. Here we develop a genome-wide assay whereby the same DNA lesion is repaired in different chromatin contexts. We insert thousands of barcoded transposons carrying a reporter of DNA mismatch repair in the genome of mouse embryonic stem cells. Upon inducing a double-strand break between tandem repeats, a mismatch is generated when the single strand annealing repair pathway is used. Surprisingly, the mismatch repair machinery favors the same strand 60-80% of the time. The location of the lesion in the genome and the type of mismatch have little influence on the repair bias in this context.